mox/store/account.go

2666 lines
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2023-01-30 16:27:06 +03:00
/*
Package store implements storage for accounts, their mailboxes, IMAP
subscriptions and messages, and broadcasts updates (e.g. mail delivery) to
interested sessions (e.g. IMAP connections).
Layout of storage for accounts:
<DataDir>/accounts/<name>/index.db
<DataDir>/accounts/<name>/msg/[a-zA-Z0-9_-]+/<id>
Index.db holds tables for user information, mailboxes, and messages. Messages
are stored in the msg/ subdirectory, each in their own file. The on-disk message
does not contain headers generated during an incoming SMTP transaction, such as
Received and Authentication-Results headers. Those are in the database to
prevent having to rewrite incoming messages (e.g. Authentication-Result for DKIM
signatures can only be determined after having read the message). Messages must
be read through MsgReader, which transparently adds the prefix from the
database.
*/
package store
// todo: make up a function naming scheme that indicates whether caller should broadcast changes.
import (
"context"
"crypto/md5"
cryptorand "crypto/rand"
"crypto/sha1"
"crypto/sha256"
"encoding"
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"encoding/json"
"errors"
"fmt"
"hash"
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"io"
"log/slog"
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"os"
"path/filepath"
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
"runtime/debug"
"slices"
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
"sort"
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
"strconv"
2023-01-30 16:27:06 +03:00
"strings"
"sync"
"time"
"golang.org/x/crypto/bcrypt"
"golang.org/x/text/secure/precis"
2023-01-30 16:27:06 +03:00
"golang.org/x/text/unicode/norm"
"github.com/mjl-/bstore"
"github.com/mjl-/mox/config"
"github.com/mjl-/mox/dns"
"github.com/mjl-/mox/message"
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
"github.com/mjl-/mox/metrics"
2023-01-30 16:27:06 +03:00
"github.com/mjl-/mox/mlog"
"github.com/mjl-/mox/mox-"
"github.com/mjl-/mox/moxio"
"github.com/mjl-/mox/publicsuffix"
"github.com/mjl-/mox/scram"
"github.com/mjl-/mox/smtp"
)
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// If true, each time an account is closed its database file is checked for
// consistency. If an inconsistency is found, panic is called. Set by default
// because of all the packages with tests, the mox main function sets it to
// false again.
var CheckConsistencyOnClose = true
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var (
ErrUnknownMailbox = errors.New("no such mailbox")
ErrUnknownCredentials = errors.New("credentials not found")
ErrAccountUnknown = errors.New("no such account")
ErrOverQuota = errors.New("account over quota")
2023-01-30 16:27:06 +03:00
)
var DefaultInitialMailboxes = config.InitialMailboxes{
SpecialUse: config.SpecialUseMailboxes{
Sent: "Sent",
Archive: "Archive",
Trash: "Trash",
Draft: "Drafts",
Junk: "Junk",
},
}
2023-01-30 16:27:06 +03:00
type SCRAM struct {
Salt []byte
Iterations int
SaltedPassword []byte
}
// CRAMMD5 holds HMAC ipad and opad hashes that are initialized with the first
// block with (a derivation of) the key/password, so we don't store the password in plain
// text.
type CRAMMD5 struct {
Ipad hash.Hash
Opad hash.Hash
}
// BinaryMarshal is used by bstore to store the ipad/opad hash states.
func (c CRAMMD5) MarshalBinary() ([]byte, error) {
if c.Ipad == nil || c.Opad == nil {
return nil, nil
}
ipad, err := c.Ipad.(encoding.BinaryMarshaler).MarshalBinary()
if err != nil {
return nil, fmt.Errorf("marshal ipad: %v", err)
}
opad, err := c.Opad.(encoding.BinaryMarshaler).MarshalBinary()
if err != nil {
return nil, fmt.Errorf("marshal opad: %v", err)
}
buf := make([]byte, 2+len(ipad)+len(opad))
ipadlen := uint16(len(ipad))
buf[0] = byte(ipadlen >> 8)
buf[1] = byte(ipadlen >> 0)
copy(buf[2:], ipad)
copy(buf[2+len(ipad):], opad)
return buf, nil
}
// BinaryUnmarshal is used by bstore to restore the ipad/opad hash states.
func (c *CRAMMD5) UnmarshalBinary(buf []byte) error {
if len(buf) == 0 {
*c = CRAMMD5{}
return nil
}
if len(buf) < 2 {
return fmt.Errorf("short buffer")
}
ipadlen := int(uint16(buf[0])<<8 | uint16(buf[1])<<0)
if len(buf) < 2+ipadlen {
return fmt.Errorf("buffer too short for ipadlen")
}
ipad := md5.New()
opad := md5.New()
if err := ipad.(encoding.BinaryUnmarshaler).UnmarshalBinary(buf[2 : 2+ipadlen]); err != nil {
return fmt.Errorf("unmarshal ipad: %v", err)
}
if err := opad.(encoding.BinaryUnmarshaler).UnmarshalBinary(buf[2+ipadlen:]); err != nil {
return fmt.Errorf("unmarshal opad: %v", err)
}
*c = CRAMMD5{ipad, opad}
return nil
}
// Password holds credentials in various forms, for logging in with SMTP/IMAP.
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type Password struct {
Hash string // bcrypt hash for IMAP LOGIN, SASL PLAIN and HTTP basic authentication.
CRAMMD5 CRAMMD5 // For SASL CRAM-MD5.
SCRAMSHA1 SCRAM // For SASL SCRAM-SHA-1.
SCRAMSHA256 SCRAM // For SASL SCRAM-SHA-256.
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}
// Subjectpass holds the secret key used to sign subjectpass tokens.
type Subjectpass struct {
Email string // Our destination address (canonical, with catchall localpart stripped).
Key string
}
// NextUIDValidity is a singleton record in the database with the next UIDValidity
// to use for the next mailbox.
type NextUIDValidity struct {
ID int // Just a single record with ID 1.
Next uint32
}
// SyncState track ModSeqs.
type SyncState struct {
ID int // Just a single record with ID 1.
// Last used, next assigned will be one higher. The first value we hand out is 2.
// That's because 0 (the default value for old existing messages, from before the
// Message.ModSeq field) is special in IMAP, so we return it as 1.
LastModSeq ModSeq `bstore:"nonzero"`
// Highest ModSeq of expunged record that we deleted. When a clients synchronizes
// and requests changes based on a modseq before this one, we don't have the
// history to provide information about deletions. We normally keep these expunged
// records around, but we may periodically truly delete them to reclaim storage
// space. Initially set to -1 because we don't want to match with any ModSeq in the
// database, which can be zero values.
HighestDeletedModSeq ModSeq
}
2023-01-30 16:27:06 +03:00
// Mailbox is collection of messages, e.g. Inbox or Sent.
type Mailbox struct {
ID int64
// "Inbox" is the name for the special IMAP "INBOX". Slash separated
// for hierarchy.
Name string `bstore:"nonzero,unique"`
// If UIDs are invalidated, e.g. when renaming a mailbox to a previously existing
// name, UIDValidity must be changed. Used by IMAP for synchronization.
UIDValidity uint32
// UID likely to be assigned to next message. Used by IMAP to detect messages
// delivered to a mailbox.
UIDNext UID
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
SpecialUse
// Keywords as used in messages. Storing a non-system keyword for a message
// automatically adds it to this list. Used in the IMAP FLAGS response. Only
// "atoms" are allowed (IMAP syntax), keywords are case-insensitive, only stored in
// lower case (for JMAP), sorted.
Keywords []string
HaveCounts bool // Whether MailboxCounts have been initialized.
MailboxCounts // Statistics about messages, kept up to date whenever a change happens.
}
// MailboxCounts tracks statistics about messages for a mailbox.
type MailboxCounts struct {
Total int64 // Total number of messages, excluding \Deleted. For JMAP.
Deleted int64 // Number of messages with \Deleted flag. Used for IMAP message count that includes messages with \Deleted.
Unread int64 // Messages without \Seen, excluding those with \Deleted, for JMAP.
Unseen int64 // Messages without \Seen, including those with \Deleted, for IMAP.
Size int64 // Number of bytes for all messages.
}
func (mc MailboxCounts) String() string {
return fmt.Sprintf("%d total, %d deleted, %d unread, %d unseen, size %d bytes", mc.Total, mc.Deleted, mc.Unread, mc.Unseen, mc.Size)
}
// Add increases mailbox counts mc with those of delta.
func (mc *MailboxCounts) Add(delta MailboxCounts) {
mc.Total += delta.Total
mc.Deleted += delta.Deleted
mc.Unread += delta.Unread
mc.Unseen += delta.Unseen
mc.Size += delta.Size
}
// Add decreases mailbox counts mc with those of delta.
func (mc *MailboxCounts) Sub(delta MailboxCounts) {
mc.Total -= delta.Total
mc.Deleted -= delta.Deleted
mc.Unread -= delta.Unread
mc.Unseen -= delta.Unseen
mc.Size -= delta.Size
}
// SpecialUse identifies a specific role for a mailbox, used by clients to
// understand where messages should go.
type SpecialUse struct {
2023-01-30 16:27:06 +03:00
Archive bool
Draft bool
Junk bool
Sent bool
Trash bool
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// CalculateCounts calculates the full current counts for messages in the mailbox.
func (mb *Mailbox) CalculateCounts(tx *bstore.Tx) (mc MailboxCounts, err error) {
q := bstore.QueryTx[Message](tx)
q.FilterNonzero(Message{MailboxID: mb.ID})
q.FilterEqual("Expunged", false)
err = q.ForEach(func(m Message) error {
mc.Add(m.MailboxCounts())
return nil
})
return
}
// ChangeSpecialUse returns a change for special-use flags, for broadcasting to
// other connections.
func (mb Mailbox) ChangeSpecialUse() ChangeMailboxSpecialUse {
return ChangeMailboxSpecialUse{mb.ID, mb.Name, mb.SpecialUse}
}
// ChangeKeywords returns a change with new keywords for a mailbox (e.g. after
// setting a new keyword on a message in the mailbox), for broadcasting to other
// connections.
func (mb Mailbox) ChangeKeywords() ChangeMailboxKeywords {
return ChangeMailboxKeywords{mb.ID, mb.Name, mb.Keywords}
}
// KeywordsChanged returns whether the keywords in a mailbox have changed.
func (mb Mailbox) KeywordsChanged(origmb Mailbox) bool {
if len(mb.Keywords) != len(origmb.Keywords) {
return true
}
// Keywords are stored sorted.
for i, kw := range mb.Keywords {
if origmb.Keywords[i] != kw {
return true
}
}
return false
}
// CountsChange returns a change with mailbox counts.
func (mb Mailbox) ChangeCounts() ChangeMailboxCounts {
return ChangeMailboxCounts{mb.ID, mb.Name, mb.MailboxCounts}
2023-01-30 16:27:06 +03:00
}
// Subscriptions are separate from existence of mailboxes.
type Subscription struct {
Name string
}
// Flags for a mail message.
type Flags struct {
Seen bool
Answered bool
Flagged bool
Forwarded bool
Junk bool
Notjunk bool
Deleted bool
Draft bool
Phishing bool
MDNSent bool
}
// FlagsAll is all flags set, for use as mask.
var FlagsAll = Flags{true, true, true, true, true, true, true, true, true, true}
// Validation of "message From" domain.
type Validation uint8
const (
ValidationUnknown Validation = 0
ValidationStrict Validation = 1 // Like DMARC, with strict policies.
ValidationDMARC Validation = 2 // Actual DMARC policy.
ValidationRelaxed Validation = 3 // Like DMARC, with relaxed policies.
ValidationPass Validation = 4 // For SPF.
ValidationNeutral Validation = 5 // For SPF.
ValidationTemperror Validation = 6
ValidationPermerror Validation = 7
ValidationFail Validation = 8
ValidationSoftfail Validation = 9 // For SPF.
ValidationNone Validation = 10 // E.g. No records.
)
// Message stored in database and per-message file on disk.
//
// Contents are always the combined data from MsgPrefix and the on-disk file named
// based on ID.
//
// Messages always have a header section, even if empty. Incoming messages without
// header section must get an empty header section added before inserting.
type Message struct {
// ID, unchanged over lifetime, determines path to on-disk msg file.
// Set during deliver.
ID int64
UID UID `bstore:"nonzero"` // UID, for IMAP. Set during deliver.
MailboxID int64 `bstore:"nonzero,unique MailboxID+UID,index MailboxID+Received,index MailboxID+ModSeq,ref Mailbox"`
// Modification sequence, for faster syncing with IMAP QRESYNC and JMAP.
// ModSeq is the last modification. CreateSeq is the Seq the message was inserted,
// always <= ModSeq. If Expunged is set, the message has been removed and should not
// be returned to the user. In this case, ModSeq is the Seq where the message is
// removed, and will never be changed again.
// We have an index on both ModSeq (for JMAP that synchronizes per account) and
// MailboxID+ModSeq (for IMAP that synchronizes per mailbox).
// The index on CreateSeq helps efficiently finding created messages for JMAP.
// The value of ModSeq is special for IMAP. Messages that existed before ModSeq was
// added have 0 as value. But modseq 0 in IMAP is special, so we return it as 1. If
// we get modseq 1 from a client, the IMAP server will translate it to 0. When we
// return modseq to clients, we turn 0 into 1.
ModSeq ModSeq `bstore:"index"`
CreateSeq ModSeq `bstore:"index"`
Expunged bool
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// If set, this message was delivered to a Rejects mailbox. When it is moved to a
// different mailbox, its MailboxOrigID is set to the destination mailbox and this
// flag cleared.
IsReject bool
// If set, this is a forwarded message (through a ruleset with IsForward). This
// causes fields used during junk analysis to be moved to their Orig variants, and
// masked IP fields cleared, so they aren't used in junk classifications for
// incoming messages. This ensures the forwarded messages don't cause negative
// reputation for the forwarding mail server, which may also be sending regular
// messages.
IsForward bool
// MailboxOrigID is the mailbox the message was originally delivered to. Typically
// Inbox or Rejects, but can also be a mailbox configured in a Ruleset, or
// Postmaster, TLS/DMARC reporting addresses. MailboxOrigID is not changed when the
// message is moved to another mailbox, e.g. Archive/Trash/Junk. Used for
// per-mailbox reputation.
//
// MailboxDestinedID is normally 0, but when a message is delivered to the Rejects
// mailbox, it is set to the intended mailbox according to delivery rules,
// typically that of Inbox. When such a message is moved out of Rejects, the
// MailboxOrigID is corrected by setting it to MailboxDestinedID. This ensures the
// message is used for reputation calculation for future deliveries to that
// mailbox.
//
// These are not bstore references to prevent having to update all messages in a
// mailbox when the original mailbox is removed. Use of these fields requires
// checking if the mailbox still exists.
MailboxOrigID int64
MailboxDestinedID int64
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Received time.Time `bstore:"default now,index"`
// Full IP address of remote SMTP server. Empty if not delivered over SMTP. The
// masked IPs are used to classify incoming messages. They are left empty for
// messages matching a ruleset for forwarded messages.
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RemoteIP string
RemoteIPMasked1 string `bstore:"index RemoteIPMasked1+Received"` // For IPv4 /32, for IPv6 /64, for reputation.
RemoteIPMasked2 string `bstore:"index RemoteIPMasked2+Received"` // For IPv4 /26, for IPv6 /48.
RemoteIPMasked3 string `bstore:"index RemoteIPMasked3+Received"` // For IPv4 /21, for IPv6 /32.
// Only set if present and not an IP address. Unicode string. Empty for forwarded
// messages.
EHLODomain string `bstore:"index EHLODomain+Received"`
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MailFrom string // With localpart and domain. Can be empty.
MailFromLocalpart smtp.Localpart // SMTP "MAIL FROM", can be empty.
// Only set if it is a domain, not an IP. Unicode string. Empty for forwarded
// messages, but see OrigMailFromDomain.
MailFromDomain string `bstore:"index MailFromDomain+Received"`
RcptToLocalpart smtp.Localpart // SMTP "RCPT TO", can be empty.
RcptToDomain string // Unicode string.
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// Parsed "From" message header, used for reputation along with domain validation.
MsgFromLocalpart smtp.Localpart
MsgFromDomain string `bstore:"index MsgFromDomain+Received"` // Unicode string.
MsgFromOrgDomain string `bstore:"index MsgFromOrgDomain+Received"` // Unicode string.
// Simplified statements of the Validation fields below, used for incoming messages
// to check reputation.
EHLOValidated bool
MailFromValidated bool
MsgFromValidated bool
EHLOValidation Validation // Validation can also take reverse IP lookup into account, not only SPF.
MailFromValidation Validation // Can have SPF-specific validations like ValidationSoftfail.
MsgFromValidation Validation // Desirable validations: Strict, DMARC, Relaxed. Will not be just Pass.
// Domains with verified DKIM signatures. Unicode string. For forwarded messages, a
// DKIM domain that matched a ruleset's verified domain is left out, but included
// in OrigDKIMDomains.
DKIMDomains []string `bstore:"index DKIMDomains+Received"`
// For forwarded messages,
OrigEHLODomain string
OrigDKIMDomains []string
2023-01-30 16:27:06 +03:00
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
// Canonicalized Message-Id, always lower-case and normalized quoting, without
// <>'s. Empty if missing. Used for matching message threads, and to prevent
// duplicate reject delivery.
2023-01-30 16:27:06 +03:00
MessageID string `bstore:"index"`
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
// lower-case: ../rfc/5256:495
2023-01-30 16:27:06 +03:00
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
// For matching threads in case there is no References/In-Reply-To header. It is
// lower-cased, white-space collapsed, mailing list tags and re/fwd tags removed.
SubjectBase string `bstore:"index"`
// ../rfc/5256:90
// Hash of message. For rejects delivery in case there is no Message-ID, only set
// when delivered as reject.
MessageHash []byte
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
// ID of message starting this thread.
ThreadID int64 `bstore:"index"`
// IDs of parent messages, from closest parent to the root message. Parent messages
// may be in a different mailbox, or may no longer exist. ThreadParentIDs must
// never contain the message id itself (a cycle), and parent messages must
// reference the same ancestors.
ThreadParentIDs []int64
// ThreadMissingLink is true if there is no match with a direct parent. E.g. first
// ID in ThreadParentIDs is not the direct ancestor (an intermediate message may
// have been deleted), or subject-based matching was done.
ThreadMissingLink bool
// If set, newly delivered child messages are automatically marked as read. This
// field is copied to new child messages. Changes are propagated to the webmail
// client.
ThreadMuted bool
// If set, this (sub)thread is collapsed in the webmail client, for threading mode
// "on" (mode "unread" ignores it). This field is copied to new child message.
// Changes are propagated to the webmail client.
ThreadCollapsed bool
// If received message was known to match a mailing list rule (with modified junk
// filtering).
IsMailingList bool
// If this message is a DSN. For DSNs, we don't look at the subject when matching
// threads.
DSN bool
ReceivedTLSVersion uint16 // 0 if unknown, 1 if plaintext/no TLS, otherwise TLS cipher suite.
ReceivedTLSCipherSuite uint16
ReceivedRequireTLS bool // Whether RequireTLS was known to be used for incoming delivery.
2023-01-30 16:27:06 +03:00
Flags
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// For keywords other than system flags or the basic well-known $-flags. Only in
// "atom" syntax (IMAP), they are case-insensitive, always stored in lower-case
// (for JMAP), sorted.
Keywords []string `bstore:"index"`
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
Size int64
TrainedJunk *bool // If nil, no training done yet. Otherwise, true is trained as junk, false trained as nonjunk.
MsgPrefix []byte // Typically holds received headers and/or header separator.
2023-01-30 16:27:06 +03:00
// ParsedBuf message structure. Currently saved as JSON of message.Part because bstore
// cannot yet store recursive types. Created when first needed, and saved in the
// database.
// todo: once replaced with non-json storage, remove date fixup in ../message/part.go.
2023-01-30 16:27:06 +03:00
ParsedBuf []byte
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// MailboxCounts returns the delta to counts this message means for its
// mailbox.
func (m Message) MailboxCounts() (mc MailboxCounts) {
if m.Expunged {
return
}
if m.Deleted {
mc.Deleted++
} else {
mc.Total++
}
if !m.Seen {
mc.Unseen++
if !m.Deleted {
mc.Unread++
}
}
mc.Size += m.Size
return
}
func (m Message) ChangeAddUID() ChangeAddUID {
return ChangeAddUID{m.MailboxID, m.UID, m.ModSeq, m.Flags, m.Keywords}
}
func (m Message) ChangeFlags(orig Flags) ChangeFlags {
mask := m.Flags.Changed(orig)
return ChangeFlags{MailboxID: m.MailboxID, UID: m.UID, ModSeq: m.ModSeq, Mask: mask, Flags: m.Flags, Keywords: m.Keywords}
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
func (m Message) ChangeThread() ChangeThread {
return ChangeThread{[]int64{m.ID}, m.ThreadMuted, m.ThreadCollapsed}
}
// ModSeq represents a modseq as stored in the database. ModSeq 0 in the
// database is sent to the client as 1, because modseq 0 is special in IMAP.
// ModSeq coming from the client are of type int64.
type ModSeq int64
func (ms ModSeq) Client() int64 {
if ms == 0 {
return 1
}
return int64(ms)
}
// ModSeqFromClient converts a modseq from a client to a modseq for internal
// use, e.g. in a database query.
// ModSeq 1 is turned into 0 (the Go zero value for ModSeq).
func ModSeqFromClient(modseq int64) ModSeq {
if modseq == 1 {
return 0
}
return ModSeq(modseq)
}
// PrepareExpunge clears fields that are no longer needed after an expunge, so
// almost all fields. Does not change ModSeq, but does set Expunged.
func (m *Message) PrepareExpunge() {
*m = Message{
ID: m.ID,
UID: m.UID,
MailboxID: m.MailboxID,
CreateSeq: m.CreateSeq,
ModSeq: m.ModSeq,
Expunged: true,
ThreadID: m.ThreadID,
}
}
// PrepareThreading sets MessageID, SubjectBase and DSN (used in threading) based
// on the part.
func (m *Message) PrepareThreading(log mlog.Log, part *message.Part) {
m.DSN = part.IsDSN()
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if part.Envelope == nil {
return
}
messageID, raw, err := message.MessageIDCanonical(part.Envelope.MessageID)
if err != nil {
log.Debugx("parsing message-id, ignoring", err, slog.String("messageid", part.Envelope.MessageID))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
} else if raw {
log.Debug("could not parse message-id as address, continuing with raw value", slog.String("messageid", part.Envelope.MessageID))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
}
m.MessageID = messageID
m.SubjectBase, _ = message.ThreadSubject(part.Envelope.Subject, false)
}
2023-01-30 16:27:06 +03:00
// LoadPart returns a message.Part by reading from m.ParsedBuf.
func (m Message) LoadPart(r io.ReaderAt) (message.Part, error) {
if m.ParsedBuf == nil {
return message.Part{}, fmt.Errorf("message not parsed")
}
var p message.Part
err := json.Unmarshal(m.ParsedBuf, &p)
if err != nil {
return p, fmt.Errorf("unmarshal message part")
}
p.SetReaderAt(r)
return p, nil
}
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
// NeedsTraining returns whether message needs a training update, based on
// TrainedJunk (current training status) and new Junk/Notjunk flags.
func (m Message) NeedsTraining() bool {
untrain := m.TrainedJunk != nil
untrainJunk := untrain && *m.TrainedJunk
train := m.Junk || m.Notjunk && !(m.Junk && m.Notjunk)
trainJunk := m.Junk
return untrain != train || untrain && train && untrainJunk != trainJunk
}
// JunkFlagsForMailbox sets Junk and Notjunk flags based on mailbox name if configured. Often
// used when delivering/moving/copying messages to a mailbox. Mail clients are not
// very helpful with setting junk/notjunk flags. But clients can move/copy messages
// to other mailboxes. So we set flags when clients move a message.
func (m *Message) JunkFlagsForMailbox(mb Mailbox, conf config.Account) {
if mb.Junk {
m.Junk = true
m.Notjunk = false
return
}
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
if !conf.AutomaticJunkFlags.Enabled {
return
}
lmailbox := strings.ToLower(mb.Name)
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
if conf.JunkMailbox != nil && conf.JunkMailbox.MatchString(lmailbox) {
m.Junk = true
m.Notjunk = false
} else if conf.NeutralMailbox != nil && conf.NeutralMailbox.MatchString(lmailbox) {
m.Junk = false
m.Notjunk = false
} else if conf.NotJunkMailbox != nil && conf.NotJunkMailbox.MatchString(lmailbox) {
m.Junk = false
m.Notjunk = true
} else if conf.JunkMailbox == nil && conf.NeutralMailbox != nil && conf.NotJunkMailbox != nil {
m.Junk = true
m.Notjunk = false
} else if conf.JunkMailbox != nil && conf.NeutralMailbox == nil && conf.NotJunkMailbox != nil {
m.Junk = false
m.Notjunk = false
} else if conf.JunkMailbox != nil && conf.NeutralMailbox != nil && conf.NotJunkMailbox == nil {
m.Junk = false
m.Notjunk = true
}
}
2023-01-30 16:27:06 +03:00
// Recipient represents the recipient of a message. It is tracked to allow
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// first-time incoming replies from users this account has sent messages to. When a
// mailbox is added to the Sent mailbox the message is parsed and recipients are
// inserted as recipient. Recipients are never removed other than for removing the
// message. On move/copy of a message, recipients aren't modified either. For IMAP,
// this assumes a client simply appends messages to the Sent mailbox (as opposed to
// copying messages from some place).
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type Recipient struct {
ID int64
MessageID int64 `bstore:"nonzero,ref Message"` // Ref gives it its own index, useful for fast removal as well.
Localpart string `bstore:"nonzero"` // Encoded localpart.
Domain string `bstore:"nonzero,index Domain+Localpart"` // Unicode string.
OrgDomain string `bstore:"nonzero,index"` // Unicode string.
Sent time.Time `bstore:"nonzero"`
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}
// Outgoing is a message submitted for delivery from the queue. Used to enforce
// maximum outgoing messages.
type Outgoing struct {
ID int64
Recipient string `bstore:"nonzero,index"` // Canonical international address with utf8 domain.
Submitted time.Time `bstore:"nonzero,default now"`
}
implement "requiretls", rfc 8689 with requiretls, the tls verification mode/rules for email deliveries can be changed by the sender/submitter. in two ways: 1. "requiretls" smtp extension to always enforce verified tls (with mta-sts or dnssec+dane), along the entire delivery path until delivery into the final destination mailbox (so entire transport is verified-tls-protected). 2. "tls-required: no" message header, to ignore any tls and tls verification errors even if the recipient domain has a policy that requires tls verification (mta-sts and/or dnssec+dane), allowing delivery of non-sensitive messages in case of misconfiguration/interoperability issues (at least useful for sending tls reports). we enable requiretls by default (only when tls is active), for smtp and submission. it can be disabled through the config. for each delivery attempt, we now store (per recipient domain, in the account of the sender) whether the smtp server supports starttls and requiretls. this support is shown (after having sent a first message) in the webmail when sending a message (the previous 3 bars under the address input field are now 5 bars, the first for starttls support, the last for requiretls support). when all recipient domains for a message are known to implement requiretls, requiretls is automatically selected for sending (instead of "default" tls behaviour). users can also select the "fallback to insecure" to add the "tls-required: no" header. new metrics are added for insight into requiretls errors and (some, not yet all) cases where tls-required-no ignored a tls/verification error. the admin can change the requiretls status for messages in the queue. so with default delivery attempts, when verified tls is required by failing, an admin could potentially change the field to "tls-required: no"-behaviour. messages received (over smtp) with the requiretls option, get a comment added to their Received header line, just before "id", after "with".
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// RecipientDomainTLS stores TLS capabilities of a recipient domain as encountered
// during most recent connection (delivery attempt).
type RecipientDomainTLS struct {
Domain string // Unicode.
Updated time.Time `bstore:"default now"`
STARTTLS bool // Supports STARTTLS.
RequireTLS bool // Supports RequireTLS SMTP extension.
}
// DiskUsage tracks quota use.
type DiskUsage struct {
ID int64 // Always one record with ID 1.
MessageSize int64 // Sum of all messages, for quota accounting.
}
replace http basic auth for web interfaces with session cookie & csrf-based auth the http basic auth we had was very simple to reason about, and to implement. but it has a major downside: there is no way to logout, browsers keep sending credentials. ideally, browsers themselves would show a button to stop sending credentials. a related downside: the http auth mechanism doesn't indicate for which server paths the credentials are. another downside: the original password is sent to the server with each request. though sending original passwords to web servers seems to be considered normal. our new approach uses session cookies, along with csrf values when we can. the sessions are server-side managed, automatically extended on each use. this makes it easy to invalidate sessions and keeps the frontend simpler (than with long- vs short-term sessions and refreshing). the cookies are httponly, samesite=strict, scoped to the path of the web interface. cookies are set "secure" when set over https. the cookie is set by a successful call to Login. a call to Logout invalidates a session. changing a password invalidates all sessions for a user, but keeps the session with which the password was changed alive. the csrf value is also random, and associated with the session cookie. the csrf must be sent as header for api calls, or as parameter for direct form posts (where we cannot set a custom header). rest-like calls made directly by the browser, e.g. for images, don't have a csrf protection. the csrf value is returned by the Login api call and stored in localstorage. api calls without credentials return code "user:noAuth", and with bad credentials return "user:badAuth". the api client recognizes this and triggers a login. after a login, all auth-failed api calls are automatically retried. only for "user:badAuth" is an error message displayed in the login form (e.g. session expired). in an ideal world, browsers would take care of most session management. a server would indicate authentication is needed (like http basic auth), and the browsers uses trusted ui to request credentials for the server & path. the browser could use safer mechanism than sending original passwords to the server, such as scram, along with a standard way to create sessions. for now, web developers have to do authentication themselves: from showing the login prompt, ensuring the right session/csrf cookies/localstorage/headers/etc are sent with each request. webauthn is a newer way to do authentication, perhaps we'll implement it in the future. though hardware tokens aren't an attractive option for many users, and it may be overkill as long as we still do old-fashioned authentication in smtp & imap where passwords can be sent to the server. for issue #58
2024-01-04 15:10:48 +03:00
// SessionToken and CSRFToken are types to prevent mixing them up.
// Base64 raw url encoded.
type SessionToken string
type CSRFToken string
// LoginSession represents a login session. We keep a limited number of sessions
// for a user, removing the oldest session when a new one is created.
type LoginSession struct {
ID int64
Created time.Time `bstore:"nonzero,default now"` // Of original login.
Expires time.Time `bstore:"nonzero"` // Extended each time it is used.
SessionTokenBinary [16]byte `bstore:"nonzero"` // Stored in cookie, like "webmailsession" or "webaccountsession".
CSRFTokenBinary [16]byte // For API requests, in "x-mox-csrf" header.
AccountName string `bstore:"nonzero"`
LoginAddress string `bstore:"nonzero"`
// Set when loading from database.
sessionToken SessionToken
csrfToken CSRFToken
}
// Types stored in DB.
replace http basic auth for web interfaces with session cookie & csrf-based auth the http basic auth we had was very simple to reason about, and to implement. but it has a major downside: there is no way to logout, browsers keep sending credentials. ideally, browsers themselves would show a button to stop sending credentials. a related downside: the http auth mechanism doesn't indicate for which server paths the credentials are. another downside: the original password is sent to the server with each request. though sending original passwords to web servers seems to be considered normal. our new approach uses session cookies, along with csrf values when we can. the sessions are server-side managed, automatically extended on each use. this makes it easy to invalidate sessions and keeps the frontend simpler (than with long- vs short-term sessions and refreshing). the cookies are httponly, samesite=strict, scoped to the path of the web interface. cookies are set "secure" when set over https. the cookie is set by a successful call to Login. a call to Logout invalidates a session. changing a password invalidates all sessions for a user, but keeps the session with which the password was changed alive. the csrf value is also random, and associated with the session cookie. the csrf must be sent as header for api calls, or as parameter for direct form posts (where we cannot set a custom header). rest-like calls made directly by the browser, e.g. for images, don't have a csrf protection. the csrf value is returned by the Login api call and stored in localstorage. api calls without credentials return code "user:noAuth", and with bad credentials return "user:badAuth". the api client recognizes this and triggers a login. after a login, all auth-failed api calls are automatically retried. only for "user:badAuth" is an error message displayed in the login form (e.g. session expired). in an ideal world, browsers would take care of most session management. a server would indicate authentication is needed (like http basic auth), and the browsers uses trusted ui to request credentials for the server & path. the browser could use safer mechanism than sending original passwords to the server, such as scram, along with a standard way to create sessions. for now, web developers have to do authentication themselves: from showing the login prompt, ensuring the right session/csrf cookies/localstorage/headers/etc are sent with each request. webauthn is a newer way to do authentication, perhaps we'll implement it in the future. though hardware tokens aren't an attractive option for many users, and it may be overkill as long as we still do old-fashioned authentication in smtp & imap where passwords can be sent to the server. for issue #58
2024-01-04 15:10:48 +03:00
var DBTypes = []any{NextUIDValidity{}, Message{}, Recipient{}, Mailbox{}, Subscription{}, Outgoing{}, Password{}, Subjectpass{}, SyncState{}, Upgrade{}, RecipientDomainTLS{}, DiskUsage{}, LoginSession{}}
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// Account holds the information about a user, includings mailboxes, messages, imap subscriptions.
type Account struct {
Name string // Name, according to configuration.
Dir string // Directory where account files, including the database, bloom filter, and mail messages, are stored for this account.
DBPath string // Path to database with mailboxes, messages, etc.
DB *bstore.DB // Open database connection.
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
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// Channel that is closed if/when account has/gets "threads" accounting (see
// Upgrade.Threads).
threadsCompleted chan struct{}
// If threads upgrade completed with error, this is set. Used for warning during
// delivery, or aborting when importing.
threadsErr error
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// Write lock must be held for account/mailbox modifications including message delivery.
// Read lock for reading mailboxes/messages.
// When making changes to mailboxes/messages, changes must be broadcasted before
// releasing the lock to ensure proper UID ordering.
sync.RWMutex
nused int // Reference count, while >0, this account is alive and shared.
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
type Upgrade struct {
ID byte
Threads byte // 0: None, 1: Adding MessageID's completed, 2: Adding ThreadID's completed.
}
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// InitialUIDValidity returns a UIDValidity used for initializing an account.
// It can be replaced during tests with a predictable value.
var InitialUIDValidity = func() uint32 {
return uint32(time.Now().Unix() >> 1) // A 2-second resolution will get us far enough beyond 2038.
}
var openAccounts = struct {
names map[string]*Account
sync.Mutex
}{
names: map[string]*Account{},
}
func closeAccount(acc *Account) (rerr error) {
openAccounts.Lock()
acc.nused--
defer openAccounts.Unlock()
if acc.nused == 0 {
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
// threadsCompleted must be closed now because it increased nused.
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rerr = acc.DB.Close()
acc.DB = nil
delete(openAccounts.names, acc.Name)
}
return
}
// OpenAccount opens an account by name.
//
// No additional data path prefix or ".db" suffix should be added to the name.
// A single shared account exists per name.
func OpenAccount(log mlog.Log, name string) (*Account, error) {
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openAccounts.Lock()
defer openAccounts.Unlock()
if acc, ok := openAccounts.names[name]; ok {
acc.nused++
return acc, nil
}
if _, ok := mox.Conf.Account(name); !ok {
return nil, ErrAccountUnknown
}
acc, err := openAccount(log, name)
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if err != nil {
return nil, err
}
openAccounts.names[name] = acc
return acc, nil
}
// openAccount opens an existing account, or creates it if it is missing.
func openAccount(log mlog.Log, name string) (a *Account, rerr error) {
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dir := filepath.Join(mox.DataDirPath("accounts"), name)
return OpenAccountDB(log, dir, name)
}
// OpenAccountDB opens an account database file and returns an initialized account
// or error. Only exported for use by subcommands that verify the database file.
// Almost all account opens must go through OpenAccount/OpenEmail/OpenEmailAuth.
func OpenAccountDB(log mlog.Log, accountDir, accountName string) (a *Account, rerr error) {
dbpath := filepath.Join(accountDir, "index.db")
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// Create account if it doesn't exist yet.
isNew := false
if _, err := os.Stat(dbpath); err != nil && os.IsNotExist(err) {
isNew = true
os.MkdirAll(accountDir, 0770)
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}
db, err := bstore.Open(context.TODO(), dbpath, &bstore.Options{Timeout: 5 * time.Second, Perm: 0660}, DBTypes...)
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if err != nil {
return nil, err
}
defer func() {
if rerr != nil {
db.Close()
if isNew {
os.Remove(dbpath)
}
}
}()
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
acc := &Account{
Name: accountName,
Dir: accountDir,
DBPath: dbpath,
DB: db,
nused: 1,
threadsCompleted: make(chan struct{}),
}
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if isNew {
if err := initAccount(db); err != nil {
return nil, fmt.Errorf("initializing account: %v", err)
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
close(acc.threadsCompleted)
return acc, nil
}
// Ensure mailbox counts and total message size are set.
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
var mentioned bool
err = db.Write(context.TODO(), func(tx *bstore.Tx) error {
err := bstore.QueryTx[Mailbox](tx).FilterEqual("HaveCounts", false).ForEach(func(mb Mailbox) error {
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if !mentioned {
mentioned = true
log.Info("first calculation of mailbox counts for account", slog.String("account", accountName))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
}
mc, err := mb.CalculateCounts(tx)
if err != nil {
return err
}
mb.HaveCounts = true
mb.MailboxCounts = mc
return tx.Update(&mb)
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
})
if err != nil {
return err
}
du := DiskUsage{ID: 1}
err = tx.Get(&du)
if err == nil || !errors.Is(err, bstore.ErrAbsent) {
return err
}
// No DiskUsage record yet, calculate total size and insert.
err = bstore.QueryTx[Mailbox](tx).ForEach(func(mb Mailbox) error {
du.MessageSize += mb.Size
return nil
})
if err != nil {
return err
}
return tx.Insert(&du)
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
})
if err != nil {
return nil, fmt.Errorf("calculating counts for mailbox: %v", err)
}
// Start adding threading if needed.
up := Upgrade{ID: 1}
err = db.Write(context.TODO(), func(tx *bstore.Tx) error {
err := tx.Get(&up)
if err == bstore.ErrAbsent {
if err := tx.Insert(&up); err != nil {
return fmt.Errorf("inserting initial upgrade record: %v", err)
}
err = nil
}
return err
})
if err != nil {
return nil, fmt.Errorf("checking message threading: %v", err)
}
if up.Threads == 2 {
close(acc.threadsCompleted)
return acc, nil
}
// Increase account use before holding on to account in background.
// Caller holds the lock. The goroutine below decreases nused by calling
// closeAccount.
acc.nused++
// Ensure all messages have a MessageID and SubjectBase, which are needed when
// matching threads.
// Then assign messages to threads, in the same way we do during imports.
log.Info("upgrading account for threading, in background", slog.String("account", acc.Name))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
go func() {
defer func() {
err := closeAccount(acc)
log.Check(err, "closing use of account after upgrading account storage for threads", slog.String("account", a.Name))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
}()
defer func() {
x := recover() // Should not happen, but don't take program down if it does.
if x != nil {
log.Error("upgradeThreads panic", slog.Any("err", x))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
debug.PrintStack()
metrics.PanicInc(metrics.Upgradethreads)
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
acc.threadsErr = fmt.Errorf("panic during upgradeThreads: %v", x)
}
// Mark that upgrade has finished, possibly error is indicated in threadsErr.
close(acc.threadsCompleted)
}()
err := upgradeThreads(mox.Shutdown, log, acc, &up)
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if err != nil {
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
a.threadsErr = err
log.Errorx("upgrading account for threading, aborted", err, slog.String("account", a.Name))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
} else {
log.Info("upgrading account for threading, completed", slog.String("account", a.Name))
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
}()
return acc, nil
}
// ThreadingWait blocks until the one-time account threading upgrade for the
// account has completed, and returns an error if not successful.
//
// To be used before starting an import of messages.
func (a *Account) ThreadingWait(log mlog.Log) error {
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
select {
case <-a.threadsCompleted:
return a.threadsErr
default:
2023-01-30 16:27:06 +03:00
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
log.Debug("waiting for account upgrade to complete")
2023-01-30 16:27:06 +03:00
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
<-a.threadsCompleted
return a.threadsErr
2023-01-30 16:27:06 +03:00
}
func initAccount(db *bstore.DB) error {
return db.Write(context.TODO(), func(tx *bstore.Tx) error {
2023-01-30 16:27:06 +03:00
uidvalidity := InitialUIDValidity()
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if err := tx.Insert(&Upgrade{ID: 1, Threads: 2}); err != nil {
return err
}
if err := tx.Insert(&DiskUsage{ID: 1}); err != nil {
return err
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if len(mox.Conf.Static.DefaultMailboxes) > 0 {
// Deprecated in favor of InitialMailboxes.
defaultMailboxes := mox.Conf.Static.DefaultMailboxes
mailboxes := []string{"Inbox"}
2023-01-30 16:27:06 +03:00
for _, name := range defaultMailboxes {
if strings.EqualFold(name, "Inbox") {
continue
}
mailboxes = append(mailboxes, name)
}
for _, name := range mailboxes {
mb := Mailbox{Name: name, UIDValidity: uidvalidity, UIDNext: 1, HaveCounts: true}
if strings.HasPrefix(name, "Archive") {
mb.Archive = true
} else if strings.HasPrefix(name, "Drafts") {
mb.Draft = true
} else if strings.HasPrefix(name, "Junk") {
mb.Junk = true
} else if strings.HasPrefix(name, "Sent") {
mb.Sent = true
} else if strings.HasPrefix(name, "Trash") {
mb.Trash = true
}
if err := tx.Insert(&mb); err != nil {
return fmt.Errorf("creating mailbox: %w", err)
}
if err := tx.Insert(&Subscription{name}); err != nil {
return fmt.Errorf("adding subscription: %w", err)
}
2023-01-30 16:27:06 +03:00
}
} else {
mailboxes := mox.Conf.Static.InitialMailboxes
var zerouse config.SpecialUseMailboxes
if mailboxes.SpecialUse == zerouse && len(mailboxes.Regular) == 0 {
mailboxes = DefaultInitialMailboxes
2023-01-30 16:27:06 +03:00
}
add := func(name string, use SpecialUse) error {
mb := Mailbox{Name: name, UIDValidity: uidvalidity, UIDNext: 1, SpecialUse: use, HaveCounts: true}
if err := tx.Insert(&mb); err != nil {
return fmt.Errorf("creating mailbox: %w", err)
}
if err := tx.Insert(&Subscription{name}); err != nil {
return fmt.Errorf("adding subscription: %w", err)
}
return nil
}
addSpecialOpt := func(nameOpt string, use SpecialUse) error {
if nameOpt == "" {
return nil
}
return add(nameOpt, use)
}
l := []struct {
nameOpt string
use SpecialUse
}{
{"Inbox", SpecialUse{}},
{mailboxes.SpecialUse.Archive, SpecialUse{Archive: true}},
{mailboxes.SpecialUse.Draft, SpecialUse{Draft: true}},
{mailboxes.SpecialUse.Junk, SpecialUse{Junk: true}},
{mailboxes.SpecialUse.Sent, SpecialUse{Sent: true}},
{mailboxes.SpecialUse.Trash, SpecialUse{Trash: true}},
}
for _, e := range l {
if err := addSpecialOpt(e.nameOpt, e.use); err != nil {
return err
}
}
for _, name := range mailboxes.Regular {
if err := add(name, SpecialUse{}); err != nil {
return err
}
2023-01-30 16:27:06 +03:00
}
}
uidvalidity++
if err := tx.Insert(&NextUIDValidity{1, uidvalidity}); err != nil {
return fmt.Errorf("inserting nextuidvalidity: %w", err)
}
return nil
})
}
// Close reduces the reference count, and closes the database connection when
// it was the last user.
func (a *Account) Close() error {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if CheckConsistencyOnClose {
xerr := a.CheckConsistency()
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
err := closeAccount(a)
if xerr != nil {
panic(xerr)
}
return err
}
2023-01-30 16:27:06 +03:00
return closeAccount(a)
}
// CheckConsistency checks the consistency of the database and returns a non-nil
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// error for these cases:
//
// - Missing on-disk file for message.
// - Mismatch between message size and length of MsgPrefix and on-disk file.
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// - Missing HaveCounts.
// - Incorrect mailbox counts.
// - Incorrect total message size.
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// - Message with UID >= mailbox uid next.
// - Mailbox uidvalidity >= account uid validity.
// - ModSeq > 0, CreateSeq > 0, CreateSeq <= ModSeq.
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
// - All messages have a nonzero ThreadID, and no cycles in ThreadParentID, and parent messages the same ThreadParentIDs tail.
func (a *Account) CheckConsistency() error {
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
var uidErrors []string // With a limit, could be many.
var modseqErrors []string // With limit.
var fileErrors []string // With limit.
var threadidErrors []string // With limit.
var threadParentErrors []string // With limit.
var threadAncestorErrors []string // With limit.
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
var errors []string
err := a.DB.Read(context.Background(), func(tx *bstore.Tx) error {
nuv := NextUIDValidity{ID: 1}
err := tx.Get(&nuv)
if err != nil {
return fmt.Errorf("fetching next uid validity: %v", err)
}
mailboxes := map[int64]Mailbox{}
err = bstore.QueryTx[Mailbox](tx).ForEach(func(mb Mailbox) error {
mailboxes[mb.ID] = mb
if mb.UIDValidity >= nuv.Next {
errmsg := fmt.Sprintf("mailbox %q (id %d) has uidvalidity %d >= account next uidvalidity %d", mb.Name, mb.ID, mb.UIDValidity, nuv.Next)
errors = append(errors, errmsg)
}
return nil
})
if err != nil {
return fmt.Errorf("listing mailboxes: %v", err)
}
counts := map[int64]MailboxCounts{}
err = bstore.QueryTx[Message](tx).ForEach(func(m Message) error {
mc := counts[m.MailboxID]
mc.Add(m.MailboxCounts())
counts[m.MailboxID] = mc
mb := mailboxes[m.MailboxID]
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if (m.ModSeq == 0 || m.CreateSeq == 0 || m.CreateSeq > m.ModSeq) && len(modseqErrors) < 20 {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
modseqerr := fmt.Sprintf("message %d in mailbox %q (id %d) has invalid modseq %d or createseq %d, both must be > 0 and createseq <= modseq", m.ID, mb.Name, mb.ID, m.ModSeq, m.CreateSeq)
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
modseqErrors = append(modseqErrors, modseqerr)
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if m.UID >= mb.UIDNext && len(uidErrors) < 20 {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
uiderr := fmt.Sprintf("message %d in mailbox %q (id %d) has uid %d >= mailbox uidnext %d", m.ID, mb.Name, mb.ID, m.UID, mb.UIDNext)
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
uidErrors = append(uidErrors, uiderr)
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
}
if m.Expunged {
return nil
}
p := a.MessagePath(m.ID)
st, err := os.Stat(p)
if err != nil {
existserr := fmt.Sprintf("message %d in mailbox %q (id %d) on-disk file %s: %v", m.ID, mb.Name, mb.ID, p, err)
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
fileErrors = append(fileErrors, existserr)
} else if len(fileErrors) < 20 && m.Size != int64(len(m.MsgPrefix))+st.Size() {
sizeerr := fmt.Sprintf("message %d in mailbox %q (id %d) has size %d != len msgprefix %d + on-disk file size %d = %d", m.ID, mb.Name, mb.ID, m.Size, len(m.MsgPrefix), st.Size(), int64(len(m.MsgPrefix))+st.Size())
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
fileErrors = append(fileErrors, sizeerr)
}
if m.ThreadID <= 0 && len(threadidErrors) < 20 {
err := fmt.Sprintf("message %d in mailbox %q (id %d) has threadid 0", m.ID, mb.Name, mb.ID)
threadidErrors = append(threadidErrors, err)
}
if slices.Contains(m.ThreadParentIDs, m.ID) && len(threadParentErrors) < 20 {
err := fmt.Sprintf("message %d in mailbox %q (id %d) references itself in threadparentids", m.ID, mb.Name, mb.ID)
threadParentErrors = append(threadParentErrors, err)
}
for i, pid := range m.ThreadParentIDs {
am := Message{ID: pid}
if err := tx.Get(&am); err == bstore.ErrAbsent {
continue
} else if err != nil {
return fmt.Errorf("get ancestor message: %v", err)
} else if !slices.Equal(m.ThreadParentIDs[i+1:], am.ThreadParentIDs) && len(threadAncestorErrors) < 20 {
err := fmt.Sprintf("message %d, thread %d has ancestor ids %v, and ancestor at index %d with id %d should have the same tail but has %v\n", m.ID, m.ThreadID, m.ThreadParentIDs, i, am.ID, am.ThreadParentIDs)
threadAncestorErrors = append(threadAncestorErrors, err)
} else {
break
}
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
return nil
})
if err != nil {
return fmt.Errorf("reading messages: %v", err)
}
var totalSize int64
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
for _, mb := range mailboxes {
totalSize += mb.Size
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if !mb.HaveCounts {
errmsg := fmt.Sprintf("mailbox %q (id %d) does not have counts, should be %#v", mb.Name, mb.ID, counts[mb.ID])
errors = append(errors, errmsg)
} else if mb.MailboxCounts != counts[mb.ID] {
mbcounterr := fmt.Sprintf("mailbox %q (id %d) has wrong counts %s, should be %s", mb.Name, mb.ID, mb.MailboxCounts, counts[mb.ID])
errors = append(errors, mbcounterr)
}
}
du := DiskUsage{ID: 1}
if err := tx.Get(&du); err != nil {
return fmt.Errorf("get diskusage")
}
if du.MessageSize != totalSize {
errmsg := fmt.Sprintf("total message size in database is %d, sum of mailbox message sizes is %d", du.MessageSize, totalSize)
errors = append(errors, errmsg)
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
return nil
})
if err != nil {
return err
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
errors = append(errors, uidErrors...)
errors = append(errors, modseqErrors...)
errors = append(errors, fileErrors...)
errors = append(errors, threadidErrors...)
errors = append(errors, threadParentErrors...)
errors = append(errors, threadAncestorErrors...)
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if len(errors) > 0 {
return fmt.Errorf("%s", strings.Join(errors, "; "))
}
return nil
}
2023-01-30 16:27:06 +03:00
// Conf returns the configuration for this account if it still exists. During
// an SMTP session, a configuration update may drop an account.
func (a *Account) Conf() (config.Account, bool) {
return mox.Conf.Account(a.Name)
}
// NextUIDValidity returns the next new/unique uidvalidity to use for this account.
func (a *Account) NextUIDValidity(tx *bstore.Tx) (uint32, error) {
nuv := NextUIDValidity{ID: 1}
if err := tx.Get(&nuv); err != nil {
return 0, err
}
v := nuv.Next
nuv.Next++
if err := tx.Update(&nuv); err != nil {
return 0, err
}
return v, nil
}
// NextModSeq returns the next modification sequence, which is global per account,
// over all types.
func (a *Account) NextModSeq(tx *bstore.Tx) (ModSeq, error) {
v := SyncState{ID: 1}
if err := tx.Get(&v); err == bstore.ErrAbsent {
// We start assigning from modseq 2. Modseq 0 is not usable, so returned as 1, so
// already used.
// HighestDeletedModSeq is -1 so comparison against the default ModSeq zero value
// makes sense.
v = SyncState{1, 2, -1}
return v.LastModSeq, tx.Insert(&v)
} else if err != nil {
return 0, err
}
v.LastModSeq++
return v.LastModSeq, tx.Update(&v)
}
func (a *Account) HighestDeletedModSeq(tx *bstore.Tx) (ModSeq, error) {
v := SyncState{ID: 1}
err := tx.Get(&v)
if err == bstore.ErrAbsent {
return 0, nil
}
return v.HighestDeletedModSeq, err
}
2023-01-30 16:27:06 +03:00
// WithWLock runs fn with account writelock held. Necessary for account/mailbox modification. For message delivery, a read lock is required.
func (a *Account) WithWLock(fn func()) {
a.Lock()
defer a.Unlock()
fn()
}
// WithRLock runs fn with account read lock held. Needed for message delivery.
func (a *Account) WithRLock(fn func()) {
a.RLock()
defer a.RUnlock()
fn()
}
// DeliverMessage delivers a mail message to the account.
2023-01-30 16:27:06 +03:00
//
// The message, with msg.MsgPrefix and msgFile combined, must have a header
// section. The caller is responsible for adding a header separator to
// msg.MsgPrefix if missing from an incoming message.
//
// If the destination mailbox has the Sent special-use flag, the message is parsed
// for its recipients (to/cc/bcc). Their domains are added to Recipients for use in
// dmarc reputation.
2023-01-30 16:27:06 +03:00
//
// If sync is true, the message file and its directory are synced. Should be true
// for regular mail delivery, but can be false when importing many messages.
//
// If updateDiskUsage is true, the account total message size (for quota) is
// updated. Callers must check if a message can be added within quota before
// calling DeliverMessage.
//
// If CreateSeq/ModSeq is not set, it is assigned automatically.
//
2023-01-30 16:27:06 +03:00
// Must be called with account rlock or wlock.
//
// Caller must broadcast new message.
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
//
// Caller must update mailbox counts.
func (a *Account) DeliverMessage(log mlog.Log, tx *bstore.Tx, m *Message, msgFile *os.File, sync, notrain, nothreads, updateDiskUsage bool) error {
if m.Expunged {
return fmt.Errorf("cannot deliver expunged message")
}
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mb := Mailbox{ID: m.MailboxID}
if err := tx.Get(&mb); err != nil {
return fmt.Errorf("get mailbox: %w", err)
}
2023-01-30 16:27:06 +03:00
m.UID = mb.UIDNext
mb.UIDNext++
if err := tx.Update(&mb); err != nil {
return fmt.Errorf("updating mailbox nextuid: %w", err)
}
2023-01-30 16:27:06 +03:00
if updateDiskUsage {
du := DiskUsage{ID: 1}
if err := tx.Get(&du); err != nil {
return fmt.Errorf("get disk usage: %v", err)
}
du.MessageSize += m.Size
if err := tx.Update(&du); err != nil {
return fmt.Errorf("update disk usage: %v", err)
}
}
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
conf, _ := a.Conf()
m.JunkFlagsForMailbox(mb, conf)
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
mr := FileMsgReader(m.MsgPrefix, msgFile) // We don't close, it would close the msgFile.
2023-01-30 16:27:06 +03:00
var part *message.Part
if m.ParsedBuf == nil {
p, err := message.EnsurePart(log.Logger, false, mr, m.Size)
2023-01-30 16:27:06 +03:00
if err != nil {
log.Infox("parsing delivered message", err, slog.String("parse", ""), slog.Int64("message", m.ID))
2023-01-30 16:27:06 +03:00
// We continue, p is still valid.
}
part = &p
buf, err := json.Marshal(part)
if err != nil {
return fmt.Errorf("marshal parsed message: %w", err)
}
2023-01-30 16:27:06 +03:00
m.ParsedBuf = buf
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
} else {
var p message.Part
if err := json.Unmarshal(m.ParsedBuf, &p); err != nil {
log.Errorx("unmarshal parsed message, continuing", err, slog.String("parse", ""))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
} else {
part = &p
}
2023-01-30 16:27:06 +03:00
}
// If we are delivering to the originally intended mailbox, no need to store the mailbox ID again.
if m.MailboxDestinedID != 0 && m.MailboxDestinedID == m.MailboxOrigID {
m.MailboxDestinedID = 0
}
if m.CreateSeq == 0 || m.ModSeq == 0 {
modseq, err := a.NextModSeq(tx)
if err != nil {
return fmt.Errorf("assigning next modseq: %w", err)
}
m.CreateSeq = modseq
m.ModSeq = modseq
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if part != nil && m.MessageID == "" && m.SubjectBase == "" {
m.PrepareThreading(log, part)
}
// Assign to thread (if upgrade has completed).
noThreadID := nothreads
if m.ThreadID == 0 && !nothreads && part != nil {
select {
case <-a.threadsCompleted:
if a.threadsErr != nil {
log.Info("not assigning threads for new delivery, upgrading to threads failed")
noThreadID = true
} else {
if err := assignThread(log, tx, m, part); err != nil {
return fmt.Errorf("assigning thread: %w", err)
}
}
default:
// note: since we have a write transaction to get here, we can't wait for the
// thread upgrade to finish.
// If we don't assign a threadid the upgrade process will do it.
log.Info("not assigning threads for new delivery, upgrading to threads in progress which will assign this message")
noThreadID = true
}
}
if err := tx.Insert(m); err != nil {
return fmt.Errorf("inserting message: %w", err)
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if !noThreadID && m.ThreadID == 0 {
m.ThreadID = m.ID
if err := tx.Update(m); err != nil {
return fmt.Errorf("updating message for its own thread id: %w", err)
}
}
2023-01-30 16:27:06 +03:00
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// todo: perhaps we should match the recipients based on smtp submission and a matching message-id? we now miss the addresses in bcc's. for webmail, we could insert the recipients directly.
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if mb.Sent && part != nil && part.Envelope != nil {
e := part.Envelope
sent := e.Date
if sent.IsZero() {
sent = m.Received
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}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
if sent.IsZero() {
sent = time.Now()
}
addrs := append(append(e.To, e.CC...), e.BCC...)
for _, addr := range addrs {
if addr.User == "" {
// Would trigger error because Recipient.Localpart must be nonzero. todo: we could allow empty localpart in db, and filter by not using FilterNonzero.
log.Info("to/cc/bcc address with empty localpart, not inserting as recipient", slog.Any("address", addr))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
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continue
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}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
d, err := dns.ParseDomain(addr.Host)
if err != nil {
log.Debugx("parsing domain in to/cc/bcc address", err, slog.Any("address", addr))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
continue
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}
lp, err := smtp.ParseLocalpart(addr.User)
if err != nil {
log.Debugx("parsing localpart in to/cc/bcc address", err, slog.Any("address", addr))
continue
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
mr := Recipient{
MessageID: m.ID,
Localpart: lp.String(),
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
Domain: d.Name(),
OrgDomain: publicsuffix.Lookup(context.TODO(), log.Logger, d).Name(),
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
Sent: sent,
}
if err := tx.Insert(&mr); err != nil {
return fmt.Errorf("inserting sent message recipients: %w", err)
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}
}
}
msgPath := a.MessagePath(m.ID)
msgDir := filepath.Dir(msgPath)
os.MkdirAll(msgDir, 0770)
// Sync file data to disk.
if sync {
if err := msgFile.Sync(); err != nil {
return fmt.Errorf("fsync message file: %w", err)
}
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}
make mox compile on windows, without "mox serve" but with working "mox localserve" getting mox to compile required changing code in only a few places where package "syscall" was used: for accessing file access times and for umask handling. an open problem is how to start a process as an unprivileged user on windows. that's why "mox serve" isn't implemented yet. and just finding a way to implement it now may not be good enough in the near future: we may want to starting using a more complete privilege separation approach, with a process handling sensitive tasks (handling private keys, authentication), where we may want to pass file descriptors between processes. how would that work on windows? anyway, getting mox to compile for windows doesn't mean it works properly on windows. the largest issue: mox would normally open a file, rename or remove it, and finally close it. this happens during message delivery. that doesn't work on windows, the rename/remove would fail because the file is still open. so this commit swaps many "remove" and "close" calls. renames are a longer story: message delivery had two ways to deliver: with "consuming" the (temporary) message file (which would rename it to its final destination), and without consuming (by hardlinking the file, falling back to copying). the last delivery to a recipient of a message (and the only one in the common case of a single recipient) would consume the message, and the earlier recipients would not. during delivery, the already open message file was used, to parse the message. we still want to use that open message file, and the caller now stays responsible for closing it, but we no longer try to rename (consume) the file. we always hardlink (or copy) during delivery (this works on windows), and the caller is responsible for closing and removing (in that order) the original temporary file. this does cost one syscall more. but it makes the delivery code (responsibilities) a bit simpler. there is one more obvious issue: the file system path separator. mox already used the "filepath" package to join paths in many places, but not everywhere. and it still used strings with slashes for local file access. with this commit, the code now uses filepath.FromSlash for path strings with slashes, uses "filepath" in a few more places where it previously didn't. also switches from "filepath" to regular "path" package when handling mailbox names in a few places, because those always use forward slashes, regardless of local file system conventions. windows can handle forward slashes when opening files, so test code that passes path strings with forward slashes straight to go stdlib file i/o functions are left unchanged to reduce code churn. the regular non-test code, or test code that uses path strings in places other than standard i/o functions, does have the paths converted for consistent paths (otherwise we would end up with paths with mixed forward/backward slashes in log messages). windows cannot dup a listening socket. for "mox localserve", it isn't important, and we can work around the issue. the current approach for "mox serve" (forking a process and passing file descriptors of listening sockets on "privileged" ports) won't work on windows. perhaps it isn't needed on windows, and any user can listen on "privileged" ports? that would be welcome. on windows, os.Open cannot open a directory, so we cannot call Sync on it after message delivery. a cursory internet search indicates that directories cannot be synced on windows. the story is probably much more nuanced than that, with long deep technical details/discussions/disagreement/confusion, like on unix. for "mox localserve" we can get away with making syncdir a no-op.
2023-10-14 11:54:07 +03:00
if err := moxio.LinkOrCopy(log, msgPath, msgFile.Name(), &moxio.AtReader{R: msgFile}, true); err != nil {
return fmt.Errorf("linking/copying message to new file: %w", err)
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}
if sync {
if err := moxio.SyncDir(log, msgDir); err != nil {
xerr := os.Remove(msgPath)
log.Check(xerr, "removing message after syncdir error", slog.String("path", msgPath))
return fmt.Errorf("sync directory: %w", err)
}
2023-01-30 16:27:06 +03:00
}
if !notrain && m.NeedsTraining() {
l := []Message{*m}
if err := a.RetrainMessages(context.TODO(), log, tx, l, false); err != nil {
xerr := os.Remove(msgPath)
log.Check(xerr, "removing message after syncdir error", slog.String("path", msgPath))
return fmt.Errorf("training junkfilter: %w", err)
}
*m = l[0]
}
return nil
2023-01-30 16:27:06 +03:00
}
// SetPassword saves a new password for this account. This password is used for
// IMAP, SMTP (submission) sessions and the HTTP account web page.
func (a *Account) SetPassword(log mlog.Log, password string) error {
password, err := precis.OpaqueString.String(password)
if err != nil {
return fmt.Errorf(`password not allowed by "precis"`)
}
if len(password) < 8 {
// We actually check for bytes...
return fmt.Errorf("password must be at least 8 characters long")
}
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hash, err := bcrypt.GenerateFromPassword([]byte(password), bcrypt.DefaultCost)
if err != nil {
return fmt.Errorf("generating password hash: %w", err)
}
err = a.DB.Write(context.TODO(), func(tx *bstore.Tx) error {
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if _, err := bstore.QueryTx[Password](tx).Delete(); err != nil {
return fmt.Errorf("deleting existing password: %v", err)
}
var pw Password
pw.Hash = string(hash)
// CRAM-MD5 calculates an HMAC-MD5, with the password as key, over a per-attempt
// unique text that includes a timestamp. HMAC performs two hashes. Both times, the
// first block is based on the key/password. We hash those first blocks now, and
// store the hash state in the database. When we actually authenticate, we'll
// complete the HMAC by hashing only the text. We cannot store crypto/hmac's hash,
// because it does not expose its internal state and isn't a BinaryMarshaler.
// ../rfc/2104:121
pw.CRAMMD5.Ipad = md5.New()
pw.CRAMMD5.Opad = md5.New()
key := []byte(password)
if len(key) > 64 {
t := md5.Sum(key)
key = t[:]
}
ipad := make([]byte, md5.BlockSize)
opad := make([]byte, md5.BlockSize)
copy(ipad, key)
copy(opad, key)
for i := range ipad {
ipad[i] ^= 0x36
opad[i] ^= 0x5c
}
pw.CRAMMD5.Ipad.Write(ipad)
pw.CRAMMD5.Opad.Write(opad)
pw.SCRAMSHA1.Salt = scram.MakeRandom()
pw.SCRAMSHA1.Iterations = 2 * 4096
pw.SCRAMSHA1.SaltedPassword = scram.SaltPassword(sha1.New, password, pw.SCRAMSHA1.Salt, pw.SCRAMSHA1.Iterations)
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pw.SCRAMSHA256.Salt = scram.MakeRandom()
pw.SCRAMSHA256.Iterations = 4096
pw.SCRAMSHA256.SaltedPassword = scram.SaltPassword(sha256.New, password, pw.SCRAMSHA256.Salt, pw.SCRAMSHA256.Iterations)
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if err := tx.Insert(&pw); err != nil {
return fmt.Errorf("inserting new password: %v", err)
}
replace http basic auth for web interfaces with session cookie & csrf-based auth the http basic auth we had was very simple to reason about, and to implement. but it has a major downside: there is no way to logout, browsers keep sending credentials. ideally, browsers themselves would show a button to stop sending credentials. a related downside: the http auth mechanism doesn't indicate for which server paths the credentials are. another downside: the original password is sent to the server with each request. though sending original passwords to web servers seems to be considered normal. our new approach uses session cookies, along with csrf values when we can. the sessions are server-side managed, automatically extended on each use. this makes it easy to invalidate sessions and keeps the frontend simpler (than with long- vs short-term sessions and refreshing). the cookies are httponly, samesite=strict, scoped to the path of the web interface. cookies are set "secure" when set over https. the cookie is set by a successful call to Login. a call to Logout invalidates a session. changing a password invalidates all sessions for a user, but keeps the session with which the password was changed alive. the csrf value is also random, and associated with the session cookie. the csrf must be sent as header for api calls, or as parameter for direct form posts (where we cannot set a custom header). rest-like calls made directly by the browser, e.g. for images, don't have a csrf protection. the csrf value is returned by the Login api call and stored in localstorage. api calls without credentials return code "user:noAuth", and with bad credentials return "user:badAuth". the api client recognizes this and triggers a login. after a login, all auth-failed api calls are automatically retried. only for "user:badAuth" is an error message displayed in the login form (e.g. session expired). in an ideal world, browsers would take care of most session management. a server would indicate authentication is needed (like http basic auth), and the browsers uses trusted ui to request credentials for the server & path. the browser could use safer mechanism than sending original passwords to the server, such as scram, along with a standard way to create sessions. for now, web developers have to do authentication themselves: from showing the login prompt, ensuring the right session/csrf cookies/localstorage/headers/etc are sent with each request. webauthn is a newer way to do authentication, perhaps we'll implement it in the future. though hardware tokens aren't an attractive option for many users, and it may be overkill as long as we still do old-fashioned authentication in smtp & imap where passwords can be sent to the server. for issue #58
2024-01-04 15:10:48 +03:00
return sessionRemoveAll(context.TODO(), log, tx, a.Name)
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})
if err == nil {
log.Info("new password set for account", slog.String("account", a.Name))
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}
return err
}
// Subjectpass returns the signing key for use with subjectpass for the given
// email address with canonical localpart.
func (a *Account) Subjectpass(email string) (key string, err error) {
return key, a.DB.Write(context.TODO(), func(tx *bstore.Tx) error {
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v := Subjectpass{Email: email}
err := tx.Get(&v)
if err == nil {
key = v.Key
return nil
}
if !errors.Is(err, bstore.ErrAbsent) {
return fmt.Errorf("get subjectpass key from accounts database: %w", err)
}
key = ""
const chars = "abcdefghijklmnopqrstuvwxyz0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"
buf := make([]byte, 16)
if _, err := cryptorand.Read(buf); err != nil {
return err
}
for _, b := range buf {
key += string(chars[int(b)%len(chars)])
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}
v.Key = key
return tx.Insert(&v)
})
}
// Ensure mailbox is present in database, adding records for the mailbox and its
// parents if they aren't present.
//
// If subscribe is true, any mailboxes that were created will also be subscribed to.
// Caller must hold account wlock.
// Caller must propagate changes if any.
func (a *Account) MailboxEnsure(tx *bstore.Tx, name string, subscribe bool) (mb Mailbox, changes []Change, rerr error) {
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if norm.NFC.String(name) != name {
return Mailbox{}, nil, fmt.Errorf("mailbox name not normalized")
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}
// Quick sanity check.
if strings.EqualFold(name, "inbox") && name != "Inbox" {
return Mailbox{}, nil, fmt.Errorf("bad casing for inbox")
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}
elems := strings.Split(name, "/")
q := bstore.QueryTx[Mailbox](tx)
q.FilterFn(func(mb Mailbox) bool {
return mb.Name == elems[0] || strings.HasPrefix(mb.Name, elems[0]+"/")
})
l, err := q.List()
if err != nil {
return Mailbox{}, nil, fmt.Errorf("list mailboxes: %v", err)
}
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mailboxes := map[string]Mailbox{}
for _, xmb := range l {
mailboxes[xmb.Name] = xmb
}
p := ""
for _, elem := range elems {
if p != "" {
p += "/"
}
p += elem
var ok bool
mb, ok = mailboxes[p]
if ok {
continue
}
uidval, err := a.NextUIDValidity(tx)
if err != nil {
return Mailbox{}, nil, fmt.Errorf("next uid validity: %v", err)
}
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mb = Mailbox{
Name: p,
UIDValidity: uidval,
UIDNext: 1,
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
HaveCounts: true,
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}
err = tx.Insert(&mb)
if err != nil {
return Mailbox{}, nil, fmt.Errorf("creating new mailbox: %v", err)
}
2023-01-30 16:27:06 +03:00
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
var flags []string
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if subscribe {
if tx.Get(&Subscription{p}) != nil {
err := tx.Insert(&Subscription{p})
if err != nil {
return Mailbox{}, nil, fmt.Errorf("subscribing to mailbox: %v", err)
}
2023-01-30 16:27:06 +03:00
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
flags = []string{`\Subscribed`}
2023-01-30 16:27:06 +03:00
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
changes = append(changes, ChangeAddMailbox{mb, flags})
2023-01-30 16:27:06 +03:00
}
return mb, changes, nil
}
// MailboxExists checks if mailbox exists.
2023-01-30 16:27:06 +03:00
// Caller must hold account rlock.
func (a *Account) MailboxExists(tx *bstore.Tx, name string) (bool, error) {
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q := bstore.QueryTx[Mailbox](tx)
q.FilterEqual("Name", name)
return q.Exists()
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}
// MailboxFind finds a mailbox by name, returning a nil mailbox and nil error if mailbox does not exist.
func (a *Account) MailboxFind(tx *bstore.Tx, name string) (*Mailbox, error) {
2023-01-30 16:27:06 +03:00
q := bstore.QueryTx[Mailbox](tx)
q.FilterEqual("Name", name)
mb, err := q.Get()
if err == bstore.ErrAbsent {
return nil, nil
}
if err != nil {
return nil, fmt.Errorf("looking up mailbox: %w", err)
2023-01-30 16:27:06 +03:00
}
return &mb, nil
2023-01-30 16:27:06 +03:00
}
// SubscriptionEnsure ensures a subscription for name exists. The mailbox does not
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// have to exist. Any parents are not automatically subscribed.
// Changes are returned and must be broadcasted by the caller.
func (a *Account) SubscriptionEnsure(tx *bstore.Tx, name string) ([]Change, error) {
if err := tx.Get(&Subscription{name}); err == nil {
return nil, nil
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}
if err := tx.Insert(&Subscription{name}); err != nil {
return nil, fmt.Errorf("inserting subscription: %w", err)
}
2023-01-30 16:27:06 +03:00
q := bstore.QueryTx[Mailbox](tx)
q.FilterEqual("Name", name)
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
_, err := q.Get()
if err == nil {
return []Change{ChangeAddSubscription{name, nil}}, nil
} else if err != bstore.ErrAbsent {
return nil, fmt.Errorf("looking up mailbox for subscription: %w", err)
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
return []Change{ChangeAddSubscription{name, []string{`\NonExistent`}}}, nil
2023-01-30 16:27:06 +03:00
}
// MessageRuleset returns the first ruleset (if any) that message the message
// represented by msgPrefix and msgFile, with smtp and validation fields from m.
func MessageRuleset(log mlog.Log, dest config.Destination, m *Message, msgPrefix []byte, msgFile *os.File) *config.Ruleset {
2023-01-30 16:27:06 +03:00
if len(dest.Rulesets) == 0 {
return nil
}
mr := FileMsgReader(msgPrefix, msgFile) // We don't close, it would close the msgFile.
p, err := message.Parse(log.Logger, false, mr)
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if err != nil {
log.Errorx("parsing message for evaluating rulesets, continuing with headers", err, slog.String("parse", ""))
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// note: part is still set.
}
// todo optimize: only parse header if needed for rulesets. and probably reuse an earlier parsing.
header, err := p.Header()
if err != nil {
log.Errorx("parsing message headers for evaluating rulesets, delivering to default mailbox", err, slog.String("parse", ""))
2023-01-30 16:27:06 +03:00
// todo: reject message?
return nil
}
ruleset:
for _, rs := range dest.Rulesets {
if rs.SMTPMailFromRegexpCompiled != nil {
if !rs.SMTPMailFromRegexpCompiled.MatchString(m.MailFrom) {
continue ruleset
}
}
if !rs.VerifiedDNSDomain.IsZero() {
d := rs.VerifiedDNSDomain.Name()
suffix := "." + d
matchDomain := func(s string) bool {
return s == d || strings.HasSuffix(s, suffix)
}
var ok bool
if m.EHLOValidated && matchDomain(m.EHLODomain) {
ok = true
}
if m.MailFromValidated && matchDomain(m.MailFromDomain) {
ok = true
}
for _, d := range m.DKIMDomains {
if matchDomain(d) {
ok = true
break
}
}
if !ok {
continue ruleset
}
}
header:
for _, t := range rs.HeadersRegexpCompiled {
for k, vl := range header {
k = strings.ToLower(k)
if !t[0].MatchString(k) {
continue
}
for _, v := range vl {
v = strings.ToLower(strings.TrimSpace(v))
if t[1].MatchString(v) {
continue header
}
}
}
continue ruleset
}
return &rs
}
return nil
}
// MessagePath returns the file system path of a message.
func (a *Account) MessagePath(messageID int64) string {
make mox compile on windows, without "mox serve" but with working "mox localserve" getting mox to compile required changing code in only a few places where package "syscall" was used: for accessing file access times and for umask handling. an open problem is how to start a process as an unprivileged user on windows. that's why "mox serve" isn't implemented yet. and just finding a way to implement it now may not be good enough in the near future: we may want to starting using a more complete privilege separation approach, with a process handling sensitive tasks (handling private keys, authentication), where we may want to pass file descriptors between processes. how would that work on windows? anyway, getting mox to compile for windows doesn't mean it works properly on windows. the largest issue: mox would normally open a file, rename or remove it, and finally close it. this happens during message delivery. that doesn't work on windows, the rename/remove would fail because the file is still open. so this commit swaps many "remove" and "close" calls. renames are a longer story: message delivery had two ways to deliver: with "consuming" the (temporary) message file (which would rename it to its final destination), and without consuming (by hardlinking the file, falling back to copying). the last delivery to a recipient of a message (and the only one in the common case of a single recipient) would consume the message, and the earlier recipients would not. during delivery, the already open message file was used, to parse the message. we still want to use that open message file, and the caller now stays responsible for closing it, but we no longer try to rename (consume) the file. we always hardlink (or copy) during delivery (this works on windows), and the caller is responsible for closing and removing (in that order) the original temporary file. this does cost one syscall more. but it makes the delivery code (responsibilities) a bit simpler. there is one more obvious issue: the file system path separator. mox already used the "filepath" package to join paths in many places, but not everywhere. and it still used strings with slashes for local file access. with this commit, the code now uses filepath.FromSlash for path strings with slashes, uses "filepath" in a few more places where it previously didn't. also switches from "filepath" to regular "path" package when handling mailbox names in a few places, because those always use forward slashes, regardless of local file system conventions. windows can handle forward slashes when opening files, so test code that passes path strings with forward slashes straight to go stdlib file i/o functions are left unchanged to reduce code churn. the regular non-test code, or test code that uses path strings in places other than standard i/o functions, does have the paths converted for consistent paths (otherwise we would end up with paths with mixed forward/backward slashes in log messages). windows cannot dup a listening socket. for "mox localserve", it isn't important, and we can work around the issue. the current approach for "mox serve" (forking a process and passing file descriptors of listening sockets on "privileged" ports) won't work on windows. perhaps it isn't needed on windows, and any user can listen on "privileged" ports? that would be welcome. on windows, os.Open cannot open a directory, so we cannot call Sync on it after message delivery. a cursory internet search indicates that directories cannot be synced on windows. the story is probably much more nuanced than that, with long deep technical details/discussions/disagreement/confusion, like on unix. for "mox localserve" we can get away with making syncdir a no-op.
2023-10-14 11:54:07 +03:00
return strings.Join(append([]string{a.Dir, "msg"}, messagePathElems(messageID)...), string(filepath.Separator))
2023-01-30 16:27:06 +03:00
}
// MessageReader opens a message for reading, transparently combining the
// message prefix with the original incoming message.
func (a *Account) MessageReader(m Message) *MsgReader {
return &MsgReader{prefix: m.MsgPrefix, path: a.MessagePath(m.ID), size: m.Size}
}
// DeliverDestination delivers an email to dest, based on the configured rulesets.
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//
// Returns ErrOverQuota when account would be over quota after adding message.
//
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// Caller must hold account wlock (mailbox may be created).
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// Message delivery, possible mailbox creation, and updated mailbox counts are
// broadcasted.
func (a *Account) DeliverDestination(log mlog.Log, dest config.Destination, m *Message, msgFile *os.File) error {
2023-01-30 16:27:06 +03:00
var mailbox string
rs := MessageRuleset(log, dest, m, m.MsgPrefix, msgFile)
if rs != nil {
mailbox = rs.Mailbox
} else if dest.Mailbox == "" {
mailbox = "Inbox"
} else {
mailbox = dest.Mailbox
}
make mox compile on windows, without "mox serve" but with working "mox localserve" getting mox to compile required changing code in only a few places where package "syscall" was used: for accessing file access times and for umask handling. an open problem is how to start a process as an unprivileged user on windows. that's why "mox serve" isn't implemented yet. and just finding a way to implement it now may not be good enough in the near future: we may want to starting using a more complete privilege separation approach, with a process handling sensitive tasks (handling private keys, authentication), where we may want to pass file descriptors between processes. how would that work on windows? anyway, getting mox to compile for windows doesn't mean it works properly on windows. the largest issue: mox would normally open a file, rename or remove it, and finally close it. this happens during message delivery. that doesn't work on windows, the rename/remove would fail because the file is still open. so this commit swaps many "remove" and "close" calls. renames are a longer story: message delivery had two ways to deliver: with "consuming" the (temporary) message file (which would rename it to its final destination), and without consuming (by hardlinking the file, falling back to copying). the last delivery to a recipient of a message (and the only one in the common case of a single recipient) would consume the message, and the earlier recipients would not. during delivery, the already open message file was used, to parse the message. we still want to use that open message file, and the caller now stays responsible for closing it, but we no longer try to rename (consume) the file. we always hardlink (or copy) during delivery (this works on windows), and the caller is responsible for closing and removing (in that order) the original temporary file. this does cost one syscall more. but it makes the delivery code (responsibilities) a bit simpler. there is one more obvious issue: the file system path separator. mox already used the "filepath" package to join paths in many places, but not everywhere. and it still used strings with slashes for local file access. with this commit, the code now uses filepath.FromSlash for path strings with slashes, uses "filepath" in a few more places where it previously didn't. also switches from "filepath" to regular "path" package when handling mailbox names in a few places, because those always use forward slashes, regardless of local file system conventions. windows can handle forward slashes when opening files, so test code that passes path strings with forward slashes straight to go stdlib file i/o functions are left unchanged to reduce code churn. the regular non-test code, or test code that uses path strings in places other than standard i/o functions, does have the paths converted for consistent paths (otherwise we would end up with paths with mixed forward/backward slashes in log messages). windows cannot dup a listening socket. for "mox localserve", it isn't important, and we can work around the issue. the current approach for "mox serve" (forking a process and passing file descriptors of listening sockets on "privileged" ports) won't work on windows. perhaps it isn't needed on windows, and any user can listen on "privileged" ports? that would be welcome. on windows, os.Open cannot open a directory, so we cannot call Sync on it after message delivery. a cursory internet search indicates that directories cannot be synced on windows. the story is probably much more nuanced than that, with long deep technical details/discussions/disagreement/confusion, like on unix. for "mox localserve" we can get away with making syncdir a no-op.
2023-10-14 11:54:07 +03:00
return a.DeliverMailbox(log, mailbox, m, msgFile)
2023-01-30 16:27:06 +03:00
}
// DeliverMailbox delivers an email to the specified mailbox.
//
// Returns ErrOverQuota when account would be over quota after adding message.
//
2023-01-30 16:27:06 +03:00
// Caller must hold account wlock (mailbox may be created).
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// Message delivery, possible mailbox creation, and updated mailbox counts are
// broadcasted.
func (a *Account) DeliverMailbox(log mlog.Log, mailbox string, m *Message, msgFile *os.File) error {
2023-01-30 16:27:06 +03:00
var changes []Change
err := a.DB.Write(context.TODO(), func(tx *bstore.Tx) error {
if ok, _, err := a.CanAddMessageSize(tx, m.Size); err != nil {
return err
} else if !ok {
return ErrOverQuota
}
mb, chl, err := a.MailboxEnsure(tx, mailbox, true)
if err != nil {
return fmt.Errorf("ensuring mailbox: %w", err)
}
2023-01-30 16:27:06 +03:00
m.MailboxID = mb.ID
m.MailboxOrigID = mb.ID
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// Update count early, DeliverMessage will update mb too and we don't want to fetch
// it again before updating.
mb.MailboxCounts.Add(m.MailboxCounts())
if err := tx.Update(&mb); err != nil {
return fmt.Errorf("updating mailbox for delivery: %w", err)
}
if err := a.DeliverMessage(log, tx, m, msgFile, true, false, false, true); err != nil {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
return err
}
changes = append(changes, chl...)
changes = append(changes, m.ChangeAddUID(), mb.ChangeCounts())
return nil
2023-01-30 16:27:06 +03:00
})
// todo: if rename succeeded but transaction failed, we should remove the file.
if err != nil {
return err
}
BroadcastChanges(a, changes)
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return nil
}
// TidyRejectsMailbox removes old reject emails, and returns whether there is space for a new delivery.
//
// Caller most hold account wlock.
// Changes are broadcasted.
func (a *Account) TidyRejectsMailbox(log mlog.Log, rejectsMailbox string) (hasSpace bool, rerr error) {
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var changes []Change
var remove []Message
defer func() {
for _, m := range remove {
p := a.MessagePath(m.ID)
err := os.Remove(p)
log.Check(err, "removing rejects message file", slog.String("path", p))
}
}()
err := a.DB.Write(context.TODO(), func(tx *bstore.Tx) error {
mb, err := a.MailboxFind(tx, rejectsMailbox)
if err != nil {
return fmt.Errorf("finding mailbox: %w", err)
}
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if mb == nil {
// No messages have been delivered yet.
hasSpace = true
return nil
}
// Gather old messages to remove.
old := time.Now().Add(-14 * 24 * time.Hour)
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qdel := bstore.QueryTx[Message](tx)
qdel.FilterNonzero(Message{MailboxID: mb.ID})
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
qdel.FilterEqual("Expunged", false)
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qdel.FilterLess("Received", old)
remove, err = qdel.List()
if err != nil {
return fmt.Errorf("listing old messages: %w", err)
}
2023-01-30 16:27:06 +03:00
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
changes, err = a.rejectsRemoveMessages(context.TODO(), log, tx, mb, remove)
if err != nil {
return fmt.Errorf("removing messages: %w", err)
}
2023-01-30 16:27:06 +03:00
// We allow up to n messages.
qcount := bstore.QueryTx[Message](tx)
qcount.FilterNonzero(Message{MailboxID: mb.ID})
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
qcount.FilterEqual("Expunged", false)
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qcount.Limit(1000)
n, err := qcount.Count()
if err != nil {
return fmt.Errorf("counting rejects: %w", err)
}
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hasSpace = n < 1000
return nil
})
if err != nil {
remove = nil // Don't remove files on failure.
return false, err
}
2023-01-30 16:27:06 +03:00
BroadcastChanges(a, changes)
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return hasSpace, nil
2023-01-30 16:27:06 +03:00
}
func (a *Account) rejectsRemoveMessages(ctx context.Context, log mlog.Log, tx *bstore.Tx, mb *Mailbox, l []Message) ([]Change, error) {
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if len(l) == 0 {
return nil, nil
2023-01-30 16:27:06 +03:00
}
ids := make([]int64, len(l))
anyids := make([]any, len(l))
for i, m := range l {
ids[i] = m.ID
anyids[i] = m.ID
}
// Remove any message recipients. Should not happen, but a user can move messages
// from a Sent mailbox to the rejects mailbox...
qdmr := bstore.QueryTx[Recipient](tx)
qdmr.FilterEqual("MessageID", anyids...)
if _, err := qdmr.Delete(); err != nil {
return nil, fmt.Errorf("deleting from message recipient: %w", err)
}
2023-01-30 16:27:06 +03:00
// Assign new modseq.
modseq, err := a.NextModSeq(tx)
if err != nil {
return nil, fmt.Errorf("assign next modseq: %w", err)
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// Expunge the messages.
qx := bstore.QueryTx[Message](tx)
qx.FilterIDs(ids)
var expunged []Message
qx.Gather(&expunged)
if _, err := qx.UpdateNonzero(Message{ModSeq: modseq, Expunged: true}); err != nil {
return nil, fmt.Errorf("expunging messages: %w", err)
}
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
var totalSize int64
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
for _, m := range expunged {
m.Expunged = false // Was set by update, but would cause wrong count.
mb.MailboxCounts.Sub(m.MailboxCounts())
totalSize += m.Size
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
}
if err := tx.Update(mb); err != nil {
return nil, fmt.Errorf("updating mailbox counts: %w", err)
}
if err := a.AddMessageSize(log, tx, -totalSize); err != nil {
return nil, fmt.Errorf("updating disk usage: %w", err)
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
// Mark as neutral and train so junk filter gets untrained with these (junk) messages.
for i := range expunged {
expunged[i].Junk = false
expunged[i].Notjunk = false
improve training of junk filter before, we used heuristics to decide when to train/untrain a message as junk or nonjunk: the message had to be seen, be in certain mailboxes. then if a message was marked as junk, it was junk. and otherwise it was nonjunk. this wasn't good enough: you may want to keep some messages around as neither junk or nonjunk. and that wasn't possible. ideally, we would just look at the imap $Junk and $NotJunk flags. the problem is that mail clients don't set these flags, or don't make it easy. thunderbird can set the flags based on its own bayesian filter. it has a shortcut for marking Junk and moving it to the junk folder (good), but the counterpart of notjunk only marks a message as notjunk without showing in the UI that it was marked as notjunk. there is also no "move and mark as notjunk" mechanism. e.g. "archive" does not mark a message as notjunk. ios mail and mutt don't appear to have any way to see or change the $Junk and $NotJunk flags. what email clients do have is the ability to move messages to other mailboxes/folders. so mox now has a mechanism that allows you to configure mailboxes that automatically set $Junk or $NotJunk (or clear both) when a message is moved/copied/delivered to that folder. e.g. a mailbox called junk or spam or rejects marks its messags as junk. inbox, postmaster, dmarc, tlsrpt, neutral* mark their messages as neither junk or notjunk. other folders mark their messages as notjunk. e.g. list/*, archive. this functionality is optional, but enabled with the quickstart and for new accounts. also, mox now keeps track of the previous training of a message and will only untrain/train if needed. before, there probably have been duplicate or missing (un)trainings. this also includes a new subcommand "retrain" to recreate the junkfilter for an account. you should run it after updating to this version. and you should probably also modify your account config to include the AutomaticJunkFlags.
2023-02-12 01:00:12 +03:00
}
if err := a.RetrainMessages(ctx, log, tx, expunged, true); err != nil {
return nil, fmt.Errorf("retraining expunged messages: %w", err)
}
2023-01-30 16:27:06 +03:00
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
changes := make([]Change, len(l), len(l)+1)
2023-01-30 16:27:06 +03:00
for i, m := range l {
changes[i] = ChangeRemoveUIDs{mb.ID, []UID{m.UID}, modseq}
2023-01-30 16:27:06 +03:00
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
changes = append(changes, mb.ChangeCounts())
return changes, nil
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}
// RejectsRemove removes a message from the rejects mailbox if present.
// Caller most hold account wlock.
// Changes are broadcasted.
func (a *Account) RejectsRemove(log mlog.Log, rejectsMailbox, messageID string) error {
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var changes []Change
var remove []Message
defer func() {
for _, m := range remove {
p := a.MessagePath(m.ID)
err := os.Remove(p)
log.Check(err, "removing rejects message file", slog.String("path", p))
}
}()
err := a.DB.Write(context.TODO(), func(tx *bstore.Tx) error {
mb, err := a.MailboxFind(tx, rejectsMailbox)
if err != nil {
return fmt.Errorf("finding mailbox: %w", err)
}
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if mb == nil {
return nil
}
q := bstore.QueryTx[Message](tx)
q.FilterNonzero(Message{MailboxID: mb.ID, MessageID: messageID})
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
q.FilterEqual("Expunged", false)
remove, err = q.List()
if err != nil {
return fmt.Errorf("listing messages to remove: %w", err)
}
2023-01-30 16:27:06 +03:00
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
changes, err = a.rejectsRemoveMessages(context.TODO(), log, tx, mb, remove)
if err != nil {
return fmt.Errorf("removing messages: %w", err)
}
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return nil
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})
if err != nil {
remove = nil // Don't remove files on failure.
return err
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}
BroadcastChanges(a, changes)
return nil
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}
// AddMessageSize adjusts the DiskUsage.MessageSize by size.
func (a *Account) AddMessageSize(log mlog.Log, tx *bstore.Tx, size int64) error {
du := DiskUsage{ID: 1}
if err := tx.Get(&du); err != nil {
return fmt.Errorf("get diskusage: %v", err)
}
du.MessageSize += size
if du.MessageSize < 0 {
log.Error("negative total message size", slog.Int64("delta", size), slog.Int64("newtotalsize", du.MessageSize))
}
if err := tx.Update(&du); err != nil {
return fmt.Errorf("update total message size: %v", err)
}
return nil
}
// QuotaMessageSize returns the effective maximum total message size for an
// account. Returns 0 if there is no maximum.
func (a *Account) QuotaMessageSize() int64 {
conf, _ := a.Conf()
size := conf.QuotaMessageSize
if size == 0 {
size = mox.Conf.Static.QuotaMessageSize
}
if size < 0 {
size = 0
}
return size
}
// CanAddMessageSize checks if a message of size bytes can be added, depending on
// total message size and configured quota for account.
func (a *Account) CanAddMessageSize(tx *bstore.Tx, size int64) (ok bool, maxSize int64, err error) {
maxSize = a.QuotaMessageSize()
if maxSize <= 0 {
return true, 0, nil
}
du := DiskUsage{ID: 1}
if err := tx.Get(&du); err != nil {
return false, maxSize, fmt.Errorf("get diskusage: %v", err)
}
return du.MessageSize+size <= maxSize, maxSize, nil
}
2023-01-30 16:27:06 +03:00
// We keep a cache of recent successful authentications, so we don't have to bcrypt successful calls each time.
change mox to start as root, bind to network sockets, then drop to regular unprivileged mox user makes it easier to run on bsd's, where you cannot (easily?) let non-root users bind to ports <1024. starting as root also paves the way for future improvements with privilege separation. unfortunately, this requires changes to how you start mox. though mox will help by automatically fix up dir/file permissions/ownership. if you start mox from the systemd unit file, you should update it so it starts as root and adds a few additional capabilities: # first update the mox binary, then, as root: ./mox config printservice >mox.service systemctl daemon-reload systemctl restart mox journalctl -f -u mox & # you should see mox start up, with messages about fixing permissions on dirs/files. if you used the recommended config/ and data/ directory, in a directory just for mox, and with the mox user called "mox", this should be enough. if you don't want mox to modify dir/file permissions, set "NoFixPermissions: true" in mox.conf. if you named the mox user something else than mox, e.g. "_mox", add "User: _mox" to mox.conf. if you created a shared service user as originally suggested, you may want to get rid of that as it is no longer useful and may get in the way. e.g. if you had /home/service/mox with a "service" user, that service user can no longer access any files: only mox and root can. this also adds scripts for building mox docker images for alpine-supported platforms. the "restart" subcommand has been removed. it wasn't all that useful and got in the way. and another change: when adding a domain while mtasts isn't enabled, don't add the per-domain mtasts config, as it would cause failure to add the domain. based on report from setting up mox on openbsd from mteege. and based on issue #3. thanks for the feedback!
2023-02-27 14:19:55 +03:00
var authCache = struct {
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sync.Mutex
success map[authKey]string
change mox to start as root, bind to network sockets, then drop to regular unprivileged mox user makes it easier to run on bsd's, where you cannot (easily?) let non-root users bind to ports <1024. starting as root also paves the way for future improvements with privilege separation. unfortunately, this requires changes to how you start mox. though mox will help by automatically fix up dir/file permissions/ownership. if you start mox from the systemd unit file, you should update it so it starts as root and adds a few additional capabilities: # first update the mox binary, then, as root: ./mox config printservice >mox.service systemctl daemon-reload systemctl restart mox journalctl -f -u mox & # you should see mox start up, with messages about fixing permissions on dirs/files. if you used the recommended config/ and data/ directory, in a directory just for mox, and with the mox user called "mox", this should be enough. if you don't want mox to modify dir/file permissions, set "NoFixPermissions: true" in mox.conf. if you named the mox user something else than mox, e.g. "_mox", add "User: _mox" to mox.conf. if you created a shared service user as originally suggested, you may want to get rid of that as it is no longer useful and may get in the way. e.g. if you had /home/service/mox with a "service" user, that service user can no longer access any files: only mox and root can. this also adds scripts for building mox docker images for alpine-supported platforms. the "restart" subcommand has been removed. it wasn't all that useful and got in the way. and another change: when adding a domain while mtasts isn't enabled, don't add the per-domain mtasts config, as it would cause failure to add the domain. based on report from setting up mox on openbsd from mteege. and based on issue #3. thanks for the feedback!
2023-02-27 14:19:55 +03:00
}{
success: map[authKey]string{},
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}
type authKey struct {
email, hash string
}
change mox to start as root, bind to network sockets, then drop to regular unprivileged mox user makes it easier to run on bsd's, where you cannot (easily?) let non-root users bind to ports <1024. starting as root also paves the way for future improvements with privilege separation. unfortunately, this requires changes to how you start mox. though mox will help by automatically fix up dir/file permissions/ownership. if you start mox from the systemd unit file, you should update it so it starts as root and adds a few additional capabilities: # first update the mox binary, then, as root: ./mox config printservice >mox.service systemctl daemon-reload systemctl restart mox journalctl -f -u mox & # you should see mox start up, with messages about fixing permissions on dirs/files. if you used the recommended config/ and data/ directory, in a directory just for mox, and with the mox user called "mox", this should be enough. if you don't want mox to modify dir/file permissions, set "NoFixPermissions: true" in mox.conf. if you named the mox user something else than mox, e.g. "_mox", add "User: _mox" to mox.conf. if you created a shared service user as originally suggested, you may want to get rid of that as it is no longer useful and may get in the way. e.g. if you had /home/service/mox with a "service" user, that service user can no longer access any files: only mox and root can. this also adds scripts for building mox docker images for alpine-supported platforms. the "restart" subcommand has been removed. it wasn't all that useful and got in the way. and another change: when adding a domain while mtasts isn't enabled, don't add the per-domain mtasts config, as it would cause failure to add the domain. based on report from setting up mox on openbsd from mteege. and based on issue #3. thanks for the feedback!
2023-02-27 14:19:55 +03:00
// StartAuthCache starts a goroutine that regularly clears the auth cache.
func StartAuthCache() {
go manageAuthCache()
}
func manageAuthCache() {
for {
authCache.Lock()
authCache.success = map[authKey]string{}
authCache.Unlock()
time.Sleep(15 * time.Minute)
}
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}
// OpenEmailAuth opens an account given an email address and password.
//
// The email address may contain a catchall separator.
func OpenEmailAuth(log mlog.Log, email string, password string) (acc *Account, rerr error) {
password, err := precis.OpaqueString.String(password)
if err != nil {
return nil, ErrUnknownCredentials
}
acc, _, rerr = OpenEmail(log, email)
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if rerr != nil {
return
}
defer func() {
if rerr != nil && acc != nil {
err := acc.Close()
log.Check(err, "closing account after open auth failure")
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acc = nil
}
}()
pw, err := bstore.QueryDB[Password](context.TODO(), acc.DB).Get()
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if err != nil {
if err == bstore.ErrAbsent {
return acc, ErrUnknownCredentials
}
return acc, fmt.Errorf("looking up password: %v", err)
}
authCache.Lock()
ok := len(password) >= 8 && authCache.success[authKey{email, pw.Hash}] == password
authCache.Unlock()
if ok {
return
}
if err := bcrypt.CompareHashAndPassword([]byte(pw.Hash), []byte(password)); err != nil {
rerr = ErrUnknownCredentials
} else {
authCache.Lock()
authCache.success[authKey{email, pw.Hash}] = password
authCache.Unlock()
}
return
}
// OpenEmail opens an account given an email address.
//
// The email address may contain a catchall separator.
func OpenEmail(log mlog.Log, email string) (*Account, config.Destination, error) {
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addr, err := smtp.ParseAddress(email)
if err != nil {
return nil, config.Destination{}, fmt.Errorf("%w: %v", ErrUnknownCredentials, err)
}
accountName, _, dest, err := mox.FindAccount(addr.Localpart, addr.Domain, false)
if err != nil && (errors.Is(err, mox.ErrAccountNotFound) || errors.Is(err, mox.ErrDomainNotFound)) {
return nil, config.Destination{}, ErrUnknownCredentials
} else if err != nil {
return nil, config.Destination{}, fmt.Errorf("looking up address: %v", err)
}
acc, err := OpenAccount(log, accountName)
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if err != nil {
return nil, config.Destination{}, err
}
return acc, dest, nil
}
// 64 characters, must be power of 2 for MessagePath
const msgDirChars = "abcdefghijklmnopqrstuvwxyz0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ-_"
make mox compile on windows, without "mox serve" but with working "mox localserve" getting mox to compile required changing code in only a few places where package "syscall" was used: for accessing file access times and for umask handling. an open problem is how to start a process as an unprivileged user on windows. that's why "mox serve" isn't implemented yet. and just finding a way to implement it now may not be good enough in the near future: we may want to starting using a more complete privilege separation approach, with a process handling sensitive tasks (handling private keys, authentication), where we may want to pass file descriptors between processes. how would that work on windows? anyway, getting mox to compile for windows doesn't mean it works properly on windows. the largest issue: mox would normally open a file, rename or remove it, and finally close it. this happens during message delivery. that doesn't work on windows, the rename/remove would fail because the file is still open. so this commit swaps many "remove" and "close" calls. renames are a longer story: message delivery had two ways to deliver: with "consuming" the (temporary) message file (which would rename it to its final destination), and without consuming (by hardlinking the file, falling back to copying). the last delivery to a recipient of a message (and the only one in the common case of a single recipient) would consume the message, and the earlier recipients would not. during delivery, the already open message file was used, to parse the message. we still want to use that open message file, and the caller now stays responsible for closing it, but we no longer try to rename (consume) the file. we always hardlink (or copy) during delivery (this works on windows), and the caller is responsible for closing and removing (in that order) the original temporary file. this does cost one syscall more. but it makes the delivery code (responsibilities) a bit simpler. there is one more obvious issue: the file system path separator. mox already used the "filepath" package to join paths in many places, but not everywhere. and it still used strings with slashes for local file access. with this commit, the code now uses filepath.FromSlash for path strings with slashes, uses "filepath" in a few more places where it previously didn't. also switches from "filepath" to regular "path" package when handling mailbox names in a few places, because those always use forward slashes, regardless of local file system conventions. windows can handle forward slashes when opening files, so test code that passes path strings with forward slashes straight to go stdlib file i/o functions are left unchanged to reduce code churn. the regular non-test code, or test code that uses path strings in places other than standard i/o functions, does have the paths converted for consistent paths (otherwise we would end up with paths with mixed forward/backward slashes in log messages). windows cannot dup a listening socket. for "mox localserve", it isn't important, and we can work around the issue. the current approach for "mox serve" (forking a process and passing file descriptors of listening sockets on "privileged" ports) won't work on windows. perhaps it isn't needed on windows, and any user can listen on "privileged" ports? that would be welcome. on windows, os.Open cannot open a directory, so we cannot call Sync on it after message delivery. a cursory internet search indicates that directories cannot be synced on windows. the story is probably much more nuanced than that, with long deep technical details/discussions/disagreement/confusion, like on unix. for "mox localserve" we can get away with making syncdir a no-op.
2023-10-14 11:54:07 +03:00
// MessagePath returns the filename of the on-disk filename, relative to the
// containing directory such as <account>/msg or queue.
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// Returns names like "AB/1".
func MessagePath(messageID int64) string {
make mox compile on windows, without "mox serve" but with working "mox localserve" getting mox to compile required changing code in only a few places where package "syscall" was used: for accessing file access times and for umask handling. an open problem is how to start a process as an unprivileged user on windows. that's why "mox serve" isn't implemented yet. and just finding a way to implement it now may not be good enough in the near future: we may want to starting using a more complete privilege separation approach, with a process handling sensitive tasks (handling private keys, authentication), where we may want to pass file descriptors between processes. how would that work on windows? anyway, getting mox to compile for windows doesn't mean it works properly on windows. the largest issue: mox would normally open a file, rename or remove it, and finally close it. this happens during message delivery. that doesn't work on windows, the rename/remove would fail because the file is still open. so this commit swaps many "remove" and "close" calls. renames are a longer story: message delivery had two ways to deliver: with "consuming" the (temporary) message file (which would rename it to its final destination), and without consuming (by hardlinking the file, falling back to copying). the last delivery to a recipient of a message (and the only one in the common case of a single recipient) would consume the message, and the earlier recipients would not. during delivery, the already open message file was used, to parse the message. we still want to use that open message file, and the caller now stays responsible for closing it, but we no longer try to rename (consume) the file. we always hardlink (or copy) during delivery (this works on windows), and the caller is responsible for closing and removing (in that order) the original temporary file. this does cost one syscall more. but it makes the delivery code (responsibilities) a bit simpler. there is one more obvious issue: the file system path separator. mox already used the "filepath" package to join paths in many places, but not everywhere. and it still used strings with slashes for local file access. with this commit, the code now uses filepath.FromSlash for path strings with slashes, uses "filepath" in a few more places where it previously didn't. also switches from "filepath" to regular "path" package when handling mailbox names in a few places, because those always use forward slashes, regardless of local file system conventions. windows can handle forward slashes when opening files, so test code that passes path strings with forward slashes straight to go stdlib file i/o functions are left unchanged to reduce code churn. the regular non-test code, or test code that uses path strings in places other than standard i/o functions, does have the paths converted for consistent paths (otherwise we would end up with paths with mixed forward/backward slashes in log messages). windows cannot dup a listening socket. for "mox localserve", it isn't important, and we can work around the issue. the current approach for "mox serve" (forking a process and passing file descriptors of listening sockets on "privileged" ports) won't work on windows. perhaps it isn't needed on windows, and any user can listen on "privileged" ports? that would be welcome. on windows, os.Open cannot open a directory, so we cannot call Sync on it after message delivery. a cursory internet search indicates that directories cannot be synced on windows. the story is probably much more nuanced than that, with long deep technical details/discussions/disagreement/confusion, like on unix. for "mox localserve" we can get away with making syncdir a no-op.
2023-10-14 11:54:07 +03:00
return strings.Join(messagePathElems(messageID), string(filepath.Separator))
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
}
// messagePathElems returns the elems, for a single join without intermediate
// string allocations.
func messagePathElems(messageID int64) []string {
2023-01-30 16:27:06 +03:00
v := messageID >> 13 // 8k files per directory.
dir := ""
for {
dir += string(msgDirChars[int(v)&(len(msgDirChars)-1)])
v >>= 6
if v == 0 {
break
}
}
implement message threading in backend and webmail we match messages to their parents based on the "references" and "in-reply-to" headers (requiring the same base subject), and in absense of those headers we also by only base subject (against messages received max 4 weeks ago). we store a threadid with messages. all messages in a thread have the same threadid. messages also have a "thread parent ids", which holds all id's of parent messages up to the thread root. then there is "thread missing link", which is set when a referenced immediate parent wasn't found (but possibly earlier ancestors can still be found and will be in thread parent ids". threads can be muted: newly delivered messages are automatically marked as read/seen. threads can be marked as collapsed: if set, the webmail collapses the thread to a single item in the basic threading view (default is to expand threads). the muted and collapsed fields are copied from their parent on message delivery. the threading is implemented in the webmail. the non-threading mode still works as before. the new default threading mode "unread" automatically expands only the threads with at least one unread (not seen) meessage. the basic threading mode "on" expands all threads except when explicitly collapsed (as saved in the thread collapsed field). new shortcuts for navigation/interaction threads have been added, e.g. go to previous/next thread root, toggle collapse/expand of thread (or double click), toggle mute of thread. some previous shortcuts have changed, see the help for details. the message threading are added with an explicit account upgrade step, automatically started when an account is opened. the upgrade is done in the background because it will take too long for large mailboxes to block account operations. the upgrade takes two steps: 1. updating all message records in the database to add a normalized message-id and thread base subject (with "re:", "fwd:" and several other schemes stripped). 2. going through all messages in the database again, reading the "references" and "in-reply-to" headers from disk, and matching against their parents. this second step is also done at the end of each import of mbox/maildir mailboxes. new deliveries are matched immediately against other existing messages, currently no attempt is made to rematch previously delivered messages (which could be useful for related messages being delivered out of order). the threading is not yet exposed over imap.
2023-09-13 09:51:50 +03:00
return []string{dir, strconv.FormatInt(messageID, 10)}
2023-01-30 16:27:06 +03:00
}
// Set returns a copy of f, with each flag that is true in mask set to the
// value from flags.
func (f Flags) Set(mask, flags Flags) Flags {
set := func(d *bool, m, v bool) {
if m {
*d = v
}
}
r := f
set(&r.Seen, mask.Seen, flags.Seen)
set(&r.Answered, mask.Answered, flags.Answered)
set(&r.Flagged, mask.Flagged, flags.Flagged)
set(&r.Forwarded, mask.Forwarded, flags.Forwarded)
set(&r.Junk, mask.Junk, flags.Junk)
set(&r.Notjunk, mask.Notjunk, flags.Notjunk)
set(&r.Deleted, mask.Deleted, flags.Deleted)
set(&r.Draft, mask.Draft, flags.Draft)
set(&r.Phishing, mask.Phishing, flags.Phishing)
set(&r.MDNSent, mask.MDNSent, flags.MDNSent)
return r
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// Changed returns a mask of flags that have been between f and other.
func (f Flags) Changed(other Flags) (mask Flags) {
mask.Seen = f.Seen != other.Seen
mask.Answered = f.Answered != other.Answered
mask.Flagged = f.Flagged != other.Flagged
mask.Forwarded = f.Forwarded != other.Forwarded
mask.Junk = f.Junk != other.Junk
mask.Notjunk = f.Notjunk != other.Notjunk
mask.Deleted = f.Deleted != other.Deleted
mask.Draft = f.Draft != other.Draft
mask.Phishing = f.Phishing != other.Phishing
mask.MDNSent = f.MDNSent != other.MDNSent
return
}
var systemWellKnownFlags = map[string]bool{
`\answered`: true,
`\flagged`: true,
`\deleted`: true,
`\seen`: true,
`\draft`: true,
`$junk`: true,
`$notjunk`: true,
`$forwarded`: true,
`$phishing`: true,
`$mdnsent`: true,
}
// ParseFlagsKeywords parses a list of textual flags into system/known flags, and
// other keywords. Keywords are lower-cased and sorted and check for valid syntax.
func ParseFlagsKeywords(l []string) (flags Flags, keywords []string, rerr error) {
fields := map[string]*bool{
`\answered`: &flags.Answered,
`\flagged`: &flags.Flagged,
`\deleted`: &flags.Deleted,
`\seen`: &flags.Seen,
`\draft`: &flags.Draft,
`$junk`: &flags.Junk,
`$notjunk`: &flags.Notjunk,
`$forwarded`: &flags.Forwarded,
`$phishing`: &flags.Phishing,
`$mdnsent`: &flags.MDNSent,
}
seen := map[string]bool{}
for _, f := range l {
f = strings.ToLower(f)
if field, ok := fields[f]; ok {
*field = true
} else if seen[f] {
if mox.Pedantic {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
return Flags{}, nil, fmt.Errorf("duplicate keyword %s", f)
}
} else {
if err := CheckKeyword(f); err != nil {
return Flags{}, nil, fmt.Errorf("invalid keyword %s", f)
}
keywords = append(keywords, f)
seen[f] = true
}
}
sort.Strings(keywords)
return flags, keywords, nil
}
// RemoveKeywords removes keywords from l, returning whether any modifications were
// made, and a slice, a new slice in case of modifications. Keywords must have been
// validated earlier, e.g. through ParseFlagKeywords or CheckKeyword. Should only
// be used with valid keywords, not with system flags like \Seen.
func RemoveKeywords(l, remove []string) ([]string, bool) {
var copied bool
var changed bool
for _, k := range remove {
if i := slices.Index(l, k); i >= 0 {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if !copied {
l = append([]string{}, l...)
copied = true
}
copy(l[i:], l[i+1:])
l = l[:len(l)-1]
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
changed = true
2023-01-30 16:27:06 +03:00
}
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
return l, changed
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// MergeKeywords adds keywords from add into l, returning whether it added any
// keyword, and the slice with keywords, a new slice if modifications were made.
// Keywords are only added if they aren't already present. Should only be used with
// keywords, not with system flags like \Seen.
func MergeKeywords(l, add []string) ([]string, bool) {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
var copied bool
var changed bool
for _, k := range add {
if !slices.Contains(l, k) {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if !copied {
l = append([]string{}, l...)
copied = true
}
l = append(l, k)
changed = true
}
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if changed {
sort.Strings(l)
}
return l, changed
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// CheckKeyword returns an error if kw is not a valid keyword. Kw should
// already be in lower-case.
func CheckKeyword(kw string) error {
if kw == "" {
return fmt.Errorf("keyword cannot be empty")
}
if systemWellKnownFlags[kw] {
return fmt.Errorf("cannot use well-known flag as keyword")
}
for _, c := range kw {
// ../rfc/9051:6334
if c <= ' ' || c > 0x7e || c >= 'A' && c <= 'Z' || strings.ContainsRune(`(){%*"\]`, c) {
return errors.New(`not a valid keyword, must be lower-case ascii without spaces and without any of these characters: (){%*"\]`)
}
}
return nil
}
// SendLimitReached checks whether sending a message to recipients would reach
// the limit of outgoing messages for the account. If so, the message should
// not be sent. If the returned numbers are >= 0, the limit was reached and the
// values are the configured limits.
//
// To limit damage to the internet and our reputation in case of account
// compromise, we limit the max number of messages sent in a 24 hour window, both
// total number of messages and number of first-time recipients.
func (a *Account) SendLimitReached(tx *bstore.Tx, recipients []smtp.Path) (msglimit, rcptlimit int, rerr error) {
conf, _ := a.Conf()
msgmax := conf.MaxOutgoingMessagesPerDay
if msgmax == 0 {
// For human senders, 1000 recipients in a day is quite a lot.
msgmax = 1000
}
rcptmax := conf.MaxFirstTimeRecipientsPerDay
if rcptmax == 0 {
// Human senders may address a new human-sized list of people once in a while. In
// case of a compromise, a spammer will probably try to send to many new addresses.
rcptmax = 200
}
rcpts := map[string]time.Time{}
n := 0
err := bstore.QueryTx[Outgoing](tx).FilterGreater("Submitted", time.Now().Add(-24*time.Hour)).ForEach(func(o Outgoing) error {
n++
if rcpts[o.Recipient].IsZero() || o.Submitted.Before(rcpts[o.Recipient]) {
rcpts[o.Recipient] = o.Submitted
}
return nil
})
if err != nil {
return -1, -1, fmt.Errorf("querying message recipients in past 24h: %w", err)
}
if n+len(recipients) > msgmax {
return msgmax, -1, nil
}
// Only check if max first-time recipients is reached if there are enough messages
// to trigger the limit.
if n+len(recipients) < rcptmax {
return -1, -1, nil
}
isFirstTime := func(rcpt string, before time.Time) (bool, error) {
exists, err := bstore.QueryTx[Outgoing](tx).FilterNonzero(Outgoing{Recipient: rcpt}).FilterLess("Submitted", before).Exists()
return !exists, err
}
firsttime := 0
now := time.Now()
for _, r := range recipients {
if first, err := isFirstTime(r.XString(true), now); err != nil {
return -1, -1, fmt.Errorf("checking whether recipient is first-time: %v", err)
} else if first {
firsttime++
}
}
for r, t := range rcpts {
if first, err := isFirstTime(r, t); err != nil {
return -1, -1, fmt.Errorf("checking whether recipient is first-time: %v", err)
} else if first {
firsttime++
}
}
if firsttime > rcptmax {
return -1, rcptmax, nil
}
return -1, -1, nil
}
// MailboxCreate creates a new mailbox, including any missing parent mailboxes,
// the total list of created mailboxes is returned in created. On success, if
// exists is false and rerr nil, the changes must be broadcasted by the caller.
//
// Name must be in normalized form.
func (a *Account) MailboxCreate(tx *bstore.Tx, name string) (changes []Change, created []string, exists bool, rerr error) {
elems := strings.Split(name, "/")
var p string
for i, elem := range elems {
if i > 0 {
p += "/"
}
p += elem
exists, err := a.MailboxExists(tx, p)
if err != nil {
return nil, nil, false, fmt.Errorf("checking if mailbox exists")
}
if exists {
if i == len(elems)-1 {
return nil, nil, true, fmt.Errorf("mailbox already exists")
}
continue
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
_, nchanges, err := a.MailboxEnsure(tx, p, true)
if err != nil {
return nil, nil, false, fmt.Errorf("ensuring mailbox exists")
}
changes = append(changes, nchanges...)
created = append(created, p)
}
return changes, created, false, nil
}
// MailboxRename renames mailbox mbsrc to dst, and any missing parents for the
// destination, and any children of mbsrc and the destination.
//
// Names must be normalized and cannot be Inbox.
func (a *Account) MailboxRename(tx *bstore.Tx, mbsrc Mailbox, dst string) (changes []Change, isInbox, notExists, alreadyExists bool, rerr error) {
if mbsrc.Name == "Inbox" || dst == "Inbox" {
return nil, true, false, false, fmt.Errorf("inbox cannot be renamed")
}
// We gather existing mailboxes that we need for deciding what to create/delete/update.
q := bstore.QueryTx[Mailbox](tx)
srcPrefix := mbsrc.Name + "/"
dstRoot := strings.SplitN(dst, "/", 2)[0]
dstRootPrefix := dstRoot + "/"
q.FilterFn(func(mb Mailbox) bool {
return mb.Name == mbsrc.Name || strings.HasPrefix(mb.Name, srcPrefix) || mb.Name == dstRoot || strings.HasPrefix(mb.Name, dstRootPrefix)
})
q.SortAsc("Name") // We'll rename the parents before children.
l, err := q.List()
if err != nil {
return nil, false, false, false, fmt.Errorf("listing relevant mailboxes: %v", err)
}
mailboxes := map[string]Mailbox{}
for _, mb := range l {
mailboxes[mb.Name] = mb
}
if _, ok := mailboxes[mbsrc.Name]; !ok {
return nil, false, true, false, fmt.Errorf("mailbox does not exist")
}
uidval, err := a.NextUIDValidity(tx)
if err != nil {
return nil, false, false, false, fmt.Errorf("next uid validity: %v", err)
}
// Ensure parent mailboxes for the destination paths exist.
var parent string
dstElems := strings.Split(dst, "/")
for i, elem := range dstElems[:len(dstElems)-1] {
if i > 0 {
parent += "/"
}
parent += elem
mb, ok := mailboxes[parent]
if ok {
continue
}
omb := mb
mb = Mailbox{
ID: omb.ID,
Name: parent,
UIDValidity: uidval,
UIDNext: 1,
HaveCounts: true,
}
if err := tx.Insert(&mb); err != nil {
return nil, false, false, false, fmt.Errorf("creating parent mailbox %q: %v", mb.Name, err)
}
if err := tx.Get(&Subscription{Name: parent}); err != nil {
if err := tx.Insert(&Subscription{Name: parent}); err != nil {
return nil, false, false, false, fmt.Errorf("creating subscription for %q: %v", parent, err)
}
}
changes = append(changes, ChangeAddMailbox{Mailbox: mb, Flags: []string{`\Subscribed`}})
}
// Process src mailboxes, renaming them to dst.
for _, srcmb := range l {
if srcmb.Name != mbsrc.Name && !strings.HasPrefix(srcmb.Name, srcPrefix) {
continue
}
srcName := srcmb.Name
dstName := dst + srcmb.Name[len(mbsrc.Name):]
if _, ok := mailboxes[dstName]; ok {
return nil, false, false, true, fmt.Errorf("destination mailbox %q already exists", dstName)
}
srcmb.Name = dstName
srcmb.UIDValidity = uidval
if err := tx.Update(&srcmb); err != nil {
return nil, false, false, false, fmt.Errorf("renaming mailbox: %v", err)
}
var dstFlags []string
if tx.Get(&Subscription{Name: dstName}) == nil {
dstFlags = []string{`\Subscribed`}
}
changes = append(changes, ChangeRenameMailbox{MailboxID: srcmb.ID, OldName: srcName, NewName: dstName, Flags: dstFlags})
}
// If we renamed e.g. a/b to a/b/c/d, and a/b/c to a/b/c/d/c, we'll have to recreate a/b and a/b/c.
srcElems := strings.Split(mbsrc.Name, "/")
xsrc := mbsrc.Name
for i := 0; i < len(dstElems) && strings.HasPrefix(dst, xsrc+"/"); i++ {
mb := Mailbox{
UIDValidity: uidval,
UIDNext: 1,
Name: xsrc,
HaveCounts: true,
}
if err := tx.Insert(&mb); err != nil {
return nil, false, false, false, fmt.Errorf("creating mailbox at old path %q: %v", mb.Name, err)
}
xsrc += "/" + dstElems[len(srcElems)+i]
}
return changes, false, false, false, nil
}
// MailboxDelete deletes a mailbox by ID. If it has children, the return value
// indicates that and an error is returned.
//
// Caller should broadcast the changes and remove files for the removed message IDs.
func (a *Account) MailboxDelete(ctx context.Context, log mlog.Log, tx *bstore.Tx, mailbox Mailbox) (changes []Change, removeMessageIDs []int64, hasChildren bool, rerr error) {
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// Look for existence of child mailboxes. There is a lot of text in the IMAP RFCs about
// NoInferior and NoSelect. We just require only leaf mailboxes are deleted.
qmb := bstore.QueryTx[Mailbox](tx)
mbprefix := mailbox.Name + "/"
qmb.FilterFn(func(mb Mailbox) bool {
return strings.HasPrefix(mb.Name, mbprefix)
})
if childExists, err := qmb.Exists(); err != nil {
return nil, nil, false, fmt.Errorf("checking if mailbox has child: %v", err)
} else if childExists {
return nil, nil, true, fmt.Errorf("mailbox has a child, only leaf mailboxes can be deleted")
}
// todo jmap: instead of completely deleting a mailbox and its messages, we need to mark them all as expunged.
qm := bstore.QueryTx[Message](tx)
qm.FilterNonzero(Message{MailboxID: mailbox.ID})
remove, err := qm.List()
if err != nil {
return nil, nil, false, fmt.Errorf("listing messages to remove: %v", err)
}
if len(remove) > 0 {
removeIDs := make([]any, len(remove))
for i, m := range remove {
removeIDs[i] = m.ID
}
qmr := bstore.QueryTx[Recipient](tx)
qmr.FilterEqual("MessageID", removeIDs...)
if _, err = qmr.Delete(); err != nil {
return nil, nil, false, fmt.Errorf("removing message recipients for messages: %v", err)
}
qm = bstore.QueryTx[Message](tx)
qm.FilterNonzero(Message{MailboxID: mailbox.ID})
if _, err := qm.Delete(); err != nil {
return nil, nil, false, fmt.Errorf("removing messages: %v", err)
}
var totalSize int64
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
for _, m := range remove {
if !m.Expunged {
removeMessageIDs = append(removeMessageIDs, m.ID)
totalSize += m.Size
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
}
}
if err := a.AddMessageSize(log, tx, -totalSize); err != nil {
return nil, nil, false, fmt.Errorf("updating disk usage: %v", err)
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
// Mark messages as not needing training. Then retrain them, so they are untrained if they were.
n := 0
o := 0
for _, m := range remove {
if !m.Expunged {
remove[o] = m
remove[o].Junk = false
remove[o].Notjunk = false
n++
}
}
remove = remove[:n]
if err := a.RetrainMessages(ctx, log, tx, remove, true); err != nil {
return nil, nil, false, fmt.Errorf("untraining deleted messages: %v", err)
}
}
if err := tx.Delete(&Mailbox{ID: mailbox.ID}); err != nil {
return nil, nil, false, fmt.Errorf("removing mailbox: %v", err)
}
return []Change{ChangeRemoveMailbox{MailboxID: mailbox.ID, Name: mailbox.Name}}, removeMessageIDs, false, nil
}
// CheckMailboxName checks if name is valid, returning an INBOX-normalized name.
// I.e. it changes various casings of INBOX and INBOX/* to Inbox and Inbox/*.
// Name is invalid if it contains leading/trailing/double slashes, or when it isn't
// unicode-normalized, or when empty or has special characters.
//
// If name is the inbox, and allowInbox is false, this is indicated with the isInbox return parameter.
// For that case, and for other invalid names, an error is returned.
func CheckMailboxName(name string, allowInbox bool) (normalizedName string, isInbox bool, rerr error) {
first := strings.SplitN(name, "/", 2)[0]
if strings.EqualFold(first, "inbox") {
if len(name) == len("inbox") && !allowInbox {
return "", true, fmt.Errorf("special mailbox name Inbox not allowed")
}
name = "Inbox" + name[len("Inbox"):]
}
if norm.NFC.String(name) != name {
return "", false, errors.New("non-unicode-normalized mailbox names not allowed")
}
if name == "" {
return "", false, errors.New("empty mailbox name")
}
if strings.HasPrefix(name, "/") || strings.HasSuffix(name, "/") || strings.Contains(name, "//") {
return "", false, errors.New("bad slashes in mailbox name")
}
// "%" and "*" are difficult to use with the IMAP LIST command, but we allow mostly
// allow them. ../rfc/3501:1002 ../rfc/9051:983
if strings.HasPrefix(name, "#") {
return "", false, errors.New("mailbox name cannot start with hash due to conflict with imap namespaces")
}
// "#" and "&" are special in IMAP mailbox names. "#" for namespaces, "&" for
// IMAP-UTF-7 encoding. We do allow them. ../rfc/3501:1018 ../rfc/9051:991
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
for _, c := range name {
// ../rfc/3501:999 ../rfc/6855:192 ../rfc/9051:979
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
if c <= 0x1f || c >= 0x7f && c <= 0x9f || c == 0x2028 || c == 0x2029 {
return "", false, errors.New("control characters not allowed in mailbox name")
}
}
add webmail it was far down on the roadmap, but implemented earlier, because it's interesting, and to help prepare for a jmap implementation. for jmap we need to implement more client-like functionality than with just imap. internal data structures need to change. jmap has lots of other requirements, so it's already a big project. by implementing a webmail now, some of the required data structure changes become clear and can be made now, so the later jmap implementation can do things similarly to the webmail code. the webmail frontend and webmail are written together, making their interface/api much smaller and simpler than jmap. one of the internal changes is that we now keep track of per-mailbox total/unread/unseen/deleted message counts and mailbox sizes. keeping this data consistent after any change to the stored messages (through the code base) is tricky, so mox now has a consistency check that verifies the counts are correct, which runs only during tests, each time an internal account reference is closed. we have a few more internal "changes" that are propagated for the webmail frontend (that imap doesn't have a way to propagate on a connection), like changes to the special-use flags on mailboxes, and used keywords in a mailbox. more changes that will be required have revealed themselves while implementing the webmail, and will be implemented next. the webmail user interface is modeled after the mail clients i use or have used: thunderbird, macos mail, mutt; and webmails i normally only use for testing: gmail, proton, yahoo, outlook. a somewhat technical user is assumed, but still the goal is to make this webmail client easy to use for everyone. the user interface looks like most other mail clients: a list of mailboxes, a search bar, a message list view, and message details. there is a top/bottom and a left/right layout for the list/message view, default is automatic based on screen size. the panes can be resized by the user. buttons for actions are just text, not icons. clicking a button briefly shows the shortcut for the action in the bottom right, helping with learning to operate quickly. any text that is underdotted has a title attribute that causes more information to be displayed, e.g. what a button does or a field is about. to highlight potential phishing attempts, any text (anywhere in the webclient) that switches unicode "blocks" (a rough approximation to (language) scripts) within a word is underlined orange. multiple messages can be selected with familiar ui interaction: clicking while holding control and/or shift keys. keyboard navigation works with arrows/page up/down and home/end keys, and also with a few basic vi-like keys for list/message navigation. we prefer showing the text instead of html (with inlined images only) version of a message. html messages are shown in an iframe served from an endpoint with CSP headers to prevent dangerous resources (scripts, external images) from being loaded. the html is also sanitized, with javascript removed. a user can choose to load external resources (e.g. images for tracking purposes). the frontend is just (strict) typescript, no external frameworks. all incoming/outgoing data is typechecked, both the api request parameters and response types, and the data coming in over SSE. the types and checking code are generated with sherpats, which uses the api definitions generated by sherpadoc based on the Go code. so types from the backend are automatically propagated to the frontend. since there is no framework to automatically propagate properties and rerender components, changes coming in over the SSE connection are propagated explicitly with regular function calls. the ui is separated into "views", each with a "root" dom element that is added to the visible document. these views have additional functions for getting changes propagated, often resulting in the view updating its (internal) ui state (dom). we keep the frontend compilation simple, it's just a few typescript files that get compiled (combined and types stripped) into a single js file, no additional runtime code needed or complicated build processes used. the webmail is served is served from a compressed, cachable html file that includes style and the javascript, currently just over 225kb uncompressed, under 60kb compressed (not minified, including comments). we include the generated js files in the repository, to keep Go's easily buildable self-contained binaries. authentication is basic http, as with the account and admin pages. most data comes in over one long-term SSE connection to the backend. api requests signal which mailbox/search/messages are requested over the SSE connection. fetching individual messages, and making changes, are done through api calls. the operations are similar to imap, so some code has been moved from package imapserver to package store. the future jmap implementation will benefit from these changes too. more functionality will probably be moved to the store package in the future. the quickstart enables webmail on the internal listener by default (for new installs). users can enable it on the public listener if they want to. mox localserve enables it too. to enable webmail on existing installs, add settings like the following to the listeners in mox.conf, similar to AccountHTTP(S): WebmailHTTP: Enabled: true WebmailHTTPS: Enabled: true special thanks to liesbeth, gerben, andrii for early user feedback. there is plenty still to do, see the list at the top of webmail/webmail.ts. feedback welcome as always.
2023-08-07 22:57:03 +03:00
return name, false, nil
2023-01-30 16:27:06 +03:00
}