mox/smtpserver/reputation.go

381 lines
13 KiB
Go

package smtpserver
import (
"errors"
"fmt"
"time"
"github.com/mjl-/bstore"
"github.com/mjl-/mox/mlog"
"github.com/mjl-/mox/smtp"
"github.com/mjl-/mox/store"
)
type reputationMethod string
const (
methodMsgfromFull reputationMethod = "msgfromfull"
methodMsgtoFull reputationMethod = "msgtofull"
methodMsgfromDomain reputationMethod = "msgfromdomain"
methodMsgfromOrgDomain reputationMethod = "msgfromorgdomain"
methodMsgtoDomain reputationMethod = "msgtodomain"
methodMsgtoOrgDomain reputationMethod = "msgtoorgdomain"
methodDKIMSPF reputationMethod = "dkimspf"
methodIP1 reputationMethod = "ip1"
methodIP2 reputationMethod = "ip2"
methodIP3 reputationMethod = "ip3"
methodNone reputationMethod = "none"
)
// Reputation returns whether message m is likely junk.
//
// This function is called after checking for a manually configured spf mailfrom
// allow (e.g. for mailing lists), and after checking for a dmarc reject policy.
//
// The decision is made based on historic messages delivered to the same
// destination mailbox, MailboxOrigID. Because each mailbox may have a different
// accept policy. We only use messages that have been marked as either junk or
// non-junk. We help users by automatically marking them as non-junk when moving to
// certain folders in the default config (e.g. the archive folder). We expect users
// to mark junk messages as such when they read it. And to keep it in their inbox,
// regular trash or archive if it is not.
//
// The basic idea is to keep accepting messages that were accepted in the past, and
// keep rejecting those that were rejected. This is relatively easy to check if
// mail passes SPF and/or DKIM with Message-From alignment. Regular email from
// known people will be let in. But spammers are trickier. They will use new IPs,
// (sub)domains, no or newly created SPF and/or DKIM identifiers, new localparts,
// etc. This function likely ends up returning "inconclusive" for such emails. The
// junkfilter will have to take care of a final decision.
//
// In case of doubt, it doesn't hurt much to accept another mail that a user has
// communicated successfully with in the past. If the most recent message is marked
// as junk that could have happened accidentally. If another message is let in, and
// it is again junk, future messages will be rejected.
//
// Actual spammers will probably try to use identifiers, i.e. (sub)domain, dkim/spf
// identifiers and ip addresses for which we have no history. We may only have
// ip-based reputation, perhaps only an ip range, perhaps nothing.
//
// Some profiles of first-time senders:
//
// - Individuals. They can typically get past the junkfilter if needed.
// - Transactional emails. They should get past the junkfilter. If they use one of
// the larger email service providers, their reputation could help. If the
// junkfilter rejects the message, users can recover the message from the Rejects
// mailbox. The first message is typically initiated by a user, e.g. by registering.
// - Desired commercial email will have to get past the junkfilter based on its
// content. There will typically be earlier communication with the (organizational)
// domain that would let the message through.
// - Mailing list. May get past the junkfilter. If delivery is to a separate
// mailbox, the junkfilter will let it in because of little history. Long enough to
// build reputation based on DKIM/SPF signals. Users are best off to
// configure accept rules for messages from mailing lists.
//
// The decision-making process looks at historic messages. The following properties
// are checked until matching messages are found. If they are found, a decision is
// returned, which may be inconclusive. The next property on the list is only
// checked if a step did not match any messages.
//
// - Messages matching full "message from" address, either with strict/relaxed
// dkim/spf-verification, or without.
// - Messages the user sent to the "message from" address.
// - Messages matching only the domain of the "message from" address (different
// localpart), again with verification or without.
// - Messages sent to an address in the domain of the "message from" address.
// - The previous two checks again, but now checking against the organizational
// domain instead of the exact domain.
// - Matching DKIM domains and a matching SPF mailfrom, or mailfrom domain, or ehlo
// domain.
// - "Exact" IP, or nearby IPs.
//
// References:
// ../rfc/5863
// ../rfc/7960
// ../rfc/6376:1915
// ../rfc/6376:3716
// ../rfc/7208:2167
func reputation(tx *bstore.Tx, log *mlog.Log, m *store.Message) (rjunk *bool, rconclusive bool, rmethod reputationMethod, rerr error) {
boolptr := func(v bool) *bool {
return &v
}
xfalse := boolptr(false)
xtrue := boolptr(true)
type queryError string
defer func() {
x := recover()
if x == nil {
return
}
if xerr, ok := x.(queryError); ok {
rerr = errors.New(string(xerr))
return
}
panic(x)
}()
now := time.Now()
// messageQuery returns a base query for historic seen messages to the same
// mailbox, at most maxAge old, and at most maxCount messages.
messageQuery := func(fm *store.Message, maxAge time.Duration, maxCount int) *bstore.Query[store.Message] {
q := bstore.QueryTx[store.Message](tx)
q.FilterEqual("MailboxOrigID", m.MailboxID)
q.FilterEqual("Expunged", false)
q.FilterFn(func(m store.Message) bool {
return m.Junk || m.Notjunk
})
if fm != nil {
q.FilterNonzero(*fm)
}
q.FilterGreaterEqual("Received", now.Add(-maxAge))
q.Limit(maxCount)
q.SortDesc("Received")
return q
}
// Execute the query, returning messages or returning error through panic.
xmessageList := func(q *bstore.Query[store.Message], descr string) []store.Message {
t0 := time.Now()
l, err := q.List()
log.Debugx("querying messages for reputation", err, mlog.Field("msgs", len(l)), mlog.Field("descr", descr), mlog.Field("queryduration", time.Since(t0)))
if err != nil {
panic(queryError(fmt.Sprintf("listing messages: %v", err)))
}
return l
}
xrecipientExists := func(q *bstore.Query[store.Recipient]) bool {
exists, err := q.Exists()
if err != nil {
panic(queryError(fmt.Sprintf("checking for recipient: %v", err)))
}
return exists
}
const year = 365 * 24 * time.Hour
// Look for historic messages with same "message from" address. We'll
// treat any validation (strict/dmarc/relaxed) the same, but "none"
// separately.
//
// We only need 1 message, and sometimes look at a second message. If
// the last message or the message before was an accept, we accept. If
// the single last or last two were a reject, we reject.
//
// If there was no validation, any signal is inconclusive.
if m.MsgFromDomain != "" {
q := messageQuery(&store.Message{MsgFromLocalpart: m.MsgFromLocalpart, MsgFromDomain: m.MsgFromDomain}, 3*year, 2)
q.FilterEqual("MsgFromValidated", m.MsgFromValidated)
msgs := xmessageList(q, "mgsfromfull")
if len(msgs) > 0 {
// todo: we may want to look at dkim/spf in this case.
spam := msgs[0].Junk && (len(msgs) == 1 || msgs[1].Junk)
conclusive := m.MsgFromValidated
return &spam, conclusive, methodMsgfromFull, nil
}
if !m.MsgFromValidated {
// Look for historic messages that were validated. If present, this is likely spam.
// Only return as conclusively spam if history also says this From-address sent
// spam.
q := messageQuery(&store.Message{MsgFromLocalpart: m.MsgFromLocalpart, MsgFromDomain: m.MsgFromDomain, MsgFromValidated: true}, 3*year, 2)
msgs = xmessageList(q, "msgfromfull-validated")
if len(msgs) > 0 {
spam := msgs[0].Junk && (len(msgs) == 1 || msgs[1].Junk)
return xtrue, spam, methodMsgfromFull, nil
}
}
// Look if we ever sent to this address. If so, we accept,
qr := bstore.QueryTx[store.Recipient](tx)
qr.FilterEqual("Localpart", m.MsgFromLocalpart)
qr.FilterEqual("Domain", m.MsgFromDomain)
qr.FilterGreaterEqual("Sent", now.Add(-3*year))
if xrecipientExists(qr) {
return xfalse, true, methodMsgtoFull, nil
}
// Look for domain match, then for organizational domain match.
for _, orgdomain := range []bool{false, true} {
qm := store.Message{}
var method reputationMethod
var descr string
if orgdomain {
qm.MsgFromOrgDomain = m.MsgFromOrgDomain
method = methodMsgfromOrgDomain
descr = "msgfromorgdomain"
} else {
qm.MsgFromDomain = m.MsgFromDomain
method = methodMsgfromDomain
descr = "msgfromdomain"
}
q := messageQuery(&qm, 2*year, 20)
q.FilterEqual("MsgFromValidated", m.MsgFromValidated)
msgs := xmessageList(q, descr)
if len(msgs) > 0 {
nonjunk := 0
for _, m := range msgs {
if !m.Junk {
nonjunk++
}
}
if 100*nonjunk/len(msgs) > 80 {
return xfalse, true, method, nil
}
if nonjunk == 0 {
// Only conclusive with at least 3 different localparts.
localparts := map[smtp.Localpart]struct{}{}
for _, m := range msgs {
localparts[m.MsgFromLocalpart] = struct{}{}
if len(localparts) == 3 {
return xtrue, true, method, nil
}
}
return xtrue, false, method, nil
}
// Mixed signals from domain. We don't want to block a new sender.
return nil, false, method, nil
}
if !m.MsgFromValidated {
// Look for historic messages that were validated. If present, this is likely spam.
// Only return as conclusively spam if history also says this From-address sent
// spam.
q := messageQuery(&qm, 2*year, 2)
q.FilterEqual("MsgFromValidated", true)
msgs = xmessageList(q, descr+"-validated")
if len(msgs) > 0 {
spam := msgs[0].Junk && (len(msgs) == 1 || msgs[1].Junk)
return xtrue, spam, method, nil
}
}
// Look if we ever sent to this address. If so, we accept,
qr := bstore.QueryTx[store.Recipient](tx)
if orgdomain {
qr.FilterEqual("OrgDomain", m.MsgFromOrgDomain)
method = methodMsgtoOrgDomain
} else {
qr.FilterEqual("Domain", m.MsgFromDomain)
method = methodMsgtoDomain
}
qr.FilterGreaterEqual("Sent", now.Add(-2*year))
if xrecipientExists(qr) {
return xfalse, true, method, nil
}
}
}
// DKIM and SPF.
// We only use identities that passed validation. Failed identities are ignored. ../rfc/6376:2447
// todo future: we could do something with the DKIM identity (i=) field if it is more specific than just the domain (d=).
dkimspfsignals := []float64{}
dkimspfmsgs := 0
for _, dom := range m.DKIMDomains {
q := messageQuery(nil, year/2, 50)
q.FilterIn("DKIMDomains", dom)
msgs := xmessageList(q, "dkimdomain")
if len(msgs) > 0 {
nspam := 0
for _, m := range msgs {
if m.Junk {
nspam++
}
}
pspam := float64(nspam) / float64(len(msgs))
dkimspfsignals = append(dkimspfsignals, pspam)
dkimspfmsgs = len(msgs)
}
}
if m.MailFromValidated || m.EHLOValidated {
var msgs []store.Message
if m.MailFromValidated && m.MailFromDomain != "" {
q := messageQuery(&store.Message{MailFromLocalpart: m.MailFromLocalpart, MailFromDomain: m.MailFromDomain}, year/2, 50)
msgs = xmessageList(q, "mailfrom")
if len(msgs) == 0 {
q := messageQuery(&store.Message{MailFromDomain: m.MailFromDomain}, year/2, 50)
msgs = xmessageList(q, "mailfromdomain")
}
}
if len(msgs) == 0 && m.EHLOValidated && m.EHLODomain != "" {
q := messageQuery(&store.Message{EHLODomain: m.EHLODomain}, year/2, 50)
msgs = xmessageList(q, "ehlodomain")
}
if len(msgs) > 0 {
nspam := 0
for _, m := range msgs {
if m.Junk {
nspam++
}
}
pspam := float64(nspam) / float64(len(msgs))
dkimspfsignals = append(dkimspfsignals, pspam)
if len(msgs) > dkimspfmsgs {
dkimspfmsgs = len(msgs)
}
}
}
if len(dkimspfsignals) > 0 {
var nham, nspam int
for _, p := range dkimspfsignals {
if p < .1 {
nham++
} else if p > .9 {
nspam++
}
}
if nham > 0 && nspam == 0 {
return xfalse, true, methodDKIMSPF, nil
}
if nspam > 0 && nham == 0 {
return xtrue, dkimspfmsgs > 1, methodDKIMSPF, nil
}
return nil, false, methodDKIMSPF, nil
}
// IP-based. A wider mask needs more messages to be conclusive.
// We require the resulting signal to be strong, i.e. likely ham or likely spam.
var msgs []store.Message
var need int
var method reputationMethod
if m.RemoteIPMasked1 != "" {
q := messageQuery(&store.Message{RemoteIPMasked1: m.RemoteIPMasked1}, year/4, 50)
msgs = xmessageList(q, "ip1")
need = 2
method = methodIP1
}
if len(msgs) == 0 && m.RemoteIPMasked2 != "" {
q := messageQuery(&store.Message{RemoteIPMasked2: m.RemoteIPMasked2}, year/4, 50)
msgs = xmessageList(q, "ip2")
need = 5
method = methodIP2
}
if len(msgs) == 0 && m.RemoteIPMasked3 != "" {
q := messageQuery(&store.Message{RemoteIPMasked3: m.RemoteIPMasked3}, year/4, 50)
msgs = xmessageList(q, "ip3")
need = 10
method = methodIP3
}
if len(msgs) > 0 {
nspam := 0
for _, m := range msgs {
if m.Junk {
nspam++
}
}
pspam := float64(nspam) / float64(len(msgs))
var spam *bool
if pspam < .25 {
spam = xfalse
} else if pspam > .75 {
spam = xtrue
}
conclusive := len(msgs) >= need && (pspam <= 0.1 || pspam >= 0.9)
return spam, conclusive, method, nil
}
return nil, false, methodNone, nil
}