mox/vendor/golang.org/x/sys/windows/security_windows.go

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2023-01-30 16:27:06 +03:00
// Copyright 2012 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package windows
import (
"syscall"
"unsafe"
)
const (
NameUnknown = 0
NameFullyQualifiedDN = 1
NameSamCompatible = 2
NameDisplay = 3
NameUniqueId = 6
NameCanonical = 7
NameUserPrincipal = 8
NameCanonicalEx = 9
NameServicePrincipal = 10
NameDnsDomain = 12
)
// This function returns 1 byte BOOLEAN rather than the 4 byte BOOL.
// http://blogs.msdn.com/b/drnick/archive/2007/12/19/windows-and-upn-format-credentials.aspx
//sys TranslateName(accName *uint16, accNameFormat uint32, desiredNameFormat uint32, translatedName *uint16, nSize *uint32) (err error) [failretval&0xff==0] = secur32.TranslateNameW
//sys GetUserNameEx(nameFormat uint32, nameBuffre *uint16, nSize *uint32) (err error) [failretval&0xff==0] = secur32.GetUserNameExW
// TranslateAccountName converts a directory service
// object name from one format to another.
func TranslateAccountName(username string, from, to uint32, initSize int) (string, error) {
u, e := UTF16PtrFromString(username)
if e != nil {
return "", e
}
n := uint32(50)
for {
b := make([]uint16, n)
e = TranslateName(u, from, to, &b[0], &n)
if e == nil {
return UTF16ToString(b[:n]), nil
}
if e != ERROR_INSUFFICIENT_BUFFER {
return "", e
}
if n <= uint32(len(b)) {
return "", e
}
}
}
const (
// do not reorder
NetSetupUnknownStatus = iota
NetSetupUnjoined
NetSetupWorkgroupName
NetSetupDomainName
)
type UserInfo10 struct {
Name *uint16
Comment *uint16
UsrComment *uint16
FullName *uint16
}
//sys NetUserGetInfo(serverName *uint16, userName *uint16, level uint32, buf **byte) (neterr error) = netapi32.NetUserGetInfo
//sys NetGetJoinInformation(server *uint16, name **uint16, bufType *uint32) (neterr error) = netapi32.NetGetJoinInformation
//sys NetApiBufferFree(buf *byte) (neterr error) = netapi32.NetApiBufferFree
const (
// do not reorder
SidTypeUser = 1 + iota
SidTypeGroup
SidTypeDomain
SidTypeAlias
SidTypeWellKnownGroup
SidTypeDeletedAccount
SidTypeInvalid
SidTypeUnknown
SidTypeComputer
SidTypeLabel
)
type SidIdentifierAuthority struct {
Value [6]byte
}
var (
SECURITY_NULL_SID_AUTHORITY = SidIdentifierAuthority{[6]byte{0, 0, 0, 0, 0, 0}}
SECURITY_WORLD_SID_AUTHORITY = SidIdentifierAuthority{[6]byte{0, 0, 0, 0, 0, 1}}
SECURITY_LOCAL_SID_AUTHORITY = SidIdentifierAuthority{[6]byte{0, 0, 0, 0, 0, 2}}
SECURITY_CREATOR_SID_AUTHORITY = SidIdentifierAuthority{[6]byte{0, 0, 0, 0, 0, 3}}
SECURITY_NON_UNIQUE_AUTHORITY = SidIdentifierAuthority{[6]byte{0, 0, 0, 0, 0, 4}}
SECURITY_NT_AUTHORITY = SidIdentifierAuthority{[6]byte{0, 0, 0, 0, 0, 5}}
SECURITY_MANDATORY_LABEL_AUTHORITY = SidIdentifierAuthority{[6]byte{0, 0, 0, 0, 0, 16}}
)
const (
SECURITY_NULL_RID = 0
SECURITY_WORLD_RID = 0
SECURITY_LOCAL_RID = 0
SECURITY_CREATOR_OWNER_RID = 0
SECURITY_CREATOR_GROUP_RID = 1
SECURITY_DIALUP_RID = 1
SECURITY_NETWORK_RID = 2
SECURITY_BATCH_RID = 3
SECURITY_INTERACTIVE_RID = 4
SECURITY_LOGON_IDS_RID = 5
SECURITY_SERVICE_RID = 6
SECURITY_LOCAL_SYSTEM_RID = 18
SECURITY_BUILTIN_DOMAIN_RID = 32
SECURITY_PRINCIPAL_SELF_RID = 10
SECURITY_CREATOR_OWNER_SERVER_RID = 0x2
SECURITY_CREATOR_GROUP_SERVER_RID = 0x3
SECURITY_LOGON_IDS_RID_COUNT = 0x3
SECURITY_ANONYMOUS_LOGON_RID = 0x7
SECURITY_PROXY_RID = 0x8
SECURITY_ENTERPRISE_CONTROLLERS_RID = 0x9
SECURITY_SERVER_LOGON_RID = SECURITY_ENTERPRISE_CONTROLLERS_RID
SECURITY_AUTHENTICATED_USER_RID = 0xb
SECURITY_RESTRICTED_CODE_RID = 0xc
SECURITY_NT_NON_UNIQUE_RID = 0x15
)
// Predefined domain-relative RIDs for local groups.
// See https://msdn.microsoft.com/en-us/library/windows/desktop/aa379649(v=vs.85).aspx
const (
DOMAIN_ALIAS_RID_ADMINS = 0x220
DOMAIN_ALIAS_RID_USERS = 0x221
DOMAIN_ALIAS_RID_GUESTS = 0x222
DOMAIN_ALIAS_RID_POWER_USERS = 0x223
DOMAIN_ALIAS_RID_ACCOUNT_OPS = 0x224
DOMAIN_ALIAS_RID_SYSTEM_OPS = 0x225
DOMAIN_ALIAS_RID_PRINT_OPS = 0x226
DOMAIN_ALIAS_RID_BACKUP_OPS = 0x227
DOMAIN_ALIAS_RID_REPLICATOR = 0x228
DOMAIN_ALIAS_RID_RAS_SERVERS = 0x229
DOMAIN_ALIAS_RID_PREW2KCOMPACCESS = 0x22a
DOMAIN_ALIAS_RID_REMOTE_DESKTOP_USERS = 0x22b
DOMAIN_ALIAS_RID_NETWORK_CONFIGURATION_OPS = 0x22c
DOMAIN_ALIAS_RID_INCOMING_FOREST_TRUST_BUILDERS = 0x22d
DOMAIN_ALIAS_RID_MONITORING_USERS = 0x22e
DOMAIN_ALIAS_RID_LOGGING_USERS = 0x22f
DOMAIN_ALIAS_RID_AUTHORIZATIONACCESS = 0x230
DOMAIN_ALIAS_RID_TS_LICENSE_SERVERS = 0x231
DOMAIN_ALIAS_RID_DCOM_USERS = 0x232
DOMAIN_ALIAS_RID_IUSERS = 0x238
DOMAIN_ALIAS_RID_CRYPTO_OPERATORS = 0x239
DOMAIN_ALIAS_RID_CACHEABLE_PRINCIPALS_GROUP = 0x23b
DOMAIN_ALIAS_RID_NON_CACHEABLE_PRINCIPALS_GROUP = 0x23c
DOMAIN_ALIAS_RID_EVENT_LOG_READERS_GROUP = 0x23d
DOMAIN_ALIAS_RID_CERTSVC_DCOM_ACCESS_GROUP = 0x23e
)
//sys LookupAccountSid(systemName *uint16, sid *SID, name *uint16, nameLen *uint32, refdDomainName *uint16, refdDomainNameLen *uint32, use *uint32) (err error) = advapi32.LookupAccountSidW
//sys LookupAccountName(systemName *uint16, accountName *uint16, sid *SID, sidLen *uint32, refdDomainName *uint16, refdDomainNameLen *uint32, use *uint32) (err error) = advapi32.LookupAccountNameW
//sys ConvertSidToStringSid(sid *SID, stringSid **uint16) (err error) = advapi32.ConvertSidToStringSidW
//sys ConvertStringSidToSid(stringSid *uint16, sid **SID) (err error) = advapi32.ConvertStringSidToSidW
//sys GetLengthSid(sid *SID) (len uint32) = advapi32.GetLengthSid
//sys CopySid(destSidLen uint32, destSid *SID, srcSid *SID) (err error) = advapi32.CopySid
//sys AllocateAndInitializeSid(identAuth *SidIdentifierAuthority, subAuth byte, subAuth0 uint32, subAuth1 uint32, subAuth2 uint32, subAuth3 uint32, subAuth4 uint32, subAuth5 uint32, subAuth6 uint32, subAuth7 uint32, sid **SID) (err error) = advapi32.AllocateAndInitializeSid
//sys createWellKnownSid(sidType WELL_KNOWN_SID_TYPE, domainSid *SID, sid *SID, sizeSid *uint32) (err error) = advapi32.CreateWellKnownSid
//sys isWellKnownSid(sid *SID, sidType WELL_KNOWN_SID_TYPE) (isWellKnown bool) = advapi32.IsWellKnownSid
//sys FreeSid(sid *SID) (err error) [failretval!=0] = advapi32.FreeSid
//sys EqualSid(sid1 *SID, sid2 *SID) (isEqual bool) = advapi32.EqualSid
//sys getSidIdentifierAuthority(sid *SID) (authority *SidIdentifierAuthority) = advapi32.GetSidIdentifierAuthority
//sys getSidSubAuthorityCount(sid *SID) (count *uint8) = advapi32.GetSidSubAuthorityCount
//sys getSidSubAuthority(sid *SID, index uint32) (subAuthority *uint32) = advapi32.GetSidSubAuthority
//sys isValidSid(sid *SID) (isValid bool) = advapi32.IsValidSid
// The security identifier (SID) structure is a variable-length
// structure used to uniquely identify users or groups.
type SID struct{}
// StringToSid converts a string-format security identifier
// SID into a valid, functional SID.
func StringToSid(s string) (*SID, error) {
var sid *SID
p, e := UTF16PtrFromString(s)
if e != nil {
return nil, e
}
e = ConvertStringSidToSid(p, &sid)
if e != nil {
return nil, e
}
defer LocalFree((Handle)(unsafe.Pointer(sid)))
return sid.Copy()
}
// LookupSID retrieves a security identifier SID for the account
// and the name of the domain on which the account was found.
// System specify target computer to search.
func LookupSID(system, account string) (sid *SID, domain string, accType uint32, err error) {
if len(account) == 0 {
return nil, "", 0, syscall.EINVAL
}
acc, e := UTF16PtrFromString(account)
if e != nil {
return nil, "", 0, e
}
var sys *uint16
if len(system) > 0 {
sys, e = UTF16PtrFromString(system)
if e != nil {
return nil, "", 0, e
}
}
n := uint32(50)
dn := uint32(50)
for {
b := make([]byte, n)
db := make([]uint16, dn)
sid = (*SID)(unsafe.Pointer(&b[0]))
e = LookupAccountName(sys, acc, sid, &n, &db[0], &dn, &accType)
if e == nil {
return sid, UTF16ToString(db), accType, nil
}
if e != ERROR_INSUFFICIENT_BUFFER {
return nil, "", 0, e
}
if n <= uint32(len(b)) {
return nil, "", 0, e
}
}
}
// String converts SID to a string format suitable for display, storage, or transmission.
func (sid *SID) String() string {
var s *uint16
e := ConvertSidToStringSid(sid, &s)
if e != nil {
return ""
}
defer LocalFree((Handle)(unsafe.Pointer(s)))
return UTF16ToString((*[256]uint16)(unsafe.Pointer(s))[:])
}
// Len returns the length, in bytes, of a valid security identifier SID.
func (sid *SID) Len() int {
return int(GetLengthSid(sid))
}
// Copy creates a duplicate of security identifier SID.
func (sid *SID) Copy() (*SID, error) {
b := make([]byte, sid.Len())
sid2 := (*SID)(unsafe.Pointer(&b[0]))
e := CopySid(uint32(len(b)), sid2, sid)
if e != nil {
return nil, e
}
return sid2, nil
}
// IdentifierAuthority returns the identifier authority of the SID.
func (sid *SID) IdentifierAuthority() SidIdentifierAuthority {
return *getSidIdentifierAuthority(sid)
}
// SubAuthorityCount returns the number of sub-authorities in the SID.
func (sid *SID) SubAuthorityCount() uint8 {
return *getSidSubAuthorityCount(sid)
}
// SubAuthority returns the sub-authority of the SID as specified by
// the index, which must be less than sid.SubAuthorityCount().
func (sid *SID) SubAuthority(idx uint32) uint32 {
if idx >= uint32(sid.SubAuthorityCount()) {
panic("sub-authority index out of range")
}
return *getSidSubAuthority(sid, idx)
}
// IsValid returns whether the SID has a valid revision and length.
func (sid *SID) IsValid() bool {
return isValidSid(sid)
}
// Equals compares two SIDs for equality.
func (sid *SID) Equals(sid2 *SID) bool {
return EqualSid(sid, sid2)
}
// IsWellKnown determines whether the SID matches the well-known sidType.
func (sid *SID) IsWellKnown(sidType WELL_KNOWN_SID_TYPE) bool {
return isWellKnownSid(sid, sidType)
}
// LookupAccount retrieves the name of the account for this SID
// and the name of the first domain on which this SID is found.
// System specify target computer to search for.
func (sid *SID) LookupAccount(system string) (account, domain string, accType uint32, err error) {
var sys *uint16
if len(system) > 0 {
sys, err = UTF16PtrFromString(system)
if err != nil {
return "", "", 0, err
}
}
n := uint32(50)
dn := uint32(50)
for {
b := make([]uint16, n)
db := make([]uint16, dn)
e := LookupAccountSid(sys, sid, &b[0], &n, &db[0], &dn, &accType)
if e == nil {
return UTF16ToString(b), UTF16ToString(db), accType, nil
}
if e != ERROR_INSUFFICIENT_BUFFER {
return "", "", 0, e
}
if n <= uint32(len(b)) {
return "", "", 0, e
}
}
}
// Various types of pre-specified SIDs that can be synthesized and compared at runtime.
type WELL_KNOWN_SID_TYPE uint32
const (
WinNullSid = 0
WinWorldSid = 1
WinLocalSid = 2
WinCreatorOwnerSid = 3
WinCreatorGroupSid = 4
WinCreatorOwnerServerSid = 5
WinCreatorGroupServerSid = 6
WinNtAuthoritySid = 7
WinDialupSid = 8
WinNetworkSid = 9
WinBatchSid = 10
WinInteractiveSid = 11
WinServiceSid = 12
WinAnonymousSid = 13
WinProxySid = 14
WinEnterpriseControllersSid = 15
WinSelfSid = 16
WinAuthenticatedUserSid = 17
WinRestrictedCodeSid = 18
WinTerminalServerSid = 19
WinRemoteLogonIdSid = 20
WinLogonIdsSid = 21
WinLocalSystemSid = 22
WinLocalServiceSid = 23
WinNetworkServiceSid = 24
WinBuiltinDomainSid = 25
WinBuiltinAdministratorsSid = 26
WinBuiltinUsersSid = 27
WinBuiltinGuestsSid = 28
WinBuiltinPowerUsersSid = 29
WinBuiltinAccountOperatorsSid = 30
WinBuiltinSystemOperatorsSid = 31
WinBuiltinPrintOperatorsSid = 32
WinBuiltinBackupOperatorsSid = 33
WinBuiltinReplicatorSid = 34
WinBuiltinPreWindows2000CompatibleAccessSid = 35
WinBuiltinRemoteDesktopUsersSid = 36
WinBuiltinNetworkConfigurationOperatorsSid = 37
WinAccountAdministratorSid = 38
WinAccountGuestSid = 39
WinAccountKrbtgtSid = 40
WinAccountDomainAdminsSid = 41
WinAccountDomainUsersSid = 42
WinAccountDomainGuestsSid = 43
WinAccountComputersSid = 44
WinAccountControllersSid = 45
WinAccountCertAdminsSid = 46
WinAccountSchemaAdminsSid = 47
WinAccountEnterpriseAdminsSid = 48
WinAccountPolicyAdminsSid = 49
WinAccountRasAndIasServersSid = 50
WinNTLMAuthenticationSid = 51
WinDigestAuthenticationSid = 52
WinSChannelAuthenticationSid = 53
WinThisOrganizationSid = 54
WinOtherOrganizationSid = 55
WinBuiltinIncomingForestTrustBuildersSid = 56
WinBuiltinPerfMonitoringUsersSid = 57
WinBuiltinPerfLoggingUsersSid = 58
WinBuiltinAuthorizationAccessSid = 59
WinBuiltinTerminalServerLicenseServersSid = 60
WinBuiltinDCOMUsersSid = 61
WinBuiltinIUsersSid = 62
WinIUserSid = 63
WinBuiltinCryptoOperatorsSid = 64
WinUntrustedLabelSid = 65
WinLowLabelSid = 66
WinMediumLabelSid = 67
WinHighLabelSid = 68
WinSystemLabelSid = 69
WinWriteRestrictedCodeSid = 70
WinCreatorOwnerRightsSid = 71
WinCacheablePrincipalsGroupSid = 72
WinNonCacheablePrincipalsGroupSid = 73
WinEnterpriseReadonlyControllersSid = 74
WinAccountReadonlyControllersSid = 75
WinBuiltinEventLogReadersGroup = 76
WinNewEnterpriseReadonlyControllersSid = 77
WinBuiltinCertSvcDComAccessGroup = 78
WinMediumPlusLabelSid = 79
WinLocalLogonSid = 80
WinConsoleLogonSid = 81
WinThisOrganizationCertificateSid = 82
WinApplicationPackageAuthoritySid = 83
WinBuiltinAnyPackageSid = 84
WinCapabilityInternetClientSid = 85
WinCapabilityInternetClientServerSid = 86
WinCapabilityPrivateNetworkClientServerSid = 87
WinCapabilityPicturesLibrarySid = 88
WinCapabilityVideosLibrarySid = 89
WinCapabilityMusicLibrarySid = 90
WinCapabilityDocumentsLibrarySid = 91
WinCapabilitySharedUserCertificatesSid = 92
WinCapabilityEnterpriseAuthenticationSid = 93
WinCapabilityRemovableStorageSid = 94
WinBuiltinRDSRemoteAccessServersSid = 95
WinBuiltinRDSEndpointServersSid = 96
WinBuiltinRDSManagementServersSid = 97
WinUserModeDriversSid = 98
WinBuiltinHyperVAdminsSid = 99
WinAccountCloneableControllersSid = 100
WinBuiltinAccessControlAssistanceOperatorsSid = 101
WinBuiltinRemoteManagementUsersSid = 102
WinAuthenticationAuthorityAssertedSid = 103
WinAuthenticationServiceAssertedSid = 104
WinLocalAccountSid = 105
WinLocalAccountAndAdministratorSid = 106
WinAccountProtectedUsersSid = 107
WinCapabilityAppointmentsSid = 108
WinCapabilityContactsSid = 109
WinAccountDefaultSystemManagedSid = 110
WinBuiltinDefaultSystemManagedGroupSid = 111
WinBuiltinStorageReplicaAdminsSid = 112
WinAccountKeyAdminsSid = 113
WinAccountEnterpriseKeyAdminsSid = 114
WinAuthenticationKeyTrustSid = 115
WinAuthenticationKeyPropertyMFASid = 116
WinAuthenticationKeyPropertyAttestationSid = 117
WinAuthenticationFreshKeyAuthSid = 118
WinBuiltinDeviceOwnersSid = 119
)
// Creates a SID for a well-known predefined alias, generally using the constants of the form
// Win*Sid, for the local machine.
func CreateWellKnownSid(sidType WELL_KNOWN_SID_TYPE) (*SID, error) {
return CreateWellKnownDomainSid(sidType, nil)
}
// Creates a SID for a well-known predefined alias, generally using the constants of the form
// Win*Sid, for the domain specified by the domainSid parameter.
func CreateWellKnownDomainSid(sidType WELL_KNOWN_SID_TYPE, domainSid *SID) (*SID, error) {
n := uint32(50)
for {
b := make([]byte, n)
sid := (*SID)(unsafe.Pointer(&b[0]))
err := createWellKnownSid(sidType, domainSid, sid, &n)
if err == nil {
return sid, nil
}
if err != ERROR_INSUFFICIENT_BUFFER {
return nil, err
}
if n <= uint32(len(b)) {
return nil, err
}
}
}
const (
// do not reorder
TOKEN_ASSIGN_PRIMARY = 1 << iota
TOKEN_DUPLICATE
TOKEN_IMPERSONATE
TOKEN_QUERY
TOKEN_QUERY_SOURCE
TOKEN_ADJUST_PRIVILEGES
TOKEN_ADJUST_GROUPS
TOKEN_ADJUST_DEFAULT
TOKEN_ADJUST_SESSIONID
TOKEN_ALL_ACCESS = STANDARD_RIGHTS_REQUIRED |
TOKEN_ASSIGN_PRIMARY |
TOKEN_DUPLICATE |
TOKEN_IMPERSONATE |
TOKEN_QUERY |
TOKEN_QUERY_SOURCE |
TOKEN_ADJUST_PRIVILEGES |
TOKEN_ADJUST_GROUPS |
TOKEN_ADJUST_DEFAULT |
TOKEN_ADJUST_SESSIONID
TOKEN_READ = STANDARD_RIGHTS_READ | TOKEN_QUERY
TOKEN_WRITE = STANDARD_RIGHTS_WRITE |
TOKEN_ADJUST_PRIVILEGES |
TOKEN_ADJUST_GROUPS |
TOKEN_ADJUST_DEFAULT
TOKEN_EXECUTE = STANDARD_RIGHTS_EXECUTE
)
const (
// do not reorder
TokenUser = 1 + iota
TokenGroups
TokenPrivileges
TokenOwner
TokenPrimaryGroup
TokenDefaultDacl
TokenSource
TokenType
TokenImpersonationLevel
TokenStatistics
TokenRestrictedSids
TokenSessionId
TokenGroupsAndPrivileges
TokenSessionReference
TokenSandBoxInert
TokenAuditPolicy
TokenOrigin
TokenElevationType
TokenLinkedToken
TokenElevation
TokenHasRestrictions
TokenAccessInformation
TokenVirtualizationAllowed
TokenVirtualizationEnabled
TokenIntegrityLevel
TokenUIAccess
TokenMandatoryPolicy
TokenLogonSid
MaxTokenInfoClass
)
// Group attributes inside of Tokengroups.Groups[i].Attributes
const (
SE_GROUP_MANDATORY = 0x00000001
SE_GROUP_ENABLED_BY_DEFAULT = 0x00000002
SE_GROUP_ENABLED = 0x00000004
SE_GROUP_OWNER = 0x00000008
SE_GROUP_USE_FOR_DENY_ONLY = 0x00000010
SE_GROUP_INTEGRITY = 0x00000020
SE_GROUP_INTEGRITY_ENABLED = 0x00000040
SE_GROUP_LOGON_ID = 0xC0000000
SE_GROUP_RESOURCE = 0x20000000
SE_GROUP_VALID_ATTRIBUTES = SE_GROUP_MANDATORY | SE_GROUP_ENABLED_BY_DEFAULT | SE_GROUP_ENABLED | SE_GROUP_OWNER | SE_GROUP_USE_FOR_DENY_ONLY | SE_GROUP_LOGON_ID | SE_GROUP_RESOURCE | SE_GROUP_INTEGRITY | SE_GROUP_INTEGRITY_ENABLED
)
// Privilege attributes
const (
SE_PRIVILEGE_ENABLED_BY_DEFAULT = 0x00000001
SE_PRIVILEGE_ENABLED = 0x00000002
SE_PRIVILEGE_REMOVED = 0x00000004
SE_PRIVILEGE_USED_FOR_ACCESS = 0x80000000
SE_PRIVILEGE_VALID_ATTRIBUTES = SE_PRIVILEGE_ENABLED_BY_DEFAULT | SE_PRIVILEGE_ENABLED | SE_PRIVILEGE_REMOVED | SE_PRIVILEGE_USED_FOR_ACCESS
)
// Token types
const (
TokenPrimary = 1
TokenImpersonation = 2
)
// Impersonation levels
const (
SecurityAnonymous = 0
SecurityIdentification = 1
SecurityImpersonation = 2
SecurityDelegation = 3
)
type LUID struct {
LowPart uint32
HighPart int32
}
type LUIDAndAttributes struct {
Luid LUID
Attributes uint32
}
type SIDAndAttributes struct {
Sid *SID
Attributes uint32
}
type Tokenuser struct {
User SIDAndAttributes
}
type Tokenprimarygroup struct {
PrimaryGroup *SID
}
type Tokengroups struct {
GroupCount uint32
Groups [1]SIDAndAttributes // Use AllGroups() for iterating.
}
// AllGroups returns a slice that can be used to iterate over the groups in g.
func (g *Tokengroups) AllGroups() []SIDAndAttributes {
return (*[(1 << 28) - 1]SIDAndAttributes)(unsafe.Pointer(&g.Groups[0]))[:g.GroupCount:g.GroupCount]
}
type Tokenprivileges struct {
PrivilegeCount uint32
Privileges [1]LUIDAndAttributes // Use AllPrivileges() for iterating.
}
// AllPrivileges returns a slice that can be used to iterate over the privileges in p.
func (p *Tokenprivileges) AllPrivileges() []LUIDAndAttributes {
return (*[(1 << 27) - 1]LUIDAndAttributes)(unsafe.Pointer(&p.Privileges[0]))[:p.PrivilegeCount:p.PrivilegeCount]
}
type Tokenmandatorylabel struct {
Label SIDAndAttributes
}
func (tml *Tokenmandatorylabel) Size() uint32 {
return uint32(unsafe.Sizeof(Tokenmandatorylabel{})) + GetLengthSid(tml.Label.Sid)
}
// Authorization Functions
//sys checkTokenMembership(tokenHandle Token, sidToCheck *SID, isMember *int32) (err error) = advapi32.CheckTokenMembership
//sys isTokenRestricted(tokenHandle Token) (ret bool, err error) [!failretval] = advapi32.IsTokenRestricted
//sys OpenProcessToken(process Handle, access uint32, token *Token) (err error) = advapi32.OpenProcessToken
//sys OpenThreadToken(thread Handle, access uint32, openAsSelf bool, token *Token) (err error) = advapi32.OpenThreadToken
//sys ImpersonateSelf(impersonationlevel uint32) (err error) = advapi32.ImpersonateSelf
//sys RevertToSelf() (err error) = advapi32.RevertToSelf
//sys SetThreadToken(thread *Handle, token Token) (err error) = advapi32.SetThreadToken
//sys LookupPrivilegeValue(systemname *uint16, name *uint16, luid *LUID) (err error) = advapi32.LookupPrivilegeValueW
//sys AdjustTokenPrivileges(token Token, disableAllPrivileges bool, newstate *Tokenprivileges, buflen uint32, prevstate *Tokenprivileges, returnlen *uint32) (err error) = advapi32.AdjustTokenPrivileges
//sys AdjustTokenGroups(token Token, resetToDefault bool, newstate *Tokengroups, buflen uint32, prevstate *Tokengroups, returnlen *uint32) (err error) = advapi32.AdjustTokenGroups
//sys GetTokenInformation(token Token, infoClass uint32, info *byte, infoLen uint32, returnedLen *uint32) (err error) = advapi32.GetTokenInformation
//sys SetTokenInformation(token Token, infoClass uint32, info *byte, infoLen uint32) (err error) = advapi32.SetTokenInformation
//sys DuplicateTokenEx(existingToken Token, desiredAccess uint32, tokenAttributes *SecurityAttributes, impersonationLevel uint32, tokenType uint32, newToken *Token) (err error) = advapi32.DuplicateTokenEx
//sys GetUserProfileDirectory(t Token, dir *uint16, dirLen *uint32) (err error) = userenv.GetUserProfileDirectoryW
//sys getSystemDirectory(dir *uint16, dirLen uint32) (len uint32, err error) = kernel32.GetSystemDirectoryW
//sys getWindowsDirectory(dir *uint16, dirLen uint32) (len uint32, err error) = kernel32.GetWindowsDirectoryW
//sys getSystemWindowsDirectory(dir *uint16, dirLen uint32) (len uint32, err error) = kernel32.GetSystemWindowsDirectoryW
// An access token contains the security information for a logon session.
// The system creates an access token when a user logs on, and every
// process executed on behalf of the user has a copy of the token.
// The token identifies the user, the user's groups, and the user's
// privileges. The system uses the token to control access to securable
// objects and to control the ability of the user to perform various
// system-related operations on the local computer.
type Token Handle
// OpenCurrentProcessToken opens an access token associated with current
// process with TOKEN_QUERY access. It is a real token that needs to be closed.
//
// Deprecated: Explicitly call OpenProcessToken(CurrentProcess(), ...)
// with the desired access instead, or use GetCurrentProcessToken for a
// TOKEN_QUERY token.
func OpenCurrentProcessToken() (Token, error) {
var token Token
err := OpenProcessToken(CurrentProcess(), TOKEN_QUERY, &token)
return token, err
}
// GetCurrentProcessToken returns the access token associated with
// the current process. It is a pseudo token that does not need
// to be closed.
func GetCurrentProcessToken() Token {
return Token(^uintptr(4 - 1))
}
// GetCurrentThreadToken return the access token associated with
// the current thread. It is a pseudo token that does not need
// to be closed.
func GetCurrentThreadToken() Token {
return Token(^uintptr(5 - 1))
}
// GetCurrentThreadEffectiveToken returns the effective access token
// associated with the current thread. It is a pseudo token that does
// not need to be closed.
func GetCurrentThreadEffectiveToken() Token {
return Token(^uintptr(6 - 1))
}
// Close releases access to access token.
func (t Token) Close() error {
return CloseHandle(Handle(t))
}
// getInfo retrieves a specified type of information about an access token.
func (t Token) getInfo(class uint32, initSize int) (unsafe.Pointer, error) {
n := uint32(initSize)
for {
b := make([]byte, n)
e := GetTokenInformation(t, class, &b[0], uint32(len(b)), &n)
if e == nil {
return unsafe.Pointer(&b[0]), nil
}
if e != ERROR_INSUFFICIENT_BUFFER {
return nil, e
}
if n <= uint32(len(b)) {
return nil, e
}
}
}
// GetTokenUser retrieves access token t user account information.
func (t Token) GetTokenUser() (*Tokenuser, error) {
i, e := t.getInfo(TokenUser, 50)
if e != nil {
return nil, e
}
return (*Tokenuser)(i), nil
}
// GetTokenGroups retrieves group accounts associated with access token t.
func (t Token) GetTokenGroups() (*Tokengroups, error) {
i, e := t.getInfo(TokenGroups, 50)
if e != nil {
return nil, e
}
return (*Tokengroups)(i), nil
}
// GetTokenPrimaryGroup retrieves access token t primary group information.
// A pointer to a SID structure representing a group that will become
// the primary group of any objects created by a process using this access token.
func (t Token) GetTokenPrimaryGroup() (*Tokenprimarygroup, error) {
i, e := t.getInfo(TokenPrimaryGroup, 50)
if e != nil {
return nil, e
}
return (*Tokenprimarygroup)(i), nil
}
// GetUserProfileDirectory retrieves path to the
// root directory of the access token t user's profile.
func (t Token) GetUserProfileDirectory() (string, error) {
n := uint32(100)
for {
b := make([]uint16, n)
e := GetUserProfileDirectory(t, &b[0], &n)
if e == nil {
return UTF16ToString(b), nil
}
if e != ERROR_INSUFFICIENT_BUFFER {
return "", e
}
if n <= uint32(len(b)) {
return "", e
}
}
}
// IsElevated returns whether the current token is elevated from a UAC perspective.
func (token Token) IsElevated() bool {
var isElevated uint32
var outLen uint32
err := GetTokenInformation(token, TokenElevation, (*byte)(unsafe.Pointer(&isElevated)), uint32(unsafe.Sizeof(isElevated)), &outLen)
if err != nil {
return false
}
return outLen == uint32(unsafe.Sizeof(isElevated)) && isElevated != 0
}
// GetLinkedToken returns the linked token, which may be an elevated UAC token.
func (token Token) GetLinkedToken() (Token, error) {
var linkedToken Token
var outLen uint32
err := GetTokenInformation(token, TokenLinkedToken, (*byte)(unsafe.Pointer(&linkedToken)), uint32(unsafe.Sizeof(linkedToken)), &outLen)
if err != nil {
return Token(0), err
}
return linkedToken, nil
}
// GetSystemDirectory retrieves the path to current location of the system
// directory, which is typically, though not always, `C:\Windows\System32`.
func GetSystemDirectory() (string, error) {
n := uint32(MAX_PATH)
for {
b := make([]uint16, n)
l, e := getSystemDirectory(&b[0], n)
if e != nil {
return "", e
}
if l <= n {
return UTF16ToString(b[:l]), nil
}
n = l
}
}
// GetWindowsDirectory retrieves the path to current location of the Windows
// directory, which is typically, though not always, `C:\Windows`. This may
// be a private user directory in the case that the application is running
// under a terminal server.
func GetWindowsDirectory() (string, error) {
n := uint32(MAX_PATH)
for {
b := make([]uint16, n)
l, e := getWindowsDirectory(&b[0], n)
if e != nil {
return "", e
}
if l <= n {
return UTF16ToString(b[:l]), nil
}
n = l
}
}
// GetSystemWindowsDirectory retrieves the path to current location of the
// Windows directory, which is typically, though not always, `C:\Windows`.
func GetSystemWindowsDirectory() (string, error) {
n := uint32(MAX_PATH)
for {
b := make([]uint16, n)
l, e := getSystemWindowsDirectory(&b[0], n)
if e != nil {
return "", e
}
if l <= n {
return UTF16ToString(b[:l]), nil
}
n = l
}
}
// IsMember reports whether the access token t is a member of the provided SID.
func (t Token) IsMember(sid *SID) (bool, error) {
var b int32
if e := checkTokenMembership(t, sid, &b); e != nil {
return false, e
}
return b != 0, nil
}
// IsRestricted reports whether the access token t is a restricted token.
func (t Token) IsRestricted() (isRestricted bool, err error) {
isRestricted, err = isTokenRestricted(t)
if !isRestricted && err == syscall.EINVAL {
// If err is EINVAL, this returned ERROR_SUCCESS indicating a non-restricted token.
err = nil
}
return
}
const (
WTS_CONSOLE_CONNECT = 0x1
WTS_CONSOLE_DISCONNECT = 0x2
WTS_REMOTE_CONNECT = 0x3
WTS_REMOTE_DISCONNECT = 0x4
WTS_SESSION_LOGON = 0x5
WTS_SESSION_LOGOFF = 0x6
WTS_SESSION_LOCK = 0x7
WTS_SESSION_UNLOCK = 0x8
WTS_SESSION_REMOTE_CONTROL = 0x9
WTS_SESSION_CREATE = 0xa
WTS_SESSION_TERMINATE = 0xb
)
const (
WTSActive = 0
WTSConnected = 1
WTSConnectQuery = 2
WTSShadow = 3
WTSDisconnected = 4
WTSIdle = 5
WTSListen = 6
WTSReset = 7
WTSDown = 8
WTSInit = 9
)
type WTSSESSION_NOTIFICATION struct {
Size uint32
SessionID uint32
}
type WTS_SESSION_INFO struct {
SessionID uint32
WindowStationName *uint16
State uint32
}
//sys WTSQueryUserToken(session uint32, token *Token) (err error) = wtsapi32.WTSQueryUserToken
//sys WTSEnumerateSessions(handle Handle, reserved uint32, version uint32, sessions **WTS_SESSION_INFO, count *uint32) (err error) = wtsapi32.WTSEnumerateSessionsW
//sys WTSFreeMemory(ptr uintptr) = wtsapi32.WTSFreeMemory
//sys WTSGetActiveConsoleSessionId() (sessionID uint32)
type ACL struct {
aclRevision byte
sbz1 byte
aclSize uint16
aceCount uint16
sbz2 uint16
}
type SECURITY_DESCRIPTOR struct {
revision byte
sbz1 byte
control SECURITY_DESCRIPTOR_CONTROL
owner *SID
group *SID
sacl *ACL
dacl *ACL
}
type SECURITY_QUALITY_OF_SERVICE struct {
Length uint32
ImpersonationLevel uint32
ContextTrackingMode byte
EffectiveOnly byte
}
// Constants for the ContextTrackingMode field of SECURITY_QUALITY_OF_SERVICE.
const (
SECURITY_STATIC_TRACKING = 0
SECURITY_DYNAMIC_TRACKING = 1
)
type SecurityAttributes struct {
Length uint32
SecurityDescriptor *SECURITY_DESCRIPTOR
InheritHandle uint32
}
type SE_OBJECT_TYPE uint32
// Constants for type SE_OBJECT_TYPE
const (
SE_UNKNOWN_OBJECT_TYPE = 0
SE_FILE_OBJECT = 1
SE_SERVICE = 2
SE_PRINTER = 3
SE_REGISTRY_KEY = 4
SE_LMSHARE = 5
SE_KERNEL_OBJECT = 6
SE_WINDOW_OBJECT = 7
SE_DS_OBJECT = 8
SE_DS_OBJECT_ALL = 9
SE_PROVIDER_DEFINED_OBJECT = 10
SE_WMIGUID_OBJECT = 11
SE_REGISTRY_WOW64_32KEY = 12
SE_REGISTRY_WOW64_64KEY = 13
)
type SECURITY_INFORMATION uint32
// Constants for type SECURITY_INFORMATION
const (
OWNER_SECURITY_INFORMATION = 0x00000001
GROUP_SECURITY_INFORMATION = 0x00000002
DACL_SECURITY_INFORMATION = 0x00000004
SACL_SECURITY_INFORMATION = 0x00000008
LABEL_SECURITY_INFORMATION = 0x00000010
ATTRIBUTE_SECURITY_INFORMATION = 0x00000020
SCOPE_SECURITY_INFORMATION = 0x00000040
BACKUP_SECURITY_INFORMATION = 0x00010000
PROTECTED_DACL_SECURITY_INFORMATION = 0x80000000
PROTECTED_SACL_SECURITY_INFORMATION = 0x40000000
UNPROTECTED_DACL_SECURITY_INFORMATION = 0x20000000
UNPROTECTED_SACL_SECURITY_INFORMATION = 0x10000000
)
type SECURITY_DESCRIPTOR_CONTROL uint16
// Constants for type SECURITY_DESCRIPTOR_CONTROL
const (
SE_OWNER_DEFAULTED = 0x0001
SE_GROUP_DEFAULTED = 0x0002
SE_DACL_PRESENT = 0x0004
SE_DACL_DEFAULTED = 0x0008
SE_SACL_PRESENT = 0x0010
SE_SACL_DEFAULTED = 0x0020
SE_DACL_AUTO_INHERIT_REQ = 0x0100
SE_SACL_AUTO_INHERIT_REQ = 0x0200
SE_DACL_AUTO_INHERITED = 0x0400
SE_SACL_AUTO_INHERITED = 0x0800
SE_DACL_PROTECTED = 0x1000
SE_SACL_PROTECTED = 0x2000
SE_RM_CONTROL_VALID = 0x4000
SE_SELF_RELATIVE = 0x8000
)
type ACCESS_MASK uint32
// Constants for type ACCESS_MASK
const (
DELETE = 0x00010000
READ_CONTROL = 0x00020000
WRITE_DAC = 0x00040000
WRITE_OWNER = 0x00080000
SYNCHRONIZE = 0x00100000
STANDARD_RIGHTS_REQUIRED = 0x000F0000
STANDARD_RIGHTS_READ = READ_CONTROL
STANDARD_RIGHTS_WRITE = READ_CONTROL
STANDARD_RIGHTS_EXECUTE = READ_CONTROL
STANDARD_RIGHTS_ALL = 0x001F0000
SPECIFIC_RIGHTS_ALL = 0x0000FFFF
ACCESS_SYSTEM_SECURITY = 0x01000000
MAXIMUM_ALLOWED = 0x02000000
GENERIC_READ = 0x80000000
GENERIC_WRITE = 0x40000000
GENERIC_EXECUTE = 0x20000000
GENERIC_ALL = 0x10000000
)
type ACCESS_MODE uint32
// Constants for type ACCESS_MODE
const (
NOT_USED_ACCESS = 0
GRANT_ACCESS = 1
SET_ACCESS = 2
DENY_ACCESS = 3
REVOKE_ACCESS = 4
SET_AUDIT_SUCCESS = 5
SET_AUDIT_FAILURE = 6
)
// Constants for AceFlags and Inheritance fields
const (
NO_INHERITANCE = 0x0
SUB_OBJECTS_ONLY_INHERIT = 0x1
SUB_CONTAINERS_ONLY_INHERIT = 0x2
SUB_CONTAINERS_AND_OBJECTS_INHERIT = 0x3
INHERIT_NO_PROPAGATE = 0x4
INHERIT_ONLY = 0x8
INHERITED_ACCESS_ENTRY = 0x10
INHERITED_PARENT = 0x10000000
INHERITED_GRANDPARENT = 0x20000000
OBJECT_INHERIT_ACE = 0x1
CONTAINER_INHERIT_ACE = 0x2
NO_PROPAGATE_INHERIT_ACE = 0x4
INHERIT_ONLY_ACE = 0x8
INHERITED_ACE = 0x10
VALID_INHERIT_FLAGS = 0x1F
)
type MULTIPLE_TRUSTEE_OPERATION uint32
// Constants for MULTIPLE_TRUSTEE_OPERATION
const (
NO_MULTIPLE_TRUSTEE = 0
TRUSTEE_IS_IMPERSONATE = 1
)
type TRUSTEE_FORM uint32
// Constants for TRUSTEE_FORM
const (
TRUSTEE_IS_SID = 0
TRUSTEE_IS_NAME = 1
TRUSTEE_BAD_FORM = 2
TRUSTEE_IS_OBJECTS_AND_SID = 3
TRUSTEE_IS_OBJECTS_AND_NAME = 4
)
type TRUSTEE_TYPE uint32
// Constants for TRUSTEE_TYPE
const (
TRUSTEE_IS_UNKNOWN = 0
TRUSTEE_IS_USER = 1
TRUSTEE_IS_GROUP = 2
TRUSTEE_IS_DOMAIN = 3
TRUSTEE_IS_ALIAS = 4
TRUSTEE_IS_WELL_KNOWN_GROUP = 5
TRUSTEE_IS_DELETED = 6
TRUSTEE_IS_INVALID = 7
TRUSTEE_IS_COMPUTER = 8
)
// Constants for ObjectsPresent field
const (
ACE_OBJECT_TYPE_PRESENT = 0x1
ACE_INHERITED_OBJECT_TYPE_PRESENT = 0x2
)
type EXPLICIT_ACCESS struct {
AccessPermissions ACCESS_MASK
AccessMode ACCESS_MODE
Inheritance uint32
Trustee TRUSTEE
}
// This type is the union inside of TRUSTEE and must be created using one of the TrusteeValueFrom* functions.
type TrusteeValue uintptr
func TrusteeValueFromString(str string) TrusteeValue {
return TrusteeValue(unsafe.Pointer(StringToUTF16Ptr(str)))
}
func TrusteeValueFromSID(sid *SID) TrusteeValue {
return TrusteeValue(unsafe.Pointer(sid))
}
func TrusteeValueFromObjectsAndSid(objectsAndSid *OBJECTS_AND_SID) TrusteeValue {
return TrusteeValue(unsafe.Pointer(objectsAndSid))
}
func TrusteeValueFromObjectsAndName(objectsAndName *OBJECTS_AND_NAME) TrusteeValue {
return TrusteeValue(unsafe.Pointer(objectsAndName))
}
type TRUSTEE struct {
MultipleTrustee *TRUSTEE
MultipleTrusteeOperation MULTIPLE_TRUSTEE_OPERATION
TrusteeForm TRUSTEE_FORM
TrusteeType TRUSTEE_TYPE
TrusteeValue TrusteeValue
}
type OBJECTS_AND_SID struct {
ObjectsPresent uint32
ObjectTypeGuid GUID
InheritedObjectTypeGuid GUID
Sid *SID
}
type OBJECTS_AND_NAME struct {
ObjectsPresent uint32
ObjectType SE_OBJECT_TYPE
ObjectTypeName *uint16
InheritedObjectTypeName *uint16
Name *uint16
}
//sys getSecurityInfo(handle Handle, objectType SE_OBJECT_TYPE, securityInformation SECURITY_INFORMATION, owner **SID, group **SID, dacl **ACL, sacl **ACL, sd **SECURITY_DESCRIPTOR) (ret error) = advapi32.GetSecurityInfo
//sys SetSecurityInfo(handle Handle, objectType SE_OBJECT_TYPE, securityInformation SECURITY_INFORMATION, owner *SID, group *SID, dacl *ACL, sacl *ACL) (ret error) = advapi32.SetSecurityInfo
//sys getNamedSecurityInfo(objectName string, objectType SE_OBJECT_TYPE, securityInformation SECURITY_INFORMATION, owner **SID, group **SID, dacl **ACL, sacl **ACL, sd **SECURITY_DESCRIPTOR) (ret error) = advapi32.GetNamedSecurityInfoW
//sys SetNamedSecurityInfo(objectName string, objectType SE_OBJECT_TYPE, securityInformation SECURITY_INFORMATION, owner *SID, group *SID, dacl *ACL, sacl *ACL) (ret error) = advapi32.SetNamedSecurityInfoW
//sys SetKernelObjectSecurity(handle Handle, securityInformation SECURITY_INFORMATION, securityDescriptor *SECURITY_DESCRIPTOR) (err error) = advapi32.SetKernelObjectSecurity
//sys buildSecurityDescriptor(owner *TRUSTEE, group *TRUSTEE, countAccessEntries uint32, accessEntries *EXPLICIT_ACCESS, countAuditEntries uint32, auditEntries *EXPLICIT_ACCESS, oldSecurityDescriptor *SECURITY_DESCRIPTOR, sizeNewSecurityDescriptor *uint32, newSecurityDescriptor **SECURITY_DESCRIPTOR) (ret error) = advapi32.BuildSecurityDescriptorW
//sys initializeSecurityDescriptor(absoluteSD *SECURITY_DESCRIPTOR, revision uint32) (err error) = advapi32.InitializeSecurityDescriptor
//sys getSecurityDescriptorControl(sd *SECURITY_DESCRIPTOR, control *SECURITY_DESCRIPTOR_CONTROL, revision *uint32) (err error) = advapi32.GetSecurityDescriptorControl
//sys getSecurityDescriptorDacl(sd *SECURITY_DESCRIPTOR, daclPresent *bool, dacl **ACL, daclDefaulted *bool) (err error) = advapi32.GetSecurityDescriptorDacl
//sys getSecurityDescriptorSacl(sd *SECURITY_DESCRIPTOR, saclPresent *bool, sacl **ACL, saclDefaulted *bool) (err error) = advapi32.GetSecurityDescriptorSacl
//sys getSecurityDescriptorOwner(sd *SECURITY_DESCRIPTOR, owner **SID, ownerDefaulted *bool) (err error) = advapi32.GetSecurityDescriptorOwner
//sys getSecurityDescriptorGroup(sd *SECURITY_DESCRIPTOR, group **SID, groupDefaulted *bool) (err error) = advapi32.GetSecurityDescriptorGroup
//sys getSecurityDescriptorLength(sd *SECURITY_DESCRIPTOR) (len uint32) = advapi32.GetSecurityDescriptorLength
//sys getSecurityDescriptorRMControl(sd *SECURITY_DESCRIPTOR, rmControl *uint8) (ret error) [failretval!=0] = advapi32.GetSecurityDescriptorRMControl
//sys isValidSecurityDescriptor(sd *SECURITY_DESCRIPTOR) (isValid bool) = advapi32.IsValidSecurityDescriptor
//sys setSecurityDescriptorControl(sd *SECURITY_DESCRIPTOR, controlBitsOfInterest SECURITY_DESCRIPTOR_CONTROL, controlBitsToSet SECURITY_DESCRIPTOR_CONTROL) (err error) = advapi32.SetSecurityDescriptorControl
//sys setSecurityDescriptorDacl(sd *SECURITY_DESCRIPTOR, daclPresent bool, dacl *ACL, daclDefaulted bool) (err error) = advapi32.SetSecurityDescriptorDacl
//sys setSecurityDescriptorSacl(sd *SECURITY_DESCRIPTOR, saclPresent bool, sacl *ACL, saclDefaulted bool) (err error) = advapi32.SetSecurityDescriptorSacl
//sys setSecurityDescriptorOwner(sd *SECURITY_DESCRIPTOR, owner *SID, ownerDefaulted bool) (err error) = advapi32.SetSecurityDescriptorOwner
//sys setSecurityDescriptorGroup(sd *SECURITY_DESCRIPTOR, group *SID, groupDefaulted bool) (err error) = advapi32.SetSecurityDescriptorGroup
//sys setSecurityDescriptorRMControl(sd *SECURITY_DESCRIPTOR, rmControl *uint8) = advapi32.SetSecurityDescriptorRMControl
//sys convertStringSecurityDescriptorToSecurityDescriptor(str string, revision uint32, sd **SECURITY_DESCRIPTOR, size *uint32) (err error) = advapi32.ConvertStringSecurityDescriptorToSecurityDescriptorW
//sys convertSecurityDescriptorToStringSecurityDescriptor(sd *SECURITY_DESCRIPTOR, revision uint32, securityInformation SECURITY_INFORMATION, str **uint16, strLen *uint32) (err error) = advapi32.ConvertSecurityDescriptorToStringSecurityDescriptorW
//sys makeAbsoluteSD(selfRelativeSD *SECURITY_DESCRIPTOR, absoluteSD *SECURITY_DESCRIPTOR, absoluteSDSize *uint32, dacl *ACL, daclSize *uint32, sacl *ACL, saclSize *uint32, owner *SID, ownerSize *uint32, group *SID, groupSize *uint32) (err error) = advapi32.MakeAbsoluteSD
//sys makeSelfRelativeSD(absoluteSD *SECURITY_DESCRIPTOR, selfRelativeSD *SECURITY_DESCRIPTOR, selfRelativeSDSize *uint32) (err error) = advapi32.MakeSelfRelativeSD
//sys setEntriesInAcl(countExplicitEntries uint32, explicitEntries *EXPLICIT_ACCESS, oldACL *ACL, newACL **ACL) (ret error) = advapi32.SetEntriesInAclW
// Control returns the security descriptor control bits.
func (sd *SECURITY_DESCRIPTOR) Control() (control SECURITY_DESCRIPTOR_CONTROL, revision uint32, err error) {
err = getSecurityDescriptorControl(sd, &control, &revision)
return
}
// SetControl sets the security descriptor control bits.
func (sd *SECURITY_DESCRIPTOR) SetControl(controlBitsOfInterest SECURITY_DESCRIPTOR_CONTROL, controlBitsToSet SECURITY_DESCRIPTOR_CONTROL) error {
return setSecurityDescriptorControl(sd, controlBitsOfInterest, controlBitsToSet)
}
// RMControl returns the security descriptor resource manager control bits.
func (sd *SECURITY_DESCRIPTOR) RMControl() (control uint8, err error) {
err = getSecurityDescriptorRMControl(sd, &control)
return
}
// SetRMControl sets the security descriptor resource manager control bits.
func (sd *SECURITY_DESCRIPTOR) SetRMControl(rmControl uint8) {
setSecurityDescriptorRMControl(sd, &rmControl)
}
// DACL returns the security descriptor DACL and whether it was defaulted. The dacl return value may be nil
// if a DACL exists but is an "empty DACL", meaning fully permissive. If the DACL does not exist, err returns
// ERROR_OBJECT_NOT_FOUND.
func (sd *SECURITY_DESCRIPTOR) DACL() (dacl *ACL, defaulted bool, err error) {
var present bool
err = getSecurityDescriptorDacl(sd, &present, &dacl, &defaulted)
if !present {
err = ERROR_OBJECT_NOT_FOUND
}
return
}
// SetDACL sets the absolute security descriptor DACL.
func (absoluteSD *SECURITY_DESCRIPTOR) SetDACL(dacl *ACL, present, defaulted bool) error {
return setSecurityDescriptorDacl(absoluteSD, present, dacl, defaulted)
}
// SACL returns the security descriptor SACL and whether it was defaulted. The sacl return value may be nil
// if a SACL exists but is an "empty SACL", meaning fully permissive. If the SACL does not exist, err returns
// ERROR_OBJECT_NOT_FOUND.
func (sd *SECURITY_DESCRIPTOR) SACL() (sacl *ACL, defaulted bool, err error) {
var present bool
err = getSecurityDescriptorSacl(sd, &present, &sacl, &defaulted)
if !present {
err = ERROR_OBJECT_NOT_FOUND
}
return
}
// SetSACL sets the absolute security descriptor SACL.
func (absoluteSD *SECURITY_DESCRIPTOR) SetSACL(sacl *ACL, present, defaulted bool) error {
return setSecurityDescriptorSacl(absoluteSD, present, sacl, defaulted)
}
// Owner returns the security descriptor owner and whether it was defaulted.
func (sd *SECURITY_DESCRIPTOR) Owner() (owner *SID, defaulted bool, err error) {
err = getSecurityDescriptorOwner(sd, &owner, &defaulted)
return
}
// SetOwner sets the absolute security descriptor owner.
func (absoluteSD *SECURITY_DESCRIPTOR) SetOwner(owner *SID, defaulted bool) error {
return setSecurityDescriptorOwner(absoluteSD, owner, defaulted)
}
// Group returns the security descriptor group and whether it was defaulted.
func (sd *SECURITY_DESCRIPTOR) Group() (group *SID, defaulted bool, err error) {
err = getSecurityDescriptorGroup(sd, &group, &defaulted)
return
}
// SetGroup sets the absolute security descriptor owner.
func (absoluteSD *SECURITY_DESCRIPTOR) SetGroup(group *SID, defaulted bool) error {
return setSecurityDescriptorGroup(absoluteSD, group, defaulted)
}
// Length returns the length of the security descriptor.
func (sd *SECURITY_DESCRIPTOR) Length() uint32 {
return getSecurityDescriptorLength(sd)
}
// IsValid returns whether the security descriptor is valid.
func (sd *SECURITY_DESCRIPTOR) IsValid() bool {
return isValidSecurityDescriptor(sd)
}
// String returns the SDDL form of the security descriptor, with a function signature that can be
// used with %v formatting directives.
func (sd *SECURITY_DESCRIPTOR) String() string {
var sddl *uint16
err := convertSecurityDescriptorToStringSecurityDescriptor(sd, 1, 0xff, &sddl, nil)
if err != nil {
return ""
}
defer LocalFree(Handle(unsafe.Pointer(sddl)))
return UTF16PtrToString(sddl)
}
// ToAbsolute converts a self-relative security descriptor into an absolute one.
func (selfRelativeSD *SECURITY_DESCRIPTOR) ToAbsolute() (absoluteSD *SECURITY_DESCRIPTOR, err error) {
control, _, err := selfRelativeSD.Control()
if err != nil {
return
}
if control&SE_SELF_RELATIVE == 0 {
err = ERROR_INVALID_PARAMETER
return
}
var absoluteSDSize, daclSize, saclSize, ownerSize, groupSize uint32
err = makeAbsoluteSD(selfRelativeSD, nil, &absoluteSDSize,
nil, &daclSize, nil, &saclSize, nil, &ownerSize, nil, &groupSize)
switch err {
case ERROR_INSUFFICIENT_BUFFER:
case nil:
// makeAbsoluteSD is expected to fail, but it succeeds.
return nil, ERROR_INTERNAL_ERROR
default:
return nil, err
}
if absoluteSDSize > 0 {
absoluteSD = (*SECURITY_DESCRIPTOR)(unsafe.Pointer(&make([]byte, absoluteSDSize)[0]))
}
var (
dacl *ACL
sacl *ACL
owner *SID
group *SID
)
if daclSize > 0 {
dacl = (*ACL)(unsafe.Pointer(&make([]byte, daclSize)[0]))
}
if saclSize > 0 {
sacl = (*ACL)(unsafe.Pointer(&make([]byte, saclSize)[0]))
}
if ownerSize > 0 {
owner = (*SID)(unsafe.Pointer(&make([]byte, ownerSize)[0]))
}
if groupSize > 0 {
group = (*SID)(unsafe.Pointer(&make([]byte, groupSize)[0]))
}
err = makeAbsoluteSD(selfRelativeSD, absoluteSD, &absoluteSDSize,
dacl, &daclSize, sacl, &saclSize, owner, &ownerSize, group, &groupSize)
return
}
// ToSelfRelative converts an absolute security descriptor into a self-relative one.
func (absoluteSD *SECURITY_DESCRIPTOR) ToSelfRelative() (selfRelativeSD *SECURITY_DESCRIPTOR, err error) {
control, _, err := absoluteSD.Control()
if err != nil {
return
}
if control&SE_SELF_RELATIVE != 0 {
err = ERROR_INVALID_PARAMETER
return
}
var selfRelativeSDSize uint32
err = makeSelfRelativeSD(absoluteSD, nil, &selfRelativeSDSize)
switch err {
case ERROR_INSUFFICIENT_BUFFER:
case nil:
// makeSelfRelativeSD is expected to fail, but it succeeds.
return nil, ERROR_INTERNAL_ERROR
default:
return nil, err
}
if selfRelativeSDSize > 0 {
selfRelativeSD = (*SECURITY_DESCRIPTOR)(unsafe.Pointer(&make([]byte, selfRelativeSDSize)[0]))
}
err = makeSelfRelativeSD(absoluteSD, selfRelativeSD, &selfRelativeSDSize)
return
}
func (selfRelativeSD *SECURITY_DESCRIPTOR) copySelfRelativeSecurityDescriptor() *SECURITY_DESCRIPTOR {
sdLen := int(selfRelativeSD.Length())
const min = int(unsafe.Sizeof(SECURITY_DESCRIPTOR{}))
if sdLen < min {
sdLen = min
}
implement dnssec-awareness throughout code, and dane for incoming/outgoing mail delivery the vendored dns resolver code is a copy of the go stdlib dns resolver, with awareness of the "authentic data" (i.e. dnssec secure) added, as well as support for enhanced dns errors, and looking up tlsa records (for dane). ideally it would be upstreamed, but the chances seem slim. dnssec-awareness is added to all packages, e.g. spf, dkim, dmarc, iprev. their dnssec status is added to the Received message headers for incoming email. but the main reason to add dnssec was for implementing dane. with dane, the verification of tls certificates can be done through certificates/public keys published in dns (in the tlsa records). this only makes sense (is trustworthy) if those dns records can be verified to be authentic. mox now applies dane to delivering messages over smtp. mox already implemented mta-sts for webpki/pkix-verification of certificates against the (large) pool of CA's, and still enforces those policies when present. but it now also checks for dane records, and will verify those if present. if dane and mta-sts are both absent, the regular opportunistic tls with starttls is still done. and the fallback to plaintext is also still done. mox also makes it easy to setup dane for incoming deliveries, so other servers can deliver with dane tls certificate verification. the quickstart now generates private keys that are used when requesting certificates with acme. the private keys are pre-generated because they must be static and known during setup, because their public keys must be published in tlsa records in dns. autocert would generate private keys on its own, so had to be forked to add the option to provide the private key when requesting a new certificate. hopefully upstream will accept the change and we can drop the fork. with this change, using the quickstart to setup a new mox instance, the checks at internet.nl result in a 100% score, provided the domain is dnssec-signed and the network doesn't have any issues.
2023-10-10 13:09:35 +03:00
src := unsafe.Slice((*byte)(unsafe.Pointer(selfRelativeSD)), sdLen)
// SECURITY_DESCRIPTOR has pointers in it, which means checkptr expects for it to
// be aligned properly. When we're copying a Windows-allocated struct to a
// Go-allocated one, make sure that the Go allocation is aligned to the
// pointer size.
2023-01-30 16:27:06 +03:00
const psize = int(unsafe.Sizeof(uintptr(0)))
alloc := make([]uintptr, (sdLen+psize-1)/psize)
implement dnssec-awareness throughout code, and dane for incoming/outgoing mail delivery the vendored dns resolver code is a copy of the go stdlib dns resolver, with awareness of the "authentic data" (i.e. dnssec secure) added, as well as support for enhanced dns errors, and looking up tlsa records (for dane). ideally it would be upstreamed, but the chances seem slim. dnssec-awareness is added to all packages, e.g. spf, dkim, dmarc, iprev. their dnssec status is added to the Received message headers for incoming email. but the main reason to add dnssec was for implementing dane. with dane, the verification of tls certificates can be done through certificates/public keys published in dns (in the tlsa records). this only makes sense (is trustworthy) if those dns records can be verified to be authentic. mox now applies dane to delivering messages over smtp. mox already implemented mta-sts for webpki/pkix-verification of certificates against the (large) pool of CA's, and still enforces those policies when present. but it now also checks for dane records, and will verify those if present. if dane and mta-sts are both absent, the regular opportunistic tls with starttls is still done. and the fallback to plaintext is also still done. mox also makes it easy to setup dane for incoming deliveries, so other servers can deliver with dane tls certificate verification. the quickstart now generates private keys that are used when requesting certificates with acme. the private keys are pre-generated because they must be static and known during setup, because their public keys must be published in tlsa records in dns. autocert would generate private keys on its own, so had to be forked to add the option to provide the private key when requesting a new certificate. hopefully upstream will accept the change and we can drop the fork. with this change, using the quickstart to setup a new mox instance, the checks at internet.nl result in a 100% score, provided the domain is dnssec-signed and the network doesn't have any issues.
2023-10-10 13:09:35 +03:00
dst := unsafe.Slice((*byte)(unsafe.Pointer(&alloc[0])), sdLen)
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copy(dst, src)
return (*SECURITY_DESCRIPTOR)(unsafe.Pointer(&dst[0]))
}
// SecurityDescriptorFromString converts an SDDL string describing a security descriptor into a
// self-relative security descriptor object allocated on the Go heap.
func SecurityDescriptorFromString(sddl string) (sd *SECURITY_DESCRIPTOR, err error) {
var winHeapSD *SECURITY_DESCRIPTOR
err = convertStringSecurityDescriptorToSecurityDescriptor(sddl, 1, &winHeapSD, nil)
if err != nil {
return
}
defer LocalFree(Handle(unsafe.Pointer(winHeapSD)))
return winHeapSD.copySelfRelativeSecurityDescriptor(), nil
}
// GetSecurityInfo queries the security information for a given handle and returns the self-relative security
// descriptor result on the Go heap.
func GetSecurityInfo(handle Handle, objectType SE_OBJECT_TYPE, securityInformation SECURITY_INFORMATION) (sd *SECURITY_DESCRIPTOR, err error) {
var winHeapSD *SECURITY_DESCRIPTOR
err = getSecurityInfo(handle, objectType, securityInformation, nil, nil, nil, nil, &winHeapSD)
if err != nil {
return
}
defer LocalFree(Handle(unsafe.Pointer(winHeapSD)))
return winHeapSD.copySelfRelativeSecurityDescriptor(), nil
}
// GetNamedSecurityInfo queries the security information for a given named object and returns the self-relative security
// descriptor result on the Go heap.
func GetNamedSecurityInfo(objectName string, objectType SE_OBJECT_TYPE, securityInformation SECURITY_INFORMATION) (sd *SECURITY_DESCRIPTOR, err error) {
var winHeapSD *SECURITY_DESCRIPTOR
err = getNamedSecurityInfo(objectName, objectType, securityInformation, nil, nil, nil, nil, &winHeapSD)
if err != nil {
return
}
defer LocalFree(Handle(unsafe.Pointer(winHeapSD)))
return winHeapSD.copySelfRelativeSecurityDescriptor(), nil
}
// BuildSecurityDescriptor makes a new security descriptor using the input trustees, explicit access lists, and
// prior security descriptor to be merged, any of which can be nil, returning the self-relative security descriptor
// result on the Go heap.
func BuildSecurityDescriptor(owner *TRUSTEE, group *TRUSTEE, accessEntries []EXPLICIT_ACCESS, auditEntries []EXPLICIT_ACCESS, mergedSecurityDescriptor *SECURITY_DESCRIPTOR) (sd *SECURITY_DESCRIPTOR, err error) {
var winHeapSD *SECURITY_DESCRIPTOR
var winHeapSDSize uint32
var firstAccessEntry *EXPLICIT_ACCESS
if len(accessEntries) > 0 {
firstAccessEntry = &accessEntries[0]
}
var firstAuditEntry *EXPLICIT_ACCESS
if len(auditEntries) > 0 {
firstAuditEntry = &auditEntries[0]
}
err = buildSecurityDescriptor(owner, group, uint32(len(accessEntries)), firstAccessEntry, uint32(len(auditEntries)), firstAuditEntry, mergedSecurityDescriptor, &winHeapSDSize, &winHeapSD)
if err != nil {
return
}
defer LocalFree(Handle(unsafe.Pointer(winHeapSD)))
return winHeapSD.copySelfRelativeSecurityDescriptor(), nil
}
// NewSecurityDescriptor creates and initializes a new absolute security descriptor.
func NewSecurityDescriptor() (absoluteSD *SECURITY_DESCRIPTOR, err error) {
absoluteSD = &SECURITY_DESCRIPTOR{}
err = initializeSecurityDescriptor(absoluteSD, 1)
return
}
// ACLFromEntries returns a new ACL on the Go heap containing a list of explicit entries as well as those of another ACL.
// Both explicitEntries and mergedACL are optional and can be nil.
func ACLFromEntries(explicitEntries []EXPLICIT_ACCESS, mergedACL *ACL) (acl *ACL, err error) {
var firstExplicitEntry *EXPLICIT_ACCESS
if len(explicitEntries) > 0 {
firstExplicitEntry = &explicitEntries[0]
}
var winHeapACL *ACL
err = setEntriesInAcl(uint32(len(explicitEntries)), firstExplicitEntry, mergedACL, &winHeapACL)
if err != nil {
return
}
defer LocalFree(Handle(unsafe.Pointer(winHeapACL)))
aclBytes := make([]byte, winHeapACL.aclSize)
copy(aclBytes, (*[(1 << 31) - 1]byte)(unsafe.Pointer(winHeapACL))[:len(aclBytes):len(aclBytes)])
return (*ACL)(unsafe.Pointer(&aclBytes[0])), nil
}