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status.go
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status.go
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package main
import (
"crypto"
"crypto/x509"
"fmt"
"os"
"sync"
"time"
"golang.org/x/crypto/openpgp/packet"
"golang.org/x/crypto/openpgp/s2k"
)
// This file implements gnupg's "status protocol". When the --status-fd argument
// is passed, gpg will output machine-readable status updates to that fd.
// Details on the "protocol" can be found at
// https://github.com/gpg/gnupg/blob/918792befd835e04b4043b9ce42ea6d829a284fa/doc/DETAILS#format-of-the-status-fd-output
type status string
const (
// BEGIN_SIGNING
// Mark the start of the actual signing process. This may be used as an
// indication that all requested secret keys are ready for use.
sBeginSigning status = "BEGIN_SIGNING"
// SIG_CREATED <type> <pk_algo> <hash_algo> <class> <timestamp> <keyfpr>
// A signature has been created using these parameters.
// Values for type <type> are:
// - D :: detached
// - C :: cleartext
// - S :: standard
// (only the first character should be checked)
//
// <class> are 2 hex digits with the OpenPGP signature class.
//
// Note, that TIMESTAMP may either be a number of seconds since Epoch
// or an ISO 8601 string which can be detected by the presence of the
// letter 'T'.
sSigCreated status = "SIG_CREATED"
// NEWSIG [<signers_uid>]
// Is issued right before a signature verification starts. This is
// useful to define a context for parsing ERROR status messages.
// arguments are currently defined. If SIGNERS_UID is given and is
// not "-" this is the percent escape value of the OpenPGP Signer's
// User ID signature sub-packet.
sNewSig status = "NEWSIG"
// GOODSIG <long_keyid_or_fpr> <username>
// The signature with the keyid is good. For each signature only one
// of the codes GOODSIG, BADSIG, EXPSIG, EXPKEYSIG, REVKEYSIG or
// ERRSIG will be emitted. In the past they were used as a marker
// for a new signature; new code should use the NEWSIG status
// instead. The username is the primary one encoded in UTF-8 and %XX
// escaped. The fingerprint may be used instead of the long keyid if
// it is available. This is the case with CMS and might eventually
// also be available for OpenPGP.
sGoodSig status = "GOODSIG"
// BADSIG <long_keyid_or_fpr> <username>
// The signature with the keyid has not been verified okay. The username is
// the primary one encoded in UTF-8 and %XX escaped. The fingerprint may be
// used instead of the long keyid if it is available. This is the case with
// CMS and might eventually also be available for OpenPGP.
sBadSig status = "BADSIG"
// ERRSIG <keyid> <pkalgo> <hashalgo> <sig_class> <time> <rc>
//
// It was not possible to check the signature. This may be caused by a
// missing public key or an unsupported algorithm. A RC of 4 indicates
// unknown algorithm, a 9 indicates a missing public key. The other fields
// give more information about this signature. sig_class is a 2 byte hex-
// value. The fingerprint may be used instead of the keyid if it is
// available. This is the case with gpgsm and might eventually also be
// available for OpenPGP.
//
// Note, that TIME may either be the number of seconds since Epoch or an ISO
// 8601 string. The latter can be detected by the presence of the letter
// ‘T’.
sErrSig status = "ERRSIG"
// TRUST_
// These are several similar status codes:
//
// - TRUST_UNDEFINED <error_token>
// - TRUST_NEVER <error_token>
// - TRUST_MARGINAL [0 [<validation_model>]]
// - TRUST_FULLY [0 [<validation_model>]]
// - TRUST_ULTIMATE [0 [<validation_model>]]
//
// For good signatures one of these status lines are emitted to
// indicate the validity of the key used to create the signature.
// The error token values are currently only emitted by gpgsm.
//
// VALIDATION_MODEL describes the algorithm used to check the
// validity of the key. The defaults are the standard Web of Trust
// model for gpg and the standard X.509 model for gpgsm. The
// defined values are
//
// - pgp :: The standard PGP WoT.
// - shell :: The standard X.509 model.
// - chain :: The chain model.
// - steed :: The STEED model.
// - tofu :: The TOFU model
//
// Note that the term =TRUST_= in the status names is used for
// historic reasons; we now speak of validity.
sTrustFully status = "TRUST_FULLY"
)
var (
_setupStatus sync.Once
statusFile *os.File
)
func setupStatus() {
_setupStatus.Do(func() {
if *statusFdOpt <= 0 {
return
}
const (
unixStdout = 1
unixStderr = 2
)
// Even though Windows uses different numbers, we always equate 1/2 with
// stdout/stderr because Git always passes `--status-fd=1`.
switch *statusFdOpt {
case unixStdout:
statusFile = os.Stdout
case unixStderr:
statusFile = os.Stderr
default:
// TODO: debugging output if this fails
statusFile = os.NewFile(uintptr(*statusFdOpt), "status")
}
})
}
func (s status) emitf(format string, args ...interface{}) {
setupStatus()
if statusFile == nil {
return
}
const prefix = "[GNUPG:] "
statusFile.WriteString(prefix)
statusFile.WriteString(string(s))
fmt.Fprintf(statusFile, " "+format+"\n", args...)
}
func (s status) emit() {
setupStatus()
if statusFile == nil {
return
}
const prefix = "[GNUPG:] "
statusFile.WriteString(prefix + string(s) + "\n")
}
func emitSigCreated(cert *x509.Certificate, isDetached bool) {
// SIG_CREATED arguments
var (
sigType string
pkAlgo, hashAlgo, sigClass byte
now int64
fpr string
)
if isDetached {
sigType = "D"
} else {
sigType = "S"
}
switch cert.SignatureAlgorithm {
case x509.SHA1WithRSA, x509.SHA256WithRSA, x509.SHA384WithRSA, x509.SHA512WithRSA:
pkAlgo = byte(packet.PubKeyAlgoRSA)
case x509.ECDSAWithSHA1, x509.ECDSAWithSHA256, x509.ECDSAWithSHA384, x509.ECDSAWithSHA512:
pkAlgo = byte(packet.PubKeyAlgoECDSA)
}
switch cert.SignatureAlgorithm {
case x509.SHA1WithRSA, x509.ECDSAWithSHA1:
hashAlgo, _ = s2k.HashToHashId(crypto.SHA1)
case x509.SHA256WithRSA, x509.ECDSAWithSHA256:
hashAlgo, _ = s2k.HashToHashId(crypto.SHA256)
case x509.SHA384WithRSA, x509.ECDSAWithSHA384:
hashAlgo, _ = s2k.HashToHashId(crypto.SHA384)
case x509.SHA512WithRSA, x509.ECDSAWithSHA512:
hashAlgo, _ = s2k.HashToHashId(crypto.SHA512)
}
// gpgsm seems to always use 0x00
sigClass = 0
now = time.Now().Unix()
fpr = certHexFingerprint(cert)
sSigCreated.emitf("%s %d %d %02x %d %s", sigType, pkAlgo, hashAlgo, sigClass, now, fpr)
}
func emitGoodSig(chains [][][]*x509.Certificate) {
cert := chains[0][0][0]
subj := cert.Subject.String()
fpr := certHexFingerprint(cert)
sGoodSig.emitf("%s %s", fpr, subj)
}
func emitBadSig(chains [][][]*x509.Certificate) {
cert := chains[0][0][0]
subj := cert.Subject.String
fpr := certHexFingerprint(cert)
sBadSig.emitf("%s %s", fpr, subj)
}
func emitTrustFully() {
sTrustFully.emitf("0 shell")
}