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// Copyright 2011 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 openpgp
import (
"crypto"
"hash"
"io"
"strconv"
"time"
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"github.com/keybase/go-crypto/openpgp/armor"
"github.com/keybase/go-crypto/openpgp/errors"
"github.com/keybase/go-crypto/openpgp/packet"
"github.com/keybase/go-crypto/openpgp/s2k"
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)
// DetachSign signs message with the private key from signer (which must
// already have been decrypted) and writes the signature to w.
// If config is nil, sensible defaults will be used.
func DetachSign ( w io . Writer , signer * Entity , message io . Reader , config * packet . Config ) error {
return detachSign ( w , signer , message , packet . SigTypeBinary , config )
}
// ArmoredDetachSign signs message with the private key from signer (which
// must already have been decrypted) and writes an armored signature to w.
// If config is nil, sensible defaults will be used.
func ArmoredDetachSign ( w io . Writer , signer * Entity , message io . Reader , config * packet . Config ) ( err error ) {
return armoredDetachSign ( w , signer , message , packet . SigTypeBinary , config )
}
// DetachSignText signs message (after canonicalising the line endings) with
// the private key from signer (which must already have been decrypted) and
// writes the signature to w.
// If config is nil, sensible defaults will be used.
func DetachSignText ( w io . Writer , signer * Entity , message io . Reader , config * packet . Config ) error {
return detachSign ( w , signer , message , packet . SigTypeText , config )
}
// ArmoredDetachSignText signs message (after canonicalising the line endings)
// with the private key from signer (which must already have been decrypted)
// and writes an armored signature to w.
// If config is nil, sensible defaults will be used.
func ArmoredDetachSignText ( w io . Writer , signer * Entity , message io . Reader , config * packet . Config ) error {
return armoredDetachSign ( w , signer , message , packet . SigTypeText , config )
}
func armoredDetachSign ( w io . Writer , signer * Entity , message io . Reader , sigType packet . SignatureType , config * packet . Config ) ( err error ) {
out , err := armor . Encode ( w , SignatureType , nil )
if err != nil {
return
}
err = detachSign ( out , signer , message , sigType , config )
if err != nil {
return
}
return out . Close ( )
}
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// SignWithSigner signs the message of type sigType with s and writes the
// signature to w.
// If config is nil, sensible defaults will be used.
func SignWithSigner ( s packet . Signer , w io . Writer , message io . Reader , sigType packet . SignatureType , config * packet . Config ) ( err error ) {
keyId := s . KeyId ( )
sig := new ( packet . Signature )
sig . SigType = sigType
sig . PubKeyAlgo = s . PublicKeyAlgo ( )
sig . Hash = config . Hash ( )
sig . CreationTime = config . Now ( )
sig . IssuerKeyId = & keyId
s . Reset ( )
wrapped := s . ( hash . Hash )
if sigType == packet . SigTypeText {
wrapped = NewCanonicalTextHash ( s )
}
io . Copy ( wrapped , message )
err = sig . Sign ( s , nil , config )
if err != nil {
return
}
err = sig . Serialize ( w )
return
}
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func detachSign ( w io . Writer , signer * Entity , message io . Reader , sigType packet . SignatureType , config * packet . Config ) ( err error ) {
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signerSubkey , ok := signer . signingKey ( config . Now ( ) )
if ! ok {
err = errors . InvalidArgumentError ( "no valid signing keys" )
return
}
if signerSubkey . PrivateKey == nil {
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return errors . InvalidArgumentError ( "signing key doesn't have a private key" )
}
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if signerSubkey . PrivateKey . Encrypted {
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return errors . InvalidArgumentError ( "signing key is encrypted" )
}
sig := new ( packet . Signature )
sig . SigType = sigType
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sig . PubKeyAlgo = signerSubkey . PrivateKey . PubKeyAlgo
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sig . Hash = config . Hash ( )
sig . CreationTime = config . Now ( )
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sig . IssuerKeyId = & signerSubkey . PrivateKey . KeyId
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h , wrappedHash , err := hashForSignature ( sig . Hash , sig . SigType )
if err != nil {
return
}
io . Copy ( wrappedHash , message )
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err = sig . Sign ( h , signerSubkey . PrivateKey , config )
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if err != nil {
return
}
return sig . Serialize ( w )
}
// FileHints contains metadata about encrypted files. This metadata is, itself,
// encrypted.
type FileHints struct {
// IsBinary can be set to hint that the contents are binary data.
IsBinary bool
// FileName hints at the name of the file that should be written. It's
// truncated to 255 bytes if longer. It may be empty to suggest that the
// file should not be written to disk. It may be equal to "_CONSOLE" to
// suggest the data should not be written to disk.
FileName string
// ModTime contains the modification time of the file, or the zero time if not applicable.
ModTime time . Time
}
// SymmetricallyEncrypt acts like gpg -c: it encrypts a file with a passphrase.
// The resulting WriteCloser must be closed after the contents of the file have
// been written.
// If config is nil, sensible defaults will be used.
func SymmetricallyEncrypt ( ciphertext io . Writer , passphrase [ ] byte , hints * FileHints , config * packet . Config ) ( plaintext io . WriteCloser , err error ) {
if hints == nil {
hints = & FileHints { }
}
key , err := packet . SerializeSymmetricKeyEncrypted ( ciphertext , passphrase , config )
if err != nil {
return
}
w , err := packet . SerializeSymmetricallyEncrypted ( ciphertext , config . Cipher ( ) , key , config )
if err != nil {
return
}
literaldata := w
if algo := config . Compression ( ) ; algo != packet . CompressionNone {
var compConfig * packet . CompressionConfig
if config != nil {
compConfig = config . CompressionConfig
}
literaldata , err = packet . SerializeCompressed ( w , algo , compConfig )
if err != nil {
return
}
}
var epochSeconds uint32
if ! hints . ModTime . IsZero ( ) {
epochSeconds = uint32 ( hints . ModTime . Unix ( ) )
}
return packet . SerializeLiteral ( literaldata , hints . IsBinary , hints . FileName , epochSeconds )
}
// intersectPreferences mutates and returns a prefix of a that contains only
// the values in the intersection of a and b. The order of a is preserved.
func intersectPreferences ( a [ ] uint8 , b [ ] uint8 ) ( intersection [ ] uint8 ) {
var j int
for _ , v := range a {
for _ , v2 := range b {
if v == v2 {
a [ j ] = v
j ++
break
}
}
}
return a [ : j ]
}
func hashToHashId ( h crypto . Hash ) uint8 {
v , ok := s2k . HashToHashId ( h )
if ! ok {
panic ( "tried to convert unknown hash" )
}
return v
}
// Encrypt encrypts a message to a number of recipients and, optionally, signs
// it. hints contains optional information, that is also encrypted, that aids
// the recipients in processing the message. The resulting WriteCloser must
// be closed after the contents of the file have been written.
// If config is nil, sensible defaults will be used.
func Encrypt ( ciphertext io . Writer , to [ ] * Entity , signed * Entity , hints * FileHints , config * packet . Config ) ( plaintext io . WriteCloser , err error ) {
var signer * packet . PrivateKey
if signed != nil {
signKey , ok := signed . signingKey ( config . Now ( ) )
if ! ok {
return nil , errors . InvalidArgumentError ( "no valid signing keys" )
}
signer = signKey . PrivateKey
if signer == nil {
return nil , errors . InvalidArgumentError ( "no private key in signing key" )
}
if signer . Encrypted {
return nil , errors . InvalidArgumentError ( "signing key must be decrypted" )
}
}
// These are the possible ciphers that we'll use for the message.
candidateCiphers := [ ] uint8 {
uint8 ( packet . CipherAES128 ) ,
uint8 ( packet . CipherAES256 ) ,
uint8 ( packet . CipherCAST5 ) ,
}
// These are the possible hash functions that we'll use for the signature.
candidateHashes := [ ] uint8 {
hashToHashId ( crypto . SHA256 ) ,
hashToHashId ( crypto . SHA512 ) ,
hashToHashId ( crypto . SHA1 ) ,
hashToHashId ( crypto . RIPEMD160 ) ,
}
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// If no preferences were specified, assume something safe and reasonable.
defaultCiphers := [ ] uint8 {
uint8 ( packet . CipherAES128 ) ,
uint8 ( packet . CipherAES192 ) ,
uint8 ( packet . CipherAES256 ) ,
uint8 ( packet . CipherCAST5 ) ,
}
defaultHashes := [ ] uint8 {
hashToHashId ( crypto . SHA256 ) ,
hashToHashId ( crypto . SHA512 ) ,
hashToHashId ( crypto . RIPEMD160 ) ,
}
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encryptKeys := make ( [ ] Key , len ( to ) )
for i := range to {
var ok bool
encryptKeys [ i ] , ok = to [ i ] . encryptionKey ( config . Now ( ) )
if ! ok {
return nil , errors . InvalidArgumentError ( "cannot encrypt a message to key id " + strconv . FormatUint ( to [ i ] . PrimaryKey . KeyId , 16 ) + " because it has no encryption keys" )
}
sig := to [ i ] . primaryIdentity ( ) . SelfSignature
preferredSymmetric := sig . PreferredSymmetric
if len ( preferredSymmetric ) == 0 {
preferredSymmetric = defaultCiphers
}
preferredHashes := sig . PreferredHash
if len ( preferredHashes ) == 0 {
preferredHashes = defaultHashes
}
candidateCiphers = intersectPreferences ( candidateCiphers , preferredSymmetric )
candidateHashes = intersectPreferences ( candidateHashes , preferredHashes )
}
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if len ( candidateCiphers ) == 0 {
return nil , errors . InvalidArgumentError ( "cannot encrypt because recipient set shares no common ciphers" )
}
if len ( candidateHashes ) == 0 {
return nil , errors . InvalidArgumentError ( "cannot encrypt because recipient set shares no common hashes" )
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}
cipher := packet . CipherFunction ( candidateCiphers [ 0 ] )
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// If the cipher specifed by config is a candidate, we'll use that.
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configuredCipher := config . Cipher ( )
for _ , c := range candidateCiphers {
cipherFunc := packet . CipherFunction ( c )
if cipherFunc == configuredCipher {
cipher = cipherFunc
break
}
}
var hash crypto . Hash
for _ , hashId := range candidateHashes {
if h , ok := s2k . HashIdToHash ( hashId ) ; ok && h . Available ( ) {
hash = h
break
}
}
// If the hash specified by config is a candidate, we'll use that.
if configuredHash := config . Hash ( ) ; configuredHash . Available ( ) {
for _ , hashId := range candidateHashes {
if h , ok := s2k . HashIdToHash ( hashId ) ; ok && h == configuredHash {
hash = h
break
}
}
}
if hash == 0 {
hashId := candidateHashes [ 0 ]
name , ok := s2k . HashIdToString ( hashId )
if ! ok {
name = "#" + strconv . Itoa ( int ( hashId ) )
}
return nil , errors . InvalidArgumentError ( "cannot encrypt because no candidate hash functions are compiled in. (Wanted " + name + " in this case.)" )
}
symKey := make ( [ ] byte , cipher . KeySize ( ) )
if _ , err := io . ReadFull ( config . Random ( ) , symKey ) ; err != nil {
return nil , err
}
for _ , key := range encryptKeys {
if err := packet . SerializeEncryptedKey ( ciphertext , key . PublicKey , cipher , symKey , config ) ; err != nil {
return nil , err
}
}
encryptedData , err := packet . SerializeSymmetricallyEncrypted ( ciphertext , cipher , symKey , config )
if err != nil {
return
}
if signer != nil {
ops := & packet . OnePassSignature {
SigType : packet . SigTypeBinary ,
Hash : hash ,
PubKeyAlgo : signer . PubKeyAlgo ,
KeyId : signer . KeyId ,
IsLast : true ,
}
if err := ops . Serialize ( encryptedData ) ; err != nil {
return nil , err
}
}
if hints == nil {
hints = & FileHints { }
}
w := encryptedData
if signer != nil {
// If we need to write a signature packet after the literal
// data then we need to stop literalData from closing
// encryptedData.
w = noOpCloser { encryptedData }
}
var epochSeconds uint32
if ! hints . ModTime . IsZero ( ) {
epochSeconds = uint32 ( hints . ModTime . Unix ( ) )
}
literalData , err := packet . SerializeLiteral ( w , hints . IsBinary , hints . FileName , epochSeconds )
if err != nil {
return nil , err
}
if signer != nil {
return signatureWriter { encryptedData , literalData , hash , hash . New ( ) , signer , config } , nil
}
return literalData , nil
}
// signatureWriter hashes the contents of a message while passing it along to
// literalData. When closed, it closes literalData, writes a signature packet
// to encryptedData and then also closes encryptedData.
type signatureWriter struct {
encryptedData io . WriteCloser
literalData io . WriteCloser
hashType crypto . Hash
h hash . Hash
signer * packet . PrivateKey
config * packet . Config
}
func ( s signatureWriter ) Write ( data [ ] byte ) ( int , error ) {
s . h . Write ( data )
return s . literalData . Write ( data )
}
func ( s signatureWriter ) Close ( ) error {
sig := & packet . Signature {
SigType : packet . SigTypeBinary ,
PubKeyAlgo : s . signer . PubKeyAlgo ,
Hash : s . hashType ,
CreationTime : s . config . Now ( ) ,
IssuerKeyId : & s . signer . KeyId ,
}
if err := sig . Sign ( s . h , s . signer , s . config ) ; err != nil {
return err
}
if err := s . literalData . Close ( ) ; err != nil {
return err
}
if err := sig . Serialize ( s . encryptedData ) ; err != nil {
return err
}
return s . encryptedData . Close ( )
}
// noOpCloser is like an ioutil.NopCloser, but for an io.Writer.
// TODO: we have two of these in OpenPGP packages alone. This probably needs
// to be promoted somewhere more common.
type noOpCloser struct {
w io . Writer
}
func ( c noOpCloser ) Write ( data [ ] byte ) ( n int , err error ) {
return c . w . Write ( data )
}
func ( c noOpCloser ) Close ( ) error {
return nil
}
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// AttachedSign is like openpgp.Encrypt (as in p.crypto/openpgp/write.go), but
// don't encrypt at all, just sign the literal unencrypted data.
// Unfortunately we need to duplicate some code here that's already
// in write.go
func AttachedSign ( out io . WriteCloser , signed Entity , hints * FileHints ,
config * packet . Config ) ( in io . WriteCloser , err error ) {
if hints == nil {
hints = & FileHints { }
}
if config == nil {
config = & packet . Config { }
}
var signer * packet . PrivateKey
signKey , ok := signed . signingKey ( config . Now ( ) )
if ! ok {
err = errors . InvalidArgumentError ( "no valid signing keys" )
return
}
signer = signKey . PrivateKey
if signer == nil {
err = errors . InvalidArgumentError ( "no valid signing keys" )
return
}
if signer . Encrypted {
err = errors . InvalidArgumentError ( "signing key must be decrypted" )
return
}
hasher := crypto . SHA512
ops := & packet . OnePassSignature {
SigType : packet . SigTypeBinary ,
Hash : hasher ,
PubKeyAlgo : signer . PubKeyAlgo ,
KeyId : signer . KeyId ,
IsLast : true ,
}
if err = ops . Serialize ( out ) ; err != nil {
return
}
var epochSeconds uint32
if ! hints . ModTime . IsZero ( ) {
epochSeconds = uint32 ( hints . ModTime . Unix ( ) )
}
// We don't want the literal serializer to closer the output stream
// since we're going to need to write to it when we finish up the
// signature stuff.
in , err = packet . SerializeLiteral ( noOpCloser { out } , hints . IsBinary , hints . FileName , epochSeconds )
if err != nil {
return
}
// If we need to write a signature packet after the literal
// data then we need to stop literalData from closing
// encryptedData.
in = signatureWriter { out , in , hasher , hasher . New ( ) , signer , config }
return
}