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gnupg/g10/build-packet.c

1117 lines
26 KiB
C

/* build-packet.c - assemble packets and write them
* Copyright (C) 1998, 1999, 2000, 2001 Free Software Foundation, Inc.
*
* This file is part of GnuPG.
*
* GnuPG is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* GnuPG is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
*/
#include <config.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include "packet.h"
#include "errors.h"
#include "iobuf.h"
#include "mpi.h"
#include "util.h"
#include "cipher.h"
#include "memory.h"
#include "options.h"
static int do_comment( IOBUF out, int ctb, PKT_comment *rem );
static int do_user_id( IOBUF out, int ctb, PKT_user_id *uid );
static int do_public_key( IOBUF out, int ctb, PKT_public_key *pk );
static int do_secret_key( IOBUF out, int ctb, PKT_secret_key *pk );
static int do_symkey_enc( IOBUF out, int ctb, PKT_symkey_enc *enc );
static int do_pubkey_enc( IOBUF out, int ctb, PKT_pubkey_enc *enc );
static u32 calc_plaintext( PKT_plaintext *pt );
static int do_plaintext( IOBUF out, int ctb, PKT_plaintext *pt );
static int do_encrypted( IOBUF out, int ctb, PKT_encrypted *ed );
static int do_encrypted_mdc( IOBUF out, int ctb, PKT_encrypted *ed );
static int do_mdc( IOBUF out, PKT_mdc *mdc );
static int do_compressed( IOBUF out, int ctb, PKT_compressed *cd );
static int do_signature( IOBUF out, int ctb, PKT_signature *sig );
static int do_onepass_sig( IOBUF out, int ctb, PKT_onepass_sig *ops );
static int calc_header_length( u32 len, int new_ctb );
static int write_16(IOBUF inp, u16 a);
static int write_32(IOBUF inp, u32 a);
static int write_header( IOBUF out, int ctb, u32 len );
static int write_sign_packet_header( IOBUF out, int ctb, u32 len );
static int write_header2( IOBUF out, int ctb, u32 len, int hdrlen, int blkmode );
static int write_new_header( IOBUF out, int ctb, u32 len, int hdrlen );
static int write_version( IOBUF out, int ctb );
/****************
* Build a packet and write it to INP
* Returns: 0 := okay
* >0 := error
* Note: Caller must free the packet
*/
int
build_packet( IOBUF out, PACKET *pkt )
{
int new_ctb=0, rc=0, ctb;
int pkttype;
if( DBG_PACKET )
log_debug("build_packet() type=%d\n", pkt->pkttype );
assert( pkt->pkt.generic );
switch( (pkttype = pkt->pkttype) ) {
case PKT_OLD_COMMENT: pkttype = pkt->pkttype = PKT_COMMENT; break;
case PKT_PLAINTEXT: new_ctb = pkt->pkt.plaintext->new_ctb; break;
case PKT_ENCRYPTED:
case PKT_ENCRYPTED_MDC: new_ctb = pkt->pkt.encrypted->new_ctb; break;
case PKT_COMPRESSED:new_ctb = pkt->pkt.compressed->new_ctb; break;
case PKT_USER_ID:
if( pkt->pkt.user_id->photo )
pkttype = PKT_PHOTO_ID;
break;
default: break;
}
if( new_ctb || pkttype > 15 ) /* new format */
ctb = 0xc0 | (pkttype & 0x3f);
else
ctb = 0x80 | ((pkttype & 15)<<2);
switch( pkttype ) {
case PKT_PHOTO_ID:
case PKT_USER_ID:
rc = do_user_id( out, ctb, pkt->pkt.user_id );
break;
case PKT_COMMENT:
rc = do_comment( out, ctb, pkt->pkt.comment );
break;
case PKT_PUBLIC_SUBKEY:
case PKT_PUBLIC_KEY:
rc = do_public_key( out, ctb, pkt->pkt.public_key );
break;
case PKT_SECRET_SUBKEY:
case PKT_SECRET_KEY:
rc = do_secret_key( out, ctb, pkt->pkt.secret_key );
break;
case PKT_SYMKEY_ENC:
rc = do_symkey_enc( out, ctb, pkt->pkt.symkey_enc );
break;
case PKT_PUBKEY_ENC:
rc = do_pubkey_enc( out, ctb, pkt->pkt.pubkey_enc );
break;
case PKT_PLAINTEXT:
rc = do_plaintext( out, ctb, pkt->pkt.plaintext );
break;
case PKT_ENCRYPTED:
rc = do_encrypted( out, ctb, pkt->pkt.encrypted );
break;
case PKT_ENCRYPTED_MDC:
rc = do_encrypted_mdc( out, ctb, pkt->pkt.encrypted );
break;
case PKT_MDC:
rc = do_mdc( out, pkt->pkt.mdc );
break;
case PKT_COMPRESSED:
rc = do_compressed( out, ctb, pkt->pkt.compressed );
break;
case PKT_SIGNATURE:
rc = do_signature( out, ctb, pkt->pkt.signature );
break;
case PKT_ONEPASS_SIG:
rc = do_onepass_sig( out, ctb, pkt->pkt.onepass_sig );
break;
case PKT_RING_TRUST:
break; /* ignore it */
default:
log_bug("invalid packet type in build_packet()\n");
break;
}
return rc;
}
/****************
* calculate the length of a packet described by PKT
*/
u32
calc_packet_length( PACKET *pkt )
{
u32 n=0;
int new_ctb = 0;
assert( pkt->pkt.generic );
switch( pkt->pkttype ) {
case PKT_PLAINTEXT:
n = calc_plaintext( pkt->pkt.plaintext );
new_ctb = pkt->pkt.plaintext->new_ctb;
break;
case PKT_PHOTO_ID:
case PKT_USER_ID:
case PKT_COMMENT:
case PKT_PUBLIC_KEY:
case PKT_SECRET_KEY:
case PKT_SYMKEY_ENC:
case PKT_PUBKEY_ENC:
case PKT_ENCRYPTED:
case PKT_SIGNATURE:
case PKT_ONEPASS_SIG:
case PKT_RING_TRUST:
case PKT_COMPRESSED:
default:
log_bug("invalid packet type in calc_packet_length()");
break;
}
n += calc_header_length(n, new_ctb);
return n;
}
static void
write_fake_data( IOBUF out, MPI a )
{
if( a ) {
int i;
void *p;
p = mpi_get_opaque( a, &i );
iobuf_write( out, p, i );
}
}
static int
do_comment( IOBUF out, int ctb, PKT_comment *rem )
{
if( !opt.no_comment ) {
write_header(out, ctb, rem->len);
if( iobuf_write( out, rem->data, rem->len ) )
return G10ERR_WRITE_FILE;
}
return 0;
}
static int
do_user_id( IOBUF out, int ctb, PKT_user_id *uid )
{
if( uid->photo ) {
write_header(out, ctb, uid->photolen);
if( iobuf_write( out, uid->photo, uid->photolen ) )
return G10ERR_WRITE_FILE;
}
else {
write_header(out, ctb, uid->len);
if( iobuf_write( out, uid->name, uid->len ) )
return G10ERR_WRITE_FILE;
}
return 0;
}
static int
do_public_key( IOBUF out, int ctb, PKT_public_key *pk )
{
int rc = 0;
int n, i;
IOBUF a = iobuf_temp();
if( !pk->version )
iobuf_put( a, 3 );
else
iobuf_put( a, pk->version );
write_32(a, pk->timestamp );
if( pk->version < 4 ) {
u16 ndays;
if( pk->expiredate )
ndays = (u16)((pk->expiredate - pk->timestamp) / 86400L);
else
ndays = 0;
write_16(a, ndays );
}
iobuf_put(a, pk->pubkey_algo );
n = pubkey_get_npkey( pk->pubkey_algo );
if( !n )
write_fake_data( a, pk->pkey[0] );
for(i=0; i < n; i++ )
mpi_write(a, pk->pkey[i] );
write_header2(out, ctb, iobuf_get_temp_length(a), pk->hdrbytes, 1 );
if( iobuf_write_temp( out, a ) )
rc = G10ERR_WRITE_FILE;
iobuf_close(a);
return rc;
}
/****************
* Make a hash value from the public key certificate
*/
void
hash_public_key( MD_HANDLE md, PKT_public_key *pk )
{
PACKET pkt;
int rc = 0;
int ctb;
ulong pktlen;
int c;
IOBUF a = iobuf_temp();
#if 0
FILE *fp = fopen("dump.pk", "a");
int i=0;
fprintf(fp, "\nHashing PK (v%d):\n", pk->version);
#endif
/* build the packet */
init_packet(&pkt);
pkt.pkttype = PKT_PUBLIC_KEY;
pkt.pkt.public_key = pk;
if( (rc = build_packet( a, &pkt )) )
log_fatal("build public_key for hashing failed: %s\n", g10_errstr(rc));
if( !(pk->version == 3 && pk->pubkey_algo == 16) ) {
/* skip the constructed header but don't do this for our very old
* v3 ElG keys */
ctb = iobuf_get_noeof(a);
pktlen = 0;
if( (ctb & 0x40) ) {
c = iobuf_get_noeof(a);
if( c < 192 )
pktlen = c;
else if( c < 224 ) {
pktlen = (c - 192) * 256;
c = iobuf_get_noeof(a);
pktlen += c + 192;
}
else if( c == 255 ) {
pktlen = iobuf_get_noeof(a) << 24;
pktlen |= iobuf_get_noeof(a) << 16;
pktlen |= iobuf_get_noeof(a) << 8;
pktlen |= iobuf_get_noeof(a);
}
}
else {
int lenbytes = ((ctb&3)==3)? 0 : (1<<(ctb & 3));
for( ; lenbytes; lenbytes-- ) {
pktlen <<= 8;
pktlen |= iobuf_get_noeof(a);
}
}
/* hash a header */
md_putc( md, 0x99 );
pktlen &= 0xffff; /* can't handle longer packets */
md_putc( md, pktlen >> 8 );
md_putc( md, pktlen & 0xff );
}
/* hash the packet body */
while( (c=iobuf_get(a)) != -1 ) {
#if 0
fprintf( fp," %02x", c );
if( (++i == 24) ) {
putc('\n', fp);
i=0;
}
#endif
md_putc( md, c );
}
#if 0
putc('\n', fp);
fclose(fp);
#endif
iobuf_cancel(a);
}
static int
do_secret_key( IOBUF out, int ctb, PKT_secret_key *sk )
{
int rc = 0;
int i, nskey, npkey;
IOBUF a = iobuf_temp();
if( !sk->version )
iobuf_put( a, 3 );
else
iobuf_put( a, sk->version );
write_32(a, sk->timestamp );
if( sk->version < 4 ) {
u16 ndays;
if( sk->expiredate )
ndays = (u16)((sk->expiredate - sk->timestamp) / 86400L);
else
ndays = 0;
write_16(a, ndays);
}
iobuf_put(a, sk->pubkey_algo );
nskey = pubkey_get_nskey( sk->pubkey_algo );
npkey = pubkey_get_npkey( sk->pubkey_algo );
if( !npkey ) {
write_fake_data( a, sk->skey[0] );
goto leave;
}
assert( npkey < nskey );
for(i=0; i < npkey; i++ )
mpi_write(a, sk->skey[i] );
if( sk->is_protected ) {
if( is_RSA(sk->pubkey_algo) && sk->version < 4
&& !sk->protect.s2k.mode ) {
iobuf_put(a, sk->protect.algo );
iobuf_write(a, sk->protect.iv, sk->protect.ivlen );
}
else {
iobuf_put(a, 0xff );
iobuf_put(a, sk->protect.algo );
if( sk->protect.s2k.mode >= 1000 ) {
iobuf_put(a, 101 );
iobuf_put(a, sk->protect.s2k.hash_algo );
iobuf_write(a, "GNU", 3 );
iobuf_put(a, sk->protect.s2k.mode - 1000 );
}
else {
iobuf_put(a, sk->protect.s2k.mode );
iobuf_put(a, sk->protect.s2k.hash_algo );
}
if( sk->protect.s2k.mode == 1
|| sk->protect.s2k.mode == 3 )
iobuf_write(a, sk->protect.s2k.salt, 8 );
if( sk->protect.s2k.mode == 3 )
iobuf_put(a, sk->protect.s2k.count );
if( sk->protect.s2k.mode != 1001 )
iobuf_write(a, sk->protect.iv, sk->protect.ivlen );
}
}
else
iobuf_put(a, 0 );
if( sk->protect.s2k.mode == 1001 )
;
else if( sk->is_protected && sk->version >= 4 ) {
byte *p;
assert( mpi_is_opaque( sk->skey[npkey] ) );
p = mpi_get_opaque( sk->skey[npkey], &i );
iobuf_write(a, p, i );
}
else {
for( ; i < nskey; i++ )
mpi_write(a, sk->skey[i] );
write_16(a, sk->csum );
}
leave:
write_header2(out, ctb, iobuf_get_temp_length(a), sk->hdrbytes, 1 );
if( iobuf_write_temp( out, a ) )
rc = G10ERR_WRITE_FILE;
iobuf_close(a);
return rc;
}
static int
do_symkey_enc( IOBUF out, int ctb, PKT_symkey_enc *enc )
{
int rc = 0;
IOBUF a = iobuf_temp();
assert( enc->version == 4 );
switch( enc->s2k.mode ) {
case 0: case 1: case 3: break;
default: log_bug("do_symkey_enc: s2k=%d\n", enc->s2k.mode );
}
iobuf_put( a, enc->version );
iobuf_put( a, enc->cipher_algo );
iobuf_put( a, enc->s2k.mode );
iobuf_put( a, enc->s2k.hash_algo );
if( enc->s2k.mode == 1 || enc->s2k.mode == 3 ) {
iobuf_write(a, enc->s2k.salt, 8 );
if( enc->s2k.mode == 3 )
iobuf_put(a, enc->s2k.count);
}
if( enc->seskeylen )
iobuf_write(a, enc->seskey, enc->seskeylen );
write_header(out, ctb, iobuf_get_temp_length(a) );
if( iobuf_write_temp( out, a ) )
rc = G10ERR_WRITE_FILE;
iobuf_close(a);
return rc;
}
static int
do_pubkey_enc( IOBUF out, int ctb, PKT_pubkey_enc *enc )
{
int rc = 0;
int n, i;
IOBUF a = iobuf_temp();
write_version( a, ctb );
if( enc->throw_keyid ) {
write_32(a, 0 ); /* don't tell Eve who can decrypt the message */
write_32(a, 0 );
}
else {
write_32(a, enc->keyid[0] );
write_32(a, enc->keyid[1] );
}
iobuf_put(a,enc->pubkey_algo );
n = pubkey_get_nenc( enc->pubkey_algo );
if( !n )
write_fake_data( a, enc->data[0] );
for(i=0; i < n; i++ )
mpi_write(a, enc->data[i] );
write_header(out, ctb, iobuf_get_temp_length(a) );
if( iobuf_write_temp( out, a ) )
rc = G10ERR_WRITE_FILE;
iobuf_close(a);
return rc;
}
static u32
calc_plaintext( PKT_plaintext *pt )
{
return pt->len? (1 + 1 + pt->namelen + 4 + pt->len) : 0;
}
static int
do_plaintext( IOBUF out, int ctb, PKT_plaintext *pt )
{
int i, rc = 0;
u32 n;
byte buf[1000]; /* this buffer has the plaintext! */
int nbytes;
write_header(out, ctb, calc_plaintext( pt ) );
iobuf_put(out, pt->mode );
iobuf_put(out, pt->namelen );
for(i=0; i < pt->namelen; i++ )
iobuf_put(out, pt->name[i] );
if( write_32(out, pt->timestamp ) )
rc = G10ERR_WRITE_FILE;
n = 0;
while( (nbytes=iobuf_read(pt->buf, buf, 1000)) != -1 ) {
if( iobuf_write(out, buf, nbytes) == -1 ) {
rc = G10ERR_WRITE_FILE;
break;
}
n += nbytes;
}
memset(buf,0,1000); /* at least burn the buffer */
if( !pt->len )
iobuf_set_block_mode(out, 0 ); /* write end marker */
else if( n != pt->len )
log_error("do_plaintext(): wrote %lu bytes but expected %lu bytes\n",
(ulong)n, (ulong)pt->len );
return rc;
}
static int
do_encrypted( IOBUF out, int ctb, PKT_encrypted *ed )
{
int rc = 0;
u32 n;
n = ed->len ? (ed->len + ed->extralen) : 0;
write_header(out, ctb, n );
/* This is all. The caller has to write the real data */
return rc;
}
static int
do_encrypted_mdc( IOBUF out, int ctb, PKT_encrypted *ed )
{
int rc = 0;
u32 n;
assert( ed->mdc_method );
n = ed->len ? (ed->len + ed->extralen) : 0;
write_header(out, ctb, n );
iobuf_put(out, 1 ); /* version */
/* This is all. The caller has to write the real data */
return rc;
}
static int
do_mdc( IOBUF out, PKT_mdc *mdc )
{
/* This packet requires a fixed header encoding */
iobuf_put( out, 0xd3 ); /* packet ID and 1 byte length */
iobuf_put( out, 0x14 ); /* length = 20 */
if( iobuf_write( out, mdc->hash, sizeof(mdc->hash) ) )
return G10ERR_WRITE_FILE;
return 0;
}
static int
do_compressed( IOBUF out, int ctb, PKT_compressed *cd )
{
int rc = 0;
/* we must use the old convention and don't use blockmode */
write_header2(out, ctb, 0, 0, 0 );
iobuf_put(out, cd->algorithm );
/* This is all. The caller has to write the real data */
return rc;
}
/****************
* Find a subpacket of type REQTYPE in BUFFER and a return a pointer
* to the first byte of that subpacket data.
* And return the length of the packet in RET_N and the number of
* header bytes in RET_HLEN (length header and type byte).
*/
byte *
find_subpkt( byte *buffer, sigsubpkttype_t reqtype,
size_t *ret_hlen, size_t *ret_n )
{
int buflen;
sigsubpkttype_t type;
byte *bufstart;
size_t n;
if( !buffer )
return NULL;
buflen = (*buffer << 8) | buffer[1];
buffer += 2;
for(;;) {
if( !buflen )
return NULL; /* end of packets; not found */
bufstart = buffer;
n = *buffer++; buflen--;
if( n == 255 ) {
if( buflen < 4 )
break;
n = (buffer[0] << 24) | (buffer[1] << 16)
| (buffer[2] << 8) | buffer[3];
buffer += 4;
buflen -= 4;
}
else if( n >= 192 ) {
if( buflen < 2 )
break;
n = (( n - 192 ) << 8) + *buffer + 192;
buffer++;
buflen--;
}
if( buflen < n )
break;
type = *buffer & 0x7f;
if( type == reqtype ) {
buffer++;
n--;
if( n > buflen )
break;
if( ret_hlen )
*ret_hlen = buffer - bufstart;
if( ret_n )
*ret_n = n;
return buffer;
}
buffer += n; buflen -=n;
}
log_error("find_subpkt: buffer shorter than subpacket\n");
return NULL;
}
/****************
* Delete all subpackets of type REQTYPE and return the number of bytes
* which are now unused at the end of the buffer.
*/
size_t
delete_sig_subpkt( byte *buffer, sigsubpkttype_t reqtype )
{
int buflen, orig_buflen;
sigsubpkttype_t type;
byte *bufstart, *orig_buffer;
size_t n;
size_t unused = 0;
int okay = 0;
if( !buffer )
return 0;
orig_buffer = buffer;
buflen = (*buffer << 8) | buffer[1];
buffer += 2;
orig_buflen = buflen;
for(;;) {
if( !buflen ) {
okay = 1;
break;
}
bufstart = buffer;
n = *buffer++; buflen--;
if( n == 255 ) {
if( buflen < 4 )
break;
n = (buffer[0] << 24) | (buffer[1] << 16)
| (buffer[2] << 8) | buffer[3];
buffer += 4;
buflen -= 4;
}
else if( n >= 192 ) {
if( buflen < 2 )
break;
n = (( n - 192 ) << 8) + *buffer + 192;
buffer++;
buflen--;
}
if( buflen < n )
break;
type = *buffer & 0x7f;
if( type == reqtype ) {
buffer++;
buflen--;
n--;
if( n > buflen )
break;
memmove (bufstart, buffer + n, n + (buffer-bufstart)); /* shift */
unused += n + (buffer-bufstart);
buffer = bufstart;
buflen -= n;
}
else {
buffer += n; buflen -=n;
}
}
if (!okay)
log_error("delete_subpkt: buffer shorter than subpacket\n");
assert (unused <= orig_buflen);
orig_buflen -= unused;
orig_buffer[0] = (orig_buflen >> 8) & 0xff;
orig_buffer[1] = orig_buflen & 0xff;
return unused;
}
/****************
* Create or update a signature subpacket for SIG of TYPE.
* This functions knows where to put the data (hashed or unhashed).
* The function may move data from the unhashed part to the hashed one.
* Note: All pointers into sig->[un]hashed are not valid after a call
* to this function. The data to put into the subpaket should be
* in buffer with a length of buflen.
*/
void
build_sig_subpkt( PKT_signature *sig, sigsubpkttype_t type,
const byte *buffer, size_t buflen )
{
byte *data;
size_t hlen, dlen, nlen;
int found=0;
int critical, hashed, realloced;
size_t n, n0;
size_t unused = 0;
critical = (type & SIGSUBPKT_FLAG_CRITICAL);
type &= ~SIGSUBPKT_FLAG_CRITICAL;
if( type == SIGSUBPKT_NOTATION )
; /* we allow multiple packets */
else if( (data = find_subpkt( sig->hashed_data, type, &hlen, &dlen )) )
found = 1;
else if( (data = find_subpkt( sig->unhashed_data, type, &hlen, &dlen )))
found = 2;
if (found==2 && type == SIGSUBPKT_PRIV_VERIFY_CACHE) {
unused = delete_sig_subpkt (sig->unhashed_data, type);
assert (unused);
found = 0;
}
if( found )
log_bug("build_sig_packet: update nyi\n");
if( (buflen+1) >= 8384 )
nlen = 5;
else if( (buflen+1) >= 192 )
nlen = 2;
else
nlen = 1;
switch( type ) {
case SIGSUBPKT_SIG_CREATED:
case SIGSUBPKT_PREF_SYM:
case SIGSUBPKT_PREF_HASH:
case SIGSUBPKT_PREF_COMPR:
case SIGSUBPKT_KS_FLAGS:
case SIGSUBPKT_KEY_EXPIRE:
case SIGSUBPKT_NOTATION:
case SIGSUBPKT_POLICY:
case SIGSUBPKT_REVOC_REASON:
hashed = 1; break;
default: hashed = 0; break;
}
if( hashed ) {
n0 = sig->hashed_data ? ((*sig->hashed_data << 8)
| sig->hashed_data[1]) : 0;
n = n0 + nlen + 1 + buflen; /* length, type, buffer */
realloced = !!sig->hashed_data;
data = sig->hashed_data ? m_realloc( sig->hashed_data, n+2 )
: m_alloc( n+2 );
}
else {
n0 = sig->unhashed_data ? ((*sig->unhashed_data << 8)
| sig->unhashed_data[1]) : 0;
n = n0 + nlen + 1 + buflen; /* length, type, buffer */
if ( sig->unhashed_data && (nlen + 1 + buflen) <= unused ) {
/* does fit into the freed area */
data = sig->unhashed_data;
realloced = 1;
log_debug ("updating area of type %d\n", type );
}
else {
realloced = !!sig->unhashed_data;
data = sig->unhashed_data ? m_realloc( sig->unhashed_data, n+2 )
: m_alloc( n+2 );
}
}
if( critical )
type |= SIGSUBPKT_FLAG_CRITICAL;
data[0] = (n >> 8) & 0xff;
data[1] = n & 0xff;
if( nlen == 5 ) {
data[n0+2] = 255;
data[n0+3] = (buflen+1) >> 24;
data[n0+4] = (buflen+1) >> 16;
data[n0+5] = (buflen+1) >> 8;
data[n0+6] = (buflen+1);
data[n0+7] = type;
memcpy(data+n0+8, buffer, buflen );
}
else if( nlen == 2 ) {
data[n0+2] = (buflen+1-192) / 256 + 192;
data[n0+3] = (buflen+1-192) % 256;
data[n0+4] = type;
memcpy(data+n0+5, buffer, buflen );
}
else {
data[n0+2] = buflen+1;
data[n0+3] = type;
memcpy(data+n0+4, buffer, buflen );
}
if( hashed ) {
if( !realloced )
m_free(sig->hashed_data);
sig->hashed_data = data;
}
else {
if( !realloced )
m_free(sig->unhashed_data);
sig->unhashed_data = data;
}
}
/****************
* Put all the required stuff from SIG into subpackets of sig.
*/
void
build_sig_subpkt_from_sig( PKT_signature *sig )
{
u32 u;
byte buf[8];
u = sig->keyid[0];
buf[0] = (u >> 24) & 0xff;
buf[1] = (u >> 16) & 0xff;
buf[2] = (u >> 8) & 0xff;
buf[3] = u & 0xff;
u = sig->keyid[1];
buf[4] = (u >> 24) & 0xff;
buf[5] = (u >> 16) & 0xff;
buf[6] = (u >> 8) & 0xff;
buf[7] = u & 0xff;
build_sig_subpkt( sig, SIGSUBPKT_ISSUER, buf, 8 );
u = sig->timestamp;
buf[0] = (u >> 24) & 0xff;
buf[1] = (u >> 16) & 0xff;
buf[2] = (u >> 8) & 0xff;
buf[3] = u & 0xff;
build_sig_subpkt( sig, SIGSUBPKT_SIG_CREATED, buf, 4 );
}
static int
do_signature( IOBUF out, int ctb, PKT_signature *sig )
{
int rc = 0;
int n, i;
IOBUF a = iobuf_temp();
if( !sig->version )
iobuf_put( a, 3 );
else
iobuf_put( a, sig->version );
if( sig->version < 4 )
iobuf_put(a, 5 ); /* constant */
iobuf_put(a, sig->sig_class );
if( sig->version < 4 ) {
write_32(a, sig->timestamp );
write_32(a, sig->keyid[0] );
write_32(a, sig->keyid[1] );
}
iobuf_put(a, sig->pubkey_algo );
iobuf_put(a, sig->digest_algo );
if( sig->version >= 4 ) {
size_t nn;
/* timestamp and keyid must have been packed into the
* subpackets prior to the call of this function, because
* these subpackets are hashed */
nn = sig->hashed_data?((sig->hashed_data[0]<<8)
|sig->hashed_data[1]) :0;
write_16(a, nn);
if( nn )
iobuf_write( a, sig->hashed_data+2, nn );
nn = sig->unhashed_data?((sig->unhashed_data[0]<<8)
|sig->unhashed_data[1]) :0;
write_16(a, nn);
if( nn )
iobuf_write( a, sig->unhashed_data+2, nn );
}
iobuf_put(a, sig->digest_start[0] );
iobuf_put(a, sig->digest_start[1] );
n = pubkey_get_nsig( sig->pubkey_algo );
if( !n )
write_fake_data( a, sig->data[0] );
for(i=0; i < n; i++ )
mpi_write(a, sig->data[i] );
if( is_RSA(sig->pubkey_algo) && sig->version < 4 )
write_sign_packet_header(out, ctb, iobuf_get_temp_length(a) );
else
write_header(out, ctb, iobuf_get_temp_length(a) );
if( iobuf_write_temp( out, a ) )
rc = G10ERR_WRITE_FILE;
iobuf_close(a);
return rc;
}
static int
do_onepass_sig( IOBUF out, int ctb, PKT_onepass_sig *ops )
{
int rc = 0;
IOBUF a = iobuf_temp();
write_version( a, ctb );
iobuf_put(a, ops->sig_class );
iobuf_put(a, ops->digest_algo );
iobuf_put(a, ops->pubkey_algo );
write_32(a, ops->keyid[0] );
write_32(a, ops->keyid[1] );
iobuf_put(a, ops->last );
write_header(out, ctb, iobuf_get_temp_length(a) );
if( iobuf_write_temp( out, a ) )
rc = G10ERR_WRITE_FILE;
iobuf_close(a);
return rc;
}
static int
write_16(IOBUF out, u16 a)
{
iobuf_put(out, a>>8);
if( iobuf_put(out,a) )
return -1;
return 0;
}
static int
write_32(IOBUF out, u32 a)
{
iobuf_put(out, a>> 24);
iobuf_put(out, a>> 16);
iobuf_put(out, a>> 8);
if( iobuf_put(out, a) )
return -1;
return 0;
}
/****************
* calculate the length of a header
*/
static int
calc_header_length( u32 len, int new_ctb )
{
if( !len )
return 1; /* only the ctb */
if( new_ctb ) {
if( len < 192 )
return 2;
if( len < 8384 )
return 3;
else
return 6;
}
if( len < 256 )
return 2;
if( len < 65536 )
return 3;
return 5;
}
/****************
* Write the CTB and the packet length
*/
static int
write_header( IOBUF out, int ctb, u32 len )
{
return write_header2( out, ctb, len, 0, 1 );
}
static int
write_sign_packet_header( IOBUF out, int ctb, u32 len )
{
/* work around a bug in the pgp read function for signature packets,
* which are not correctly coded and silently assume at some
* point 2 byte length headers.*/
iobuf_put(out, 0x89 );
iobuf_put(out, len >> 8 );
return iobuf_put(out, len ) == -1 ? -1:0;
}
/****************
* if HDRLEN is > 0, try to build a header of this length.
* we need this, so that we can hash packets without reading them again.
*/
static int
write_header2( IOBUF out, int ctb, u32 len, int hdrlen, int blkmode )
{
if( ctb & 0x40 )
return write_new_header( out, ctb, len, hdrlen );
if( hdrlen ) {
if( !len )
ctb |= 3;
else if( hdrlen == 2 && len < 256 )
;
else if( hdrlen == 3 && len < 65536 )
ctb |= 1;
else
ctb |= 2;
}
else {
if( !len )
ctb |= 3;
else if( len < 256 )
;
else if( len < 65536 )
ctb |= 1;
else
ctb |= 2;
}
if( iobuf_put(out, ctb ) )
return -1;
if( !len ) {
if( blkmode )
iobuf_set_block_mode(out, 8196 );
}
else {
if( ctb & 2 ) {
iobuf_put(out, len >> 24 );
iobuf_put(out, len >> 16 );
}
if( ctb & 3 )
iobuf_put(out, len >> 8 );
if( iobuf_put(out, len ) )
return -1;
}
return 0;
}
static int
write_new_header( IOBUF out, int ctb, u32 len, int hdrlen )
{
if( hdrlen )
log_bug("can't cope with hdrlen yet\n");
if( iobuf_put(out, ctb ) )
return -1;
if( !len ) {
iobuf_set_partial_block_mode(out, 512 );
}
else {
if( len < 192 ) {
if( iobuf_put(out, len ) )
return -1;
}
else if( len < 8384 ) {
len -= 192;
if( iobuf_put( out, (len / 256) + 192) )
return -1;
if( iobuf_put( out, (len % 256) ) )
return -1;
}
else {
if( iobuf_put( out, 0xff ) )
return -1;
if( iobuf_put( out, (len >> 24)&0xff ) )
return -1;
if( iobuf_put( out, (len >> 16)&0xff ) )
return -1;
if( iobuf_put( out, (len >> 8)&0xff ) )
return -1;
if( iobuf_put( out, len & 0xff ) )
return -1;
}
}
return 0;
}
static int
write_version( IOBUF out, int ctb )
{
if( iobuf_put( out, 3 ) )
return -1;
return 0;
}