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samba-mirror/source4/heimdal/lib/gssapi/krb5/cfx.c
Andreas Schneider 8ba8267308 s4-heimdal: Remove the execute flag of cfx.c. 
The scripts which are extracting debuginfo are looking for files with
the executable bit and find cfx.c which isn't a executable.
2012-02-23 19:23:59 +01:00

1766 lines
44 KiB
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/*
* Copyright (c) 2003, PADL Software Pty Ltd.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* 3. Neither the name of PADL Software nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY PADL SOFTWARE AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL PADL SOFTWARE OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include "gsskrb5_locl.h"
/*
* Implementation of RFC 4121
*/
#define CFXSentByAcceptor (1 << 0)
#define CFXSealed (1 << 1)
#define CFXAcceptorSubkey (1 << 2)
krb5_error_code
_gsskrb5cfx_wrap_length_cfx(krb5_context context,
krb5_crypto crypto,
int conf_req_flag,
int dce_style,
size_t input_length,
size_t *output_length,
size_t *cksumsize,
uint16_t *padlength)
{
krb5_error_code ret;
krb5_cksumtype type;
/* 16-byte header is always first */
*output_length = sizeof(gss_cfx_wrap_token_desc);
*padlength = 0;
ret = krb5_crypto_get_checksum_type(context, crypto, &type);
if (ret)
return ret;
ret = krb5_checksumsize(context, type, cksumsize);
if (ret)
return ret;
if (conf_req_flag) {
size_t padsize;
/* Header is concatenated with data before encryption */
input_length += sizeof(gss_cfx_wrap_token_desc);
if (dce_style) {
ret = krb5_crypto_getblocksize(context, crypto, &padsize);
} else {
ret = krb5_crypto_getpadsize(context, crypto, &padsize);
}
if (ret) {
return ret;
}
if (padsize > 1) {
/* XXX check this */
*padlength = padsize - (input_length % padsize);
/* We add the pad ourselves (noted here for completeness only) */
input_length += *padlength;
}
*output_length += krb5_get_wrapped_length(context,
crypto, input_length);
} else {
/* Checksum is concatenated with data */
*output_length += input_length + *cksumsize;
}
assert(*output_length > input_length);
return 0;
}
OM_uint32
_gssapi_wrap_size_cfx(OM_uint32 *minor_status,
const gsskrb5_ctx ctx,
krb5_context context,
int conf_req_flag,
gss_qop_t qop_req,
OM_uint32 req_output_size,
OM_uint32 *max_input_size)
{
krb5_error_code ret;
*max_input_size = 0;
/* 16-byte header is always first */
if (req_output_size < 16)
return 0;
req_output_size -= 16;
if (conf_req_flag) {
size_t wrapped_size, sz;
wrapped_size = req_output_size + 1;
do {
wrapped_size--;
sz = krb5_get_wrapped_length(context,
ctx->crypto, wrapped_size);
} while (wrapped_size && sz > req_output_size);
if (wrapped_size == 0)
return 0;
/* inner header */
if (wrapped_size < 16)
return 0;
wrapped_size -= 16;
*max_input_size = wrapped_size;
} else {
krb5_cksumtype type;
size_t cksumsize;
ret = krb5_crypto_get_checksum_type(context, ctx->crypto, &type);
if (ret)
return ret;
ret = krb5_checksumsize(context, type, &cksumsize);
if (ret)
return ret;
if (req_output_size < cksumsize)
return 0;
/* Checksum is concatenated with data */
*max_input_size = req_output_size - cksumsize;
}
return 0;
}
/*
* Rotate "rrc" bytes to the front or back
*/
static krb5_error_code
rrc_rotate(void *data, size_t len, uint16_t rrc, krb5_boolean unrotate)
{
u_char *tmp, buf[256];
size_t left;
if (len == 0)
return 0;
rrc %= len;
if (rrc == 0)
return 0;
left = len - rrc;
if (rrc <= sizeof(buf)) {
tmp = buf;
} else {
tmp = malloc(rrc);
if (tmp == NULL)
return ENOMEM;
}
if (unrotate) {
memcpy(tmp, data, rrc);
memmove(data, (u_char *)data + rrc, left);
memcpy((u_char *)data + left, tmp, rrc);
} else {
memcpy(tmp, (u_char *)data + left, rrc);
memmove((u_char *)data + rrc, data, left);
memcpy(data, tmp, rrc);
}
if (rrc > sizeof(buf))
free(tmp);
return 0;
}
gss_iov_buffer_desc *
_gk_find_buffer(gss_iov_buffer_desc *iov, int iov_count, OM_uint32 type)
{
int i;
for (i = 0; i < iov_count; i++)
if (type == GSS_IOV_BUFFER_TYPE(iov[i].type))
return &iov[i];
return NULL;
}
OM_uint32
_gk_allocate_buffer(OM_uint32 *minor_status, gss_iov_buffer_desc *buffer, size_t size)
{
if (buffer->type & GSS_IOV_BUFFER_FLAG_ALLOCATED) {
if (buffer->buffer.length == size)
return GSS_S_COMPLETE;
free(buffer->buffer.value);
}
buffer->buffer.value = malloc(size);
buffer->buffer.length = size;
if (buffer->buffer.value == NULL) {
*minor_status = ENOMEM;
return GSS_S_FAILURE;
}
buffer->type |= GSS_IOV_BUFFER_FLAG_ALLOCATED;
return GSS_S_COMPLETE;
}
OM_uint32
_gk_verify_buffers(OM_uint32 *minor_status,
const gsskrb5_ctx ctx,
const gss_iov_buffer_desc *header,
const gss_iov_buffer_desc *padding,
const gss_iov_buffer_desc *trailer)
{
if (header == NULL) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
if (IS_DCE_STYLE(ctx)) {
/*
* In DCE style mode we reject having a padding or trailer buffer
*/
if (padding) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
if (trailer) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
} else {
/*
* In non-DCE style mode we require having a padding buffer
*/
if (padding == NULL) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
}
*minor_status = 0;
return GSS_S_COMPLETE;
}
OM_uint32
_gssapi_wrap_cfx_iov(OM_uint32 *minor_status,
gsskrb5_ctx ctx,
krb5_context context,
int conf_req_flag,
int *conf_state,
gss_iov_buffer_desc *iov,
int iov_count)
{
OM_uint32 major_status, junk;
gss_iov_buffer_desc *header, *trailer, *padding;
size_t gsshsize, k5hsize;
size_t gsstsize, k5tsize;
size_t rrc = 0, ec = 0;
int i;
gss_cfx_wrap_token token;
krb5_error_code ret;
int32_t seq_number;
unsigned usage;
krb5_crypto_iov *data = NULL;
header = _gk_find_buffer(iov, iov_count, GSS_IOV_BUFFER_TYPE_HEADER);
if (header == NULL) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
padding = _gk_find_buffer(iov, iov_count, GSS_IOV_BUFFER_TYPE_PADDING);
if (padding != NULL) {
padding->buffer.length = 0;
}
trailer = _gk_find_buffer(iov, iov_count, GSS_IOV_BUFFER_TYPE_TRAILER);
major_status = _gk_verify_buffers(minor_status, ctx, header, padding, trailer);
if (major_status != GSS_S_COMPLETE) {
return major_status;
}
if (conf_req_flag) {
size_t k5psize = 0;
size_t k5pbase = 0;
size_t k5bsize = 0;
size_t size = 0;
for (i = 0; i < iov_count; i++) {
switch (GSS_IOV_BUFFER_TYPE(iov[i].type)) {
case GSS_IOV_BUFFER_TYPE_DATA:
size += iov[i].buffer.length;
break;
default:
break;
}
}
size += sizeof(gss_cfx_wrap_token_desc);
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_HEADER,
&k5hsize);
if (*minor_status)
return GSS_S_FAILURE;
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_TRAILER,
&k5tsize);
if (*minor_status)
return GSS_S_FAILURE;
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_PADDING,
&k5pbase);
if (*minor_status)
return GSS_S_FAILURE;
if (k5pbase > 1) {
k5psize = k5pbase - (size % k5pbase);
} else {
k5psize = 0;
}
if (k5psize == 0 && IS_DCE_STYLE(ctx)) {
*minor_status = krb5_crypto_getblocksize(context, ctx->crypto,
&k5bsize);
if (*minor_status)
return GSS_S_FAILURE;
ec = k5bsize;
} else {
ec = k5psize;
}
gsshsize = sizeof(gss_cfx_wrap_token_desc) + k5hsize;
gsstsize = sizeof(gss_cfx_wrap_token_desc) + ec + k5tsize;
} else {
if (IS_DCE_STYLE(ctx)) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
k5hsize = 0;
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_CHECKSUM,
&k5tsize);
if (*minor_status)
return GSS_S_FAILURE;
gsshsize = sizeof(gss_cfx_wrap_token_desc);
gsstsize = k5tsize;
}
/*
*
*/
if (trailer == NULL) {
rrc = gsstsize;
if (IS_DCE_STYLE(ctx))
rrc -= ec;
gsshsize += gsstsize;
gsstsize = 0;
} else if (GSS_IOV_BUFFER_FLAGS(trailer->type) & GSS_IOV_BUFFER_FLAG_ALLOCATE) {
major_status = _gk_allocate_buffer(minor_status, trailer, gsstsize);
if (major_status)
goto failure;
} else if (trailer->buffer.length < gsstsize) {
*minor_status = KRB5_BAD_MSIZE;
major_status = GSS_S_FAILURE;
goto failure;
} else
trailer->buffer.length = gsstsize;
/*
*
*/
if (GSS_IOV_BUFFER_FLAGS(header->type) & GSS_IOV_BUFFER_FLAG_ALLOCATE) {
major_status = _gk_allocate_buffer(minor_status, header, gsshsize);
if (major_status != GSS_S_COMPLETE)
goto failure;
} else if (header->buffer.length < gsshsize) {
*minor_status = KRB5_BAD_MSIZE;
major_status = GSS_S_FAILURE;
goto failure;
} else
header->buffer.length = gsshsize;
token = (gss_cfx_wrap_token)header->buffer.value;
token->TOK_ID[0] = 0x05;
token->TOK_ID[1] = 0x04;
token->Flags = 0;
token->Filler = 0xFF;
if ((ctx->more_flags & LOCAL) == 0)
token->Flags |= CFXSentByAcceptor;
if (ctx->more_flags & ACCEPTOR_SUBKEY)
token->Flags |= CFXAcceptorSubkey;
if (ctx->more_flags & LOCAL)
usage = KRB5_KU_USAGE_INITIATOR_SEAL;
else
usage = KRB5_KU_USAGE_ACCEPTOR_SEAL;
if (conf_req_flag) {
/*
* In Wrap tokens with confidentiality, the EC field is
* used to encode the size (in bytes) of the random filler.
*/
token->Flags |= CFXSealed;
token->EC[0] = (ec >> 8) & 0xFF;
token->EC[1] = (ec >> 0) & 0xFF;
} else {
/*
* In Wrap tokens without confidentiality, the EC field is
* used to encode the size (in bytes) of the trailing
* checksum.
*
* This is not used in the checksum calcuation itself,
* because the checksum length could potentially vary
* depending on the data length.
*/
token->EC[0] = 0;
token->EC[1] = 0;
}
/*
* In Wrap tokens that provide for confidentiality, the RRC
* field in the header contains the hex value 00 00 before
* encryption.
*
* In Wrap tokens that do not provide for confidentiality,
* both the EC and RRC fields in the appended checksum
* contain the hex value 00 00 for the purpose of calculating
* the checksum.
*/
token->RRC[0] = 0;
token->RRC[1] = 0;
HEIMDAL_MUTEX_lock(&ctx->ctx_id_mutex);
krb5_auth_con_getlocalseqnumber(context,
ctx->auth_context,
&seq_number);
_gsskrb5_encode_be_om_uint32(0, &token->SND_SEQ[0]);
_gsskrb5_encode_be_om_uint32(seq_number, &token->SND_SEQ[4]);
krb5_auth_con_setlocalseqnumber(context,
ctx->auth_context,
++seq_number);
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
data = calloc(iov_count + 3, sizeof(data[0]));
if (data == NULL) {
*minor_status = ENOMEM;
major_status = GSS_S_FAILURE;
goto failure;
}
if (conf_req_flag) {
/*
plain packet:
{"header" | encrypt(plaintext-data | ec-padding | E"header")}
Expanded, this is with with RRC = 0:
{"header" | krb5-header | plaintext-data | ec-padding | E"header" | krb5-trailer }
In DCE-RPC mode == no trailer: RRC = gss "trailer" == length(ec-padding | E"header" | krb5-trailer)
{"header" | ec-padding | E"header" | krb5-trailer | krb5-header | plaintext-data }
*/
i = 0;
data[i].flags = KRB5_CRYPTO_TYPE_HEADER;
data[i].data.data = ((uint8_t *)header->buffer.value) + header->buffer.length - k5hsize;
data[i].data.length = k5hsize;
for (i = 1; i < iov_count + 1; i++) {
switch (GSS_IOV_BUFFER_TYPE(iov[i - 1].type)) {
case GSS_IOV_BUFFER_TYPE_DATA:
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
break;
case GSS_IOV_BUFFER_TYPE_SIGN_ONLY:
data[i].flags = KRB5_CRYPTO_TYPE_SIGN_ONLY;
break;
default:
data[i].flags = KRB5_CRYPTO_TYPE_EMPTY;
break;
}
data[i].data.length = iov[i - 1].buffer.length;
data[i].data.data = iov[i - 1].buffer.value;
}
/*
* Any necessary padding is added here to ensure that the
* encrypted token header is always at the end of the
* ciphertext.
*/
/* encrypted CFX header in trailer (or after the header if in
DCE mode). Copy in header into E"header"
*/
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
if (trailer)
data[i].data.data = trailer->buffer.value;
else
data[i].data.data = ((uint8_t *)header->buffer.value) + sizeof(*token);
data[i].data.length = ec + sizeof(*token);
memset(data[i].data.data, 0xFF, ec);
memcpy(((uint8_t *)data[i].data.data) + ec, token, sizeof(*token));
i++;
/* Kerberos trailer comes after the gss trailer */
data[i].flags = KRB5_CRYPTO_TYPE_TRAILER;
data[i].data.data = ((uint8_t *)data[i-1].data.data) + ec + sizeof(*token);
data[i].data.length = k5tsize;
i++;
ret = krb5_encrypt_iov_ivec(context, ctx->crypto, usage, data, i, NULL);
if (ret != 0) {
*minor_status = ret;
major_status = GSS_S_FAILURE;
goto failure;
}
if (rrc) {
token->RRC[0] = (rrc >> 8) & 0xFF;
token->RRC[1] = (rrc >> 0) & 0xFF;
}
} else {
/*
plain packet:
{data | "header" | gss-trailer (krb5 checksum)
don't do RRC != 0
*/
for (i = 0; i < iov_count; i++) {
switch (GSS_IOV_BUFFER_TYPE(iov[i].type)) {
case GSS_IOV_BUFFER_TYPE_DATA:
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
break;
case GSS_IOV_BUFFER_TYPE_SIGN_ONLY:
data[i].flags = KRB5_CRYPTO_TYPE_SIGN_ONLY;
break;
default:
data[i].flags = KRB5_CRYPTO_TYPE_EMPTY;
break;
}
data[i].data.length = iov[i].buffer.length;
data[i].data.data = iov[i].buffer.value;
}
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
data[i].data.data = header->buffer.value;
data[i].data.length = sizeof(gss_cfx_wrap_token_desc);
i++;
data[i].flags = KRB5_CRYPTO_TYPE_CHECKSUM;
if (trailer) {
data[i].data.data = trailer->buffer.value;
} else {
data[i].data.data = (uint8_t *)header->buffer.value +
sizeof(gss_cfx_wrap_token_desc);
}
data[i].data.length = k5tsize;
i++;
ret = krb5_create_checksum_iov(context, ctx->crypto, usage, data, i, NULL);
if (ret) {
*minor_status = ret;
major_status = GSS_S_FAILURE;
goto failure;
}
if (rrc) {
token->RRC[0] = (rrc >> 8) & 0xFF;
token->RRC[1] = (rrc >> 0) & 0xFF;
}
token->EC[0] = (k5tsize >> 8) & 0xFF;
token->EC[1] = (k5tsize >> 0) & 0xFF;
}
if (conf_state != NULL)
*conf_state = conf_req_flag;
free(data);
*minor_status = 0;
return GSS_S_COMPLETE;
failure:
if (data)
free(data);
gss_release_iov_buffer(&junk, iov, iov_count);
return major_status;
}
/* This is slowpath */
static OM_uint32
unrotate_iov(OM_uint32 *minor_status, size_t rrc, gss_iov_buffer_desc *iov, int iov_count)
{
uint8_t *p, *q;
size_t len = 0, skip;
int i;
for (i = 0; i < iov_count; i++)
if (GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_DATA ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_PADDING ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_TRAILER)
len += iov[i].buffer.length;
p = malloc(len);
if (p == NULL) {
*minor_status = ENOMEM;
return GSS_S_FAILURE;
}
q = p;
/* copy up */
for (i = 0; i < iov_count; i++) {
if (GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_DATA ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_PADDING ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_TRAILER)
{
memcpy(q, iov[i].buffer.value, iov[i].buffer.length);
q += iov[i].buffer.length;
}
}
assert((size_t)(q - p) == len);
/* unrotate first part */
q = p + rrc;
skip = rrc;
for (i = 0; i < iov_count; i++) {
if (GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_DATA ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_PADDING ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_TRAILER)
{
if (iov[i].buffer.length <= skip) {
skip -= iov[i].buffer.length;
} else {
memcpy(((uint8_t *)iov[i].buffer.value) + skip, q, iov[i].buffer.length - skip);
q += iov[i].buffer.length - skip;
skip = 0;
}
}
}
/* copy trailer */
q = p;
skip = rrc;
for (i = 0; i < iov_count; i++) {
if (GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_DATA ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_PADDING ||
GSS_IOV_BUFFER_TYPE(iov[i].type) == GSS_IOV_BUFFER_TYPE_TRAILER)
{
memcpy(q, iov[i].buffer.value, min(iov[i].buffer.length, skip));
if (iov[i].buffer.length > skip)
break;
skip -= iov[i].buffer.length;
q += iov[i].buffer.length;
}
}
return GSS_S_COMPLETE;
}
OM_uint32
_gssapi_unwrap_cfx_iov(OM_uint32 *minor_status,
gsskrb5_ctx ctx,
krb5_context context,
int *conf_state,
gss_qop_t *qop_state,
gss_iov_buffer_desc *iov,
int iov_count)
{
OM_uint32 seq_number_lo, seq_number_hi, major_status, junk;
gss_iov_buffer_desc *header, *trailer, *padding;
gss_cfx_wrap_token token, ttoken;
u_char token_flags;
krb5_error_code ret;
unsigned usage;
uint16_t ec, rrc;
krb5_crypto_iov *data = NULL;
int i, j;
*minor_status = 0;
header = _gk_find_buffer(iov, iov_count, GSS_IOV_BUFFER_TYPE_HEADER);
if (header == NULL) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
if (header->buffer.length < sizeof(*token)) /* we check exact below */
return GSS_S_DEFECTIVE_TOKEN;
padding = _gk_find_buffer(iov, iov_count, GSS_IOV_BUFFER_TYPE_PADDING);
if (padding != NULL && padding->buffer.length != 0) {
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
trailer = _gk_find_buffer(iov, iov_count, GSS_IOV_BUFFER_TYPE_TRAILER);
major_status = _gk_verify_buffers(minor_status, ctx, header, padding, trailer);
if (major_status != GSS_S_COMPLETE) {
return major_status;
}
token = (gss_cfx_wrap_token)header->buffer.value;
if (token->TOK_ID[0] != 0x05 || token->TOK_ID[1] != 0x04)
return GSS_S_DEFECTIVE_TOKEN;
/* Ignore unknown flags */
token_flags = token->Flags &
(CFXSentByAcceptor | CFXSealed | CFXAcceptorSubkey);
if (token_flags & CFXSentByAcceptor) {
if ((ctx->more_flags & LOCAL) == 0)
return GSS_S_DEFECTIVE_TOKEN;
}
if (ctx->more_flags & ACCEPTOR_SUBKEY) {
if ((token_flags & CFXAcceptorSubkey) == 0)
return GSS_S_DEFECTIVE_TOKEN;
} else {
if (token_flags & CFXAcceptorSubkey)
return GSS_S_DEFECTIVE_TOKEN;
}
if (token->Filler != 0xFF)
return GSS_S_DEFECTIVE_TOKEN;
if (conf_state != NULL)
*conf_state = (token_flags & CFXSealed) ? 1 : 0;
ec = (token->EC[0] << 8) | token->EC[1];
rrc = (token->RRC[0] << 8) | token->RRC[1];
/*
* Check sequence number
*/
_gsskrb5_decode_be_om_uint32(&token->SND_SEQ[0], &seq_number_hi);
_gsskrb5_decode_be_om_uint32(&token->SND_SEQ[4], &seq_number_lo);
if (seq_number_hi) {
/* no support for 64-bit sequence numbers */
*minor_status = ERANGE;
return GSS_S_UNSEQ_TOKEN;
}
HEIMDAL_MUTEX_lock(&ctx->ctx_id_mutex);
ret = _gssapi_msg_order_check(ctx->order, seq_number_lo);
if (ret != 0) {
*minor_status = 0;
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
return ret;
}
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
/*
* Decrypt and/or verify checksum
*/
if (ctx->more_flags & LOCAL) {
usage = KRB5_KU_USAGE_ACCEPTOR_SEAL;
} else {
usage = KRB5_KU_USAGE_INITIATOR_SEAL;
}
data = calloc(iov_count + 3, sizeof(data[0]));
if (data == NULL) {
*minor_status = ENOMEM;
major_status = GSS_S_FAILURE;
goto failure;
}
if (token_flags & CFXSealed) {
size_t k5tsize, k5hsize;
krb5_crypto_length(context, ctx->crypto, KRB5_CRYPTO_TYPE_HEADER, &k5hsize);
krb5_crypto_length(context, ctx->crypto, KRB5_CRYPTO_TYPE_TRAILER, &k5tsize);
/* Rotate by RRC; bogus to do this in-place XXX */
/* Check RRC */
if (trailer == NULL) {
size_t gsstsize = k5tsize + sizeof(*token);
size_t gsshsize = k5hsize + sizeof(*token);
if (rrc != gsstsize) {
major_status = GSS_S_DEFECTIVE_TOKEN;
goto failure;
}
if (IS_DCE_STYLE(ctx))
gsstsize += ec;
gsshsize += gsstsize;
if (header->buffer.length != gsshsize) {
major_status = GSS_S_DEFECTIVE_TOKEN;
goto failure;
}
} else if (trailer->buffer.length != sizeof(*token) + k5tsize) {
major_status = GSS_S_DEFECTIVE_TOKEN;
goto failure;
} else if (header->buffer.length != sizeof(*token) + k5hsize) {
major_status = GSS_S_DEFECTIVE_TOKEN;
goto failure;
} else if (rrc != 0) {
/* go though slowpath */
major_status = unrotate_iov(minor_status, rrc, iov, iov_count);
if (major_status)
goto failure;
}
i = 0;
data[i].flags = KRB5_CRYPTO_TYPE_HEADER;
data[i].data.data = ((uint8_t *)header->buffer.value) + header->buffer.length - k5hsize;
data[i].data.length = k5hsize;
i++;
for (j = 0; j < iov_count; i++, j++) {
switch (GSS_IOV_BUFFER_TYPE(iov[j].type)) {
case GSS_IOV_BUFFER_TYPE_DATA:
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
break;
case GSS_IOV_BUFFER_TYPE_SIGN_ONLY:
data[i].flags = KRB5_CRYPTO_TYPE_SIGN_ONLY;
break;
default:
data[i].flags = KRB5_CRYPTO_TYPE_EMPTY;
break;
}
data[i].data.length = iov[j].buffer.length;
data[i].data.data = iov[j].buffer.value;
}
/* encrypted CFX header in trailer (or after the header if in
DCE mode). Copy in header into E"header"
*/
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
if (trailer) {
data[i].data.data = trailer->buffer.value;
} else {
data[i].data.data = ((uint8_t *)header->buffer.value) +
header->buffer.length - k5hsize - k5tsize - ec- sizeof(*token);
}
data[i].data.length = ec + sizeof(*token);
ttoken = (gss_cfx_wrap_token)(((uint8_t *)data[i].data.data) + ec);
i++;
/* Kerberos trailer comes after the gss trailer */
data[i].flags = KRB5_CRYPTO_TYPE_TRAILER;
data[i].data.data = ((uint8_t *)data[i-1].data.data) + ec + sizeof(*token);
data[i].data.length = k5tsize;
i++;
ret = krb5_decrypt_iov_ivec(context, ctx->crypto, usage, data, i, NULL);
if (ret != 0) {
*minor_status = ret;
major_status = GSS_S_FAILURE;
goto failure;
}
ttoken->RRC[0] = token->RRC[0];
ttoken->RRC[1] = token->RRC[1];
/* Check the integrity of the header */
if (ct_memcmp(ttoken, token, sizeof(*token)) != 0) {
major_status = GSS_S_BAD_MIC;
goto failure;
}
} else {
size_t gsstsize = ec;
size_t gsshsize = sizeof(*token);
if (trailer == NULL) {
/* Check RRC */
if (rrc != gsstsize) {
*minor_status = EINVAL;
major_status = GSS_S_FAILURE;
goto failure;
}
gsshsize += gsstsize;
gsstsize = 0;
} else if (trailer->buffer.length != gsstsize) {
major_status = GSS_S_DEFECTIVE_TOKEN;
goto failure;
} else if (rrc != 0) {
/* Check RRC */
*minor_status = EINVAL;
major_status = GSS_S_FAILURE;
goto failure;
}
if (header->buffer.length != gsshsize) {
major_status = GSS_S_DEFECTIVE_TOKEN;
goto failure;
}
for (i = 0; i < iov_count; i++) {
switch (GSS_IOV_BUFFER_TYPE(iov[i].type)) {
case GSS_IOV_BUFFER_TYPE_DATA:
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
break;
case GSS_IOV_BUFFER_TYPE_SIGN_ONLY:
data[i].flags = KRB5_CRYPTO_TYPE_SIGN_ONLY;
break;
default:
data[i].flags = KRB5_CRYPTO_TYPE_EMPTY;
break;
}
data[i].data.length = iov[i].buffer.length;
data[i].data.data = iov[i].buffer.value;
}
data[i].flags = KRB5_CRYPTO_TYPE_DATA;
data[i].data.data = header->buffer.value;
data[i].data.length = sizeof(*token);
i++;
data[i].flags = KRB5_CRYPTO_TYPE_CHECKSUM;
if (trailer) {
data[i].data.data = trailer->buffer.value;
} else {
data[i].data.data = (uint8_t *)header->buffer.value +
sizeof(*token);
}
data[i].data.length = ec;
i++;
token = (gss_cfx_wrap_token)header->buffer.value;
token->EC[0] = 0;
token->EC[1] = 0;
token->RRC[0] = 0;
token->RRC[1] = 0;
ret = krb5_verify_checksum_iov(context, ctx->crypto, usage, data, i, NULL);
if (ret) {
*minor_status = ret;
major_status = GSS_S_FAILURE;
goto failure;
}
}
if (qop_state != NULL) {
*qop_state = GSS_C_QOP_DEFAULT;
}
free(data);
*minor_status = 0;
return GSS_S_COMPLETE;
failure:
if (data)
free(data);
gss_release_iov_buffer(&junk, iov, iov_count);
return major_status;
}
OM_uint32
_gssapi_wrap_iov_length_cfx(OM_uint32 *minor_status,
gsskrb5_ctx ctx,
krb5_context context,
int conf_req_flag,
gss_qop_t qop_req,
int *conf_state,
gss_iov_buffer_desc *iov,
int iov_count)
{
OM_uint32 major_status;
size_t size;
int i;
gss_iov_buffer_desc *header = NULL;
gss_iov_buffer_desc *padding = NULL;
gss_iov_buffer_desc *trailer = NULL;
size_t gsshsize = 0;
size_t gsstsize = 0;
size_t k5hsize = 0;
size_t k5tsize = 0;
GSSAPI_KRB5_INIT (&context);
*minor_status = 0;
for (size = 0, i = 0; i < iov_count; i++) {
switch(GSS_IOV_BUFFER_TYPE(iov[i].type)) {
case GSS_IOV_BUFFER_TYPE_EMPTY:
break;
case GSS_IOV_BUFFER_TYPE_DATA:
size += iov[i].buffer.length;
break;
case GSS_IOV_BUFFER_TYPE_HEADER:
if (header != NULL) {
*minor_status = 0;
return GSS_S_FAILURE;
}
header = &iov[i];
break;
case GSS_IOV_BUFFER_TYPE_TRAILER:
if (trailer != NULL) {
*minor_status = 0;
return GSS_S_FAILURE;
}
trailer = &iov[i];
break;
case GSS_IOV_BUFFER_TYPE_PADDING:
if (padding != NULL) {
*minor_status = 0;
return GSS_S_FAILURE;
}
padding = &iov[i];
break;
case GSS_IOV_BUFFER_TYPE_SIGN_ONLY:
break;
default:
*minor_status = EINVAL;
return GSS_S_FAILURE;
}
}
major_status = _gk_verify_buffers(minor_status, ctx, header, padding, trailer);
if (major_status != GSS_S_COMPLETE) {
return major_status;
}
if (conf_req_flag) {
size_t k5psize = 0;
size_t k5pbase = 0;
size_t k5bsize = 0;
size_t ec = 0;
size += sizeof(gss_cfx_wrap_token_desc);
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_HEADER,
&k5hsize);
if (*minor_status)
return GSS_S_FAILURE;
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_TRAILER,
&k5tsize);
if (*minor_status)
return GSS_S_FAILURE;
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_PADDING,
&k5pbase);
if (*minor_status)
return GSS_S_FAILURE;
if (k5pbase > 1) {
k5psize = k5pbase - (size % k5pbase);
} else {
k5psize = 0;
}
if (k5psize == 0 && IS_DCE_STYLE(ctx)) {
*minor_status = krb5_crypto_getblocksize(context, ctx->crypto,
&k5bsize);
if (*minor_status)
return GSS_S_FAILURE;
ec = k5bsize;
} else {
ec = k5psize;
}
gsshsize = sizeof(gss_cfx_wrap_token_desc) + k5hsize;
gsstsize = sizeof(gss_cfx_wrap_token_desc) + ec + k5tsize;
} else {
*minor_status = krb5_crypto_length(context, ctx->crypto,
KRB5_CRYPTO_TYPE_CHECKSUM,
&k5tsize);
if (*minor_status)
return GSS_S_FAILURE;
gsshsize = sizeof(gss_cfx_wrap_token_desc);
gsstsize = k5tsize;
}
if (trailer != NULL) {
trailer->buffer.length = gsstsize;
} else {
gsshsize += gsstsize;
}
header->buffer.length = gsshsize;
if (padding) {
/* padding is done via EC and is contained in the header or trailer */
padding->buffer.length = 0;
}
if (conf_state) {
*conf_state = conf_req_flag;
}
return GSS_S_COMPLETE;
}
OM_uint32 _gssapi_wrap_cfx(OM_uint32 *minor_status,
const gsskrb5_ctx ctx,
krb5_context context,
int conf_req_flag,
const gss_buffer_t input_message_buffer,
int *conf_state,
gss_buffer_t output_message_buffer)
{
gss_cfx_wrap_token token;
krb5_error_code ret;
unsigned usage;
krb5_data cipher;
size_t wrapped_len, cksumsize;
uint16_t padlength, rrc = 0;
int32_t seq_number;
u_char *p;
ret = _gsskrb5cfx_wrap_length_cfx(context,
ctx->crypto, conf_req_flag,
IS_DCE_STYLE(ctx),
input_message_buffer->length,
&wrapped_len, &cksumsize, &padlength);
if (ret != 0) {
*minor_status = ret;
return GSS_S_FAILURE;
}
/* Always rotate encrypted token (if any) and checksum to header */
rrc = (conf_req_flag ? sizeof(*token) : 0) + (uint16_t)cksumsize;
output_message_buffer->length = wrapped_len;
output_message_buffer->value = malloc(output_message_buffer->length);
if (output_message_buffer->value == NULL) {
*minor_status = ENOMEM;
return GSS_S_FAILURE;
}
p = output_message_buffer->value;
token = (gss_cfx_wrap_token)p;
token->TOK_ID[0] = 0x05;
token->TOK_ID[1] = 0x04;
token->Flags = 0;
token->Filler = 0xFF;
if ((ctx->more_flags & LOCAL) == 0)
token->Flags |= CFXSentByAcceptor;
if (ctx->more_flags & ACCEPTOR_SUBKEY)
token->Flags |= CFXAcceptorSubkey;
if (conf_req_flag) {
/*
* In Wrap tokens with confidentiality, the EC field is
* used to encode the size (in bytes) of the random filler.
*/
token->Flags |= CFXSealed;
token->EC[0] = (padlength >> 8) & 0xFF;
token->EC[1] = (padlength >> 0) & 0xFF;
} else {
/*
* In Wrap tokens without confidentiality, the EC field is
* used to encode the size (in bytes) of the trailing
* checksum.
*
* This is not used in the checksum calcuation itself,
* because the checksum length could potentially vary
* depending on the data length.
*/
token->EC[0] = 0;
token->EC[1] = 0;
}
/*
* In Wrap tokens that provide for confidentiality, the RRC
* field in the header contains the hex value 00 00 before
* encryption.
*
* In Wrap tokens that do not provide for confidentiality,
* both the EC and RRC fields in the appended checksum
* contain the hex value 00 00 for the purpose of calculating
* the checksum.
*/
token->RRC[0] = 0;
token->RRC[1] = 0;
HEIMDAL_MUTEX_lock(&ctx->ctx_id_mutex);
krb5_auth_con_getlocalseqnumber(context,
ctx->auth_context,
&seq_number);
_gsskrb5_encode_be_om_uint32(0, &token->SND_SEQ[0]);
_gsskrb5_encode_be_om_uint32(seq_number, &token->SND_SEQ[4]);
krb5_auth_con_setlocalseqnumber(context,
ctx->auth_context,
++seq_number);
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
/*
* If confidentiality is requested, the token header is
* appended to the plaintext before encryption; the resulting
* token is {"header" | encrypt(plaintext | pad | "header")}.
*
* If no confidentiality is requested, the checksum is
* calculated over the plaintext concatenated with the
* token header.
*/
if (ctx->more_flags & LOCAL) {
usage = KRB5_KU_USAGE_INITIATOR_SEAL;
} else {
usage = KRB5_KU_USAGE_ACCEPTOR_SEAL;
}
if (conf_req_flag) {
/*
* Any necessary padding is added here to ensure that the
* encrypted token header is always at the end of the
* ciphertext.
*
* The specification does not require that the padding
* bytes are initialized.
*/
p += sizeof(*token);
memcpy(p, input_message_buffer->value, input_message_buffer->length);
memset(p + input_message_buffer->length, 0xFF, padlength);
memcpy(p + input_message_buffer->length + padlength,
token, sizeof(*token));
ret = krb5_encrypt(context, ctx->crypto,
usage, p,
input_message_buffer->length + padlength +
sizeof(*token),
&cipher);
if (ret != 0) {
*minor_status = ret;
_gsskrb5_release_buffer(minor_status, output_message_buffer);
return GSS_S_FAILURE;
}
assert(sizeof(*token) + cipher.length == wrapped_len);
token->RRC[0] = (rrc >> 8) & 0xFF;
token->RRC[1] = (rrc >> 0) & 0xFF;
/*
* this is really ugly, but needed against windows
* for DCERPC, as windows rotates by EC+RRC.
*/
if (IS_DCE_STYLE(ctx)) {
ret = rrc_rotate(cipher.data, cipher.length, rrc+padlength, FALSE);
} else {
ret = rrc_rotate(cipher.data, cipher.length, rrc, FALSE);
}
if (ret != 0) {
*minor_status = ret;
_gsskrb5_release_buffer(minor_status, output_message_buffer);
return GSS_S_FAILURE;
}
memcpy(p, cipher.data, cipher.length);
krb5_data_free(&cipher);
} else {
char *buf;
Checksum cksum;
buf = malloc(input_message_buffer->length + sizeof(*token));
if (buf == NULL) {
*minor_status = ENOMEM;
_gsskrb5_release_buffer(minor_status, output_message_buffer);
return GSS_S_FAILURE;
}
memcpy(buf, input_message_buffer->value, input_message_buffer->length);
memcpy(buf + input_message_buffer->length, token, sizeof(*token));
ret = krb5_create_checksum(context, ctx->crypto,
usage, 0, buf,
input_message_buffer->length +
sizeof(*token),
&cksum);
if (ret != 0) {
*minor_status = ret;
_gsskrb5_release_buffer(minor_status, output_message_buffer);
free(buf);
return GSS_S_FAILURE;
}
free(buf);
assert(cksum.checksum.length == cksumsize);
token->EC[0] = (cksum.checksum.length >> 8) & 0xFF;
token->EC[1] = (cksum.checksum.length >> 0) & 0xFF;
token->RRC[0] = (rrc >> 8) & 0xFF;
token->RRC[1] = (rrc >> 0) & 0xFF;
p += sizeof(*token);
memcpy(p, input_message_buffer->value, input_message_buffer->length);
memcpy(p + input_message_buffer->length,
cksum.checksum.data, cksum.checksum.length);
ret = rrc_rotate(p,
input_message_buffer->length + cksum.checksum.length, rrc, FALSE);
if (ret != 0) {
*minor_status = ret;
_gsskrb5_release_buffer(minor_status, output_message_buffer);
free_Checksum(&cksum);
return GSS_S_FAILURE;
}
free_Checksum(&cksum);
}
if (conf_state != NULL) {
*conf_state = conf_req_flag;
}
*minor_status = 0;
return GSS_S_COMPLETE;
}
OM_uint32 _gssapi_unwrap_cfx(OM_uint32 *minor_status,
const gsskrb5_ctx ctx,
krb5_context context,
const gss_buffer_t input_message_buffer,
gss_buffer_t output_message_buffer,
int *conf_state,
gss_qop_t *qop_state)
{
gss_cfx_wrap_token token;
u_char token_flags;
krb5_error_code ret;
unsigned usage;
krb5_data data;
uint16_t ec, rrc;
OM_uint32 seq_number_lo, seq_number_hi;
size_t len;
u_char *p;
*minor_status = 0;
if (input_message_buffer->length < sizeof(*token)) {
return GSS_S_DEFECTIVE_TOKEN;
}
p = input_message_buffer->value;
token = (gss_cfx_wrap_token)p;
if (token->TOK_ID[0] != 0x05 || token->TOK_ID[1] != 0x04) {
return GSS_S_DEFECTIVE_TOKEN;
}
/* Ignore unknown flags */
token_flags = token->Flags &
(CFXSentByAcceptor | CFXSealed | CFXAcceptorSubkey);
if (token_flags & CFXSentByAcceptor) {
if ((ctx->more_flags & LOCAL) == 0)
return GSS_S_DEFECTIVE_TOKEN;
}
if (ctx->more_flags & ACCEPTOR_SUBKEY) {
if ((token_flags & CFXAcceptorSubkey) == 0)
return GSS_S_DEFECTIVE_TOKEN;
} else {
if (token_flags & CFXAcceptorSubkey)
return GSS_S_DEFECTIVE_TOKEN;
}
if (token->Filler != 0xFF) {
return GSS_S_DEFECTIVE_TOKEN;
}
if (conf_state != NULL) {
*conf_state = (token_flags & CFXSealed) ? 1 : 0;
}
ec = (token->EC[0] << 8) | token->EC[1];
rrc = (token->RRC[0] << 8) | token->RRC[1];
/*
* Check sequence number
*/
_gsskrb5_decode_be_om_uint32(&token->SND_SEQ[0], &seq_number_hi);
_gsskrb5_decode_be_om_uint32(&token->SND_SEQ[4], &seq_number_lo);
if (seq_number_hi) {
/* no support for 64-bit sequence numbers */
*minor_status = ERANGE;
return GSS_S_UNSEQ_TOKEN;
}
HEIMDAL_MUTEX_lock(&ctx->ctx_id_mutex);
ret = _gssapi_msg_order_check(ctx->order, seq_number_lo);
if (ret != 0) {
*minor_status = 0;
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
_gsskrb5_release_buffer(minor_status, output_message_buffer);
return ret;
}
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
/*
* Decrypt and/or verify checksum
*/
if (ctx->more_flags & LOCAL) {
usage = KRB5_KU_USAGE_ACCEPTOR_SEAL;
} else {
usage = KRB5_KU_USAGE_INITIATOR_SEAL;
}
p += sizeof(*token);
len = input_message_buffer->length;
len -= (p - (u_char *)input_message_buffer->value);
if (token_flags & CFXSealed) {
/*
* this is really ugly, but needed against windows
* for DCERPC, as windows rotates by EC+RRC.
*/
if (IS_DCE_STYLE(ctx)) {
*minor_status = rrc_rotate(p, len, rrc+ec, TRUE);
} else {
*minor_status = rrc_rotate(p, len, rrc, TRUE);
}
if (*minor_status != 0) {
return GSS_S_FAILURE;
}
ret = krb5_decrypt(context, ctx->crypto, usage,
p, len, &data);
if (ret != 0) {
*minor_status = ret;
return GSS_S_BAD_MIC;
}
/* Check that there is room for the pad and token header */
if (data.length < ec + sizeof(*token)) {
krb5_data_free(&data);
return GSS_S_DEFECTIVE_TOKEN;
}
p = data.data;
p += data.length - sizeof(*token);
/* RRC is unprotected; don't modify input buffer */
((gss_cfx_wrap_token)p)->RRC[0] = token->RRC[0];
((gss_cfx_wrap_token)p)->RRC[1] = token->RRC[1];
/* Check the integrity of the header */
if (ct_memcmp(p, token, sizeof(*token)) != 0) {
krb5_data_free(&data);
return GSS_S_BAD_MIC;
}
output_message_buffer->value = data.data;
output_message_buffer->length = data.length - ec - sizeof(*token);
} else {
Checksum cksum;
/* Rotate by RRC; bogus to do this in-place XXX */
*minor_status = rrc_rotate(p, len, rrc, TRUE);
if (*minor_status != 0) {
return GSS_S_FAILURE;
}
/* Determine checksum type */
ret = krb5_crypto_get_checksum_type(context,
ctx->crypto,
&cksum.cksumtype);
if (ret != 0) {
*minor_status = ret;
return GSS_S_FAILURE;
}
cksum.checksum.length = ec;
/* Check we have at least as much data as the checksum */
if (len < cksum.checksum.length) {
*minor_status = ERANGE;
return GSS_S_BAD_MIC;
}
/* Length now is of the plaintext only, no checksum */
len -= cksum.checksum.length;
cksum.checksum.data = p + len;
output_message_buffer->length = len; /* for later */
output_message_buffer->value = malloc(len + sizeof(*token));
if (output_message_buffer->value == NULL) {
*minor_status = ENOMEM;
return GSS_S_FAILURE;
}
/* Checksum is over (plaintext-data | "header") */
memcpy(output_message_buffer->value, p, len);
memcpy((u_char *)output_message_buffer->value + len,
token, sizeof(*token));
/* EC is not included in checksum calculation */
token = (gss_cfx_wrap_token)((u_char *)output_message_buffer->value +
len);
token->EC[0] = 0;
token->EC[1] = 0;
token->RRC[0] = 0;
token->RRC[1] = 0;
ret = krb5_verify_checksum(context, ctx->crypto,
usage,
output_message_buffer->value,
len + sizeof(*token),
&cksum);
if (ret != 0) {
*minor_status = ret;
_gsskrb5_release_buffer(minor_status, output_message_buffer);
return GSS_S_BAD_MIC;
}
}
if (qop_state != NULL) {
*qop_state = GSS_C_QOP_DEFAULT;
}
*minor_status = 0;
return GSS_S_COMPLETE;
}
OM_uint32 _gssapi_mic_cfx(OM_uint32 *minor_status,
const gsskrb5_ctx ctx,
krb5_context context,
gss_qop_t qop_req,
const gss_buffer_t message_buffer,
gss_buffer_t message_token)
{
gss_cfx_mic_token token;
krb5_error_code ret;
unsigned usage;
Checksum cksum;
u_char *buf;
size_t len;
int32_t seq_number;
len = message_buffer->length + sizeof(*token);
buf = malloc(len);
if (buf == NULL) {
*minor_status = ENOMEM;
return GSS_S_FAILURE;
}
memcpy(buf, message_buffer->value, message_buffer->length);
token = (gss_cfx_mic_token)(buf + message_buffer->length);
token->TOK_ID[0] = 0x04;
token->TOK_ID[1] = 0x04;
token->Flags = 0;
if ((ctx->more_flags & LOCAL) == 0)
token->Flags |= CFXSentByAcceptor;
if (ctx->more_flags & ACCEPTOR_SUBKEY)
token->Flags |= CFXAcceptorSubkey;
memset(token->Filler, 0xFF, 5);
HEIMDAL_MUTEX_lock(&ctx->ctx_id_mutex);
krb5_auth_con_getlocalseqnumber(context,
ctx->auth_context,
&seq_number);
_gsskrb5_encode_be_om_uint32(0, &token->SND_SEQ[0]);
_gsskrb5_encode_be_om_uint32(seq_number, &token->SND_SEQ[4]);
krb5_auth_con_setlocalseqnumber(context,
ctx->auth_context,
++seq_number);
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
if (ctx->more_flags & LOCAL) {
usage = KRB5_KU_USAGE_INITIATOR_SIGN;
} else {
usage = KRB5_KU_USAGE_ACCEPTOR_SIGN;
}
ret = krb5_create_checksum(context, ctx->crypto,
usage, 0, buf, len, &cksum);
if (ret != 0) {
*minor_status = ret;
free(buf);
return GSS_S_FAILURE;
}
/* Determine MIC length */
message_token->length = sizeof(*token) + cksum.checksum.length;
message_token->value = malloc(message_token->length);
if (message_token->value == NULL) {
*minor_status = ENOMEM;
free_Checksum(&cksum);
free(buf);
return GSS_S_FAILURE;
}
/* Token is { "header" | get_mic("header" | plaintext-data) } */
memcpy(message_token->value, token, sizeof(*token));
memcpy((u_char *)message_token->value + sizeof(*token),
cksum.checksum.data, cksum.checksum.length);
free_Checksum(&cksum);
free(buf);
*minor_status = 0;
return GSS_S_COMPLETE;
}
OM_uint32 _gssapi_verify_mic_cfx(OM_uint32 *minor_status,
const gsskrb5_ctx ctx,
krb5_context context,
const gss_buffer_t message_buffer,
const gss_buffer_t token_buffer,
gss_qop_t *qop_state)
{
gss_cfx_mic_token token;
u_char token_flags;
krb5_error_code ret;
unsigned usage;
OM_uint32 seq_number_lo, seq_number_hi;
u_char *buf, *p;
Checksum cksum;
*minor_status = 0;
if (token_buffer->length < sizeof(*token)) {
return GSS_S_DEFECTIVE_TOKEN;
}
p = token_buffer->value;
token = (gss_cfx_mic_token)p;
if (token->TOK_ID[0] != 0x04 || token->TOK_ID[1] != 0x04) {
return GSS_S_DEFECTIVE_TOKEN;
}
/* Ignore unknown flags */
token_flags = token->Flags & (CFXSentByAcceptor | CFXAcceptorSubkey);
if (token_flags & CFXSentByAcceptor) {
if ((ctx->more_flags & LOCAL) == 0)
return GSS_S_DEFECTIVE_TOKEN;
}
if (ctx->more_flags & ACCEPTOR_SUBKEY) {
if ((token_flags & CFXAcceptorSubkey) == 0)
return GSS_S_DEFECTIVE_TOKEN;
} else {
if (token_flags & CFXAcceptorSubkey)
return GSS_S_DEFECTIVE_TOKEN;
}
if (ct_memcmp(token->Filler, "\xff\xff\xff\xff\xff", 5) != 0) {
return GSS_S_DEFECTIVE_TOKEN;
}
/*
* Check sequence number
*/
_gsskrb5_decode_be_om_uint32(&token->SND_SEQ[0], &seq_number_hi);
_gsskrb5_decode_be_om_uint32(&token->SND_SEQ[4], &seq_number_lo);
if (seq_number_hi) {
*minor_status = ERANGE;
return GSS_S_UNSEQ_TOKEN;
}
HEIMDAL_MUTEX_lock(&ctx->ctx_id_mutex);
ret = _gssapi_msg_order_check(ctx->order, seq_number_lo);
if (ret != 0) {
*minor_status = 0;
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
return ret;
}
HEIMDAL_MUTEX_unlock(&ctx->ctx_id_mutex);
/*
* Verify checksum
*/
ret = krb5_crypto_get_checksum_type(context, ctx->crypto,
&cksum.cksumtype);
if (ret != 0) {
*minor_status = ret;
return GSS_S_FAILURE;
}
cksum.checksum.data = p + sizeof(*token);
cksum.checksum.length = token_buffer->length - sizeof(*token);
if (ctx->more_flags & LOCAL) {
usage = KRB5_KU_USAGE_ACCEPTOR_SIGN;
} else {
usage = KRB5_KU_USAGE_INITIATOR_SIGN;
}
buf = malloc(message_buffer->length + sizeof(*token));
if (buf == NULL) {
*minor_status = ENOMEM;
return GSS_S_FAILURE;
}
memcpy(buf, message_buffer->value, message_buffer->length);
memcpy(buf + message_buffer->length, token, sizeof(*token));
ret = krb5_verify_checksum(context, ctx->crypto,
usage,
buf,
sizeof(*token) + message_buffer->length,
&cksum);
if (ret != 0) {
*minor_status = ret;
free(buf);
return GSS_S_BAD_MIC;
}
free(buf);
if (qop_state != NULL) {
*qop_state = GSS_C_QOP_DEFAULT;
}
return GSS_S_COMPLETE;
}
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