/*
Unix SMB/CIFS implementation.
libndr compression support
Copyright (C) Stefan Metzmacher 2005
Copyright (C) Matthieu Suiche 2008
This program 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 3 of the License, or
(at your option) any later version.
This program 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, see .
*/
#include "includes.h"
#include "../lib/compression/lzxpress.h"
#include "../lib/compression/lzxpress_huffman.h"
#include "librpc/ndr/libndr.h"
#include "../librpc/ndr/ndr_compression.h"
#include
struct ndr_compression_state {
enum ndr_compression_alg type;
union {
struct {
struct z_stream_s *z;
uint8_t *dict;
size_t dict_size;
} mszip;
struct {
struct lzxhuff_compressor_mem *mem;
} lzxpress_huffman;
} alg;
};
static voidpf ndr_zlib_alloc(voidpf opaque, uInt items, uInt size)
{
return talloc_zero_size(opaque, items * size);
}
static void ndr_zlib_free(voidpf opaque, voidpf address)
{
talloc_free(address);
}
static enum ndr_err_code ndr_pull_compression_mszip_cab_chunk(struct ndr_pull *ndrpull,
struct ndr_push *ndrpush,
struct ndr_compression_state *state,
ssize_t decompressed_len,
ssize_t compressed_len)
{
DATA_BLOB comp_chunk;
uint32_t comp_chunk_offset;
uint32_t comp_chunk_size;
DATA_BLOB plain_chunk;
uint32_t plain_chunk_offset;
uint32_t plain_chunk_size;
z_stream *z = state->alg.mszip.z;
int z_ret;
plain_chunk_size = decompressed_len;
if (plain_chunk_size > 0x00008000) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad MSZIP CAB plain chunk size %08"PRIX32" > 0x00008000 (PULL)",
plain_chunk_size);
}
comp_chunk_size = compressed_len;
DEBUG(9,("MSZIP CAB plain_chunk_size: %08"PRIX32" (%"PRIu32") comp_chunk_size: %08"PRIX32" (%"PRIu32")\n",
plain_chunk_size, plain_chunk_size, comp_chunk_size, comp_chunk_size));
comp_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, comp_chunk_size));
comp_chunk.length = comp_chunk_size;
comp_chunk.data = ndrpull->data + comp_chunk_offset;
plain_chunk_offset = ndrpush->offset;
NDR_CHECK(ndr_push_zero(ndrpush, plain_chunk_size));
plain_chunk.length = plain_chunk_size;
plain_chunk.data = ndrpush->data + plain_chunk_offset;
if (comp_chunk.length < 2) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad MSZIP CAB comp chunk size %zu < 2 (PULL)",
comp_chunk.length);
}
/* CK = Chris Kirmse, official Microsoft purloiner */
if (comp_chunk.data[0] != 'C' ||
comp_chunk.data[1] != 'K') {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad MSZIP CAB invalid prefix [%c%c] != [CK]",
comp_chunk.data[0], comp_chunk.data[1]);
}
/*
* This is a MSZIP block. It is actually using the deflate
* algorithm which can be decompressed by zlib. zlib will try
* to decompress as much as it can in each run. If we provide
* all the input and enough room for the uncompressed output,
* one call is enough. It will loop over all the sub-blocks
* that make up a deflate block.
*
* See corresponding push function for more info.
*/
z->next_in = comp_chunk.data + 2;
z->avail_in = comp_chunk.length - 2;
z->next_out = plain_chunk.data;
z->avail_out = plain_chunk.length;
/*
* Each MSZIP CDATA contains a complete deflate stream
* i.e. the stream starts and ends in the CFDATA but the
* _dictionary_ is shared between all CFDATA of a CFFOLDER.
*
* When decompressing, the initial dictionary of the first
* CDATA is empty. All other CFDATA use the previous CFDATA
* uncompressed output as dictionary.
*/
if (state->alg.mszip.dict_size) {
z_ret = inflateSetDictionary(z, state->alg.mszip.dict, state->alg.mszip.dict_size);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib inflateSetDictionary error %s (%d) %s (PULL)",
zError(z_ret), z_ret, z->msg);
}
}
z_ret = inflate(z, Z_FINISH);
if (z_ret == Z_OK) {
/*
* Z_OK here means there was no error but the stream
* hasn't been fully decompressed because there was
* not enough room for the output, which should not
* happen
*/
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib inflate error not enough space for output (PULL)");
}
if (z_ret != Z_STREAM_END) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib inflate error %s (%d) %s (PULL)", zError(z_ret), z_ret, z->msg);
}
if (z->total_out < plain_chunk.length) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib uncompressed output is smaller than expected (%lu < %zu) (PULL)",
z->total_out, plain_chunk.length);
}
/*
* Keep a copy of the output to set as dictionary for the
* next decompression call.
*
* The input pointer seems to be still valid between calls, so
* we can just store that instead of copying the memory over
* the dict temp buffer.
*/
state->alg.mszip.dict = plain_chunk.data;
state->alg.mszip.dict_size = plain_chunk.length;
z_ret = inflateReset(z);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib inflateReset error %s (%d) %s (PULL)",
zError(z_ret), z_ret, z->msg);
}
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_push_compression_mszip_cab_chunk(struct ndr_push *ndrpush,
struct ndr_pull *ndrpull,
struct ndr_compression_state *state)
{
DATA_BLOB comp_chunk;
uint32_t comp_chunk_size;
DATA_BLOB plain_chunk;
uint32_t plain_chunk_size;
uint32_t plain_chunk_offset;
uint32_t max_plain_size = 0x00008000;
/*
* The maximum compressed size of each MSZIP block is 32k + 12 bytes
* header size.
*/
uint32_t max_comp_size = 0x00008000 + 12;
int z_ret;
z_stream *z;
if (ndrpull->data_size <= ndrpull->offset) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"strange NDR pull size and offset (integer overflow?)");
}
plain_chunk_size = MIN(max_plain_size, ndrpull->data_size - ndrpull->offset);
plain_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, plain_chunk_size));
plain_chunk.data = ndrpull->data + plain_chunk_offset;
plain_chunk.length = plain_chunk_size;
NDR_CHECK(ndr_push_expand(ndrpush, max_comp_size));
comp_chunk.data = ndrpush->data + ndrpush->offset;
comp_chunk.length = max_comp_size;
/* CK = Chris Kirmse, official Microsoft purloiner */
comp_chunk.data[0] = 'C';
comp_chunk.data[1] = 'K';
z = state->alg.mszip.z;
z->next_in = plain_chunk.data;
z->avail_in = plain_chunk.length;
z->total_in = 0;
z->next_out = comp_chunk.data + 2;
z->avail_out = comp_chunk.length;
z->total_out = 0;
/*
* See pull function for explanations of the MSZIP format.
*
* The CFDATA block contains a full deflate stream. Each stream
* uses the uncompressed input of the previous CFDATA in the
* same CFFOLDER as a dictionary for the compression.
*/
if (state->alg.mszip.dict_size) {
z_ret = deflateSetDictionary(z, state->alg.mszip.dict, state->alg.mszip.dict_size);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib deflateSetDictionary error %s (%d) %s (PUSH)",
zError(z_ret), z_ret, z->msg);
}
}
/*
* Z_FINISH should make deflate process all of the input in
* one call. If the stream is not finished there was an error
* e.g. not enough room to store the compressed output.
*/
z_ret = deflate(z, Z_FINISH);
if (z_ret != Z_STREAM_END) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"zlib deflate error %s (%d) %s (PUSH)",
zError(z_ret), z_ret, z->msg);
}
if (z->avail_in) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"MSZIP not all avail_in[%u] bytes consumed (PUSH)",
z->avail_in);
}
comp_chunk_size = 2 + z->total_out;
if (comp_chunk_size < z->total_out) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"strange NDR push compressed size (integer overflow?)");
}
z_ret = deflateReset(z);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib deflateReset error %s (%d) %s (PUSH)",
zError(z_ret), z_ret, z->msg);
}
if (plain_chunk.length > talloc_array_length(state->alg.mszip.dict)) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"zlib dict buffer is too big (PUSH)");
}
/*
* Keep a copy of the input to set as dictionary for the next
* compression call.
*
* Ideally we would just store the input pointer and length
* without copying but the memory gets invalidated between the
* calls, so we just copy to a dedicated buffer we know is
* still going to be valid for the lifetime of the
* compressions state object.
*/
memcpy(state->alg.mszip.dict, plain_chunk.data, plain_chunk.length);
state->alg.mszip.dict_size = plain_chunk.length;
DEBUG(9,("MSZIP comp plain_chunk_size: %08zX (%zu) comp_chunk_size: %08"PRIX32" (%"PRIu32")\n",
plain_chunk.length,
plain_chunk.length,
comp_chunk_size, comp_chunk_size));
ndrpush->offset += comp_chunk_size;
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_pull_compression_mszip_chunk(struct ndr_pull *ndrpull,
struct ndr_push *ndrpush,
z_stream *z,
bool *last)
{
DATA_BLOB comp_chunk;
uint32_t comp_chunk_offset;
uint32_t comp_chunk_size;
DATA_BLOB plain_chunk;
uint32_t plain_chunk_offset;
uint32_t plain_chunk_size;
int z_ret;
NDR_CHECK(ndr_pull_uint32(ndrpull, NDR_SCALARS, &plain_chunk_size));
if (plain_chunk_size > 0x00008000) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION, "Bad MSZIP plain chunk size %08"PRIX32" > 0x00008000 (PULL)",
plain_chunk_size);
}
NDR_CHECK(ndr_pull_uint32(ndrpull, NDR_SCALARS, &comp_chunk_size));
DEBUG(9,("MSZIP plain_chunk_size: %08"PRIX32" (%"PRIu32") comp_chunk_size: %08"PRIX32" (%"PRIu32")\n",
plain_chunk_size, plain_chunk_size, comp_chunk_size, comp_chunk_size));
comp_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, comp_chunk_size));
comp_chunk.length = comp_chunk_size;
comp_chunk.data = ndrpull->data + comp_chunk_offset;
plain_chunk_offset = ndrpush->offset;
NDR_CHECK(ndr_push_zero(ndrpush, plain_chunk_size));
plain_chunk.length = plain_chunk_size;
plain_chunk.data = ndrpush->data + plain_chunk_offset;
if (comp_chunk.length < 2) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad MSZIP comp chunk size %zu < 2 (PULL)",
comp_chunk.length);
}
/* CK = Chris Kirmse, official Microsoft purloiner */
if (comp_chunk.data[0] != 'C' ||
comp_chunk.data[1] != 'K') {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad MSZIP invalid prefix [%c%c] != [CK]",
comp_chunk.data[0], comp_chunk.data[1]);
}
z->next_in = comp_chunk.data + 2;
z->avail_in = comp_chunk.length -2;
z->total_in = 0;
z->next_out = plain_chunk.data;
z->avail_out = plain_chunk.length;
z->total_out = 0;
if (!z->opaque) {
/* the first time we need to initialize completely */
z->zalloc = ndr_zlib_alloc;
z->zfree = ndr_zlib_free;
z->opaque = ndrpull;
z_ret = inflateInit2(z, -MAX_WBITS);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad inflateInit2 error %s(%d) (PULL)",
zError(z_ret), z_ret);
}
}
/* call inflate until we get Z_STREAM_END or an error */
while (true) {
z_ret = inflate(z, Z_BLOCK);
if (z_ret != Z_OK) break;
}
if (z_ret != Z_STREAM_END) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad inflate(Z_BLOCK) error %s(%d) (PULL)",
zError(z_ret), z_ret);
}
if (z->avail_in) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"MSZIP not all avail_in[%u] bytes consumed (PULL)",
z->avail_in);
}
if (z->avail_out) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"MSZIP not all avail_out[%u] bytes consumed (PULL)",
z->avail_out);
}
if ((plain_chunk_size < 0x00008000) || (ndrpull->offset+4 >= ndrpull->data_size)) {
/* this is the last chunk */
*last = true;
}
z_ret = inflateReset(z);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad inflateReset error %s(%d) (PULL)",
zError(z_ret), z_ret);
}
z_ret = inflateSetDictionary(z, plain_chunk.data, plain_chunk.length);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad inflateSetDictionary error %s(%d) (PULL)",
zError(z_ret), z_ret);
}
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_push_compression_mszip_chunk(struct ndr_push *ndrpush,
struct ndr_pull *ndrpull,
z_stream *z,
bool *last)
{
DATA_BLOB comp_chunk;
uint32_t comp_chunk_size;
uint32_t comp_chunk_size_offset;
DATA_BLOB plain_chunk;
uint32_t plain_chunk_size;
uint32_t plain_chunk_offset;
uint32_t max_plain_size = 0x00008000;
/*
* The maximum compressed size of each MSZIP block is 32k + 12 bytes
* header size.
*/
uint32_t max_comp_size = 0x00008000 + 12;
uint32_t tmp_offset;
int z_ret;
plain_chunk_size = MIN(max_plain_size, ndrpull->data_size - ndrpull->offset);
plain_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, plain_chunk_size));
plain_chunk.data = ndrpull->data + plain_chunk_offset;
plain_chunk.length = plain_chunk_size;
if (plain_chunk_size < max_plain_size) {
*last = true;
}
NDR_CHECK(ndr_push_uint32(ndrpush, NDR_SCALARS, plain_chunk_size));
comp_chunk_size_offset = ndrpush->offset;
NDR_CHECK(ndr_push_uint32(ndrpush, NDR_SCALARS, 0xFEFEFEFE));
NDR_CHECK(ndr_push_expand(ndrpush, max_comp_size));
comp_chunk.data = ndrpush->data + ndrpush->offset;
comp_chunk.length = max_comp_size;
/* CK = Chris Kirmse, official Microsoft purloiner */
comp_chunk.data[0] = 'C';
comp_chunk.data[1] = 'K';
z->next_in = plain_chunk.data;
z->avail_in = plain_chunk.length;
z->total_in = 0;
z->next_out = comp_chunk.data + 2;
z->avail_out = comp_chunk.length;
z->total_out = 0;
if (!z->opaque) {
/* the first time we need to initialize completely */
z->zalloc = ndr_zlib_alloc;
z->zfree = ndr_zlib_free;
z->opaque = ndrpull;
/* TODO: find how to trigger the same parameters windows uses */
z_ret = deflateInit2(z,
Z_DEFAULT_COMPRESSION,
Z_DEFLATED,
-MAX_WBITS,
8, /* memLevel */
Z_DEFAULT_STRATEGY);
if (z_ret != Z_OK) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"Bad deflateInit2 error %s(%d) (PUSH)",
zError(z_ret), z_ret);
}
}
/* call deflate until we get Z_STREAM_END or an error */
while (true) {
z_ret = deflate(z, Z_FINISH);
if (z_ret != Z_OK) break;
}
if (z_ret != Z_STREAM_END) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"Bad deflate(Z_BLOCK) error %s(%d) (PUSH)",
zError(z_ret), z_ret);
}
if (z->avail_in) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"MSZIP not all avail_in[%u] bytes consumed (PUSH)",
z->avail_in);
}
comp_chunk_size = 2 + z->total_out;
z_ret = deflateReset(z);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad deflateReset error %s(%d) (PULL)",
zError(z_ret), z_ret);
}
z_ret = deflateSetDictionary(z, plain_chunk.data, plain_chunk.length);
if (z_ret != Z_OK) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"Bad deflateSetDictionary error %s(%d) (PULL)",
zError(z_ret), z_ret);
}
tmp_offset = ndrpush->offset;
ndrpush->offset = comp_chunk_size_offset;
NDR_CHECK(ndr_push_uint32(ndrpush, NDR_SCALARS, comp_chunk_size));
ndrpush->offset = tmp_offset;
DEBUG(9,("MSZIP comp plain_chunk_size: %08zX (%zu) comp_chunk_size: %08"PRIX32" (%"PRIu32")\n",
plain_chunk.length,
plain_chunk.length,
comp_chunk_size, comp_chunk_size));
ndrpush->offset += comp_chunk_size;
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_pull_compression_xpress_chunk(struct ndr_pull *ndrpull,
struct ndr_push *ndrpush,
bool *last)
{
DATA_BLOB comp_chunk;
DATA_BLOB plain_chunk;
uint32_t comp_chunk_offset;
uint32_t plain_chunk_offset;
uint32_t comp_chunk_size;
uint32_t plain_chunk_size;
ssize_t ret;
NDR_CHECK(ndr_pull_uint32(ndrpull, NDR_SCALARS, &plain_chunk_size));
if (plain_chunk_size > 0x00010000) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION, "Bad XPRESS plain chunk size %08"PRIX32" > 0x00010000 (PULL)",
plain_chunk_size);
}
NDR_CHECK(ndr_pull_uint32(ndrpull, NDR_SCALARS, &comp_chunk_size));
comp_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, comp_chunk_size));
comp_chunk.length = comp_chunk_size;
comp_chunk.data = ndrpull->data + comp_chunk_offset;
plain_chunk_offset = ndrpush->offset;
NDR_CHECK(ndr_push_zero(ndrpush, plain_chunk_size));
plain_chunk.length = plain_chunk_size;
plain_chunk.data = ndrpush->data + plain_chunk_offset;
DEBUG(9,("XPRESS plain_chunk_size: %08"PRIX32" (%"PRIu32") comp_chunk_size: %08"PRIX32" (%"PRIu32")\n",
plain_chunk_size, plain_chunk_size, comp_chunk_size, comp_chunk_size));
/* Uncompressing the buffer using LZ Xpress algorithm */
ret = lzxpress_decompress(comp_chunk.data,
comp_chunk.length,
plain_chunk.data,
plain_chunk.length);
if (ret < 0) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"XPRESS lzxpress_decompress() returned %zd\n",
ret);
}
plain_chunk.length = ret;
if ((plain_chunk_size < 0x00010000) || (ndrpull->offset+4 >= ndrpull->data_size)) {
/* this is the last chunk */
*last = true;
}
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_push_compression_xpress_chunk(struct ndr_push *ndrpush,
struct ndr_pull *ndrpull,
bool *last)
{
DATA_BLOB comp_chunk;
uint32_t comp_chunk_size_offset;
DATA_BLOB plain_chunk;
uint32_t plain_chunk_size;
uint32_t plain_chunk_offset;
uint32_t max_plain_size = 0x00010000;
uint32_t max_comp_size = 0x00020000 + 2; /* TODO: use the correct value here */
uint32_t tmp_offset;
ssize_t ret;
plain_chunk_size = MIN(max_plain_size, ndrpull->data_size - ndrpull->offset);
plain_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, plain_chunk_size));
plain_chunk.data = ndrpull->data + plain_chunk_offset;
plain_chunk.length = plain_chunk_size;
if (plain_chunk_size < max_plain_size) {
*last = true;
}
NDR_CHECK(ndr_push_uint32(ndrpush, NDR_SCALARS, plain_chunk_size));
comp_chunk_size_offset = ndrpush->offset;
NDR_CHECK(ndr_push_uint32(ndrpush, NDR_SCALARS, 0xFEFEFEFE));
NDR_CHECK(ndr_push_expand(ndrpush, max_comp_size));
comp_chunk.data = ndrpush->data + ndrpush->offset;
comp_chunk.length = max_comp_size;
/* Compressing the buffer using LZ Xpress algorithm */
ret = lzxpress_compress(plain_chunk.data,
plain_chunk.length,
comp_chunk.data,
comp_chunk.length);
if (ret < 0) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"XPRESS lzxpress_compress() returned %zd\n",
ret);
}
comp_chunk.length = ret;
tmp_offset = ndrpush->offset;
ndrpush->offset = comp_chunk_size_offset;
NDR_CHECK(ndr_push_uint32(ndrpush, NDR_SCALARS, comp_chunk.length));
ndrpush->offset = tmp_offset;
ndrpush->offset += comp_chunk.length;
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_pull_compression_none(struct ndr_pull *ndrpull,
struct ndr_push *ndrpush,
ssize_t decompressed_len,
ssize_t compressed_len)
{
DATA_BLOB comp_chunk;
uint32_t comp_chunk_size = compressed_len;
uint32_t comp_chunk_offset;
if (decompressed_len != compressed_len) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"decompressed len %zd != compressed_len %zd in 'NONE' compression!",
decompressed_len,
compressed_len);
}
if (comp_chunk_size != compressed_len) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"compressed_len %zd overflows uint32_t in 'NONE' compression!",
compressed_len);
}
comp_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, comp_chunk_size));
comp_chunk.length = comp_chunk_size;
comp_chunk.data = ndrpull->data + comp_chunk_offset;
NDR_CHECK(ndr_push_array_uint8(ndrpush,
NDR_SCALARS,
comp_chunk.data,
comp_chunk.length));
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_push_compression_none(struct ndr_push *ndrpush,
struct ndr_pull *ndrpull)
{
DATA_BLOB plain_chunk;
uint32_t plain_chunk_size;
uint32_t plain_chunk_offset;
plain_chunk_size = ndrpull->data_size - ndrpull->offset;
plain_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, plain_chunk_size));
plain_chunk.data = ndrpull->data + plain_chunk_offset;
plain_chunk.length = plain_chunk_size;
NDR_CHECK(ndr_push_array_uint8(ndrpush,
NDR_SCALARS,
plain_chunk.data,
plain_chunk.length));
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_pull_compression_xpress_huff_raw_chunk(struct ndr_pull *ndrpull,
struct ndr_push *ndrpush,
ssize_t decompressed_len,
ssize_t compressed_len)
{
DATA_BLOB comp_chunk;
uint32_t comp_chunk_offset;
uint32_t comp_chunk_size;
DATA_BLOB plain_chunk;
uint32_t plain_chunk_offset;
uint32_t plain_chunk_size;
ssize_t ret;
plain_chunk_size = decompressed_len;
comp_chunk_size = compressed_len;
DEBUG(9,("XPRESS_HUFF plain_chunk_size: %08X (%u) comp_chunk_size: %08X (%u)\n",
plain_chunk_size, plain_chunk_size, comp_chunk_size, comp_chunk_size));
comp_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, comp_chunk_size));
comp_chunk.length = comp_chunk_size;
comp_chunk.data = ndrpull->data + comp_chunk_offset;
plain_chunk_offset = ndrpush->offset;
NDR_CHECK(ndr_push_zero(ndrpush, plain_chunk_size));
plain_chunk.length = plain_chunk_size;
plain_chunk.data = ndrpush->data + plain_chunk_offset;
/* Decompressing the buffer using LZ Xpress w/ Huffman algorithm */
ret = lzxpress_huffman_decompress(comp_chunk.data,
comp_chunk.length,
plain_chunk.data,
plain_chunk.length);
if (ret < 0) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"XPRESS HUFF lzxpress_huffman_decompress() returned %zd\n",
ret);
}
if (plain_chunk.length != ret) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"XPRESS HUFF lzxpress_huffman_decompress() output is not as expected (%zd != %zu) (PULL)",
ret, plain_chunk.length);
}
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code ndr_push_compression_xpress_huff_raw_chunk(struct ndr_push *ndrpush,
struct ndr_pull *ndrpull,
struct ndr_compression_state *state)
{
DATA_BLOB comp_chunk;
DATA_BLOB plain_chunk;
uint32_t plain_chunk_size;
uint32_t plain_chunk_offset;
ssize_t ret;
struct lzxhuff_compressor_mem *mem = state->alg.lzxpress_huffman.mem;
if (ndrpull->data_size <= ndrpull->offset) {
return ndr_push_error(ndrpush, NDR_ERR_COMPRESSION,
"strange NDR pull size and offset (integer overflow?)");
}
plain_chunk_size = ndrpull->data_size - ndrpull->offset;
plain_chunk_offset = ndrpull->offset;
NDR_CHECK(ndr_pull_advance(ndrpull, plain_chunk_size));
plain_chunk.data = ndrpull->data + plain_chunk_offset;
plain_chunk.length = plain_chunk_size;
comp_chunk.length = lzxpress_huffman_max_compressed_size(plain_chunk_size);
NDR_CHECK(ndr_push_expand(ndrpush, comp_chunk.length));
comp_chunk.data = ndrpush->data + ndrpush->offset;
/* Compressing the buffer using LZ Xpress w/ Huffman algorithm */
ret = lzxpress_huffman_compress(mem,
plain_chunk.data,
plain_chunk.length,
comp_chunk.data,
comp_chunk.length);
if (ret < 0) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"XPRESS HUFF lzxpress_huffman_compress() returned %zd\n",
ret);
}
if (ret > comp_chunk.length) {
return ndr_pull_error(ndrpull, NDR_ERR_COMPRESSION,
"XPRESS HUFF lzxpress_huffman_compress() output is not as expected (%zd > %zu) (PULL)",
ret, comp_chunk.length);
}
ndrpush->offset += ret;
return NDR_ERR_SUCCESS;
}
/*
handle compressed subcontext buffers, which in midl land are user-marshalled, but
we use magic in pidl to make them easier to cope with
*/
enum ndr_err_code ndr_pull_compression_start(struct ndr_pull *subndr,
struct ndr_pull **_comndr,
enum ndr_compression_alg compression_alg,
ssize_t decompressed_len,
ssize_t compressed_len)
{
struct ndr_push *ndrpush;
struct ndr_pull *comndr;
DATA_BLOB uncompressed;
bool last = false;
z_stream z;
ndrpush = ndr_push_init_ctx(subndr);
NDR_ERR_HAVE_NO_MEMORY(ndrpush);
switch (compression_alg) {
case NDR_COMPRESSION_NONE:
NDR_CHECK(ndr_pull_compression_none(subndr, ndrpush,
decompressed_len,
compressed_len));
break;
case NDR_COMPRESSION_MSZIP_CAB:
NDR_CHECK(ndr_pull_compression_mszip_cab_chunk(subndr, ndrpush,
subndr->cstate,
decompressed_len,
compressed_len));
break;
case NDR_COMPRESSION_MSZIP:
ZERO_STRUCT(z);
while (!last) {
NDR_CHECK(ndr_pull_compression_mszip_chunk(subndr, ndrpush, &z, &last));
}
break;
case NDR_COMPRESSION_XPRESS:
while (!last) {
NDR_CHECK(ndr_pull_compression_xpress_chunk(subndr, ndrpush, &last));
}
break;
case NDR_COMPRESSION_XPRESS_HUFF_RAW:
NDR_CHECK(ndr_pull_compression_xpress_huff_raw_chunk(subndr, ndrpush,
decompressed_len,
compressed_len));
break;
default:
return ndr_pull_error(subndr, NDR_ERR_COMPRESSION, "Bad compression algorithm %d (PULL)",
compression_alg);
}
uncompressed = ndr_push_blob(ndrpush);
if (uncompressed.length != decompressed_len) {
return ndr_pull_error(subndr, NDR_ERR_COMPRESSION,
"Bad uncompressed_len [%zu] != [%zd](0x%08zX) (PULL)",
uncompressed.length,
decompressed_len,
decompressed_len);
}
comndr = talloc_zero(subndr, struct ndr_pull);
NDR_ERR_HAVE_NO_MEMORY(comndr);
comndr->flags = subndr->flags;
comndr->current_mem_ctx = subndr->current_mem_ctx;
comndr->data = uncompressed.data;
comndr->data_size = uncompressed.length;
comndr->offset = 0;
*_comndr = comndr;
return NDR_ERR_SUCCESS;
}
enum ndr_err_code ndr_pull_compression_end(struct ndr_pull *subndr,
struct ndr_pull *comndr,
enum ndr_compression_alg compression_alg,
ssize_t decompressed_len)
{
return NDR_ERR_SUCCESS;
}
/*
push a compressed subcontext
*/
enum ndr_err_code ndr_push_compression_start(struct ndr_push *subndr,
struct ndr_push **_uncomndr)
{
struct ndr_push *uncomndr;
enum ndr_compression_alg compression_alg = subndr->cstate->type;
switch (compression_alg) {
case NDR_COMPRESSION_NONE:
case NDR_COMPRESSION_MSZIP_CAB:
case NDR_COMPRESSION_MSZIP:
case NDR_COMPRESSION_XPRESS:
case NDR_COMPRESSION_XPRESS_HUFF_RAW:
break;
default:
return ndr_push_error(subndr, NDR_ERR_COMPRESSION,
"Bad compression algorithm %d (PUSH)",
compression_alg);
}
uncomndr = ndr_push_init_ctx(subndr);
NDR_ERR_HAVE_NO_MEMORY(uncomndr);
uncomndr->flags = subndr->flags;
*_uncomndr = uncomndr;
return NDR_ERR_SUCCESS;
}
/*
push a compressed subcontext
*/
enum ndr_err_code ndr_push_compression_end(struct ndr_push *subndr,
struct ndr_push *uncomndr)
{
struct ndr_pull *ndrpull;
bool last = false;
z_stream z;
enum ndr_compression_alg compression_alg = subndr->cstate->type;
ndrpull = talloc_zero(uncomndr, struct ndr_pull);
NDR_ERR_HAVE_NO_MEMORY(ndrpull);
ndrpull->flags = uncomndr->flags;
ndrpull->data = uncomndr->data;
ndrpull->data_size = uncomndr->offset;
ndrpull->offset = 0;
switch (compression_alg) {
case NDR_COMPRESSION_NONE:
NDR_CHECK(ndr_push_compression_none(subndr, ndrpull));
break;
case NDR_COMPRESSION_MSZIP_CAB:
NDR_CHECK(ndr_push_compression_mszip_cab_chunk(subndr, ndrpull, subndr->cstate));
break;
case NDR_COMPRESSION_MSZIP:
ZERO_STRUCT(z);
while (!last) {
NDR_CHECK(ndr_push_compression_mszip_chunk(subndr, ndrpull, &z, &last));
}
break;
case NDR_COMPRESSION_XPRESS:
while (!last) {
NDR_CHECK(ndr_push_compression_xpress_chunk(subndr, ndrpull, &last));
}
break;
case NDR_COMPRESSION_XPRESS_HUFF_RAW:
NDR_CHECK(ndr_push_compression_xpress_huff_raw_chunk(subndr, ndrpull, subndr->cstate));
break;
default:
return ndr_push_error(subndr, NDR_ERR_COMPRESSION, "Bad compression algorithm %d (PUSH)",
compression_alg);
}
talloc_free(uncomndr);
return NDR_ERR_SUCCESS;
}
static enum ndr_err_code generic_mszip_init(struct ndr_compression_state *state)
{
z_stream *z = talloc_zero(state, z_stream);
NDR_ERR_HAVE_NO_MEMORY(z);
z->zalloc = ndr_zlib_alloc;
z->zfree = ndr_zlib_free;
z->opaque = state;
state->alg.mszip.z = z;
state->alg.mszip.dict_size = 0;
/* pre-alloc dictionary */
state->alg.mszip.dict = talloc_array(state, uint8_t, 0x8000);
NDR_ERR_HAVE_NO_MEMORY(state->alg.mszip.dict);
return NDR_ERR_SUCCESS;
}
enum ndr_err_code ndr_pull_compression_state_init(struct ndr_pull *ndr,
enum ndr_compression_alg compression_alg,
struct ndr_compression_state **state)
{
struct ndr_compression_state *s;
int z_ret;
s = talloc_zero(ndr, struct ndr_compression_state);
NDR_ERR_HAVE_NO_MEMORY(s);
s->type = compression_alg;
switch (compression_alg) {
case NDR_COMPRESSION_NONE:
case NDR_COMPRESSION_MSZIP:
case NDR_COMPRESSION_XPRESS:
case NDR_COMPRESSION_XPRESS_HUFF_RAW:
break;
case NDR_COMPRESSION_MSZIP_CAB:
NDR_CHECK(generic_mszip_init(s));
z_ret = inflateInit2(s->alg.mszip.z, -MAX_WBITS);
if (z_ret != Z_OK) {
return ndr_pull_error(ndr, NDR_ERR_COMPRESSION,
"zlib inflateinit2 error %s (%d) %s (PULL)",
zError(z_ret), z_ret, s->alg.mszip.z->msg);
}
break;
default:
return ndr_pull_error(ndr, NDR_ERR_COMPRESSION,
"Bad compression algorithm %d (PULL)",
compression_alg);
break;
}
*state = s;
return NDR_ERR_SUCCESS;
}
enum ndr_err_code ndr_push_compression_state_init(struct ndr_push *ndr,
enum ndr_compression_alg compression_alg)
{
struct ndr_compression_state *s;
int z_ret;
/*
* Avoid confusion, NULL out ndr->cstate at the start of the
* compression block
*/
ndr->cstate = NULL;
s = talloc_zero(ndr, struct ndr_compression_state);
NDR_ERR_HAVE_NO_MEMORY(s);
s->type = compression_alg;
switch (compression_alg) {
case NDR_COMPRESSION_NONE:
case NDR_COMPRESSION_XPRESS:
break;
case NDR_COMPRESSION_XPRESS_HUFF_RAW:
s->alg.lzxpress_huffman.mem = talloc(s, struct lzxhuff_compressor_mem);
if (s->alg.lzxpress_huffman.mem == NULL) {
return NDR_ERR_ALLOC;
}
break;
case NDR_COMPRESSION_MSZIP:
break;
case NDR_COMPRESSION_MSZIP_CAB:
NDR_CHECK(generic_mszip_init(s));
z_ret = deflateInit2(s->alg.mszip.z,
Z_DEFAULT_COMPRESSION,
Z_DEFLATED,
-MAX_WBITS,
8, /* memLevel */
Z_DEFAULT_STRATEGY);
if (z_ret != Z_OK) {
return ndr_push_error(ndr, NDR_ERR_COMPRESSION,
"zlib inflateinit2 error %s (%d) %s (PUSH)",
zError(z_ret), z_ret, s->alg.mszip.z->msg);
}
break;
default:
return ndr_push_error(ndr, NDR_ERR_COMPRESSION,
"Bad compression algorithm %d (PUSH)",
compression_alg);
break;
}
ndr->cstate = s;
return NDR_ERR_SUCCESS;
}