#include "zipint.h"
#include <limits.h>
#include <lzma.h>
#include <stdlib.h>
#include <zlib.h>
enum header_state { INCOMPLETE, OUTPUT, DONE };
#define HEADER_BYTES_ZIP 9
#define HEADER_MAGIC_LENGTH 4
#define HEADER_MAGIC1_OFFSET 0
#define HEADER_MAGIC2_OFFSET 2
#define HEADER_SIZE_OFFSET 9
#define HEADER_SIZE_LENGTH 8
#define HEADER_PARAMETERS_LENGTH 5
#define HEADER_LZMA_ALONE_LENGTH (HEADER_PARAMETERS_LENGTH + HEADER_SIZE_LENGTH)
struct ctx {
zip_error_t *error;
bool compress;
zip_uint32_t compression_flags;
bool end_of_input;
lzma_stream zstr;
zip_uint16_t method;
zip_uint8_t header[HEADER_MAGIC_LENGTH + HEADER_LZMA_ALONE_LENGTH];
zip_uint8_t header_bytes_offset;
enum header_state header_state;
zip_uint64_t uncompresssed_size;
};
static zip_uint64_t
maximum_compressed_size(zip_uint64_t uncompressed_size) {
zip_uint64_t compressed_size = (zip_uint64_t)((double)uncompressed_size * 1.1) + 64 * 1024 + 13;
if (compressed_size < uncompressed_size) {
return ZIP_UINT64_MAX;
}
return compressed_size;
}
static void *
allocate(bool compress, zip_uint32_t compression_flags, zip_error_t *error, zip_uint16_t method) {
struct ctx *ctx;
if ((ctx = (struct ctx *)malloc(sizeof(*ctx))) == NULL) {
zip_error_set(error, ZIP_ER_MEMORY, 0);
return NULL;
}
ctx->error = error;
ctx->compress = compress;
if (compression_flags <= 9) {
ctx->compression_flags = compression_flags;
} else {
ctx->compression_flags = 6;
}
ctx->compression_flags |= LZMA_PRESET_EXTREME;
ctx->end_of_input = false;
memset(ctx->header, 0, sizeof(ctx->header));
ctx->header_bytes_offset = 0;
if (method == ZIP_CM_LZMA) {
ctx->header_state = INCOMPLETE;
}
else {
ctx->header_state = DONE;
}
memset(&ctx->zstr, 0, sizeof(ctx->zstr));
ctx->method = method;
return ctx;
}
static void *
compress_allocate(zip_uint16_t method, zip_uint32_t compression_flags, zip_error_t *error) {
return allocate(true, compression_flags, error, method);
}
static void *
decompress_allocate(zip_uint16_t method, zip_uint32_t compression_flags, zip_error_t *error) {
return allocate(false, compression_flags, error, method);
}
static void
deallocate(void *ud) {
struct ctx *ctx = (struct ctx *)ud;
free(ctx);
}
static zip_uint16_t
general_purpose_bit_flags(void *ud) {
struct ctx *ctx = (struct ctx *)ud;
if (!ctx->compress) {
return 0;
}
if (ctx->method == ZIP_CM_LZMA) {
return 1 << 1;
}
return 0;
}
static int
map_error(lzma_ret ret) {
switch (ret) {
case LZMA_DATA_ERROR:
case LZMA_UNSUPPORTED_CHECK:
return ZIP_ER_COMPRESSED_DATA;
case LZMA_MEM_ERROR:
return ZIP_ER_MEMORY;
case LZMA_OPTIONS_ERROR:
return ZIP_ER_INVAL;
default:
return ZIP_ER_INTERNAL;
}
}
static bool
start(void *ud, zip_stat_t *st, zip_file_attributes_t *attributes) {
struct ctx *ctx = (struct ctx *)ud;
lzma_ret ret;
lzma_options_lzma opt_lzma;
lzma_lzma_preset(&opt_lzma, ctx->compression_flags);
lzma_filter filters[] = {
{.id = (ctx->method == ZIP_CM_LZMA ? LZMA_FILTER_LZMA1 : LZMA_FILTER_LZMA2), .options = &opt_lzma},
{.id = LZMA_VLI_UNKNOWN, .options = NULL},
};
ctx->zstr.avail_in = 0;
ctx->zstr.next_in = NULL;
ctx->zstr.avail_out = 0;
ctx->zstr.next_out = NULL;
if (ctx->compress) {
if (ctx->method == ZIP_CM_LZMA)
ret = lzma_alone_encoder(&ctx->zstr, filters[0].options);
else
ret = lzma_stream_encoder(&ctx->zstr, filters, LZMA_CHECK_CRC64);
}
else {
if (ctx->method == ZIP_CM_LZMA)
ret = lzma_alone_decoder(&ctx->zstr, UINT64_MAX);
else
ret = lzma_stream_decoder(&ctx->zstr, UINT64_MAX, LZMA_CONCATENATED);
}
if (ret != LZMA_OK) {
zip_error_set(ctx->error, map_error(ret), 0);
return false;
}
if ((attributes->valid & ZIP_FILE_ATTRIBUTES_GENERAL_PURPOSE_BIT_FLAGS) && (attributes->general_purpose_bit_mask & 0x6) == 0x6 && (attributes->general_purpose_bit_flags & 0x06) == 0 && (st->valid & ZIP_STAT_SIZE)) {
ctx->uncompresssed_size = st->size;
}
else {
ctx->uncompresssed_size = ZIP_UINT64_MAX;
}
return true;
}
static bool
end(void *ud) {
struct ctx *ctx = (struct ctx *)ud;
lzma_end(&ctx->zstr);
return true;
}
static bool
input(void *ud, zip_uint8_t *data, zip_uint64_t length) {
struct ctx *ctx = (struct ctx *)ud;
if (length > UINT_MAX || ctx->zstr.avail_in > 0) {
zip_error_set(ctx->error, ZIP_ER_INVAL, 0);
return false;
}
if (ctx->method == ZIP_CM_LZMA && !ctx->compress && ctx->header_state == INCOMPLETE) {
zip_uint8_t got = (zip_uint8_t)ZIP_MIN(HEADER_BYTES_ZIP - ctx->header_bytes_offset, length);
(void)memcpy_s(ctx->header + ctx->header_bytes_offset, sizeof(ctx->header) - ctx->header_bytes_offset, data, got);
ctx->header_bytes_offset += got;
length -= got;
data += got;
if (ctx->header_bytes_offset == HEADER_BYTES_ZIP) {
Bytef empty_buffer[1];
zip_buffer_t *buffer;
if (ctx->header[HEADER_MAGIC2_OFFSET] != 0x05 || ctx->header[HEADER_MAGIC2_OFFSET + 1] != 0x00) {
zip_error_set(ctx->error, ZIP_ER_COMPRESSED_DATA, 0);
return false;
}
if ((buffer = _zip_buffer_new(ctx->header + HEADER_SIZE_OFFSET, HEADER_SIZE_LENGTH)) == NULL) {
zip_error_set(ctx->error, ZIP_ER_MEMORY, 0);
return false;
}
_zip_buffer_put_64(buffer, ctx->uncompresssed_size);
_zip_buffer_free(buffer);
ctx->zstr.next_in = (void *)(ctx->header + HEADER_MAGIC_LENGTH);
ctx->zstr.avail_in = HEADER_LZMA_ALONE_LENGTH;
ctx->zstr.total_in = 0;
ctx->zstr.next_out = empty_buffer;
ctx->zstr.avail_out = sizeof(*empty_buffer);
ctx->zstr.total_out = 0;
if (lzma_code(&ctx->zstr, LZMA_RUN) != LZMA_OK || ctx->zstr.total_out > 0) {
zip_error_set(ctx->error, ZIP_ER_COMPRESSED_DATA, 0);
return false;
}
ctx->header_state = DONE;
}
}
ctx->zstr.avail_in = (uInt)length;
ctx->zstr.next_in = (Bytef *)data;
return true;
}
static bool end_of_input(void *ud) {
struct ctx *ctx = (struct ctx *)ud;
ctx->end_of_input = true;
return ctx->zstr.avail_in != 0;
}
static zip_compression_status_t
process(void *ud, zip_uint8_t *data, zip_uint64_t *length) {
struct ctx *ctx = (struct ctx *)ud;
uInt avail_out;
lzma_ret ret;
if (ctx->method == ZIP_CM_LZMA && ctx->compress) {
if (ctx->header_state == INCOMPLETE) {
ctx->header[0] = 0x09;
ctx->header[1] = 0x14;
ctx->header[2] = 0x05;
ctx->header[3] = 0x00;
ctx->zstr.avail_out = HEADER_LZMA_ALONE_LENGTH;
ctx->zstr.next_out = ctx->header + HEADER_MAGIC_LENGTH;
ret = lzma_code(&ctx->zstr, LZMA_RUN);
if (ret != LZMA_OK || ctx->zstr.avail_out != 0) {
return ZIP_COMPRESSION_ERROR;
}
ctx->header_state = OUTPUT;
}
if (ctx->header_state == OUTPUT) {
zip_uint8_t write_len = (zip_uint8_t)ZIP_MIN(HEADER_BYTES_ZIP - ctx->header_bytes_offset, *length);
(void)memcpy_s(data, *length, ctx->header + ctx->header_bytes_offset, write_len);
ctx->header_bytes_offset += write_len;
*length = write_len;
if (ctx->header_bytes_offset == HEADER_BYTES_ZIP) {
ctx->header_state = DONE;
}
return ZIP_COMPRESSION_OK;
}
}
avail_out = (uInt)ZIP_MIN(UINT_MAX, *length);
ctx->zstr.avail_out = avail_out;
ctx->zstr.next_out = (Bytef *)data;
ret = lzma_code(&ctx->zstr, ctx->end_of_input ? LZMA_FINISH : LZMA_RUN);
*length = avail_out - ctx->zstr.avail_out;
switch (ret) {
case LZMA_OK:
return ZIP_COMPRESSION_OK;
case LZMA_STREAM_END:
return ZIP_COMPRESSION_END;
case LZMA_BUF_ERROR:
if (ctx->zstr.avail_in == 0) {
return ZIP_COMPRESSION_NEED_DATA;
}
default:
zip_error_set(ctx->error, map_error(ret), 0);
return ZIP_COMPRESSION_ERROR;
}
}
zip_compression_algorithm_t zip_algorithm_xz_compress = {
maximum_compressed_size,
compress_allocate,
deallocate,
general_purpose_bit_flags,
20,
start,
end,
input,
end_of_input,
process
};
zip_compression_algorithm_t zip_algorithm_xz_decompress = {
maximum_compressed_size,
decompress_allocate,
deallocate,
general_purpose_bit_flags,
20,
start,
end,
input,
end_of_input,
process
};