Distributed under MIT license.
See file LICENSE for detail or copy at https://opensource.org/licenses/MIT
*/
#include <brotli/decode.h>
#include <stdlib.h>
#include <string.h>
#include "../common/constants.h"
#include "../common/context.h"
#include "../common/dictionary.h"
#include "../common/platform.h"
#include "../common/shared_dictionary_internal.h"
#include "../common/transform.h"
#include "../common/version.h"
#include "bit_reader.h"
#include "huffman.h"
#include "prefix.h"
#include "state.h"
#if defined(BROTLI_TARGET_NEON)
#include <arm_neon.h>
#endif
#if defined(__cplusplus) || defined(c_plusplus)
extern "C" {
#endif
#define BROTLI_FAILURE(CODE) (BROTLI_DUMP(), CODE)
#define BROTLI_LOG_UINT(name) \
BROTLI_LOG(("[%s] %s = %lu\n", __func__, #name, (unsigned long)(name)))
#define BROTLI_LOG_ARRAY_INDEX(array_name, idx) \
BROTLI_LOG(("[%s] %s[%lu] = %lu\n", __func__, #array_name, \
(unsigned long)(idx), (unsigned long)array_name[idx]))
#define HUFFMAN_TABLE_BITS 8U
#define HUFFMAN_TABLE_MASK 0xFF
- doing up to two 16-byte copies for fast backward copying
- inserting transformed dictionary word:
255 prefix + 32 base + 255 suffix */
static const uint32_t kRingBufferWriteAheadSlack = 542;
static const uint8_t kCodeLengthCodeOrder[BROTLI_CODE_LENGTH_CODES] = {
1, 2, 3, 4, 0, 5, 17, 6, 16, 7, 8, 9, 10, 11, 12, 13, 14, 15,
};
static const uint8_t kCodeLengthPrefixLength[16] = {
2, 2, 2, 3, 2, 2, 2, 4, 2, 2, 2, 3, 2, 2, 2, 4,
};
static const uint8_t kCodeLengthPrefixValue[16] = {
0, 4, 3, 2, 0, 4, 3, 1, 0, 4, 3, 2, 0, 4, 3, 5,
};
BROTLI_BOOL BrotliDecoderSetParameter(
BrotliDecoderState* state, BrotliDecoderParameter p, uint32_t value) {
if (state->state != BROTLI_STATE_UNINITED) return BROTLI_FALSE;
switch (p) {
case BROTLI_DECODER_PARAM_DISABLE_RING_BUFFER_REALLOCATION:
state->canny_ringbuffer_allocation = !!value ? 0 : 1;
return BROTLI_TRUE;
case BROTLI_DECODER_PARAM_LARGE_WINDOW:
state->large_window = TO_BROTLI_BOOL(!!value);
return BROTLI_TRUE;
default: return BROTLI_FALSE;
}
}
BrotliDecoderState* BrotliDecoderCreateInstance(
brotli_alloc_func alloc_func, brotli_free_func free_func, void* opaque) {
BrotliDecoderState* state = 0;
if (!alloc_func && !free_func) {
state = (BrotliDecoderState*)malloc(sizeof(BrotliDecoderState));
} else if (alloc_func && free_func) {
state = (BrotliDecoderState*)alloc_func(opaque, sizeof(BrotliDecoderState));
}
if (state == 0) {
BROTLI_DUMP();
return 0;
}
if (!BrotliDecoderStateInit(state, alloc_func, free_func, opaque)) {
BROTLI_DUMP();
if (!alloc_func && !free_func) {
free(state);
} else if (alloc_func && free_func) {
free_func(opaque, state);
}
return 0;
}
return state;
}
void BrotliDecoderDestroyInstance(BrotliDecoderState* state) {
if (!state) {
return;
} else {
brotli_free_func free_func = state->free_func;
void* opaque = state->memory_manager_opaque;
BrotliDecoderStateCleanup(state);
free_func(opaque, state);
}
}
static BROTLI_NOINLINE BrotliDecoderResult SaveErrorCode(
BrotliDecoderState* s, BrotliDecoderErrorCode e) {
s->error_code = (int)e;
switch (e) {
case BROTLI_DECODER_SUCCESS:
return BROTLI_DECODER_RESULT_SUCCESS;
case BROTLI_DECODER_NEEDS_MORE_INPUT:
return BROTLI_DECODER_RESULT_NEEDS_MORE_INPUT;
case BROTLI_DECODER_NEEDS_MORE_OUTPUT:
return BROTLI_DECODER_RESULT_NEEDS_MORE_OUTPUT;
default:
return BROTLI_DECODER_RESULT_ERROR;
}
}
Precondition: bit-reader accumulator has at least 8 bits. */
static BrotliDecoderErrorCode DecodeWindowBits(BrotliDecoderState* s,
BrotliBitReader* br) {
uint32_t n;
BROTLI_BOOL large_window = s->large_window;
s->large_window = BROTLI_FALSE;
BrotliTakeBits(br, 1, &n);
if (n == 0) {
s->window_bits = 16;
return BROTLI_DECODER_SUCCESS;
}
BrotliTakeBits(br, 3, &n);
if (n != 0) {
s->window_bits = 17 + n;
return BROTLI_DECODER_SUCCESS;
}
BrotliTakeBits(br, 3, &n);
if (n == 1) {
if (large_window) {
BrotliTakeBits(br, 1, &n);
if (n == 1) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_WINDOW_BITS);
}
s->large_window = BROTLI_TRUE;
return BROTLI_DECODER_SUCCESS;
} else {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_WINDOW_BITS);
}
}
if (n != 0) {
s->window_bits = 8 + n;
return BROTLI_DECODER_SUCCESS;
}
s->window_bits = 17;
return BROTLI_DECODER_SUCCESS;
}
static BROTLI_INLINE void memmove16(uint8_t* dst, uint8_t* src) {
#if defined(BROTLI_TARGET_NEON)
vst1q_u8(dst, vld1q_u8(src));
#else
uint32_t buffer[4];
memcpy(buffer, src, 16);
memcpy(dst, buffer, 16);
#endif
}
static BROTLI_NOINLINE BrotliDecoderErrorCode DecodeVarLenUint8(
BrotliDecoderState* s, BrotliBitReader* br, uint32_t* value) {
uint32_t bits;
switch (s->substate_decode_uint8) {
case BROTLI_STATE_DECODE_UINT8_NONE:
if (BROTLI_PREDICT_FALSE(!BrotliSafeReadBits(br, 1, &bits))) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (bits == 0) {
*value = 0;
return BROTLI_DECODER_SUCCESS;
}
case BROTLI_STATE_DECODE_UINT8_SHORT:
if (BROTLI_PREDICT_FALSE(!BrotliSafeReadBits(br, 3, &bits))) {
s->substate_decode_uint8 = BROTLI_STATE_DECODE_UINT8_SHORT;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (bits == 0) {
*value = 1;
s->substate_decode_uint8 = BROTLI_STATE_DECODE_UINT8_NONE;
return BROTLI_DECODER_SUCCESS;
}
*value = bits;
case BROTLI_STATE_DECODE_UINT8_LONG:
if (BROTLI_PREDICT_FALSE(!BrotliSafeReadBits(br, *value, &bits))) {
s->substate_decode_uint8 = BROTLI_STATE_DECODE_UINT8_LONG;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
*value = (1U << *value) + bits;
s->substate_decode_uint8 = BROTLI_STATE_DECODE_UINT8_NONE;
return BROTLI_DECODER_SUCCESS;
default:
return
BROTLI_FAILURE(BROTLI_DECODER_ERROR_UNREACHABLE);
}
}
static BrotliDecoderErrorCode BROTLI_NOINLINE DecodeMetaBlockLength(
BrotliDecoderState* s, BrotliBitReader* br) {
uint32_t bits;
int i;
for (;;) {
switch (s->substate_metablock_header) {
case BROTLI_STATE_METABLOCK_HEADER_NONE:
if (!BrotliSafeReadBits(br, 1, &bits)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
s->is_last_metablock = bits ? 1 : 0;
s->meta_block_remaining_len = 0;
s->is_uncompressed = 0;
s->is_metadata = 0;
if (!s->is_last_metablock) {
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_NIBBLES;
break;
}
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_EMPTY;
case BROTLI_STATE_METABLOCK_HEADER_EMPTY:
if (!BrotliSafeReadBits(br, 1, &bits)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (bits) {
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_NONE;
return BROTLI_DECODER_SUCCESS;
}
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_NIBBLES;
case BROTLI_STATE_METABLOCK_HEADER_NIBBLES:
if (!BrotliSafeReadBits(br, 2, &bits)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
s->size_nibbles = (uint8_t)(bits + 4);
s->loop_counter = 0;
if (bits == 3) {
s->is_metadata = 1;
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_RESERVED;
break;
}
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_SIZE;
case BROTLI_STATE_METABLOCK_HEADER_SIZE:
i = s->loop_counter;
for (; i < (int)s->size_nibbles; ++i) {
if (!BrotliSafeReadBits(br, 4, &bits)) {
s->loop_counter = i;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (i + 1 == (int)s->size_nibbles && s->size_nibbles > 4 &&
bits == 0) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_EXUBERANT_NIBBLE);
}
s->meta_block_remaining_len |= (int)(bits << (i * 4));
}
s->substate_metablock_header =
BROTLI_STATE_METABLOCK_HEADER_UNCOMPRESSED;
case BROTLI_STATE_METABLOCK_HEADER_UNCOMPRESSED:
if (!s->is_last_metablock) {
if (!BrotliSafeReadBits(br, 1, &bits)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
s->is_uncompressed = bits ? 1 : 0;
}
++s->meta_block_remaining_len;
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_NONE;
return BROTLI_DECODER_SUCCESS;
case BROTLI_STATE_METABLOCK_HEADER_RESERVED:
if (!BrotliSafeReadBits(br, 1, &bits)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (bits != 0) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_RESERVED);
}
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_BYTES;
case BROTLI_STATE_METABLOCK_HEADER_BYTES:
if (!BrotliSafeReadBits(br, 2, &bits)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (bits == 0) {
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_NONE;
return BROTLI_DECODER_SUCCESS;
}
s->size_nibbles = (uint8_t)bits;
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_METADATA;
case BROTLI_STATE_METABLOCK_HEADER_METADATA:
i = s->loop_counter;
for (; i < (int)s->size_nibbles; ++i) {
if (!BrotliSafeReadBits(br, 8, &bits)) {
s->loop_counter = i;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (i + 1 == (int)s->size_nibbles && s->size_nibbles > 1 &&
bits == 0) {
return BROTLI_FAILURE(
BROTLI_DECODER_ERROR_FORMAT_EXUBERANT_META_NIBBLE);
}
s->meta_block_remaining_len |= (int)(bits << (i * 8));
}
++s->meta_block_remaining_len;
s->substate_metablock_header = BROTLI_STATE_METABLOCK_HEADER_NONE;
return BROTLI_DECODER_SUCCESS;
default:
return
BROTLI_FAILURE(BROTLI_DECODER_ERROR_UNREACHABLE);
}
}
}
This method doesn't read data from the bit reader, BUT drops the amount of
bits that correspond to the decoded symbol.
bits MUST contain at least 15 (BROTLI_HUFFMAN_MAX_CODE_LENGTH) valid bits. */
static BROTLI_INLINE uint32_t DecodeSymbol(uint32_t bits,
const HuffmanCode* table,
BrotliBitReader* br) {
BROTLI_HC_MARK_TABLE_FOR_FAST_LOAD(table);
BROTLI_HC_ADJUST_TABLE_INDEX(table, bits & HUFFMAN_TABLE_MASK);
if (BROTLI_HC_FAST_LOAD_BITS(table) > HUFFMAN_TABLE_BITS) {
uint32_t nbits = BROTLI_HC_FAST_LOAD_BITS(table) - HUFFMAN_TABLE_BITS;
BrotliDropBits(br, HUFFMAN_TABLE_BITS);
BROTLI_HC_ADJUST_TABLE_INDEX(table,
BROTLI_HC_FAST_LOAD_VALUE(table) +
((bits >> HUFFMAN_TABLE_BITS) & BitMask(nbits)));
}
BrotliDropBits(br, BROTLI_HC_FAST_LOAD_BITS(table));
return BROTLI_HC_FAST_LOAD_VALUE(table);
}
This method peeks 16 bits of input and drops 0 - 15 of them. */
static BROTLI_INLINE uint32_t ReadSymbol(const HuffmanCode* table,
BrotliBitReader* br) {
return DecodeSymbol(BrotliGet16BitsUnmasked(br), table, br);
}
input are currently available. */
static BROTLI_NOINLINE BROTLI_BOOL SafeDecodeSymbol(
const HuffmanCode* table, BrotliBitReader* br, uint32_t* result) {
uint32_t val;
uint32_t available_bits = BrotliGetAvailableBits(br);
BROTLI_HC_MARK_TABLE_FOR_FAST_LOAD(table);
if (available_bits == 0) {
if (BROTLI_HC_FAST_LOAD_BITS(table) == 0) {
*result = BROTLI_HC_FAST_LOAD_VALUE(table);
return BROTLI_TRUE;
}
return BROTLI_FALSE;
}
val = (uint32_t)BrotliGetBitsUnmasked(br);
BROTLI_HC_ADJUST_TABLE_INDEX(table, val & HUFFMAN_TABLE_MASK);
if (BROTLI_HC_FAST_LOAD_BITS(table) <= HUFFMAN_TABLE_BITS) {
if (BROTLI_HC_FAST_LOAD_BITS(table) <= available_bits) {
BrotliDropBits(br, BROTLI_HC_FAST_LOAD_BITS(table));
*result = BROTLI_HC_FAST_LOAD_VALUE(table);
return BROTLI_TRUE;
} else {
return BROTLI_FALSE;
}
}
if (available_bits <= HUFFMAN_TABLE_BITS) {
return BROTLI_FALSE;
}
val = (val & BitMask(BROTLI_HC_FAST_LOAD_BITS(table))) >> HUFFMAN_TABLE_BITS;
available_bits -= HUFFMAN_TABLE_BITS;
BROTLI_HC_ADJUST_TABLE_INDEX(table, BROTLI_HC_FAST_LOAD_VALUE(table) + val);
if (available_bits < BROTLI_HC_FAST_LOAD_BITS(table)) {
return BROTLI_FALSE;
}
BrotliDropBits(br, HUFFMAN_TABLE_BITS + BROTLI_HC_FAST_LOAD_BITS(table));
*result = BROTLI_HC_FAST_LOAD_VALUE(table);
return BROTLI_TRUE;
}
static BROTLI_INLINE BROTLI_BOOL SafeReadSymbol(
const HuffmanCode* table, BrotliBitReader* br, uint32_t* result) {
uint32_t val;
if (BROTLI_PREDICT_TRUE(BrotliSafeGetBits(br, 15, &val))) {
*result = DecodeSymbol(val, table, br);
return BROTLI_TRUE;
}
return SafeDecodeSymbol(table, br, result);
}
static BROTLI_INLINE void PreloadSymbol(int safe,
const HuffmanCode* table,
BrotliBitReader* br,
uint32_t* bits,
uint32_t* value) {
if (safe) {
return;
}
BROTLI_HC_MARK_TABLE_FOR_FAST_LOAD(table);
BROTLI_HC_ADJUST_TABLE_INDEX(table, BrotliGetBits(br, HUFFMAN_TABLE_BITS));
*bits = BROTLI_HC_FAST_LOAD_BITS(table);
*value = BROTLI_HC_FAST_LOAD_VALUE(table);
}
Reads 0 - 15 bits. Also peeks 8 following bits. */
static BROTLI_INLINE uint32_t ReadPreloadedSymbol(const HuffmanCode* table,
BrotliBitReader* br,
uint32_t* bits,
uint32_t* value) {
uint32_t result = *value;
if (BROTLI_PREDICT_FALSE(*bits > HUFFMAN_TABLE_BITS)) {
uint32_t val = BrotliGet16BitsUnmasked(br);
const HuffmanCode* ext = table + (val & HUFFMAN_TABLE_MASK) + *value;
uint32_t mask = BitMask((*bits - HUFFMAN_TABLE_BITS));
BROTLI_HC_MARK_TABLE_FOR_FAST_LOAD(ext);
BrotliDropBits(br, HUFFMAN_TABLE_BITS);
BROTLI_HC_ADJUST_TABLE_INDEX(ext, (val >> HUFFMAN_TABLE_BITS) & mask);
BrotliDropBits(br, BROTLI_HC_FAST_LOAD_BITS(ext));
result = BROTLI_HC_FAST_LOAD_VALUE(ext);
} else {
BrotliDropBits(br, *bits);
}
PreloadSymbol(0, table, br, bits, value);
return result;
}
static BROTLI_INLINE uint32_t Log2Floor(uint32_t x) {
uint32_t result = 0;
while (x) {
x >>= 1;
++result;
}
return result;
}
Totally 1..4 symbols are read, 1..11 bits each.
The list of symbols MUST NOT contain duplicates. */
static BrotliDecoderErrorCode ReadSimpleHuffmanSymbols(
uint32_t alphabet_size_max, uint32_t alphabet_size_limit,
BrotliDecoderState* s) {
BrotliBitReader* br = &s->br;
BrotliMetablockHeaderArena* h = &s->arena.header;
uint32_t max_bits = Log2Floor(alphabet_size_max - 1);
uint32_t i = h->sub_loop_counter;
uint32_t num_symbols = h->symbol;
while (i <= num_symbols) {
uint32_t v;
if (BROTLI_PREDICT_FALSE(!BrotliSafeReadBits(br, max_bits, &v))) {
h->sub_loop_counter = i;
h->substate_huffman = BROTLI_STATE_HUFFMAN_SIMPLE_READ;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (v >= alphabet_size_limit) {
return
BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_SIMPLE_HUFFMAN_ALPHABET);
}
h->symbols_lists_array[i] = (uint16_t)v;
BROTLI_LOG_UINT(h->symbols_lists_array[i]);
++i;
}
for (i = 0; i < num_symbols; ++i) {
uint32_t k = i + 1;
for (; k <= num_symbols; ++k) {
if (h->symbols_lists_array[i] == h->symbols_lists_array[k]) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_SIMPLE_HUFFMAN_SAME);
}
}
}
return BROTLI_DECODER_SUCCESS;
}
A) reset the repeat variable
B) remember code length (if it is not 0)
C) extend corresponding index-chain
D) reduce the Huffman space
E) update the histogram */
static BROTLI_INLINE void ProcessSingleCodeLength(uint32_t code_len,
uint32_t* symbol, uint32_t* repeat, uint32_t* space,
uint32_t* prev_code_len, uint16_t* symbol_lists,
uint16_t* code_length_histo, int* next_symbol) {
*repeat = 0;
if (code_len != 0) {
symbol_lists[next_symbol[code_len]] = (uint16_t)(*symbol);
next_symbol[code_len] = (int)(*symbol);
*prev_code_len = code_len;
*space -= 32768U >> code_len;
code_length_histo[code_len]++;
BROTLI_LOG(("[ReadHuffmanCode] code_length[%d] = %d\n",
(int)*symbol, (int)code_len));
}
(*symbol)++;
}
A) Check if it is the extension of previous repeat sequence; if the decoded
value is not BROTLI_REPEAT_PREVIOUS_CODE_LENGTH, then it is a new
symbol-skip
B) Update repeat variable
C) Check if operation is feasible (fits alphabet)
D) For each symbol do the same operations as in ProcessSingleCodeLength
PRECONDITION: code_len == BROTLI_REPEAT_PREVIOUS_CODE_LENGTH or
code_len == BROTLI_REPEAT_ZERO_CODE_LENGTH */
static BROTLI_INLINE void ProcessRepeatedCodeLength(uint32_t code_len,
uint32_t repeat_delta, uint32_t alphabet_size, uint32_t* symbol,
uint32_t* repeat, uint32_t* space, uint32_t* prev_code_len,
uint32_t* repeat_code_len, uint16_t* symbol_lists,
uint16_t* code_length_histo, int* next_symbol) {
uint32_t old_repeat;
uint32_t extra_bits = 3;
uint32_t new_len = 0;
if (code_len == BROTLI_REPEAT_PREVIOUS_CODE_LENGTH) {
new_len = *prev_code_len;
extra_bits = 2;
}
if (*repeat_code_len != new_len) {
*repeat = 0;
*repeat_code_len = new_len;
}
old_repeat = *repeat;
if (*repeat > 0) {
*repeat -= 2;
*repeat <<= extra_bits;
}
*repeat += repeat_delta + 3U;
repeat_delta = *repeat - old_repeat;
if (*symbol + repeat_delta > alphabet_size) {
BROTLI_DUMP();
*symbol = alphabet_size;
*space = 0xFFFFF;
return;
}
BROTLI_LOG(("[ReadHuffmanCode] code_length[%d..%d] = %d\n",
(int)*symbol, (int)(*symbol + repeat_delta - 1), (int)*repeat_code_len));
if (*repeat_code_len != 0) {
unsigned last = *symbol + repeat_delta;
int next = next_symbol[*repeat_code_len];
do {
symbol_lists[next] = (uint16_t)*symbol;
next = (int)*symbol;
} while (++(*symbol) != last);
next_symbol[*repeat_code_len] = next;
*space -= repeat_delta << (15 - *repeat_code_len);
code_length_histo[*repeat_code_len] =
(uint16_t)(code_length_histo[*repeat_code_len] + repeat_delta);
} else {
*symbol += repeat_delta;
}
}
static BrotliDecoderErrorCode ReadSymbolCodeLengths(
uint32_t alphabet_size, BrotliDecoderState* s) {
BrotliBitReader* br = &s->br;
BrotliMetablockHeaderArena* h = &s->arena.header;
uint32_t symbol = h->symbol;
uint32_t repeat = h->repeat;
uint32_t space = h->space;
uint32_t prev_code_len = h->prev_code_len;
uint32_t repeat_code_len = h->repeat_code_len;
uint16_t* symbol_lists = h->symbol_lists;
uint16_t* code_length_histo = h->code_length_histo;
int* next_symbol = h->next_symbol;
if (!BrotliWarmupBitReader(br)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
while (symbol < alphabet_size && space > 0) {
const HuffmanCode* p = h->table;
uint32_t code_len;
BROTLI_HC_MARK_TABLE_FOR_FAST_LOAD(p);
if (!BrotliCheckInputAmount(br, BROTLI_SHORT_FILL_BIT_WINDOW_READ)) {
h->symbol = symbol;
h->repeat = repeat;
h->prev_code_len = prev_code_len;
h->repeat_code_len = repeat_code_len;
h->space = space;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
BrotliFillBitWindow16(br);
BROTLI_HC_ADJUST_TABLE_INDEX(p, BrotliGetBitsUnmasked(br) &
BitMask(BROTLI_HUFFMAN_MAX_CODE_LENGTH_CODE_LENGTH));
BrotliDropBits(br, BROTLI_HC_FAST_LOAD_BITS(p));
code_len = BROTLI_HC_FAST_LOAD_VALUE(p);
if (code_len < BROTLI_REPEAT_PREVIOUS_CODE_LENGTH) {
ProcessSingleCodeLength(code_len, &symbol, &repeat, &space,
&prev_code_len, symbol_lists, code_length_histo, next_symbol);
} else {
uint32_t extra_bits =
(code_len == BROTLI_REPEAT_PREVIOUS_CODE_LENGTH) ? 2 : 3;
uint32_t repeat_delta =
(uint32_t)BrotliGetBitsUnmasked(br) & BitMask(extra_bits);
BrotliDropBits(br, extra_bits);
ProcessRepeatedCodeLength(code_len, repeat_delta, alphabet_size,
&symbol, &repeat, &space, &prev_code_len, &repeat_code_len,
symbol_lists, code_length_histo, next_symbol);
}
}
h->space = space;
return BROTLI_DECODER_SUCCESS;
}
static BrotliDecoderErrorCode SafeReadSymbolCodeLengths(
uint32_t alphabet_size, BrotliDecoderState* s) {
BrotliBitReader* br = &s->br;
BrotliMetablockHeaderArena* h = &s->arena.header;
BROTLI_BOOL get_byte = BROTLI_FALSE;
while (h->symbol < alphabet_size && h->space > 0) {
const HuffmanCode* p = h->table;
uint32_t code_len;
uint32_t available_bits;
uint32_t bits = 0;
BROTLI_HC_MARK_TABLE_FOR_FAST_LOAD(p);
if (get_byte && !BrotliPullByte(br)) return BROTLI_DECODER_NEEDS_MORE_INPUT;
get_byte = BROTLI_FALSE;
available_bits = BrotliGetAvailableBits(br);
if (available_bits != 0) {
bits = (uint32_t)BrotliGetBitsUnmasked(br);
}
BROTLI_HC_ADJUST_TABLE_INDEX(p,
bits & BitMask(BROTLI_HUFFMAN_MAX_CODE_LENGTH_CODE_LENGTH));
if (BROTLI_HC_FAST_LOAD_BITS(p) > available_bits) {
get_byte = BROTLI_TRUE;
continue;
}
code_len = BROTLI_HC_FAST_LOAD_VALUE(p);
if (code_len < BROTLI_REPEAT_PREVIOUS_CODE_LENGTH) {
BrotliDropBits(br, BROTLI_HC_FAST_LOAD_BITS(p));
ProcessSingleCodeLength(code_len, &h->symbol, &h->repeat, &h->space,
&h->prev_code_len, h->symbol_lists, h->code_length_histo,
h->next_symbol);
} else {
uint32_t extra_bits = code_len - 14U;
uint32_t repeat_delta = (bits >> BROTLI_HC_FAST_LOAD_BITS(p)) &
BitMask(extra_bits);
if (available_bits < BROTLI_HC_FAST_LOAD_BITS(p) + extra_bits) {
get_byte = BROTLI_TRUE;
continue;
}
BrotliDropBits(br, BROTLI_HC_FAST_LOAD_BITS(p) + extra_bits);
ProcessRepeatedCodeLength(code_len, repeat_delta, alphabet_size,
&h->symbol, &h->repeat, &h->space, &h->prev_code_len,
&h->repeat_code_len, h->symbol_lists, h->code_length_histo,
h->next_symbol);
}
}
return BROTLI_DECODER_SUCCESS;
}
Each code is 2..4 bits long. In total 30..72 bits are used. */
static BrotliDecoderErrorCode ReadCodeLengthCodeLengths(BrotliDecoderState* s) {
BrotliBitReader* br = &s->br;
BrotliMetablockHeaderArena* h = &s->arena.header;
uint32_t num_codes = h->repeat;
unsigned space = h->space;
uint32_t i = h->sub_loop_counter;
for (; i < BROTLI_CODE_LENGTH_CODES; ++i) {
const uint8_t code_len_idx = kCodeLengthCodeOrder[i];
uint32_t ix;
uint32_t v;
if (BROTLI_PREDICT_FALSE(!BrotliSafeGetBits(br, 4, &ix))) {
uint32_t available_bits = BrotliGetAvailableBits(br);
if (available_bits != 0) {
ix = BrotliGetBitsUnmasked(br) & 0xF;
} else {
ix = 0;
}
if (kCodeLengthPrefixLength[ix] > available_bits) {
h->sub_loop_counter = i;
h->repeat = num_codes;
h->space = space;
h->substate_huffman = BROTLI_STATE_HUFFMAN_COMPLEX;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
}
v = kCodeLengthPrefixValue[ix];
BrotliDropBits(br, kCodeLengthPrefixLength[ix]);
h->code_length_code_lengths[code_len_idx] = (uint8_t)v;
BROTLI_LOG_ARRAY_INDEX(h->code_length_code_lengths, code_len_idx);
if (v != 0) {
space = space - (32U >> v);
++num_codes;
++h->code_length_histo[v];
if (space - 1U >= 32U) {
break;
}
}
}
if (!(num_codes == 1 || space == 0)) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_CL_SPACE);
}
return BROTLI_DECODER_SUCCESS;
}
There are 2 scenarios:
A) Huffman code contains only few symbols (1..4). Those symbols are read
directly; their code lengths are defined by the number of symbols.
For this scenario 4 - 49 bits will be read.
B) 2-phase decoding:
B.1) Small Huffman table is decoded; it is specified with code lengths
encoded with predefined entropy code. 32 - 74 bits are used.
B.2) Decoded table is used to decode code lengths of symbols in resulting
Huffman table. In worst case 3520 bits are read. */
static BrotliDecoderErrorCode ReadHuffmanCode(uint32_t alphabet_size_max,
uint32_t alphabet_size_limit,
HuffmanCode* table,
uint32_t* opt_table_size,
BrotliDecoderState* s) {
BrotliBitReader* br = &s->br;
BrotliMetablockHeaderArena* h = &s->arena.header;
for (;;) {
switch (h->substate_huffman) {
case BROTLI_STATE_HUFFMAN_NONE:
if (!BrotliSafeReadBits(br, 2, &h->sub_loop_counter)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
BROTLI_LOG_UINT(h->sub_loop_counter);
1 for simple code;
0 for no skipping, 2 skips 2 code lengths, 3 skips 3 code lengths */
if (h->sub_loop_counter != 1) {
h->space = 32;
h->repeat = 0;
memset(&h->code_length_histo[0], 0, sizeof(h->code_length_histo[0]) *
(BROTLI_HUFFMAN_MAX_CODE_LENGTH_CODE_LENGTH + 1));
memset(&h->code_length_code_lengths[0], 0,
sizeof(h->code_length_code_lengths));
h->substate_huffman = BROTLI_STATE_HUFFMAN_COMPLEX;
continue;
}
case BROTLI_STATE_HUFFMAN_SIMPLE_SIZE:
if (!BrotliSafeReadBits(br, 2, &h->symbol)) {
h->substate_huffman = BROTLI_STATE_HUFFMAN_SIMPLE_SIZE;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
h->sub_loop_counter = 0;
case BROTLI_STATE_HUFFMAN_SIMPLE_READ: {
BrotliDecoderErrorCode result =
ReadSimpleHuffmanSymbols(alphabet_size_max, alphabet_size_limit, s);
if (result != BROTLI_DECODER_SUCCESS) {
return result;
}
}
case BROTLI_STATE_HUFFMAN_SIMPLE_BUILD: {
uint32_t table_size;
if (h->symbol == 3) {
uint32_t bits;
if (!BrotliSafeReadBits(br, 1, &bits)) {
h->substate_huffman = BROTLI_STATE_HUFFMAN_SIMPLE_BUILD;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
h->symbol += bits;
}
BROTLI_LOG_UINT(h->symbol);
table_size = BrotliBuildSimpleHuffmanTable(
table, HUFFMAN_TABLE_BITS, h->symbols_lists_array, h->symbol);
if (opt_table_size) {
*opt_table_size = table_size;
}
h->substate_huffman = BROTLI_STATE_HUFFMAN_NONE;
return BROTLI_DECODER_SUCCESS;
}
case BROTLI_STATE_HUFFMAN_COMPLEX: {
uint32_t i;
BrotliDecoderErrorCode result = ReadCodeLengthCodeLengths(s);
if (result != BROTLI_DECODER_SUCCESS) {
return result;
}
BrotliBuildCodeLengthsHuffmanTable(h->table,
h->code_length_code_lengths,
h->code_length_histo);
memset(&h->code_length_histo[0], 0, sizeof(h->code_length_histo));
for (i = 0; i <= BROTLI_HUFFMAN_MAX_CODE_LENGTH; ++i) {
h->next_symbol[i] = (int)i - (BROTLI_HUFFMAN_MAX_CODE_LENGTH + 1);
h->symbol_lists[h->next_symbol[i]] = 0xFFFF;
}
h->symbol = 0;
h->prev_code_len = BROTLI_INITIAL_REPEATED_CODE_LENGTH;
h->repeat = 0;
h->repeat_code_len = 0;
h->space = 32768;
h->substate_huffman = BROTLI_STATE_HUFFMAN_LENGTH_SYMBOLS;
}
case BROTLI_STATE_HUFFMAN_LENGTH_SYMBOLS: {
uint32_t table_size;
BrotliDecoderErrorCode result = ReadSymbolCodeLengths(
alphabet_size_limit, s);
if (result == BROTLI_DECODER_NEEDS_MORE_INPUT) {
result = SafeReadSymbolCodeLengths(alphabet_size_limit, s);
}
if (result != BROTLI_DECODER_SUCCESS) {
return result;
}
if (h->space != 0) {
BROTLI_LOG(("[ReadHuffmanCode] space = %d\n", (int)h->space));
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_HUFFMAN_SPACE);
}
table_size = BrotliBuildHuffmanTable(
table, HUFFMAN_TABLE_BITS, h->symbol_lists, h->code_length_histo);
if (opt_table_size) {
*opt_table_size = table_size;
}
h->substate_huffman = BROTLI_STATE_HUFFMAN_NONE;
return BROTLI_DECODER_SUCCESS;
}
default:
return
BROTLI_FAILURE(BROTLI_DECODER_ERROR_UNREACHABLE);
}
}
}
static BROTLI_INLINE uint32_t ReadBlockLength(const HuffmanCode* table,
BrotliBitReader* br) {
uint32_t code;
uint32_t nbits;
code = ReadSymbol(table, br);
nbits = _kBrotliPrefixCodeRanges[code].nbits;
return _kBrotliPrefixCodeRanges[code].offset + BrotliReadBits24(br, nbits);
}
reading can't be continued with ReadBlockLength. */
static BROTLI_INLINE BROTLI_BOOL SafeReadBlockLength(
BrotliDecoderState* s, uint32_t* result, const HuffmanCode* table,
BrotliBitReader* br) {
uint32_t index;
if (s->substate_read_block_length == BROTLI_STATE_READ_BLOCK_LENGTH_NONE) {
if (!SafeReadSymbol(table, br, &index)) {
return BROTLI_FALSE;
}
} else {
index = s->block_length_index;
}
{
uint32_t bits;
uint32_t nbits = _kBrotliPrefixCodeRanges[index].nbits;
uint32_t offset = _kBrotliPrefixCodeRanges[index].offset;
if (!BrotliSafeReadBits(br, nbits, &bits)) {
s->block_length_index = index;
s->substate_read_block_length = BROTLI_STATE_READ_BLOCK_LENGTH_SUFFIX;
return BROTLI_FALSE;
}
*result = offset + bits;
s->substate_read_block_length = BROTLI_STATE_READ_BLOCK_LENGTH_NONE;
return BROTLI_TRUE;
}
}
1) initialize list L with values 0, 1,... 255
2) For each input element X:
2.1) let Y = L[X]
2.2) remove X-th element from L
2.3) prepend Y to L
2.4) append Y to output
In most cases max(Y) <= 7, so most of L remains intact.
To reduce the cost of initialization, we reuse L, remember the upper bound
of Y values, and reinitialize only first elements in L.
Most of input values are 0 and 1. To reduce number of branches, we replace
inner for loop with do-while. */
static BROTLI_NOINLINE void InverseMoveToFrontTransform(
uint8_t* v, uint32_t v_len, BrotliDecoderState* state) {
uint32_t i = 1;
uint32_t upper_bound = state->mtf_upper_bound;
uint32_t* mtf = &state->mtf[1];
uint8_t* mtf_u8 = (uint8_t*)mtf;
const uint8_t b0123[4] = {0, 1, 2, 3};
uint32_t pattern;
memcpy(&pattern, &b0123, 4);
mtf[0] = pattern;
do {
pattern += 0x04040404;
mtf[i] = pattern;
i++;
} while (i <= upper_bound);
upper_bound = 0;
for (i = 0; i < v_len; ++i) {
int index = v[i];
uint8_t value = mtf_u8[index];
upper_bound |= v[i];
v[i] = value;
mtf_u8[-1] = value;
do {
index--;
mtf_u8[index + 1] = mtf_u8[index];
} while (index >= 0);
}
state->mtf_upper_bound = upper_bound >> 2;
}
static BrotliDecoderErrorCode HuffmanTreeGroupDecode(
HuffmanTreeGroup* group, BrotliDecoderState* s) {
BrotliMetablockHeaderArena* h = &s->arena.header;
if (h->substate_tree_group != BROTLI_STATE_TREE_GROUP_LOOP) {
h->next = group->codes;
h->htree_index = 0;
h->substate_tree_group = BROTLI_STATE_TREE_GROUP_LOOP;
}
while (h->htree_index < group->num_htrees) {
uint32_t table_size;
BrotliDecoderErrorCode result = ReadHuffmanCode(group->alphabet_size_max,
group->alphabet_size_limit, h->next, &table_size, s);
if (result != BROTLI_DECODER_SUCCESS) return result;
group->htrees[h->htree_index] = h->next;
h->next += table_size;
++h->htree_index;
}
h->substate_tree_group = BROTLI_STATE_TREE_GROUP_NONE;
return BROTLI_DECODER_SUCCESS;
}
Decoding is done in 4 phases:
1) Read auxiliary information (6..16 bits) and allocate memory.
In case of trivial context map, decoding is finished at this phase.
2) Decode Huffman table using ReadHuffmanCode function.
This table will be used for reading context map items.
3) Read context map items; "0" values could be run-length encoded.
4) Optionally, apply InverseMoveToFront transform to the resulting map. */
static BrotliDecoderErrorCode DecodeContextMap(uint32_t context_map_size,
uint32_t* num_htrees,
uint8_t** context_map_arg,
BrotliDecoderState* s) {
BrotliBitReader* br = &s->br;
BrotliDecoderErrorCode result = BROTLI_DECODER_SUCCESS;
BrotliMetablockHeaderArena* h = &s->arena.header;
switch ((int)h->substate_context_map) {
case BROTLI_STATE_CONTEXT_MAP_NONE:
result = DecodeVarLenUint8(s, br, num_htrees);
if (result != BROTLI_DECODER_SUCCESS) {
return result;
}
(*num_htrees)++;
h->context_index = 0;
BROTLI_LOG_UINT(context_map_size);
BROTLI_LOG_UINT(*num_htrees);
*context_map_arg =
(uint8_t*)BROTLI_DECODER_ALLOC(s, (size_t)context_map_size);
if (*context_map_arg == 0) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_ALLOC_CONTEXT_MAP);
}
if (*num_htrees <= 1) {
memset(*context_map_arg, 0, (size_t)context_map_size);
return BROTLI_DECODER_SUCCESS;
}
h->substate_context_map = BROTLI_STATE_CONTEXT_MAP_READ_PREFIX;
case BROTLI_STATE_CONTEXT_MAP_READ_PREFIX: {
uint32_t bits;
to peek 4 bits ahead. */
if (!BrotliSafeGetBits(br, 5, &bits)) {
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if ((bits & 1) != 0) {
h->max_run_length_prefix = (bits >> 1) + 1;
BrotliDropBits(br, 5);
} else {
h->max_run_length_prefix = 0;
BrotliDropBits(br, 1);
}
BROTLI_LOG_UINT(h->max_run_length_prefix);
h->substate_context_map = BROTLI_STATE_CONTEXT_MAP_HUFFMAN;
}
case BROTLI_STATE_CONTEXT_MAP_HUFFMAN: {
uint32_t alphabet_size = *num_htrees + h->max_run_length_prefix;
result = ReadHuffmanCode(alphabet_size, alphabet_size,
h->context_map_table, NULL, s);
if (result != BROTLI_DECODER_SUCCESS) return result;
h->code = 0xFFFF;
h->substate_context_map = BROTLI_STATE_CONTEXT_MAP_DECODE;
}
case BROTLI_STATE_CONTEXT_MAP_DECODE: {
uint32_t context_index = h->context_index;
uint32_t max_run_length_prefix = h->max_run_length_prefix;
uint8_t* context_map = *context_map_arg;
uint32_t code = h->code;
BROTLI_BOOL skip_preamble = (code != 0xFFFF);
while (context_index < context_map_size || skip_preamble) {
if (!skip_preamble) {
if (!SafeReadSymbol(h->context_map_table, br, &code)) {
h->code = 0xFFFF;
h->context_index = context_index;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
BROTLI_LOG_UINT(code);
if (code == 0) {
context_map[context_index++] = 0;
continue;
}
if (code > max_run_length_prefix) {
context_map[context_index++] =
(uint8_t)(code - max_run_length_prefix);
continue;
}
} else {
skip_preamble = BROTLI_FALSE;
}
{
uint32_t reps;
if (!BrotliSafeReadBits(br, code, &reps)) {
h->code = code;
h->context_index = context_index;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
reps += 1U << code;
BROTLI_LOG_UINT(reps);
if (context_index + reps > context_map_size) {
return
BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_CONTEXT_MAP_REPEAT);
}
do {
context_map[context_index++] = 0;
} while (--reps);
}
}
}
case BROTLI_STATE_CONTEXT_MAP_TRANSFORM: {
uint32_t bits;
if (!BrotliSafeReadBits(br, 1, &bits)) {
h->substate_context_map = BROTLI_STATE_CONTEXT_MAP_TRANSFORM;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
if (bits != 0) {
InverseMoveToFrontTransform(*context_map_arg, context_map_size, s);
}
h->substate_context_map = BROTLI_STATE_CONTEXT_MAP_NONE;
return BROTLI_DECODER_SUCCESS;
}
default:
return
BROTLI_FAILURE(BROTLI_DECODER_ERROR_UNREACHABLE);
}
}
Reads 3..54 bits. */
static BROTLI_INLINE BROTLI_BOOL DecodeBlockTypeAndLength(
int safe, BrotliDecoderState* s, int tree_type) {
uint32_t max_block_type = s->num_block_types[tree_type];
const HuffmanCode* type_tree = &s->block_type_trees[
tree_type * BROTLI_HUFFMAN_MAX_SIZE_258];
const HuffmanCode* len_tree = &s->block_len_trees[
tree_type * BROTLI_HUFFMAN_MAX_SIZE_26];
BrotliBitReader* br = &s->br;
uint32_t* ringbuffer = &s->block_type_rb[tree_type * 2];
uint32_t block_type;
if (max_block_type <= 1) {
return BROTLI_FALSE;
}
if (!safe) {
block_type = ReadSymbol(type_tree, br);
s->block_length[tree_type] = ReadBlockLength(len_tree, br);
} else {
BrotliBitReaderState memento;
BrotliBitReaderSaveState(br, &memento);
if (!SafeReadSymbol(type_tree, br, &block_type)) return BROTLI_FALSE;
if (!SafeReadBlockLength(s, &s->block_length[tree_type], len_tree, br)) {
s->substate_read_block_length = BROTLI_STATE_READ_BLOCK_LENGTH_NONE;
BrotliBitReaderRestoreState(br, &memento);
return BROTLI_FALSE;
}
}
if (block_type == 1) {
block_type = ringbuffer[1] + 1;
} else if (block_type == 0) {
block_type = ringbuffer[0];
} else {
block_type -= 2;
}
if (block_type >= max_block_type) {
block_type -= max_block_type;
}
ringbuffer[0] = ringbuffer[1];
ringbuffer[1] = block_type;
return BROTLI_TRUE;
}
static BROTLI_INLINE void DetectTrivialLiteralBlockTypes(
BrotliDecoderState* s) {
size_t i;
for (i = 0; i < 8; ++i) s->trivial_literal_contexts[i] = 0;
for (i = 0; i < s->num_block_types[0]; i++) {
size_t offset = i << BROTLI_LITERAL_CONTEXT_BITS;
size_t error = 0;
size_t sample = s->context_map[offset];
size_t j;
for (j = 0; j < (1u << BROTLI_LITERAL_CONTEXT_BITS);) {
BROTLI_REPEAT(4, error |= s->context_map[offset + j++] ^ sample;)
}
if (error == 0) {
s->trivial_literal_contexts[i >> 5] |= 1u << (i & 31);
}
}
}
static BROTLI_INLINE void PrepareLiteralDecoding(BrotliDecoderState* s) {
uint8_t context_mode;
size_t trivial;
uint32_t block_type = s->block_type_rb[1];
uint32_t context_offset = block_type << BROTLI_LITERAL_CONTEXT_BITS;
s->context_map_slice = s->context_map + context_offset;
trivial = s->trivial_literal_contexts[block_type >> 5];
s->trivial_literal_context = (trivial >> (block_type & 31)) & 1;
s->literal_htree = s->literal_hgroup.htrees[s->context_map_slice[0]];
context_mode = s->context_modes[block_type] & 3;
s->context_lookup = BROTLI_CONTEXT_LUT(context_mode);
}
Reads 3..54 bits. */
static BROTLI_INLINE BROTLI_BOOL DecodeLiteralBlockSwitchInternal(
int safe, BrotliDecoderState* s) {
if (!DecodeBlockTypeAndLength(safe, s, 0)) {
return BROTLI_FALSE;
}
PrepareLiteralDecoding(s);
return BROTLI_TRUE;
}
static void BROTLI_NOINLINE DecodeLiteralBlockSwitch(BrotliDecoderState* s) {
DecodeLiteralBlockSwitchInternal(0, s);
}
static BROTLI_BOOL BROTLI_NOINLINE SafeDecodeLiteralBlockSwitch(
BrotliDecoderState* s) {
return DecodeLiteralBlockSwitchInternal(1, s);
}
Reads 3..54 bits. */
static BROTLI_INLINE BROTLI_BOOL DecodeCommandBlockSwitchInternal(
int safe, BrotliDecoderState* s) {
if (!DecodeBlockTypeAndLength(safe, s, 1)) {
return BROTLI_FALSE;
}
s->htree_command = s->insert_copy_hgroup.htrees[s->block_type_rb[3]];
return BROTLI_TRUE;
}
static void BROTLI_NOINLINE DecodeCommandBlockSwitch(BrotliDecoderState* s) {
DecodeCommandBlockSwitchInternal(0, s);
}
static BROTLI_BOOL BROTLI_NOINLINE SafeDecodeCommandBlockSwitch(
BrotliDecoderState* s) {
return DecodeCommandBlockSwitchInternal(1, s);
}
Reads 3..54 bits. */
static BROTLI_INLINE BROTLI_BOOL DecodeDistanceBlockSwitchInternal(
int safe, BrotliDecoderState* s) {
if (!DecodeBlockTypeAndLength(safe, s, 2)) {
return BROTLI_FALSE;
}
s->dist_context_map_slice = s->dist_context_map +
(s->block_type_rb[5] << BROTLI_DISTANCE_CONTEXT_BITS);
s->dist_htree_index = s->dist_context_map_slice[s->distance_context];
return BROTLI_TRUE;
}
static void BROTLI_NOINLINE DecodeDistanceBlockSwitch(BrotliDecoderState* s) {
DecodeDistanceBlockSwitchInternal(0, s);
}
static BROTLI_BOOL BROTLI_NOINLINE SafeDecodeDistanceBlockSwitch(
BrotliDecoderState* s) {
return DecodeDistanceBlockSwitchInternal(1, s);
}
static size_t UnwrittenBytes(const BrotliDecoderState* s, BROTLI_BOOL wrap) {
size_t pos = wrap && s->pos > s->ringbuffer_size ?
(size_t)s->ringbuffer_size : (size_t)(s->pos);
size_t partial_pos_rb = (s->rb_roundtrips * (size_t)s->ringbuffer_size) + pos;
return partial_pos_rb - s->partial_pos_out;
}
Returns BROTLI_DECODER_NEEDS_MORE_OUTPUT only if there is more output to push
and either ring-buffer is as big as window size, or |force| is true. */
static BrotliDecoderErrorCode BROTLI_NOINLINE WriteRingBuffer(
BrotliDecoderState* s, size_t* available_out, uint8_t** next_out,
size_t* total_out, BROTLI_BOOL force) {
uint8_t* start =
s->ringbuffer + (s->partial_pos_out & (size_t)s->ringbuffer_mask);
size_t to_write = UnwrittenBytes(s, BROTLI_TRUE);
size_t num_written = *available_out;
if (num_written > to_write) {
num_written = to_write;
}
if (s->meta_block_remaining_len < 0) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_BLOCK_LENGTH_1);
}
if (next_out && !*next_out) {
*next_out = start;
} else {
if (next_out) {
memcpy(*next_out, start, num_written);
*next_out += num_written;
}
}
*available_out -= num_written;
BROTLI_LOG_UINT(to_write);
BROTLI_LOG_UINT(num_written);
s->partial_pos_out += num_written;
if (total_out) {
*total_out = s->partial_pos_out;
}
if (num_written < to_write) {
if (s->ringbuffer_size == (1 << s->window_bits) || force) {
return BROTLI_DECODER_NEEDS_MORE_OUTPUT;
} else {
return BROTLI_DECODER_SUCCESS;
}
}
if (s->ringbuffer_size == (1 << s->window_bits) &&
s->pos >= s->ringbuffer_size) {
s->pos -= s->ringbuffer_size;
s->rb_roundtrips++;
s->should_wrap_ringbuffer = (size_t)s->pos != 0 ? 1 : 0;
}
return BROTLI_DECODER_SUCCESS;
}
static void BROTLI_NOINLINE WrapRingBuffer(BrotliDecoderState* s) {
if (s->should_wrap_ringbuffer) {
memcpy(s->ringbuffer, s->ringbuffer_end, (size_t)s->pos);
s->should_wrap_ringbuffer = 0;
}
}
s->ringbuffer_size MUST be updated by BrotliCalculateRingBufferSize before
this function is called.
Last two bytes of ring-buffer are initialized to 0, so context calculation
could be done uniformly for the first two and all other positions. */
static BROTLI_BOOL BROTLI_NOINLINE BrotliEnsureRingBuffer(
BrotliDecoderState* s) {
uint8_t* old_ringbuffer = s->ringbuffer;
if (s->ringbuffer_size == s->new_ringbuffer_size) {
return BROTLI_TRUE;
}
s->ringbuffer = (uint8_t*)BROTLI_DECODER_ALLOC(s,
(size_t)(s->new_ringbuffer_size) + kRingBufferWriteAheadSlack);
if (s->ringbuffer == 0) {
s->ringbuffer = old_ringbuffer;
return BROTLI_FALSE;
}
s->ringbuffer[s->new_ringbuffer_size - 2] = 0;
s->ringbuffer[s->new_ringbuffer_size - 1] = 0;
if (!!old_ringbuffer) {
memcpy(s->ringbuffer, old_ringbuffer, (size_t)s->pos);
BROTLI_DECODER_FREE(s, old_ringbuffer);
}
s->ringbuffer_size = s->new_ringbuffer_size;
s->ringbuffer_mask = s->new_ringbuffer_size - 1;
s->ringbuffer_end = s->ringbuffer + s->ringbuffer_size;
return BROTLI_TRUE;
}
static BrotliDecoderErrorCode BROTLI_NOINLINE CopyUncompressedBlockToOutput(
size_t* available_out, uint8_t** next_out, size_t* total_out,
BrotliDecoderState* s) {
if (!BrotliEnsureRingBuffer(s)) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_ALLOC_RING_BUFFER_1);
}
for (;;) {
switch (s->substate_uncompressed) {
case BROTLI_STATE_UNCOMPRESSED_NONE: {
int nbytes = (int)BrotliGetRemainingBytes(&s->br);
if (nbytes > s->meta_block_remaining_len) {
nbytes = s->meta_block_remaining_len;
}
if (s->pos + nbytes > s->ringbuffer_size) {
nbytes = s->ringbuffer_size - s->pos;
}
BrotliCopyBytes(&s->ringbuffer[s->pos], &s->br, (size_t)nbytes);
s->pos += nbytes;
s->meta_block_remaining_len -= nbytes;
if (s->pos < 1 << s->window_bits) {
if (s->meta_block_remaining_len == 0) {
return BROTLI_DECODER_SUCCESS;
}
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
s->substate_uncompressed = BROTLI_STATE_UNCOMPRESSED_WRITE;
}
case BROTLI_STATE_UNCOMPRESSED_WRITE: {
BrotliDecoderErrorCode result;
result = WriteRingBuffer(
s, available_out, next_out, total_out, BROTLI_FALSE);
if (result != BROTLI_DECODER_SUCCESS) {
return result;
}
if (s->ringbuffer_size == 1 << s->window_bits) {
s->max_distance = s->max_backward_distance;
}
s->substate_uncompressed = BROTLI_STATE_UNCOMPRESSED_NONE;
break;
}
}
}
BROTLI_DCHECK(0);
}
static BROTLI_BOOL AttachCompoundDictionary(
BrotliDecoderState* state, const uint8_t* data, size_t size) {
BrotliDecoderCompoundDictionary* addon = state->compound_dictionary;
if (state->state != BROTLI_STATE_UNINITED) return BROTLI_FALSE;
if (!addon) {
addon = (BrotliDecoderCompoundDictionary*)BROTLI_DECODER_ALLOC(
state, sizeof(BrotliDecoderCompoundDictionary));
if (!addon) return BROTLI_FALSE;
addon->num_chunks = 0;
addon->total_size = 0;
addon->br_length = 0;
addon->br_copied = 0;
addon->block_bits = -1;
addon->chunk_offsets[0] = 0;
state->compound_dictionary = addon;
}
if (addon->num_chunks == 15) return BROTLI_FALSE;
addon->chunks[addon->num_chunks] = data;
addon->num_chunks++;
addon->total_size += (int)size;
addon->chunk_offsets[addon->num_chunks] = addon->total_size;
return BROTLI_TRUE;
}
static void EnsureCoumpoundDictionaryInitialized(BrotliDecoderState* state) {
BrotliDecoderCompoundDictionary* addon = state->compound_dictionary;
int block_bits = 8;
int cursor = 0;
int index = 0;
if (addon->block_bits != -1) return;
while (((addon->total_size - 1) >> block_bits) != 0) block_bits++;
block_bits -= 8;
addon->block_bits = block_bits;
while (cursor < addon->total_size) {
while (addon->chunk_offsets[index + 1] < cursor) index++;
addon->block_map[cursor >> block_bits] = (uint8_t)index;
cursor += 1 << block_bits;
}
}
static BROTLI_BOOL InitializeCompoundDictionaryCopy(BrotliDecoderState* s,
int address, int length) {
BrotliDecoderCompoundDictionary* addon = s->compound_dictionary;
int index;
EnsureCoumpoundDictionaryInitialized(s);
index = addon->block_map[address >> addon->block_bits];
while (address >= addon->chunk_offsets[index + 1]) index++;
if (addon->total_size < address + length) return BROTLI_FALSE;
s->dist_rb[s->dist_rb_idx & 3] = s->distance_code;
++s->dist_rb_idx;
s->meta_block_remaining_len -= length;
addon->br_index = index;
addon->br_offset = address - addon->chunk_offsets[index];
addon->br_length = length;
addon->br_copied = 0;
return BROTLI_TRUE;
}
static int GetCompoundDictionarySize(BrotliDecoderState* s) {
return s->compound_dictionary ? s->compound_dictionary->total_size : 0;
}
static int CopyFromCompoundDictionary(BrotliDecoderState* s, int pos) {
BrotliDecoderCompoundDictionary* addon = s->compound_dictionary;
int orig_pos = pos;
while (addon->br_length != addon->br_copied) {
uint8_t* copy_dst = &s->ringbuffer[pos];
const uint8_t* copy_src =
addon->chunks[addon->br_index] + addon->br_offset;
int space = s->ringbuffer_size - pos;
int rem_chunk_length = (addon->chunk_offsets[addon->br_index + 1] -
addon->chunk_offsets[addon->br_index]) - addon->br_offset;
int length = addon->br_length - addon->br_copied;
if (length > rem_chunk_length) length = rem_chunk_length;
if (length > space) length = space;
memcpy(copy_dst, copy_src, (size_t)length);
pos += length;
addon->br_offset += length;
addon->br_copied += length;
if (length == rem_chunk_length) {
addon->br_index++;
addon->br_offset = 0;
}
if (pos == s->ringbuffer_size) break;
}
return pos - orig_pos;
}
BROTLI_BOOL BrotliDecoderAttachDictionary(
BrotliDecoderState* state, BrotliSharedDictionaryType type,
size_t data_size, const uint8_t data[BROTLI_ARRAY_PARAM(data_size)]) {
uint32_t i;
uint32_t num_prefix_before = state->dictionary->num_prefix;
if (state->state != BROTLI_STATE_UNINITED) return BROTLI_FALSE;
if (!BrotliSharedDictionaryAttach(state->dictionary, type, data_size, data)) {
return BROTLI_FALSE;
}
for (i = num_prefix_before; i < state->dictionary->num_prefix; i++) {
if (!AttachCompoundDictionary(
state, state->dictionary->prefix[i],
state->dictionary->prefix_size[i])) {
return BROTLI_FALSE;
}
}
return BROTLI_TRUE;
}
If we know the data size is small, do not allocate more ring buffer
size than needed to reduce memory usage.
When this method is called, metablock size and flags MUST be decoded. */
static void BROTLI_NOINLINE BrotliCalculateRingBufferSize(
BrotliDecoderState* s) {
int window_size = 1 << s->window_bits;
int new_ringbuffer_size = window_size;
bytes for context from there */
int min_size = s->ringbuffer_size ? s->ringbuffer_size : 1024;
int output_size;
if (s->ringbuffer_size == window_size) {
return;
}
if (s->is_metadata) {
return;
}
if (!s->ringbuffer) {
output_size = 0;
} else {
output_size = s->pos;
}
output_size += s->meta_block_remaining_len;
min_size = min_size < output_size ? output_size : min_size;
if (!!s->canny_ringbuffer_allocation) {
In worst case memory usage might be 1.5x bigger for a short period of
ring buffer reallocation. */
while ((new_ringbuffer_size >> 1) >= min_size) {
new_ringbuffer_size >>= 1;
}
}
s->new_ringbuffer_size = new_ringbuffer_size;
}
static BrotliDecoderErrorCode ReadContextModes(BrotliDecoderState* s) {
BrotliBitReader* br = &s->br;
int i = s->loop_counter;
while (i < (int)s->num_block_types[0]) {
uint32_t bits;
if (!BrotliSafeReadBits(br, 2, &bits)) {
s->loop_counter = i;
return BROTLI_DECODER_NEEDS_MORE_INPUT;
}
s->context_modes[i] = (uint8_t)bits;
BROTLI_LOG_ARRAY_INDEX(s->context_modes, i);
i++;
}
return BROTLI_DECODER_SUCCESS;
}
static BROTLI_INLINE void TakeDistanceFromRingBuffer(BrotliDecoderState* s) {
int offset = s->distance_code - 3;
if (s->distance_code <= 3) {
s->distance_context = 1 >> s->distance_code;
s->distance_code = s->dist_rb[(s->dist_rb_idx - offset) & 3];
s->dist_rb_idx -= s->distance_context;
} else {
int index_delta = 3;
int delta;
int base = s->distance_code - 10;
if (s->distance_code < 10) {
base = s->distance_code - 4;
} else {
index_delta = 2;
}
delta = ((0x605142 >> (4 * base)) & 0xF) - 3;
s->distance_code = s->dist_rb[(s->dist_rb_idx + index_delta) & 0x3] + delta;
if (s->distance_code <= 0) {
This is a little faster than failing here. */
s->distance_code = 0x7FFFFFFF;
}
}
}
static BROTLI_INLINE BROTLI_BOOL SafeReadBits(
BrotliBitReader* const br, uint32_t n_bits, uint32_t* val) {
if (n_bits != 0) {
return BrotliSafeReadBits(br, n_bits, val);
} else {
*val = 0;
return BROTLI_TRUE;
}
}
static BROTLI_INLINE BROTLI_BOOL SafeReadBits32(
BrotliBitReader* const br, uint32_t n_bits, uint32_t* val) {
if (n_bits != 0) {
return BrotliSafeReadBits32(br, n_bits, val);
} else {
*val = 0;
return BROTLI_TRUE;
}
}
RFC 7932 Section 4 with "..." shortenings and "[]" emendations.
Each distance ... is represented with a pair <distance code, extra bits>...
The distance code is encoded using a prefix code... The number of extra bits
can be 0..24... Two additional parameters: NPOSTFIX (0..3), and ...
NDIRECT (0..120) ... are encoded in the meta-block header...
The first 16 distance symbols ... reference past distances... ring buffer ...
Next NDIRECT distance symbols ... represent distances from 1 to NDIRECT...
[For] distance symbols 16 + NDIRECT and greater ... the number of extra bits
... is given by the following formula:
[ xcode = dcode - NDIRECT - 16 ]
ndistbits = 1 + [ xcode ] >> (NPOSTFIX + 1)
...
*/
RFC 7932 Section 9.2 with "..." shortenings and "[]" emendations.
... to get the actual value of the parameter NDIRECT, left-shift this
four-bit number by NPOSTFIX bits ...
*/
alphabet_size = 16 + NDIRECT + (max_distbits << (NPOSTFIX + 1))
half = ((xcode >> NPOSTFIX) & 1) << ndistbits
postfix = xcode & ((1 << NPOSTFIX) - 1)
range_start = 2 * (1 << ndistbits - 1 - 1)
distance = (range_start + half + extra) << NPOSTFIX + postfix + NDIRECT + 1
NB: ndistbits >= 1 -> range_start >= 0
NB: range_start has factor 2, as the range is covered by 2 "halves"
NB: extra -1 offset in range_start formula covers the absence of
ndistbits = 0 case
NB: when NPOSTFIX = 0, NDIRECT is not greater than 15
In other words, xcode has the following binary structure - XXXHPPP:
- XXX represent the number of extra distance bits
- H selects upper / lower range of distances
- PPP represent "postfix"
"Regular" distance encoding has NPOSTFIX = 0; omitting the postfix part
simplifies distance calculation.
Using NPOSTFIX > 0 allows cheaper encoding of regular structures, e.g. where
most of distances have the same reminder of division by 2/4/8. For example,
the table of int32_t values that come from different sources; if it is likely
that 3 highest bytes of values from the same source are the same, then
copy distance often looks like 4x + y.
Distance calculation could be rewritten to:
ndistbits = NDISTBITS(NDIRECT, NPOSTFIX)[dcode]
distance = OFFSET(NDIRECT, NPOSTFIX)[dcode] + extra << NPOSTFIX
NDISTBITS and OFFSET could be pre-calculated, as NDIRECT and NPOSTFIX could
change only once per meta-block.
*/
NB: it is possible to have all 64 tables precalculated. */
static void CalculateDistanceLut(BrotliDecoderState* s) {
BrotliMetablockBodyArena* b = &s->arena.body;
uint32_t npostfix = s->distance_postfix_bits;
uint32_t ndirect = s->num_direct_distance_codes;
uint32_t alphabet_size_limit = s->distance_hgroup.alphabet_size_limit;
uint32_t postfix = 1u << npostfix;
uint32_t j;
uint32_t bits = 1;
uint32_t half = 0;
uint32_t i = BROTLI_NUM_DISTANCE_SHORT_CODES;
for (j = 0; j < ndirect; ++j) {
b->dist_extra_bits[i] = 0;
b->dist_offset[i] = j + 1;
++i;
}
while (i < alphabet_size_limit) {
uint32_t base = ndirect + ((((2 + half) << bits) - 4) << npostfix) + 1;
for (j = 0; j < postfix; ++j) {
b->dist_extra_bits[i] = (uint8_t)bits;
b->dist_offset[i] = base + j;
++i;
}
bits = bits + half;
half = half ^ 1;
}
}
static BROTLI_INLINE BROTLI_BOOL ReadDistanceInternal(
int safe, BrotliDecoderState* s, BrotliBitReader* br) {
BrotliMetablockBodyArena* b = &s->arena.body;
uint32_t code;
uint32_t bits;
BrotliBitReaderState memento;
HuffmanCode* distance_tree = s->distance_hgroup.htrees[s->dist_htree_index];
if (!safe) {
code = ReadSymbol(distance_tree, br);
} else {
BrotliBitReaderSaveState(br, &memento);
if (!SafeReadSymbol(distance_tree, br, &code)) {
return BROTLI_FALSE;
}
}
--s->block_length[2];
looking up past distances from the s->dist_rb. */
s->distance_context = 0;
if ((code & ~0xFu) == 0) {
s->distance_code = (int)code;
TakeDistanceFromRingBuffer(s);
return BROTLI_TRUE;
}
if (!safe) {
bits = BrotliReadBits32(br, b->dist_extra_bits[code]);
} else {
if (!SafeReadBits32(br, b->dist_extra_bits[code], &bits)) {
++s->block_length[2];
BrotliBitReaderRestoreState(br, &memento);
return BROTLI_FALSE;
}
}
s->distance_code =
(int)(b->dist_offset[code] + (bits << s->distance_postfix_bits));
return BROTLI_TRUE;
}
static BROTLI_INLINE void ReadDistance(
BrotliDecoderState* s, BrotliBitReader* br) {
ReadDistanceInternal(0, s, br);
}
static BROTLI_INLINE BROTLI_BOOL SafeReadDistance(
BrotliDecoderState* s, BrotliBitReader* br) {
return ReadDistanceInternal(1, s, br);
}
static BROTLI_INLINE BROTLI_BOOL ReadCommandInternal(
int safe, BrotliDecoderState* s, BrotliBitReader* br, int* insert_length) {
uint32_t cmd_code;
uint32_t insert_len_extra = 0;
uint32_t copy_length;
CmdLutElement v;
BrotliBitReaderState memento;
if (!safe) {
cmd_code = ReadSymbol(s->htree_command, br);
} else {
BrotliBitReaderSaveState(br, &memento);
if (!SafeReadSymbol(s->htree_command, br, &cmd_code)) {
return BROTLI_FALSE;
}
}
v = kCmdLut[cmd_code];
s->distance_code = v.distance_code;
s->distance_context = v.context;
s->dist_htree_index = s->dist_context_map_slice[s->distance_context];
*insert_length = v.insert_len_offset;
if (!safe) {
if (BROTLI_PREDICT_FALSE(v.insert_len_extra_bits != 0)) {
insert_len_extra = BrotliReadBits24(br, v.insert_len_extra_bits);
}
copy_length = BrotliReadBits24(br, v.copy_len_extra_bits);
} else {
if (!SafeReadBits(br, v.insert_len_extra_bits, &insert_len_extra) ||
!SafeReadBits(br, v.copy_len_extra_bits, ©_length)) {
BrotliBitReaderRestoreState(br, &memento);
return BROTLI_FALSE;
}
}
s->copy_length = (int)copy_length + v.copy_len_offset;
--s->block_length[1];
*insert_length += (int)insert_len_extra;
return BROTLI_TRUE;
}
static BROTLI_INLINE void ReadCommand(
BrotliDecoderState* s, BrotliBitReader* br, int* insert_length) {
ReadCommandInternal(0, s, br, insert_length);
}
static BROTLI_INLINE BROTLI_BOOL SafeReadCommand(
BrotliDecoderState* s, BrotliBitReader* br, int* insert_length) {
return ReadCommandInternal(1, s, br, insert_length);
}
static BROTLI_INLINE BROTLI_BOOL CheckInputAmount(
int safe, BrotliBitReader* const br, size_t num) {
if (safe) {
return BROTLI_TRUE;
}
return BrotliCheckInputAmount(br, num);
}
#define BROTLI_SAFE(METHOD) \
{ \
if (safe) { \
if (!Safe##METHOD) { \
result = BROTLI_DECODER_NEEDS_MORE_INPUT; \
goto saveStateAndReturn; \
} \
} else { \
METHOD; \
} \
}
static BROTLI_INLINE BrotliDecoderErrorCode ProcessCommandsInternal(
int safe, BrotliDecoderState* s) {
int pos = s->pos;
int i = s->loop_counter;
BrotliDecoderErrorCode result = BROTLI_DECODER_SUCCESS;
BrotliBitReader* br = &s->br;
int compound_dictionary_size = GetCompoundDictionarySize(s);
if (!CheckInputAmount(safe, br, 28)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
goto saveStateAndReturn;
}
if (!safe) {
BROTLI_UNUSED(BrotliWarmupBitReader(br));
}
if (s->state == BROTLI_STATE_COMMAND_BEGIN) {
goto CommandBegin;
} else if (s->state == BROTLI_STATE_COMMAND_INNER) {
goto CommandInner;
} else if (s->state == BROTLI_STATE_COMMAND_POST_DECODE_LITERALS) {
goto CommandPostDecodeLiterals;
} else if (s->state == BROTLI_STATE_COMMAND_POST_WRAP_COPY) {
goto CommandPostWrapCopy;
} else {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_UNREACHABLE);
}
CommandBegin:
if (safe) {
s->state = BROTLI_STATE_COMMAND_BEGIN;
}
if (!CheckInputAmount(safe, br, 28)) {
s->state = BROTLI_STATE_COMMAND_BEGIN;
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
goto saveStateAndReturn;
}
if (BROTLI_PREDICT_FALSE(s->block_length[1] == 0)) {
BROTLI_SAFE(DecodeCommandBlockSwitch(s));
goto CommandBegin;
}
BROTLI_SAFE(ReadCommand(s, br, &i));
BROTLI_LOG(("[ProcessCommandsInternal] pos = %d insert = %d copy = %d\n",
pos, i, s->copy_length));
if (i == 0) {
goto CommandPostDecodeLiterals;
}
s->meta_block_remaining_len -= i;
CommandInner:
if (safe) {
s->state = BROTLI_STATE_COMMAND_INNER;
}
if (s->trivial_literal_context) {
uint32_t bits;
uint32_t value;
PreloadSymbol(safe, s->literal_htree, br, &bits, &value);
do {
if (!CheckInputAmount(safe, br, 28)) {
s->state = BROTLI_STATE_COMMAND_INNER;
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
goto saveStateAndReturn;
}
if (BROTLI_PREDICT_FALSE(s->block_length[0] == 0)) {
BROTLI_SAFE(DecodeLiteralBlockSwitch(s));
PreloadSymbol(safe, s->literal_htree, br, &bits, &value);
if (!s->trivial_literal_context) goto CommandInner;
}
if (!safe) {
s->ringbuffer[pos] =
(uint8_t)ReadPreloadedSymbol(s->literal_htree, br, &bits, &value);
} else {
uint32_t literal;
if (!SafeReadSymbol(s->literal_htree, br, &literal)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
goto saveStateAndReturn;
}
s->ringbuffer[pos] = (uint8_t)literal;
}
--s->block_length[0];
BROTLI_LOG_ARRAY_INDEX(s->ringbuffer, pos);
++pos;
if (BROTLI_PREDICT_FALSE(pos == s->ringbuffer_size)) {
s->state = BROTLI_STATE_COMMAND_INNER_WRITE;
--i;
goto saveStateAndReturn;
}
} while (--i != 0);
} else {
uint8_t p1 = s->ringbuffer[(pos - 1) & s->ringbuffer_mask];
uint8_t p2 = s->ringbuffer[(pos - 2) & s->ringbuffer_mask];
do {
const HuffmanCode* hc;
uint8_t context;
if (!CheckInputAmount(safe, br, 28)) {
s->state = BROTLI_STATE_COMMAND_INNER;
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
goto saveStateAndReturn;
}
if (BROTLI_PREDICT_FALSE(s->block_length[0] == 0)) {
BROTLI_SAFE(DecodeLiteralBlockSwitch(s));
if (s->trivial_literal_context) goto CommandInner;
}
context = BROTLI_CONTEXT(p1, p2, s->context_lookup);
BROTLI_LOG_UINT(context);
hc = s->literal_hgroup.htrees[s->context_map_slice[context]];
p2 = p1;
if (!safe) {
p1 = (uint8_t)ReadSymbol(hc, br);
} else {
uint32_t literal;
if (!SafeReadSymbol(hc, br, &literal)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
goto saveStateAndReturn;
}
p1 = (uint8_t)literal;
}
s->ringbuffer[pos] = p1;
--s->block_length[0];
BROTLI_LOG_UINT(s->context_map_slice[context]);
BROTLI_LOG_ARRAY_INDEX(s->ringbuffer, pos & s->ringbuffer_mask);
++pos;
if (BROTLI_PREDICT_FALSE(pos == s->ringbuffer_size)) {
s->state = BROTLI_STATE_COMMAND_INNER_WRITE;
--i;
goto saveStateAndReturn;
}
} while (--i != 0);
}
BROTLI_LOG_UINT(s->meta_block_remaining_len);
if (BROTLI_PREDICT_FALSE(s->meta_block_remaining_len <= 0)) {
s->state = BROTLI_STATE_METABLOCK_DONE;
goto saveStateAndReturn;
}
CommandPostDecodeLiterals:
if (safe) {
s->state = BROTLI_STATE_COMMAND_POST_DECODE_LITERALS;
}
if (s->distance_code >= 0) {
s->distance_context = s->distance_code ? 0 : 1;
--s->dist_rb_idx;
s->distance_code = s->dist_rb[s->dist_rb_idx & 3];
} else {
if (BROTLI_PREDICT_FALSE(s->block_length[2] == 0)) {
BROTLI_SAFE(DecodeDistanceBlockSwitch(s));
}
BROTLI_SAFE(ReadDistance(s, br));
}
BROTLI_LOG(("[ProcessCommandsInternal] pos = %d distance = %d\n",
pos, s->distance_code));
if (s->max_distance != s->max_backward_distance) {
s->max_distance =
(pos < s->max_backward_distance) ? pos : s->max_backward_distance;
}
i = s->copy_length;
the distance is larger than the max LZ77 distance */
if (s->distance_code > s->max_distance) {
With this choice, no signed overflow can occur after decoding
a special distance code (e.g., after adding 3 to the last distance). */
if (s->distance_code > BROTLI_MAX_ALLOWED_DISTANCE) {
BROTLI_LOG(("Invalid backward reference. pos: %d distance: %d "
"len: %d bytes left: %d\n",
pos, s->distance_code, i, s->meta_block_remaining_len));
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_DISTANCE);
}
if (s->distance_code - s->max_distance - 1 < compound_dictionary_size) {
int address = compound_dictionary_size -
(s->distance_code - s->max_distance);
if (!InitializeCompoundDictionaryCopy(s, address, i)) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_COMPOUND_DICTIONARY);
}
pos += CopyFromCompoundDictionary(s, pos);
if (pos >= s->ringbuffer_size) {
s->state = BROTLI_STATE_COMMAND_POST_WRITE_1;
goto saveStateAndReturn;
}
} else if (i >= SHARED_BROTLI_MIN_DICTIONARY_WORD_LENGTH &&
i <= SHARED_BROTLI_MAX_DICTIONARY_WORD_LENGTH) {
uint8_t p1 = s->ringbuffer[(pos - 1) & s->ringbuffer_mask];
uint8_t p2 = s->ringbuffer[(pos - 2) & s->ringbuffer_mask];
uint8_t dict_id = s->dictionary->context_based ?
s->dictionary->context_map[BROTLI_CONTEXT(p1, p2, s->context_lookup)]
: 0;
const BrotliDictionary* words = s->dictionary->words[dict_id];
const BrotliTransforms* transforms = s->dictionary->transforms[dict_id];
int offset = (int)words->offsets_by_length[i];
uint32_t shift = words->size_bits_by_length[i];
int address =
s->distance_code - s->max_distance - 1 - compound_dictionary_size;
int mask = (int)BitMask(shift);
int word_idx = address & mask;
int transform_idx = address >> shift;
s->dist_rb_idx += s->distance_context;
offset += word_idx * i;
there exist multiple. */
if ((transform_idx >= (int)transforms->num_transforms ||
words->size_bits_by_length[i] == 0) &&
s->dictionary->num_dictionaries > 1) {
uint8_t dict_id2;
int dist_remaining = address -
(int)(((1u << shift) & ~1u)) * (int)transforms->num_transforms;
for (dict_id2 = 0; dict_id2 < s->dictionary->num_dictionaries;
dict_id2++) {
const BrotliDictionary* words2 = s->dictionary->words[dict_id2];
if (dict_id2 != dict_id && words2->size_bits_by_length[i] != 0) {
const BrotliTransforms* transforms2 =
s->dictionary->transforms[dict_id2];
uint32_t shift2 = words2->size_bits_by_length[i];
int num = (int)((1u << shift2) & ~1u) *
(int)transforms2->num_transforms;
if (dist_remaining < num) {
dict_id = dict_id2;
words = words2;
transforms = transforms2;
address = dist_remaining;
shift = shift2;
mask = (int)BitMask(shift);
word_idx = address & mask;
transform_idx = address >> shift;
offset = (int)words->offsets_by_length[i] + word_idx * i;
break;
}
dist_remaining -= num;
}
}
}
if (BROTLI_PREDICT_FALSE(words->size_bits_by_length[i] == 0)) {
BROTLI_LOG(("Invalid backward reference. pos: %d distance: %d "
"len: %d bytes left: %d\n",
pos, s->distance_code, i, s->meta_block_remaining_len));
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_DICTIONARY);
}
if (BROTLI_PREDICT_FALSE(!words->data)) {
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_DICTIONARY_NOT_SET);
}
if (transform_idx < (int)transforms->num_transforms) {
const uint8_t* word = &words->data[offset];
int len = i;
if (transform_idx == transforms->cutOffTransforms[0]) {
memcpy(&s->ringbuffer[pos], word, (size_t)len);
BROTLI_LOG(("[ProcessCommandsInternal] dictionary word: [%.*s]\n",
len, word));
} else {
len = BrotliTransformDictionaryWord(&s->ringbuffer[pos], word, len,
transforms, transform_idx);
BROTLI_LOG(("[ProcessCommandsInternal] dictionary word: [%.*s],"
" transform_idx = %d, transformed: [%.*s]\n",
i, word, transform_idx, len, &s->ringbuffer[pos]));
if (len == 0 && s->distance_code <= 120) {
BROTLI_LOG(("Invalid length-0 dictionary word after transform\n"));
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_TRANSFORM);
}
}
pos += len;
s->meta_block_remaining_len -= len;
if (pos >= s->ringbuffer_size) {
s->state = BROTLI_STATE_COMMAND_POST_WRITE_1;
goto saveStateAndReturn;
}
} else {
BROTLI_LOG(("Invalid backward reference. pos: %d distance: %d "
"len: %d bytes left: %d\n",
pos, s->distance_code, i, s->meta_block_remaining_len));
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_TRANSFORM);
}
} else {
BROTLI_LOG(("Invalid backward reference. pos: %d distance: %d "
"len: %d bytes left: %d\n",
pos, s->distance_code, i, s->meta_block_remaining_len));
return BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_DICTIONARY);
}
} else {
int src_start = (pos - s->distance_code) & s->ringbuffer_mask;
uint8_t* copy_dst = &s->ringbuffer[pos];
uint8_t* copy_src = &s->ringbuffer[src_start];
int dst_end = pos + i;
int src_end = src_start + i;
s->dist_rb[s->dist_rb_idx & 3] = s->distance_code;
++s->dist_rb_idx;
s->meta_block_remaining_len -= i;
Also, we have 16 short codes, that make these 16 bytes irrelevant
in the ring-buffer. Let's copy over them as a first guess. */
memmove16(copy_dst, copy_src);
if (src_end > pos && dst_end > src_start) {
goto CommandPostWrapCopy;
}
if (dst_end >= s->ringbuffer_size || src_end >= s->ringbuffer_size) {
goto CommandPostWrapCopy;
}
pos += i;
if (i > 16) {
if (i > 32) {
memcpy(copy_dst + 16, copy_src + 16, (size_t)(i - 16));
} else {
Fixed size short copy allows more compiler optimizations. */
memmove16(copy_dst + 16, copy_src + 16);
}
}
}
BROTLI_LOG_UINT(s->meta_block_remaining_len);
if (s->meta_block_remaining_len <= 0) {
s->state = BROTLI_STATE_METABLOCK_DONE;
goto saveStateAndReturn;
} else {
goto CommandBegin;
}
CommandPostWrapCopy:
{
int wrap_guard = s->ringbuffer_size - pos;
while (--i >= 0) {
s->ringbuffer[pos] =
s->ringbuffer[(pos - s->distance_code) & s->ringbuffer_mask];
++pos;
if (BROTLI_PREDICT_FALSE(--wrap_guard == 0)) {
s->state = BROTLI_STATE_COMMAND_POST_WRITE_2;
goto saveStateAndReturn;
}
}
}
if (s->meta_block_remaining_len <= 0) {
s->state = BROTLI_STATE_METABLOCK_DONE;
goto saveStateAndReturn;
} else {
goto CommandBegin;
}
saveStateAndReturn:
s->pos = pos;
s->loop_counter = i;
return result;
}
#undef BROTLI_SAFE
static BROTLI_NOINLINE BrotliDecoderErrorCode ProcessCommands(
BrotliDecoderState* s) {
return ProcessCommandsInternal(0, s);
}
static BROTLI_NOINLINE BrotliDecoderErrorCode SafeProcessCommands(
BrotliDecoderState* s) {
return ProcessCommandsInternal(1, s);
}
BrotliDecoderResult BrotliDecoderDecompress(
size_t encoded_size,
const uint8_t encoded_buffer[BROTLI_ARRAY_PARAM(encoded_size)],
size_t* decoded_size,
uint8_t decoded_buffer[BROTLI_ARRAY_PARAM(*decoded_size)]) {
BrotliDecoderState s;
BrotliDecoderResult result;
size_t total_out = 0;
size_t available_in = encoded_size;
const uint8_t* next_in = encoded_buffer;
size_t available_out = *decoded_size;
uint8_t* next_out = decoded_buffer;
if (!BrotliDecoderStateInit(&s, 0, 0, 0)) {
return BROTLI_DECODER_RESULT_ERROR;
}
result = BrotliDecoderDecompressStream(
&s, &available_in, &next_in, &available_out, &next_out, &total_out);
*decoded_size = total_out;
BrotliDecoderStateCleanup(&s);
if (result != BROTLI_DECODER_RESULT_SUCCESS) {
result = BROTLI_DECODER_RESULT_ERROR;
}
return result;
}
- invalid input implies that the whole stream is invalid -> any amount of
input could be read and discarded
- when result is "needs more input", then at least one more byte is REQUIRED
to complete decoding; all input data MUST be consumed by decoder, so
client could swap the input buffer
- when result is "needs more output" decoder MUST ensure that it doesn't
hold more than 7 bits in bit reader; this saves client from swapping input
buffer ahead of time
- when result is "success" decoder MUST return all unused data back to input
buffer; this is possible because the invariant is held on enter */
BrotliDecoderResult BrotliDecoderDecompressStream(
BrotliDecoderState* s, size_t* available_in, const uint8_t** next_in,
size_t* available_out, uint8_t** next_out, size_t* total_out) {
BrotliDecoderErrorCode result = BROTLI_DECODER_SUCCESS;
BrotliBitReader* br = &s->br;
if (total_out) {
*total_out = s->partial_pos_out;
}
if ((int)s->error_code < 0) {
return BROTLI_DECODER_RESULT_ERROR;
}
if (*available_out && (!next_out || !*next_out)) {
return SaveErrorCode(
s, BROTLI_FAILURE(BROTLI_DECODER_ERROR_INVALID_ARGUMENTS));
}
if (!*available_out) next_out = 0;
if (s->buffer_length == 0) {
br->avail_in = *available_in;
br->next_in = *next_in;
} else {
be required to complete the transaction -> reading more data must be
done in a loop -> do it in a main loop. */
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
br->next_in = &s->buffer.u8[0];
}
for (;;) {
if (result != BROTLI_DECODER_SUCCESS) {
if (result == BROTLI_DECODER_NEEDS_MORE_INPUT) {
if (s->ringbuffer != 0) {
BrotliDecoderErrorCode intermediate_result = WriteRingBuffer(s,
available_out, next_out, total_out, BROTLI_TRUE);
if ((int)intermediate_result < 0) {
result = intermediate_result;
break;
}
}
if (s->buffer_length != 0) {
if (br->avail_in == 0) {
Accumulator contains less than 8 bits, because internal buffer
is expanded byte-by-byte until it is enough to complete read. */
s->buffer_length = 0;
result = BROTLI_DECODER_SUCCESS;
br->avail_in = *available_in;
br->next_in = *next_in;
continue;
} else if (*available_in != 0) {
input stream. */
result = BROTLI_DECODER_SUCCESS;
s->buffer.u8[s->buffer_length] = **next_in;
s->buffer_length++;
br->avail_in = s->buffer_length;
(*next_in)++;
(*available_in)--;
continue;
}
break;
} else {
*next_in = br->next_in;
*available_in = br->avail_in;
while (*available_in) {
s->buffer.u8[s->buffer_length] = **next_in;
s->buffer_length++;
(*next_in)++;
(*available_in)--;
}
break;
}
}
if (s->buffer_length != 0) {
it would result in "needs more input". Reset internal buffer. */
s->buffer_length = 0;
} else {
stream it has less than 8 bits in accumulator, so it is safe to
return unused accumulator bits there. */
BrotliBitReaderUnload(br);
*available_in = br->avail_in;
*next_in = br->next_in;
}
break;
}
switch (s->state) {
case BROTLI_STATE_UNINITED:
if (!BrotliWarmupBitReader(br)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
break;
}
result = DecodeWindowBits(s, br);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
if (s->large_window) {
s->state = BROTLI_STATE_LARGE_WINDOW_BITS;
break;
}
s->state = BROTLI_STATE_INITIALIZE;
break;
case BROTLI_STATE_LARGE_WINDOW_BITS:
if (!BrotliSafeReadBits(br, 6, &s->window_bits)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
break;
}
if (s->window_bits < BROTLI_LARGE_MIN_WBITS ||
s->window_bits > BROTLI_LARGE_MAX_WBITS) {
result = BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_WINDOW_BITS);
break;
}
s->state = BROTLI_STATE_INITIALIZE;
case BROTLI_STATE_INITIALIZE:
BROTLI_LOG_UINT(s->window_bits);
s->max_backward_distance = (1 << s->window_bits) - BROTLI_WINDOW_GAP;
s->block_type_trees = (HuffmanCode*)BROTLI_DECODER_ALLOC(s,
sizeof(HuffmanCode) * 3 *
(BROTLI_HUFFMAN_MAX_SIZE_258 + BROTLI_HUFFMAN_MAX_SIZE_26));
if (s->block_type_trees == 0) {
result = BROTLI_FAILURE(BROTLI_DECODER_ERROR_ALLOC_BLOCK_TYPE_TREES);
break;
}
s->block_len_trees =
s->block_type_trees + 3 * BROTLI_HUFFMAN_MAX_SIZE_258;
s->state = BROTLI_STATE_METABLOCK_BEGIN;
case BROTLI_STATE_METABLOCK_BEGIN:
BrotliDecoderStateMetablockBegin(s);
BROTLI_LOG_UINT(s->pos);
s->state = BROTLI_STATE_METABLOCK_HEADER;
case BROTLI_STATE_METABLOCK_HEADER:
result = DecodeMetaBlockLength(s, br);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
BROTLI_LOG_UINT(s->is_last_metablock);
BROTLI_LOG_UINT(s->meta_block_remaining_len);
BROTLI_LOG_UINT(s->is_metadata);
BROTLI_LOG_UINT(s->is_uncompressed);
if (s->is_metadata || s->is_uncompressed) {
if (!BrotliJumpToByteBoundary(br)) {
result = BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_PADDING_1);
break;
}
}
if (s->is_metadata) {
s->state = BROTLI_STATE_METADATA;
break;
}
if (s->meta_block_remaining_len == 0) {
s->state = BROTLI_STATE_METABLOCK_DONE;
break;
}
BrotliCalculateRingBufferSize(s);
if (s->is_uncompressed) {
s->state = BROTLI_STATE_UNCOMPRESSED;
break;
}
s->state = BROTLI_STATE_BEFORE_COMPRESSED_METABLOCK_HEADER;
case BROTLI_STATE_BEFORE_COMPRESSED_METABLOCK_HEADER: {
BrotliMetablockHeaderArena* h = &s->arena.header;
s->loop_counter = 0;
h->sub_loop_counter = 0;
h->symbol_lists =
&h->symbols_lists_array[BROTLI_HUFFMAN_MAX_CODE_LENGTH + 1];
h->substate_huffman = BROTLI_STATE_HUFFMAN_NONE;
h->substate_tree_group = BROTLI_STATE_TREE_GROUP_NONE;
h->substate_context_map = BROTLI_STATE_CONTEXT_MAP_NONE;
s->state = BROTLI_STATE_HUFFMAN_CODE_0;
}
case BROTLI_STATE_HUFFMAN_CODE_0:
if (s->loop_counter >= 3) {
s->state = BROTLI_STATE_METABLOCK_HEADER_2;
break;
}
result = DecodeVarLenUint8(s, br, &s->num_block_types[s->loop_counter]);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
s->num_block_types[s->loop_counter]++;
BROTLI_LOG_UINT(s->num_block_types[s->loop_counter]);
if (s->num_block_types[s->loop_counter] < 2) {
s->loop_counter++;
break;
}
s->state = BROTLI_STATE_HUFFMAN_CODE_1;
case BROTLI_STATE_HUFFMAN_CODE_1: {
uint32_t alphabet_size = s->num_block_types[s->loop_counter] + 2;
int tree_offset = s->loop_counter * BROTLI_HUFFMAN_MAX_SIZE_258;
result = ReadHuffmanCode(alphabet_size, alphabet_size,
&s->block_type_trees[tree_offset], NULL, s);
if (result != BROTLI_DECODER_SUCCESS) break;
s->state = BROTLI_STATE_HUFFMAN_CODE_2;
}
case BROTLI_STATE_HUFFMAN_CODE_2: {
uint32_t alphabet_size = BROTLI_NUM_BLOCK_LEN_SYMBOLS;
int tree_offset = s->loop_counter * BROTLI_HUFFMAN_MAX_SIZE_26;
result = ReadHuffmanCode(alphabet_size, alphabet_size,
&s->block_len_trees[tree_offset], NULL, s);
if (result != BROTLI_DECODER_SUCCESS) break;
s->state = BROTLI_STATE_HUFFMAN_CODE_3;
}
case BROTLI_STATE_HUFFMAN_CODE_3: {
int tree_offset = s->loop_counter * BROTLI_HUFFMAN_MAX_SIZE_26;
if (!SafeReadBlockLength(s, &s->block_length[s->loop_counter],
&s->block_len_trees[tree_offset], br)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
break;
}
BROTLI_LOG_UINT(s->block_length[s->loop_counter]);
s->loop_counter++;
s->state = BROTLI_STATE_HUFFMAN_CODE_0;
break;
}
case BROTLI_STATE_UNCOMPRESSED: {
result = CopyUncompressedBlockToOutput(
available_out, next_out, total_out, s);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
s->state = BROTLI_STATE_METABLOCK_DONE;
break;
}
case BROTLI_STATE_METADATA:
for (; s->meta_block_remaining_len > 0; --s->meta_block_remaining_len) {
uint32_t bits;
if (!BrotliSafeReadBits(br, 8, &bits)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
break;
}
}
if (result == BROTLI_DECODER_SUCCESS) {
s->state = BROTLI_STATE_METABLOCK_DONE;
}
break;
case BROTLI_STATE_METABLOCK_HEADER_2: {
uint32_t bits;
if (!BrotliSafeReadBits(br, 6, &bits)) {
result = BROTLI_DECODER_NEEDS_MORE_INPUT;
break;
}
s->distance_postfix_bits = bits & BitMask(2);
bits >>= 2;
s->num_direct_distance_codes = bits << s->distance_postfix_bits;
BROTLI_LOG_UINT(s->num_direct_distance_codes);
BROTLI_LOG_UINT(s->distance_postfix_bits);
s->context_modes =
(uint8_t*)BROTLI_DECODER_ALLOC(s, (size_t)s->num_block_types[0]);
if (s->context_modes == 0) {
result = BROTLI_FAILURE(BROTLI_DECODER_ERROR_ALLOC_CONTEXT_MODES);
break;
}
s->loop_counter = 0;
s->state = BROTLI_STATE_CONTEXT_MODES;
}
case BROTLI_STATE_CONTEXT_MODES:
result = ReadContextModes(s);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
s->state = BROTLI_STATE_CONTEXT_MAP_1;
case BROTLI_STATE_CONTEXT_MAP_1:
result = DecodeContextMap(
s->num_block_types[0] << BROTLI_LITERAL_CONTEXT_BITS,
&s->num_literal_htrees, &s->context_map, s);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
DetectTrivialLiteralBlockTypes(s);
s->state = BROTLI_STATE_CONTEXT_MAP_2;
case BROTLI_STATE_CONTEXT_MAP_2: {
uint32_t npostfix = s->distance_postfix_bits;
uint32_t ndirect = s->num_direct_distance_codes;
uint32_t distance_alphabet_size_max = BROTLI_DISTANCE_ALPHABET_SIZE(
npostfix, ndirect, BROTLI_MAX_DISTANCE_BITS);
uint32_t distance_alphabet_size_limit = distance_alphabet_size_max;
BROTLI_BOOL allocation_success = BROTLI_TRUE;
if (s->large_window) {
BrotliDistanceCodeLimit limit = BrotliCalculateDistanceCodeLimit(
BROTLI_MAX_ALLOWED_DISTANCE, npostfix, ndirect);
distance_alphabet_size_max = BROTLI_DISTANCE_ALPHABET_SIZE(
npostfix, ndirect, BROTLI_LARGE_MAX_DISTANCE_BITS);
distance_alphabet_size_limit = limit.max_alphabet_size;
}
result = DecodeContextMap(
s->num_block_types[2] << BROTLI_DISTANCE_CONTEXT_BITS,
&s->num_dist_htrees, &s->dist_context_map, s);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
allocation_success &= BrotliDecoderHuffmanTreeGroupInit(
s, &s->literal_hgroup, BROTLI_NUM_LITERAL_SYMBOLS,
BROTLI_NUM_LITERAL_SYMBOLS, s->num_literal_htrees);
allocation_success &= BrotliDecoderHuffmanTreeGroupInit(
s, &s->insert_copy_hgroup, BROTLI_NUM_COMMAND_SYMBOLS,
BROTLI_NUM_COMMAND_SYMBOLS, s->num_block_types[1]);
allocation_success &= BrotliDecoderHuffmanTreeGroupInit(
s, &s->distance_hgroup, distance_alphabet_size_max,
distance_alphabet_size_limit, s->num_dist_htrees);
if (!allocation_success) {
return SaveErrorCode(s,
BROTLI_FAILURE(BROTLI_DECODER_ERROR_ALLOC_TREE_GROUPS));
}
s->loop_counter = 0;
s->state = BROTLI_STATE_TREE_GROUP;
}
case BROTLI_STATE_TREE_GROUP: {
HuffmanTreeGroup* hgroup = NULL;
switch (s->loop_counter) {
case 0: hgroup = &s->literal_hgroup; break;
case 1: hgroup = &s->insert_copy_hgroup; break;
case 2: hgroup = &s->distance_hgroup; break;
default: return SaveErrorCode(s, BROTLI_FAILURE(
BROTLI_DECODER_ERROR_UNREACHABLE));
}
result = HuffmanTreeGroupDecode(hgroup, s);
if (result != BROTLI_DECODER_SUCCESS) break;
s->loop_counter++;
if (s->loop_counter < 3) {
break;
}
s->state = BROTLI_STATE_BEFORE_COMPRESSED_METABLOCK_BODY;
}
case BROTLI_STATE_BEFORE_COMPRESSED_METABLOCK_BODY:
PrepareLiteralDecoding(s);
s->dist_context_map_slice = s->dist_context_map;
s->htree_command = s->insert_copy_hgroup.htrees[0];
if (!BrotliEnsureRingBuffer(s)) {
result = BROTLI_FAILURE(BROTLI_DECODER_ERROR_ALLOC_RING_BUFFER_2);
break;
}
CalculateDistanceLut(s);
s->state = BROTLI_STATE_COMMAND_BEGIN;
case BROTLI_STATE_COMMAND_BEGIN:
case BROTLI_STATE_COMMAND_INNER:
case BROTLI_STATE_COMMAND_POST_DECODE_LITERALS:
case BROTLI_STATE_COMMAND_POST_WRAP_COPY:
result = ProcessCommands(s);
if (result == BROTLI_DECODER_NEEDS_MORE_INPUT) {
result = SafeProcessCommands(s);
}
break;
case BROTLI_STATE_COMMAND_INNER_WRITE:
case BROTLI_STATE_COMMAND_POST_WRITE_1:
case BROTLI_STATE_COMMAND_POST_WRITE_2:
result = WriteRingBuffer(
s, available_out, next_out, total_out, BROTLI_FALSE);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
WrapRingBuffer(s);
if (s->ringbuffer_size == 1 << s->window_bits) {
s->max_distance = s->max_backward_distance;
}
if (s->state == BROTLI_STATE_COMMAND_POST_WRITE_1) {
BrotliDecoderCompoundDictionary* addon = s->compound_dictionary;
if (addon && (addon->br_length != addon->br_copied)) {
s->pos += CopyFromCompoundDictionary(s, s->pos);
if (s->pos >= s->ringbuffer_size) continue;
}
if (s->meta_block_remaining_len == 0) {
s->state = BROTLI_STATE_METABLOCK_DONE;
} else {
s->state = BROTLI_STATE_COMMAND_BEGIN;
}
break;
} else if (s->state == BROTLI_STATE_COMMAND_POST_WRITE_2) {
s->state = BROTLI_STATE_COMMAND_POST_WRAP_COPY;
} else {
if (s->loop_counter == 0) {
if (s->meta_block_remaining_len == 0) {
s->state = BROTLI_STATE_METABLOCK_DONE;
} else {
s->state = BROTLI_STATE_COMMAND_POST_DECODE_LITERALS;
}
break;
}
s->state = BROTLI_STATE_COMMAND_INNER;
}
break;
case BROTLI_STATE_METABLOCK_DONE:
if (s->meta_block_remaining_len < 0) {
result = BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_BLOCK_LENGTH_2);
break;
}
BrotliDecoderStateCleanupAfterMetablock(s);
if (!s->is_last_metablock) {
s->state = BROTLI_STATE_METABLOCK_BEGIN;
break;
}
if (!BrotliJumpToByteBoundary(br)) {
result = BROTLI_FAILURE(BROTLI_DECODER_ERROR_FORMAT_PADDING_2);
break;
}
if (s->buffer_length == 0) {
BrotliBitReaderUnload(br);
*available_in = br->avail_in;
*next_in = br->next_in;
}
s->state = BROTLI_STATE_DONE;
case BROTLI_STATE_DONE:
if (s->ringbuffer != 0) {
result = WriteRingBuffer(
s, available_out, next_out, total_out, BROTLI_TRUE);
if (result != BROTLI_DECODER_SUCCESS) {
break;
}
}
return SaveErrorCode(s, result);
}
}
return SaveErrorCode(s, result);
}
BROTLI_BOOL BrotliDecoderHasMoreOutput(const BrotliDecoderState* s) {
if ((int)s->error_code < 0) {
return BROTLI_FALSE;
}
return TO_BROTLI_BOOL(
s->ringbuffer != 0 && UnwrittenBytes(s, BROTLI_FALSE) != 0);
}
const uint8_t* BrotliDecoderTakeOutput(BrotliDecoderState* s, size_t* size) {
uint8_t* result = 0;
size_t available_out = *size ? *size : 1u << 24;
size_t requested_out = available_out;
BrotliDecoderErrorCode status;
if ((s->ringbuffer == 0) || ((int)s->error_code < 0)) {
*size = 0;
return 0;
}
WrapRingBuffer(s);
status = WriteRingBuffer(s, &available_out, &result, 0, BROTLI_TRUE);
if (status == BROTLI_DECODER_SUCCESS ||
status == BROTLI_DECODER_NEEDS_MORE_OUTPUT) {
*size = requested_out - available_out;
} else {
BrotliDecoderDecompressStream, this is just a safeguard. */
if ((int)status < 0) SaveErrorCode(s, status);
*size = 0;
result = 0;
}
return result;
}
BROTLI_BOOL BrotliDecoderIsUsed(const BrotliDecoderState* s) {
return TO_BROTLI_BOOL(s->state != BROTLI_STATE_UNINITED ||
BrotliGetAvailableBits(&s->br) != 0);
}
BROTLI_BOOL BrotliDecoderIsFinished(const BrotliDecoderState* s) {
return TO_BROTLI_BOOL(s->state == BROTLI_STATE_DONE) &&
!BrotliDecoderHasMoreOutput(s);
}
BrotliDecoderErrorCode BrotliDecoderGetErrorCode(const BrotliDecoderState* s) {
return (BrotliDecoderErrorCode)s->error_code;
}
const char* BrotliDecoderErrorString(BrotliDecoderErrorCode c) {
switch (c) {
#define BROTLI_ERROR_CODE_CASE_(PREFIX, NAME, CODE) \
case BROTLI_DECODER ## PREFIX ## NAME: return #NAME;
#define BROTLI_NOTHING_
BROTLI_DECODER_ERROR_CODES_LIST(BROTLI_ERROR_CODE_CASE_, BROTLI_NOTHING_)
#undef BROTLI_ERROR_CODE_CASE_
#undef BROTLI_NOTHING_
default: return "INVALID";
}
}
uint32_t BrotliDecoderVersion() {
return BROTLI_VERSION;
}
#if defined(BROTLI_TEST)
BROTLI_BOOL SafeReadSymbolForTest(
const HuffmanCode*, BrotliBitReader*, uint32_t*);
BROTLI_BOOL SafeReadSymbolForTest(
const HuffmanCode* table, BrotliBitReader* br, uint32_t* result) {
return SafeReadSymbol(table, br, result);
}
void InverseMoveToFrontTransformForTest(
uint8_t*, uint32_t, BrotliDecoderState*);
void InverseMoveToFrontTransformForTest(
uint8_t* v, uint32_t l, BrotliDecoderState* s) {
InverseMoveToFrontTransform(v, l, s);
}
#endif
#if defined(__cplusplus) || defined(c_plusplus)
}
#endif
