brotli/c/enc/memory.c
Eugene Kliuchnikov 35e69fc7cf
New feature: "Large Window Brotli" (#640)
* New feature: "Large Window Brotli"

By setting special encoder/decoder flag it is now possible to extend
LZ-window up to 30 bits; though produced stream will not be RFC7932
compliant.

Added new dictionary generator - "DSH". It combines speed of "Sieve"
and quality of "DM". Plus utilities to prepare train corpora
(remove unique strings).

Improved compression ratio: now two sub-blocks could be stitched:
the last copy command could be extended to span the next sub-block.

Fixed compression ineffectiveness caused by floating numbers rounding and
wrong cost heuristic.

Other C changes:
 - combined / moved `context.h` to `common`
 - moved transforms to `common`
 - unified some aspects of code formatting
 - added an abstraction for encoder (static) dictionary
 - moved default allocator/deallocator functions to `common`

brotli CLI:
 - window size is auto-adjusted if not specified explicitly

Java:
 - added "eager" decoding both to JNI wrapper and pure decoder
 - huge speed-up of `DictionaryData` initialization

* Add dictionaryless compressed dictionary

* Fix `sources.lst`

* Fix `sources.lst` and add a note that `libtool` is also required.

* Update setup.py

* Fix `EagerStreamTest`

* Fix BUILD file

* Add missing `libdivsufsort` dependency

* Fix "unused parameter" warning.
2018-02-26 09:04:36 -05:00

171 lines
4.8 KiB
C

/* Copyright 2015 Google Inc. All Rights Reserved.
Distributed under MIT license.
See file LICENSE for detail or copy at https://opensource.org/licenses/MIT
*/
/* Algorithms for distributing the literals and commands of a metablock between
block types and contexts. */
#include "./memory.h"
#include <stdlib.h> /* exit, free, malloc */
#include <string.h> /* memcpy */
#include "../common/platform.h"
#include <brotli/types.h>
#if defined(__cplusplus) || defined(c_plusplus)
extern "C" {
#endif
#define MAX_PERM_ALLOCATED 128
#define MAX_NEW_ALLOCATED 64
#define MAX_NEW_FREED 64
#define PERM_ALLOCATED_OFFSET 0
#define NEW_ALLOCATED_OFFSET MAX_PERM_ALLOCATED
#define NEW_FREED_OFFSET (MAX_PERM_ALLOCATED + MAX_NEW_ALLOCATED)
void BrotliInitMemoryManager(
MemoryManager* m, brotli_alloc_func alloc_func, brotli_free_func free_func,
void* opaque) {
if (!alloc_func) {
m->alloc_func = BrotliDefaultAllocFunc;
m->free_func = BrotliDefaultFreeFunc;
m->opaque = 0;
} else {
m->alloc_func = alloc_func;
m->free_func = free_func;
m->opaque = opaque;
}
#if !defined(BROTLI_ENCODER_EXIT_ON_OOM)
m->is_oom = BROTLI_FALSE;
m->perm_allocated = 0;
m->new_allocated = 0;
m->new_freed = 0;
#endif /* BROTLI_ENCODER_EXIT_ON_OOM */
}
#if defined(BROTLI_ENCODER_EXIT_ON_OOM)
void* BrotliAllocate(MemoryManager* m, size_t n) {
void* result = m->alloc_func(m->opaque, n);
if (!result) exit(EXIT_FAILURE);
return result;
}
void BrotliFree(MemoryManager* m, void* p) {
m->free_func(m->opaque, p);
}
void BrotliWipeOutMemoryManager(MemoryManager* m) {
BROTLI_UNUSED(m);
}
#else /* BROTLI_ENCODER_EXIT_ON_OOM */
static void SortPointers(void** items, const size_t n) {
/* Shell sort. */
static const size_t gaps[] = {23, 10, 4, 1};
int g = 0;
for (; g < 4; ++g) {
size_t gap = gaps[g];
size_t i;
for (i = gap; i < n; ++i) {
size_t j = i;
void* tmp = items[i];
for (; j >= gap && tmp < items[j - gap]; j -= gap) {
items[j] = items[j - gap];
}
items[j] = tmp;
}
}
}
static size_t Annihilate(void** a, size_t a_len, void** b, size_t b_len) {
size_t a_read_index = 0;
size_t b_read_index = 0;
size_t a_write_index = 0;
size_t b_write_index = 0;
size_t annihilated = 0;
while (a_read_index < a_len && b_read_index < b_len) {
if (a[a_read_index] == b[b_read_index]) {
a_read_index++;
b_read_index++;
annihilated++;
} else if (a[a_read_index] < b[b_read_index]) {
a[a_write_index++] = a[a_read_index++];
} else {
b[b_write_index++] = b[b_read_index++];
}
}
while (a_read_index < a_len) a[a_write_index++] = a[a_read_index++];
while (b_read_index < b_len) b[b_write_index++] = b[b_read_index++];
return annihilated;
}
static void CollectGarbagePointers(MemoryManager* m) {
size_t annihilated;
SortPointers(m->pointers + NEW_ALLOCATED_OFFSET, m->new_allocated);
SortPointers(m->pointers + NEW_FREED_OFFSET, m->new_freed);
annihilated = Annihilate(
m->pointers + NEW_ALLOCATED_OFFSET, m->new_allocated,
m->pointers + NEW_FREED_OFFSET, m->new_freed);
m->new_allocated -= annihilated;
m->new_freed -= annihilated;
if (m->new_freed != 0) {
annihilated = Annihilate(
m->pointers + PERM_ALLOCATED_OFFSET, m->perm_allocated,
m->pointers + NEW_FREED_OFFSET, m->new_freed);
m->perm_allocated -= annihilated;
m->new_freed -= annihilated;
BROTLI_DCHECK(m->new_freed == 0);
}
if (m->new_allocated != 0) {
BROTLI_DCHECK(m->perm_allocated + m->new_allocated <= MAX_PERM_ALLOCATED);
memcpy(m->pointers + PERM_ALLOCATED_OFFSET + m->perm_allocated,
m->pointers + NEW_ALLOCATED_OFFSET,
sizeof(void*) * m->new_allocated);
m->perm_allocated += m->new_allocated;
m->new_allocated = 0;
SortPointers(m->pointers + PERM_ALLOCATED_OFFSET, m->perm_allocated);
}
}
void* BrotliAllocate(MemoryManager* m, size_t n) {
void* result = m->alloc_func(m->opaque, n);
if (!result) {
m->is_oom = BROTLI_TRUE;
return NULL;
}
if (m->new_allocated == MAX_NEW_ALLOCATED) CollectGarbagePointers(m);
m->pointers[NEW_ALLOCATED_OFFSET + (m->new_allocated++)] = result;
return result;
}
void BrotliFree(MemoryManager* m, void* p) {
if (!p) return;
m->free_func(m->opaque, p);
if (m->new_freed == MAX_NEW_FREED) CollectGarbagePointers(m);
m->pointers[NEW_FREED_OFFSET + (m->new_freed++)] = p;
}
void BrotliWipeOutMemoryManager(MemoryManager* m) {
size_t i;
CollectGarbagePointers(m);
/* Now all unfreed pointers are in perm-allocated list. */
for (i = 0; i < m->perm_allocated; ++i) {
m->free_func(m->opaque, m->pointers[PERM_ALLOCATED_OFFSET + i]);
}
m->perm_allocated = 0;
}
#endif /* BROTLI_ENCODER_EXIT_ON_OOM */
#if defined(__cplusplus) || defined(c_plusplus)
} /* extern "C" */
#endif