BaseTools/Source/C/BrotliCompress/enc/memory.c - edk2 - Git at Google

 /* 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 <assert.h>
 #include <stdlib.h>  /* exit, free, malloc */
 #include <string.h>  /* memcpy */

 #include "../common/types.h"
 #include "./port.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)

 static void* DefaultAllocFunc(void* opaque, size_t size) {
   BROTLI_UNUSED(opaque);
   return malloc(size);
 }

 static void DefaultFreeFunc(void* opaque, void* address) {
   BROTLI_UNUSED(opaque);
   free(address);
 }

 void BrotliInitMemoryManager(
     MemoryManager* m, brotli_alloc_func alloc_func, brotli_free_func free_func,
     void* opaque) {
   if (!alloc_func) {
     m->alloc_func = DefaultAllocFunc;
     m->free_func = DefaultFreeFunc;
     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;
     assert(m->new_freed == 0);
   }

   if (m->new_allocated != 0) {
     assert(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
	/* 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 <assert.h>
	#include <stdlib.h> /* exit, free, malloc */
	#include <string.h> /* memcpy */

	#include "../common/types.h"
	#include "./port.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)

	static void* DefaultAllocFunc(void* opaque, size_t size) {
	BROTLI_UNUSED(opaque);
	return malloc(size);
	}

	static void DefaultFreeFunc(void* opaque, void* address) {
	BROTLI_UNUSED(opaque);
	free(address);
	}

	void BrotliInitMemoryManager(
	MemoryManager* m, brotli_alloc_func alloc_func, brotli_free_func free_func,
	void* opaque) {
	if (!alloc_func) {
	m->alloc_func = DefaultAllocFunc;
	m->free_func = DefaultFreeFunc;
	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;
	assert(m->new_freed == 0);
	}

	if (m->new_allocated != 0) {
	assert(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