src/third_party/mozjs/js/src/ds/LifoAlloc.cpp - cobalt - Git at Google

 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
  * vim: set ts=8 sts=4 et sw=4 tw=99:
  * This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

 #include "LifoAlloc.h"

 using namespace js;

 namespace js {
 namespace detail {

 BumpChunk *
 BumpChunk::new_(size_t chunkSize)
 {
     JS_ASSERT(RoundUpPow2(chunkSize) == chunkSize);
     void *mem = js_malloc(chunkSize);
     if (!mem)
         return NULL;
     BumpChunk *result = new (mem) BumpChunk(chunkSize - sizeof(BumpChunk));

     // We assume that the alignment of sAlign is less than that of
     // the underlying memory allocator -- creating a new BumpChunk should
     // always satisfy the sAlign alignment constraint.
     JS_ASSERT(AlignPtr(result->bump) == result->bump);
     return result;
 }

 void
 BumpChunk::delete_(BumpChunk *chunk)
 {
 #ifdef DEBUG
     // Part of the chunk may have been marked as poisoned/noaccess.  Undo that
     // before writing the 0xcd bytes.
     size_t size = sizeof(*chunk) + chunk->bumpSpaceSize;
     MOZ_MAKE_MEM_UNDEFINED(chunk, size);
     memset(chunk, 0xcd, size);
 #endif
     js_free(chunk);
 }

 bool
 BumpChunk::canAlloc(size_t n)
 {
     char *aligned = AlignPtr(bump);
     char *bumped = aligned + n;
     return bumped <= limit && bumped > headerBase();
 }

 } // namespace detail
 } // namespace js

 void
 LifoAlloc::freeAll()
 {
     while (first) {
         BumpChunk *victim = first;
         first = first->next();
         decrementCurSize(victim->computedSizeOfIncludingThis());
         BumpChunk::delete_(victim);
     }
     first = latest = last = NULL;

     // Nb: maintaining curSize_ correctly isn't easy.  Fortunately, this is an
     // excellent sanity check.
     JS_ASSERT(curSize_ == 0);
 }

 LifoAlloc::BumpChunk *
 LifoAlloc::getOrCreateChunk(size_t n)
 {
     if (first) {
         // Look for existing, unused BumpChunks to satisfy the request.
         while (latest->next()) {
             latest = latest->next();
             latest->resetBump();    // This was an unused BumpChunk on the chain.
             if (latest->canAlloc(n))
                 return latest;
         }
     }

     size_t defaultChunkFreeSpace = defaultChunkSize_ - sizeof(BumpChunk);
     size_t chunkSize;
     if (n > defaultChunkFreeSpace) {
         size_t allocSizeWithHeader = n + sizeof(BumpChunk);

         // Guard for overflow.
         if (allocSizeWithHeader < n ||
             (allocSizeWithHeader & (size_t(1) << (tl::BitSize<size_t>::result - 1)))) {
             return NULL;
         }

         chunkSize = RoundUpPow2(allocSizeWithHeader);
     } else {
         chunkSize = defaultChunkSize_;
     }

     // If we get here, we couldn't find an existing BumpChunk to fill the request.
     BumpChunk *newChunk = BumpChunk::new_(chunkSize);
     if (!newChunk)
         return NULL;
     if (!first) {
         latest = first = last = newChunk;
     } else {
         JS_ASSERT(latest && !latest->next());
         latest->setNext(newChunk);
         latest = last = newChunk;
     }

     size_t computedChunkSize = newChunk->computedSizeOfIncludingThis();
     JS_ASSERT(computedChunkSize == chunkSize);
     incrementCurSize(computedChunkSize);

     return newChunk;
 }

 void
 LifoAlloc::transferFrom(LifoAlloc *other)
 {
     JS_ASSERT(!markCount);
     JS_ASSERT(latest == first);
     JS_ASSERT(!other->markCount);

     if (!other->first)
         return;

     incrementCurSize(other->curSize_);
     append(other->first, other->last);
     other->first = other->last = other->latest = NULL;
     other->curSize_ = 0;
 }

 void
 LifoAlloc::transferUnusedFrom(LifoAlloc *other)
 {
     JS_ASSERT(!markCount);
     JS_ASSERT(latest == first);

     if (other->markCount || !other->first)
         return;

     // Transfer all chunks *after* |latest|.

     if (other->latest->next()) {
         if (other->latest == other->first) {
             // We're transferring everything except the first chunk.
             size_t delta = other->curSize_ - other->first->computedSizeOfIncludingThis();
             other->decrementCurSize(delta);
             incrementCurSize(delta);
         } else {
             for (BumpChunk *chunk = other->latest->next(); chunk; chunk = chunk->next()) {
                 size_t size = chunk->computedSizeOfIncludingThis();
                 incrementCurSize(size);
                 other->decrementCurSize(size);
             }
         }

         append(other->latest->next(), other->last);
         other->latest->setNext(NULL);
         other->last = other->latest;
     }
 }
	/* -- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 --
	* vim: set ts=8 sts=4 et sw=4 tw=99:
	* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */

	#include "LifoAlloc.h"

	using namespace js;

	namespace js {
	namespace detail {

	BumpChunk *
	BumpChunk::new_(size_t chunkSize)
	{
	JS_ASSERT(RoundUpPow2(chunkSize) == chunkSize);
	void *mem = js_malloc(chunkSize);
	if (!mem)
	return NULL;
	BumpChunk *result = new (mem) BumpChunk(chunkSize - sizeof(BumpChunk));

	// We assume that the alignment of sAlign is less than that of
	// the underlying memory allocator -- creating a new BumpChunk should
	// always satisfy the sAlign alignment constraint.
	JS_ASSERT(AlignPtr(result->bump) == result->bump);
	return result;
	}

	void
	BumpChunk::delete_(BumpChunk *chunk)
	{
	#ifdef DEBUG
	// Part of the chunk may have been marked as poisoned/noaccess. Undo that
	// before writing the 0xcd bytes.
	size_t size = sizeof(*chunk) + chunk->bumpSpaceSize;
	MOZ_MAKE_MEM_UNDEFINED(chunk, size);
	memset(chunk, 0xcd, size);
	#endif
	js_free(chunk);
	}

	bool
	BumpChunk::canAlloc(size_t n)
	{
	char *aligned = AlignPtr(bump);
	char *bumped = aligned + n;
	return bumped <= limit && bumped > headerBase();
	}

	} // namespace detail
	} // namespace js

	void
	LifoAlloc::freeAll()
	{
	while (first) {
	BumpChunk *victim = first;
	first = first->next();
	decrementCurSize(victim->computedSizeOfIncludingThis());
	BumpChunk::delete_(victim);
	}
	first = latest = last = NULL;

	// Nb: maintaining curSize_ correctly isn't easy. Fortunately, this is an
	// excellent sanity check.
	JS_ASSERT(curSize_ == 0);
	}

	LifoAlloc::BumpChunk *
	LifoAlloc::getOrCreateChunk(size_t n)
	{
	if (first) {
	// Look for existing, unused BumpChunks to satisfy the request.
	while (latest->next()) {
	latest = latest->next();
	latest->resetBump(); // This was an unused BumpChunk on the chain.
	if (latest->canAlloc(n))
	return latest;
	}
	}

	size_t defaultChunkFreeSpace = defaultChunkSize_ - sizeof(BumpChunk);
	size_t chunkSize;
	if (n > defaultChunkFreeSpace) {
	size_t allocSizeWithHeader = n + sizeof(BumpChunk);

	// Guard for overflow.
	if (allocSizeWithHeader < n \|\|
	(allocSizeWithHeader & (size_t(1) << (tl::BitSize<size_t>::result - 1)))) {
	return NULL;
	}

	chunkSize = RoundUpPow2(allocSizeWithHeader);
	} else {
	chunkSize = defaultChunkSize_;
	}

	// If we get here, we couldn't find an existing BumpChunk to fill the request.
	BumpChunk *newChunk = BumpChunk::new_(chunkSize);
	if (!newChunk)
	return NULL;
	if (!first) {
	latest = first = last = newChunk;
	} else {
	JS_ASSERT(latest && !latest->next());
	latest->setNext(newChunk);
	latest = last = newChunk;
	}

	size_t computedChunkSize = newChunk->computedSizeOfIncludingThis();
	JS_ASSERT(computedChunkSize == chunkSize);
	incrementCurSize(computedChunkSize);

	return newChunk;
	}

	void
	LifoAlloc::transferFrom(LifoAlloc *other)
	{
	JS_ASSERT(!markCount);
	JS_ASSERT(latest == first);
	JS_ASSERT(!other->markCount);

	if (!other->first)
	return;

	incrementCurSize(other->curSize_);
	append(other->first, other->last);
	other->first = other->last = other->latest = NULL;
	other->curSize_ = 0;
	}

	void
	LifoAlloc::transferUnusedFrom(LifoAlloc *other)
	{
	JS_ASSERT(!markCount);
	JS_ASSERT(latest == first);

	if (other->markCount \|\| !other->first)
	return;

	// Transfer all chunks after \|latest\|.

	if (other->latest->next()) {
	if (other->latest == other->first) {
	// We're transferring everything except the first chunk.
	size_t delta = other->curSize_ - other->first->computedSizeOfIncludingThis();
	other->decrementCurSize(delta);
	incrementCurSize(delta);
	} else {
	for (BumpChunk *chunk = other->latest->next(); chunk; chunk = chunk->next()) {
	size_t size = chunk->computedSizeOfIncludingThis();
	incrementCurSize(size);
	other->decrementCurSize(size);
	}
	}

	append(other->latest->next(), other->last);
	other->latest->setNext(NULL);
	other->last = other->latest;
	}
	}