示例#1
0
/**
 * Allocate and initialize the receivers internal structures.
 * @return true on success, false on failure.
 */
bool
MM_ParallelSweepChunkArray::initialize(MM_EnvironmentBase* env, bool useVmem)
{
	bool result = false;
	MM_GCExtensionsBase* extensions = env->getExtensions();

	_useVmem = useVmem;

	if (extensions->isFvtestForceSweepChunkArrayCommitFailure()) {
		Trc_MM_SweepHeapSectioning_parallelSweepChunkArrayCommitFailureForced(env->getLanguageVMThread());
	} else {
		if (useVmem) {
			MM_MemoryManager* memoryManager = extensions->memoryManager;
			if (memoryManager->createVirtualMemoryForMetadata(env, &_memoryHandle, extensions->heapAlignment, _size * sizeof(MM_ParallelSweepChunk))) {
				void* base = memoryManager->getHeapBase(&_memoryHandle);
				result = memoryManager->commitMemory(&_memoryHandle, base, _size * sizeof(MM_ParallelSweepChunk));
				if (!result) {
					Trc_MM_SweepHeapSectioning_parallelSweepChunkArrayCommitFailed(env->getLanguageVMThread(), base, _size * sizeof(MM_ParallelSweepChunk));
				}
				_array = (MM_ParallelSweepChunk*)base;
			}
		} else {
			if (0 != _size) {
				_array = (MM_ParallelSweepChunk*)env->getForge()->allocate(_size * sizeof(MM_ParallelSweepChunk), MM_AllocationCategory::FIXED, OMR_GET_CALLSITE());
				result = (NULL != _array);
			} else {
				result = true;
			}
		}
	}
	return result;
}
示例#2
0
/**
 * Attach a physical arena of the specified size to the receiver.
 * This reserves the address space within the receiver for the arena, and connects the arena to the list
 * of those associated to the receiver (in address order).
 * 
 * @return true if the arena was attached successfully, false otherwise.
 * @note The memory reseved is not commited.
 */
bool
MM_HeapVirtualMemory::attachArena(MM_EnvironmentBase* env, MM_PhysicalArena* arena, uintptr_t size)
{
	/* Sanity check of the size */
	if (getMaximumMemorySize() < size) {
		return false;
	}

	MM_GCExtensionsBase* extensions = env->getExtensions();
	MM_MemoryManager* memoryManager = extensions->memoryManager;

	/* Find the insertion point for the currentArena */
	void* candidateBase = memoryManager->getHeapBase(&_vmemHandle);
	MM_PhysicalArena* insertionHead = NULL;
	MM_PhysicalArena* insertionTail = _physicalArena;
	MM_PhysicalArena* currentArena = arena;

	while (insertionTail) {
		if ((((uintptr_t)insertionTail->getLowAddress()) - ((uintptr_t)candidateBase)) >= size) {
			break;
		}

		candidateBase = insertionTail->getHighAddress();

		insertionHead = insertionTail;
		insertionTail = insertionTail->getNextArena();
	}

	/* If we have reached the end of the currentArena list, check if there is room between the candidateBase
	 * and the end of virtual memory */
	if (!insertionTail) {
		if ((memoryManager->calculateOffsetToHeapTop(&_vmemHandle, candidateBase)) < size) {
			return false;
		}
	}

	/* Connect the physical currentArena into the list at the appropriate point */
	currentArena->setPreviousArena(insertionHead);
	currentArena->setNextArena(insertionTail);

	if (insertionTail) {
		insertionTail->setPreviousArena(currentArena);
	}

	if (insertionHead) {
		insertionHead->setNextArena(currentArena);
	} else {
		_physicalArena = currentArena;
	}

	currentArena->setLowAddress(candidateBase);
	currentArena->setHighAddress((void*)(((uint8_t*)candidateBase) + size));

	/* Set the arena state to being attached */
	arena->setAttached(true);

	return true;
}
示例#3
0
bool
MM_HeapRegionManagerTarok::enableRegionsInTable(MM_EnvironmentBase *env, MM_MemoryHandle *handle)
{
	bool result = true;
	MM_GCExtensionsBase *extensions = env->getExtensions();
	MM_MemoryManager *memoryManager = extensions->memoryManager;
	void *lowHeapEdge = memoryManager->getHeapBase(handle);
	void *highHeapEdge = memoryManager->getHeapTop(handle);
	
	/* maintained for RTJ */
	setNodeAndLinkRegions(env, lowHeapEdge, highHeapEdge, 0);

	return result;
}
示例#4
0
bool
MM_HeapVirtualMemory::initializeHeapRegionManager(MM_EnvironmentBase* env, MM_HeapRegionManager* manager)
{
	bool result = false;

	/* since this kind of heap is backed by contiguous memory, tell the heap region manager (which was just
	 * initialized by super) that we want to enable this range of regions for later use.
	 */
	MM_MemoryManager* memoryManager = MM_GCExtensionsBase::getExtensions(_omrVM)->memoryManager;
	void* heapBase = memoryManager->getHeapBase(&_vmemHandle);
	void* heapTop = memoryManager->getHeapTop(&_vmemHandle);

	if (manager->setContiguousHeapRange(env, heapBase, heapTop)) {
		result = manager->enableRegionsInTable(env, &_vmemHandle);
	}

	return result;
}
示例#5
0
/**
 * Find and return the backing store addresses base.
 * This routine uses the backing store of the base array and uses this memory as the return value.
 * @return base address of the backing store.
 */
void*
MM_SweepHeapSectioning::getBackingStoreAddress()
{
	MM_MemoryManager* memoryManager = _extensions->memoryManager;
	return (void*)memoryManager->getHeapBase(&_baseArray->_memoryHandle);
}
示例#6
0
/**
 * Answer the lowest possible address for the heap that will ever be possible.
 * @return Lowest address possible for the heap.
 */
void*
MM_HeapVirtualMemory::getHeapBase()
{
	MM_MemoryManager* memoryManager = MM_GCExtensionsBase::getExtensions(_omrVM)->memoryManager;
	return memoryManager->getHeapBase(&_vmemHandle);
}