Pool sub-allocated resource heaps.

Allow resource heaps to be recycled when
no longer used.

BUG=dawn:496

Change-Id: I36518f8b0c0b26d2cceecc4e7b05e00a5fd5bd25
Reviewed-on: https://dawn-review.googlesource.com/c/dawn/+/26126
Reviewed-by: Corentin Wallez <cwallez@chromium.org>
Reviewed-by: Austin Eng <enga@chromium.org>
Commit-Queue: Bryan Bernhart <bryan.bernhart@intel.com>
This commit is contained in:
Bryan Bernhart 2020-08-17 17:47:15 +00:00 committed by Commit Bot service account
parent 5e9b29fab9
commit 988f19e208
11 changed files with 257 additions and 3 deletions

View File

@ -228,6 +228,8 @@ source_set("dawn_native_sources") {
"Pipeline.h", "Pipeline.h",
"PipelineLayout.cpp", "PipelineLayout.cpp",
"PipelineLayout.h", "PipelineLayout.h",
"PooledResourceMemoryAllocator.cpp",
"PooledResourceMemoryAllocator.h",
"ProgrammablePassEncoder.cpp", "ProgrammablePassEncoder.cpp",
"ProgrammablePassEncoder.h", "ProgrammablePassEncoder.h",
"QuerySet.cpp", "QuerySet.cpp",

View File

@ -103,6 +103,8 @@ target_sources(dawn_native PRIVATE
"Pipeline.h" "Pipeline.h"
"PipelineLayout.cpp" "PipelineLayout.cpp"
"PipelineLayout.h" "PipelineLayout.h"
"PooledResourceMemoryAllocator.cpp"
"PooledResourceMemoryAllocator.h"
"ProgrammablePassEncoder.cpp" "ProgrammablePassEncoder.cpp"
"ProgrammablePassEncoder.h" "ProgrammablePassEncoder.h"
"QuerySet.cpp" "QuerySet.cpp"

View File

@ -0,0 +1,60 @@
// Copyright 2020 The Dawn Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "dawn_native/PooledResourceMemoryAllocator.h"
#include "dawn_native/Device.h"
namespace dawn_native {
PooledResourceMemoryAllocator::PooledResourceMemoryAllocator(
ResourceHeapAllocator* heapAllocator)
: mHeapAllocator(heapAllocator) {
}
void PooledResourceMemoryAllocator::DestroyPool() {
for (auto& resourceHeap : mPool) {
ASSERT(resourceHeap != nullptr);
mHeapAllocator->DeallocateResourceHeap(std::move(resourceHeap));
}
mPool.clear();
}
ResultOrError<std::unique_ptr<ResourceHeapBase>>
PooledResourceMemoryAllocator::AllocateResourceHeap(uint64_t size) {
// Pooled memory is LIFO because memory can be evicted by LRU. However, this means
// pooling is disabled in-frame when the memory is still pending. For high in-frame
// memory users, FIFO might be preferable when memory consumption is a higher priority.
std::unique_ptr<ResourceHeapBase> memory;
if (!mPool.empty()) {
memory = std::move(mPool.front());
mPool.pop_front();
}
if (memory == nullptr) {
DAWN_TRY_ASSIGN(memory, mHeapAllocator->AllocateResourceHeap(size));
}
return std::move(memory);
}
void PooledResourceMemoryAllocator::DeallocateResourceHeap(
std::unique_ptr<ResourceHeapBase> allocation) {
mPool.push_front(std::move(allocation));
}
uint64_t PooledResourceMemoryAllocator::GetPoolSizeForTesting() const {
return mPool.size();
}
} // namespace dawn_native

View File

@ -0,0 +1,53 @@
// Copyright 2020 The Dawn Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#ifndef DAWNNATIVE_POOLEDRESOURCEMEMORYALLOCATOR_H_
#define DAWNNATIVE_POOLEDRESOURCEMEMORYALLOCATOR_H_
#include "common/SerialQueue.h"
#include "dawn_native/ResourceHeapAllocator.h"
#include <deque>
namespace dawn_native {
class DeviceBase;
// |PooledResourceMemoryAllocator| allocates a fixed-size resource memory from a resource memory
// pool. Internally, it manages a list of heaps using LIFO (newest heaps are recycled first).
// The heap is in one of two states: AVAILABLE or not. Upon de-allocate, the heap is returned
// the pool and made AVAILABLE.
class PooledResourceMemoryAllocator : public ResourceHeapAllocator {
public:
PooledResourceMemoryAllocator(ResourceHeapAllocator* heapAllocator);
~PooledResourceMemoryAllocator() override = default;
ResultOrError<std::unique_ptr<ResourceHeapBase>> AllocateResourceHeap(
uint64_t size) override;
void DeallocateResourceHeap(std::unique_ptr<ResourceHeapBase> allocation) override;
void DestroyPool();
// For testing purposes.
uint64_t GetPoolSizeForTesting() const;
private:
ResourceHeapAllocator* mHeapAllocator = nullptr;
std::deque<std::unique_ptr<ResourceHeapBase>> mPool;
};
} // namespace dawn_native
#endif // DAWNNATIVE_POOLEDRESOURCEMEMORYALLOCATOR_H_

View File

@ -570,8 +570,11 @@ namespace dawn_native { namespace d3d12 {
::CloseHandle(mFenceEvent); ::CloseHandle(mFenceEvent);
} }
// Release recycled resource heaps.
mResourceAllocatorManager->DestroyPool();
// We need to handle clearing up com object refs that were enqeued after TickImpl // We need to handle clearing up com object refs that were enqeued after TickImpl
mUsedComObjectRefs.ClearUpTo(GetCompletedCommandSerial()); mUsedComObjectRefs.ClearUpTo(std::numeric_limits<Serial>::max());
ASSERT(mUsedComObjectRefs.Empty()); ASSERT(mUsedComObjectRefs.Empty());
ASSERT(!mPendingCommands.IsOpen()); ASSERT(!mPendingCommands.IsOpen());

View File

@ -172,8 +172,10 @@ namespace dawn_native { namespace d3d12 {
mHeapAllocators[i] = std::make_unique<HeapAllocator>( mHeapAllocators[i] = std::make_unique<HeapAllocator>(
mDevice, GetD3D12HeapType(resourceHeapKind), GetD3D12HeapFlags(resourceHeapKind), mDevice, GetD3D12HeapType(resourceHeapKind), GetD3D12HeapFlags(resourceHeapKind),
GetMemorySegment(device, GetD3D12HeapType(resourceHeapKind))); GetMemorySegment(device, GetD3D12HeapType(resourceHeapKind)));
mPooledHeapAllocators[i] =
std::make_unique<PooledResourceMemoryAllocator>(mHeapAllocators[i].get());
mSubAllocatedResourceAllocators[i] = std::make_unique<BuddyMemoryAllocator>( mSubAllocatedResourceAllocators[i] = std::make_unique<BuddyMemoryAllocator>(
kMaxHeapSize, kMinHeapSize, mHeapAllocators[i].get()); kMaxHeapSize, kMinHeapSize, mPooledHeapAllocators[i].get());
} }
} }
@ -396,4 +398,10 @@ namespace dawn_native { namespace d3d12 {
/*offset*/ 0, std::move(committedResource), heap}; /*offset*/ 0, std::move(committedResource), heap};
} }
void ResourceAllocatorManager::DestroyPool() {
for (auto& alloc : mPooledHeapAllocators) {
alloc->DestroyPool();
}
}
}} // namespace dawn_native::d3d12 }} // namespace dawn_native::d3d12

View File

@ -17,6 +17,7 @@
#include "common/SerialQueue.h" #include "common/SerialQueue.h"
#include "dawn_native/BuddyMemoryAllocator.h" #include "dawn_native/BuddyMemoryAllocator.h"
#include "dawn_native/PooledResourceMemoryAllocator.h"
#include "dawn_native/d3d12/HeapAllocatorD3D12.h" #include "dawn_native/d3d12/HeapAllocatorD3D12.h"
#include "dawn_native/d3d12/ResourceHeapAllocationD3D12.h" #include "dawn_native/d3d12/ResourceHeapAllocationD3D12.h"
@ -67,6 +68,8 @@ namespace dawn_native { namespace d3d12 {
void Tick(Serial lastCompletedSerial); void Tick(Serial lastCompletedSerial);
void DestroyPool();
private: private:
void FreeMemory(ResourceHeapAllocation& allocation); void FreeMemory(ResourceHeapAllocation& allocation);
@ -92,6 +95,9 @@ namespace dawn_native { namespace d3d12 {
mSubAllocatedResourceAllocators; mSubAllocatedResourceAllocators;
std::array<std::unique_ptr<HeapAllocator>, ResourceHeapKind::EnumCount> mHeapAllocators; std::array<std::unique_ptr<HeapAllocator>, ResourceHeapKind::EnumCount> mHeapAllocators;
std::array<std::unique_ptr<PooledResourceMemoryAllocator>, ResourceHeapKind::EnumCount>
mPooledHeapAllocators;
SerialQueue<ResourceHeapAllocation> mAllocationsToDelete; SerialQueue<ResourceHeapAllocation> mAllocationsToDelete;
}; };

View File

@ -888,6 +888,9 @@ namespace dawn_native { namespace vulkan {
mResourceMemoryAllocator->Tick(GetCompletedCommandSerial()); mResourceMemoryAllocator->Tick(GetCompletedCommandSerial());
mDeleter->Tick(GetCompletedCommandSerial()); mDeleter->Tick(GetCompletedCommandSerial());
// Allow recycled memory to be deleted.
mResourceMemoryAllocator->DestroyPool();
// The VkRenderPasses in the cache can be destroyed immediately since all commands referring // The VkRenderPasses in the cache can be destroyed immediately since all commands referring
// to them are guaranteed to be finished executing. // to them are guaranteed to be finished executing.
mRenderPassCache = nullptr; mRenderPassCache = nullptr;

View File

@ -46,17 +46,22 @@ namespace dawn_native { namespace vulkan {
: mDevice(device), : mDevice(device),
mMemoryTypeIndex(memoryTypeIndex), mMemoryTypeIndex(memoryTypeIndex),
mMemoryHeapSize(memoryHeapSize), mMemoryHeapSize(memoryHeapSize),
mPooledMemoryAllocator(this),
mBuddySystem( mBuddySystem(
// Round down to a power of 2 that's <= mMemoryHeapSize. This will always // Round down to a power of 2 that's <= mMemoryHeapSize. This will always
// be a multiple of kBuddyHeapsSize because kBuddyHeapsSize is a power of 2. // be a multiple of kBuddyHeapsSize because kBuddyHeapsSize is a power of 2.
uint64_t(1) << Log2(mMemoryHeapSize), uint64_t(1) << Log2(mMemoryHeapSize),
// Take the min in the very unlikely case the memory heap is tiny. // Take the min in the very unlikely case the memory heap is tiny.
std::min(uint64_t(1) << Log2(mMemoryHeapSize), kBuddyHeapsSize), std::min(uint64_t(1) << Log2(mMemoryHeapSize), kBuddyHeapsSize),
this) { &mPooledMemoryAllocator) {
ASSERT(IsPowerOfTwo(kBuddyHeapsSize)); ASSERT(IsPowerOfTwo(kBuddyHeapsSize));
} }
~SingleTypeAllocator() override = default; ~SingleTypeAllocator() override = default;
void DestroyPool() {
mPooledMemoryAllocator.DestroyPool();
}
ResultOrError<ResourceMemoryAllocation> AllocateMemory( ResultOrError<ResourceMemoryAllocation> AllocateMemory(
const VkMemoryRequirements& requirements) { const VkMemoryRequirements& requirements) {
return mBuddySystem.Allocate(requirements.size, requirements.alignment); return mBuddySystem.Allocate(requirements.size, requirements.alignment);
@ -100,6 +105,7 @@ namespace dawn_native { namespace vulkan {
Device* mDevice; Device* mDevice;
size_t mMemoryTypeIndex; size_t mMemoryTypeIndex;
VkDeviceSize mMemoryHeapSize; VkDeviceSize mMemoryHeapSize;
PooledResourceMemoryAllocator mPooledMemoryAllocator;
BuddyMemoryAllocator mBuddySystem; BuddyMemoryAllocator mBuddySystem;
}; };
@ -258,4 +264,10 @@ namespace dawn_native { namespace vulkan {
return bestType; return bestType;
} }
void ResourceMemoryAllocator::DestroyPool() {
for (auto& alloc : mAllocatorsPerType) {
alloc->DestroyPool();
}
}
}} // namespace dawn_native::vulkan }} // namespace dawn_native::vulkan

View File

@ -18,6 +18,7 @@
#include "common/SerialQueue.h" #include "common/SerialQueue.h"
#include "common/vulkan_platform.h" #include "common/vulkan_platform.h"
#include "dawn_native/Error.h" #include "dawn_native/Error.h"
#include "dawn_native/PooledResourceMemoryAllocator.h"
#include "dawn_native/ResourceMemoryAllocation.h" #include "dawn_native/ResourceMemoryAllocation.h"
#include <memory> #include <memory>
@ -36,6 +37,8 @@ namespace dawn_native { namespace vulkan {
bool mappable); bool mappable);
void Deallocate(ResourceMemoryAllocation* allocation); void Deallocate(ResourceMemoryAllocation* allocation);
void DestroyPool();
void Tick(Serial completedSerial); void Tick(Serial completedSerial);
int FindBestTypeIndex(VkMemoryRequirements requirements, bool mappable); int FindBestTypeIndex(VkMemoryRequirements requirements, bool mappable);

View File

@ -15,8 +15,12 @@
#include <gtest/gtest.h> #include <gtest/gtest.h>
#include "dawn_native/BuddyMemoryAllocator.h" #include "dawn_native/BuddyMemoryAllocator.h"
#include "dawn_native/PooledResourceMemoryAllocator.h"
#include "dawn_native/ResourceHeapAllocator.h" #include "dawn_native/ResourceHeapAllocator.h"
#include <set>
#include <vector>
using namespace dawn_native; using namespace dawn_native;
class DummyResourceHeapAllocator : public ResourceHeapAllocator { class DummyResourceHeapAllocator : public ResourceHeapAllocator {
@ -34,6 +38,12 @@ class DummyBuddyResourceAllocator {
: mAllocator(maxBlockSize, memorySize, &mHeapAllocator) { : mAllocator(maxBlockSize, memorySize, &mHeapAllocator) {
} }
DummyBuddyResourceAllocator(uint64_t maxBlockSize,
uint64_t memorySize,
ResourceHeapAllocator* heapAllocator)
: mAllocator(maxBlockSize, memorySize, heapAllocator) {
}
ResourceMemoryAllocation Allocate(uint64_t allocationSize, uint64_t alignment = 1) { ResourceMemoryAllocation Allocate(uint64_t allocationSize, uint64_t alignment = 1) {
ResultOrError<ResourceMemoryAllocation> result = ResultOrError<ResourceMemoryAllocation> result =
mAllocator.Allocate(allocationSize, alignment); mAllocator.Allocate(allocationSize, alignment);
@ -120,6 +130,7 @@ TEST(BuddyMemoryAllocatorTests, MultipleHeaps) {
// Second allocation creates second heap. // Second allocation creates second heap.
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u);
ASSERT_NE(allocation1.GetResourceHeap(), allocation2.GetResourceHeap());
// Deallocate both allocations // Deallocate both allocations
allocator.Deallocate(allocation1); allocator.Deallocate(allocation1);
@ -159,6 +170,7 @@ TEST(BuddyMemoryAllocatorTests, MultipleSplitHeaps) {
// Second allocation re-uses first heap. // Second allocation re-uses first heap.
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 1u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 1u);
ASSERT_EQ(allocation1.GetResourceHeap(), allocation2.GetResourceHeap());
ResourceMemoryAllocation allocation3 = allocator.Allocate(heapSize / 2); ResourceMemoryAllocation allocation3 = allocator.Allocate(heapSize / 2);
ASSERT_EQ(allocation3.GetInfo().mBlockOffset, heapSize); ASSERT_EQ(allocation3.GetInfo().mBlockOffset, heapSize);
@ -166,6 +178,7 @@ TEST(BuddyMemoryAllocatorTests, MultipleSplitHeaps) {
// Third allocation creates second heap. // Third allocation creates second heap.
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u);
ASSERT_NE(allocation1.GetResourceHeap(), allocation3.GetResourceHeap());
// Deallocate all allocations in reverse order. // Deallocate all allocations in reverse order.
allocator.Deallocate(allocation1); allocator.Deallocate(allocation1);
@ -210,6 +223,7 @@ TEST(BuddyMemoryAllocatorTests, MultiplSplitHeapsVariableSizes) {
// A1 and A2 share H0 // A1 and A2 share H0
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 1u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 1u);
ASSERT_EQ(allocation1.GetResourceHeap(), allocation2.GetResourceHeap());
ResourceMemoryAllocation allocation3 = allocator.Allocate(128); ResourceMemoryAllocation allocation3 = allocator.Allocate(128);
ASSERT_EQ(allocation3.GetInfo().mBlockOffset, 128u); ASSERT_EQ(allocation3.GetInfo().mBlockOffset, 128u);
@ -218,6 +232,7 @@ TEST(BuddyMemoryAllocatorTests, MultiplSplitHeapsVariableSizes) {
// A3 creates and fully occupies a new heap. // A3 creates and fully occupies a new heap.
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u);
ASSERT_NE(allocation2.GetResourceHeap(), allocation3.GetResourceHeap());
ResourceMemoryAllocation allocation4 = allocator.Allocate(64); ResourceMemoryAllocation allocation4 = allocator.Allocate(64);
ASSERT_EQ(allocation4.GetInfo().mBlockOffset, 256u); ASSERT_EQ(allocation4.GetInfo().mBlockOffset, 256u);
@ -225,6 +240,7 @@ TEST(BuddyMemoryAllocatorTests, MultiplSplitHeapsVariableSizes) {
ASSERT_EQ(allocation4.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation4.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u);
ASSERT_NE(allocation3.GetResourceHeap(), allocation4.GetResourceHeap());
// R5 size forms 64 byte hole after R4. // R5 size forms 64 byte hole after R4.
ResourceMemoryAllocation allocation5 = allocator.Allocate(128); ResourceMemoryAllocation allocation5 = allocator.Allocate(128);
@ -233,6 +249,7 @@ TEST(BuddyMemoryAllocatorTests, MultiplSplitHeapsVariableSizes) {
ASSERT_EQ(allocation5.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation5.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 4u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 4u);
ASSERT_NE(allocation4.GetResourceHeap(), allocation5.GetResourceHeap());
// Deallocate allocations in staggered order. // Deallocate allocations in staggered order.
allocator.Deallocate(allocation1); allocator.Deallocate(allocation1);
@ -282,6 +299,7 @@ TEST(BuddyMemoryAllocatorTests, SameSizeVariousAlignment) {
ASSERT_EQ(allocation2.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation2.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u);
ASSERT_NE(allocation1.GetResourceHeap(), allocation2.GetResourceHeap());
ResourceMemoryAllocation allocation3 = allocator.Allocate(64, 128); ResourceMemoryAllocation allocation3 = allocator.Allocate(64, 128);
ASSERT_EQ(allocation3.GetInfo().mBlockOffset, 256u); ASSERT_EQ(allocation3.GetInfo().mBlockOffset, 256u);
@ -289,6 +307,7 @@ TEST(BuddyMemoryAllocatorTests, SameSizeVariousAlignment) {
ASSERT_EQ(allocation3.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation3.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u);
ASSERT_NE(allocation2.GetResourceHeap(), allocation3.GetResourceHeap());
ResourceMemoryAllocation allocation4 = allocator.Allocate(64, 64); ResourceMemoryAllocation allocation4 = allocator.Allocate(64, 64);
ASSERT_EQ(allocation4.GetInfo().mBlockOffset, 320u); ASSERT_EQ(allocation4.GetInfo().mBlockOffset, 320u);
@ -296,6 +315,7 @@ TEST(BuddyMemoryAllocatorTests, SameSizeVariousAlignment) {
ASSERT_EQ(allocation4.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation4.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u);
ASSERT_EQ(allocation3.GetResourceHeap(), allocation4.GetResourceHeap());
} }
// Verify resource sub-allocation of various sizes with same alignments. // Verify resource sub-allocation of various sizes with same alignments.
@ -330,6 +350,7 @@ TEST(BuddyMemoryAllocatorTests, VariousSizeSameAlignment) {
ASSERT_EQ(allocation2.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation2.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 1u); // Reuses H0 ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 1u); // Reuses H0
ASSERT_EQ(allocation1.GetResourceHeap(), allocation2.GetResourceHeap());
ResourceMemoryAllocation allocation3 = allocator.Allocate(128, alignment); ResourceMemoryAllocation allocation3 = allocator.Allocate(128, alignment);
ASSERT_EQ(allocation3.GetInfo().mBlockOffset, 128u); ASSERT_EQ(allocation3.GetInfo().mBlockOffset, 128u);
@ -337,6 +358,7 @@ TEST(BuddyMemoryAllocatorTests, VariousSizeSameAlignment) {
ASSERT_EQ(allocation3.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation3.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 2u);
ASSERT_NE(allocation2.GetResourceHeap(), allocation3.GetResourceHeap());
ResourceMemoryAllocation allocation4 = allocator.Allocate(128, alignment); ResourceMemoryAllocation allocation4 = allocator.Allocate(128, alignment);
ASSERT_EQ(allocation4.GetInfo().mBlockOffset, 256u); ASSERT_EQ(allocation4.GetInfo().mBlockOffset, 256u);
@ -344,6 +366,7 @@ TEST(BuddyMemoryAllocatorTests, VariousSizeSameAlignment) {
ASSERT_EQ(allocation4.GetInfo().mMethod, AllocationMethod::kSubAllocated); ASSERT_EQ(allocation4.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u); ASSERT_EQ(allocator.ComputeTotalNumOfHeapsForTesting(), 3u);
ASSERT_NE(allocation3.GetResourceHeap(), allocation4.GetResourceHeap());
} }
// Verify allocating a very large resource does not overflow. // Verify allocating a very large resource does not overflow.
@ -356,3 +379,82 @@ TEST(BuddyMemoryAllocatorTests, AllocationOverflow) {
ResourceMemoryAllocation invalidAllocation = allocator.Allocate(largeBlock); ResourceMemoryAllocation invalidAllocation = allocator.Allocate(largeBlock);
ASSERT_EQ(invalidAllocation.GetInfo().mMethod, AllocationMethod::kInvalid); ASSERT_EQ(invalidAllocation.GetInfo().mMethod, AllocationMethod::kInvalid);
} }
// Verify resource heaps will be reused from a pool.
TEST(BuddyMemoryAllocatorTests, ReuseFreedHeaps) {
constexpr uint64_t kHeapSize = 128;
constexpr uint64_t kMaxBlockSize = 4096;
DummyResourceHeapAllocator heapAllocator;
PooledResourceMemoryAllocator poolAllocator(&heapAllocator);
DummyBuddyResourceAllocator allocator(kMaxBlockSize, kHeapSize, &poolAllocator);
std::set<ResourceHeapBase*> heaps = {};
std::vector<ResourceMemoryAllocation> allocations = {};
constexpr uint32_t kNumOfAllocations = 100;
// Allocate |kNumOfAllocations|.
for (uint32_t i = 0; i < kNumOfAllocations; i++) {
ResourceMemoryAllocation allocation = allocator.Allocate(4);
ASSERT_EQ(allocation.GetInfo().mMethod, AllocationMethod::kSubAllocated);
heaps.insert(allocation.GetResourceHeap());
allocations.push_back(std::move(allocation));
}
ASSERT_EQ(poolAllocator.GetPoolSizeForTesting(), 0u);
// Return the allocations to the pool.
for (ResourceMemoryAllocation& allocation : allocations) {
allocator.Deallocate(allocation);
}
ASSERT_EQ(poolAllocator.GetPoolSizeForTesting(), heaps.size());
// Allocate again reusing the same heaps.
for (uint32_t i = 0; i < kNumOfAllocations; i++) {
ResourceMemoryAllocation allocation = allocator.Allocate(4);
ASSERT_EQ(allocation.GetInfo().mMethod, AllocationMethod::kSubAllocated);
ASSERT_FALSE(heaps.insert(allocation.GetResourceHeap()).second);
}
ASSERT_EQ(poolAllocator.GetPoolSizeForTesting(), 0u);
}
// Verify resource heaps that were reused from a pool can be destroyed.
TEST(BuddyMemoryAllocatorTests, DestroyHeaps) {
constexpr uint64_t kHeapSize = 128;
constexpr uint64_t kMaxBlockSize = 4096;
DummyResourceHeapAllocator heapAllocator;
PooledResourceMemoryAllocator poolAllocator(&heapAllocator);
DummyBuddyResourceAllocator allocator(kMaxBlockSize, kHeapSize, &poolAllocator);
std::set<ResourceHeapBase*> heaps = {};
std::vector<ResourceMemoryAllocation> allocations = {};
// Count by heap (vs number of allocations) to ensure there are exactly |kNumOfHeaps| worth of
// buffers. Otherwise, the heap may be reused if not full.
constexpr uint32_t kNumOfHeaps = 10;
// Allocate |kNumOfHeaps| worth.
while (heaps.size() < kNumOfHeaps) {
ResourceMemoryAllocation allocation = allocator.Allocate(4);
ASSERT_EQ(allocation.GetInfo().mMethod, AllocationMethod::kSubAllocated);
heaps.insert(allocation.GetResourceHeap());
allocations.push_back(std::move(allocation));
}
ASSERT_EQ(poolAllocator.GetPoolSizeForTesting(), 0u);
// Return the allocations to the pool.
for (ResourceMemoryAllocation& allocation : allocations) {
allocator.Deallocate(allocation);
}
ASSERT_EQ(poolAllocator.GetPoolSizeForTesting(), kNumOfHeaps);
// Make sure we can destroy the remaining heaps.
poolAllocator.DestroyPool();
ASSERT_EQ(poolAllocator.GetPoolSizeForTesting(), 0u);
}