src/tests/unittests/CommandAllocatorTests.cpp - dawn - Git at Google

 // Copyright 2017 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 <gtest/gtest.h>

 #include "dawn_native/CommandAllocator.h"

 #include <limits>

 using namespace dawn_native;

 // Definition of the command types used in the tests
 enum class CommandType {
     Draw,
     Pipeline,
     PushConstants,
     Big,
     Small,
 };

 struct CommandDraw {
     uint32_t first;
     uint32_t count;
 };

 struct CommandPipeline {
     uint64_t pipeline;
     uint32_t attachmentPoint;
 };

 struct CommandPushConstants {
     uint8_t size;
     uint8_t offset;
 };

 constexpr int kBigBufferSize = 65536;

 struct CommandBig {
     uint32_t buffer[kBigBufferSize];
 };

 struct CommandSmall {
     uint16_t data;
 };

 // Test allocating nothing works
 TEST(CommandAllocator, DoNothingAllocator) {
     CommandAllocator allocator;
 }

 // Test iterating over nothing works
 TEST(CommandAllocator, DoNothingAllocatorWithIterator) {
     CommandAllocator allocator;
     CommandIterator iterator(std::move(allocator));
     iterator.DataWasDestroyed();
 }

 // Test basic usage of allocator + iterator
 TEST(CommandAllocator, Basic) {
     CommandAllocator allocator;

     uint64_t myPipeline = 0xDEADBEEFBEEFDEAD;
     uint32_t myAttachmentPoint = 2;
     uint32_t myFirst = 42;
     uint32_t myCount = 16;

     {
         CommandPipeline* pipeline = allocator.Allocate<CommandPipeline>(CommandType::Pipeline);
         pipeline->pipeline = myPipeline;
         pipeline->attachmentPoint = myAttachmentPoint;

         CommandDraw* draw = allocator.Allocate<CommandDraw>(CommandType::Draw);
         draw->first = myFirst;
         draw->count = myCount;
     }

     {
         CommandIterator iterator(std::move(allocator));
         CommandType type;

         bool hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::Pipeline);

         CommandPipeline* pipeline = iterator.NextCommand<CommandPipeline>();
         ASSERT_EQ(pipeline->pipeline, myPipeline);
         ASSERT_EQ(pipeline->attachmentPoint, myAttachmentPoint);

         hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::Draw);

         CommandDraw* draw = iterator.NextCommand<CommandDraw>();
         ASSERT_EQ(draw->first, myFirst);
         ASSERT_EQ(draw->count, myCount);

         hasNext = iterator.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         iterator.DataWasDestroyed();
     }
 }

 // Test basic usage of allocator + iterator with data
 TEST(CommandAllocator, BasicWithData) {
     CommandAllocator allocator;

     uint8_t mySize = 8;
     uint8_t myOffset = 3;
     uint32_t myValues[5] = {6, 42, 0xFFFFFFFF, 0, 54};

     {
         CommandPushConstants* pushConstants = allocator.Allocate<CommandPushConstants>(CommandType::PushConstants);
         pushConstants->size = mySize;
         pushConstants->offset = myOffset;

         uint32_t* values = allocator.AllocateData<uint32_t>(5);
         for (size_t i = 0; i < 5; i++) {
             values[i] = myValues[i];
         }
     }

     {
         CommandIterator iterator(std::move(allocator));
         CommandType type;

         bool hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::PushConstants);

         CommandPushConstants* pushConstants = iterator.NextCommand<CommandPushConstants>();
         ASSERT_EQ(pushConstants->size, mySize);
         ASSERT_EQ(pushConstants->offset, myOffset);

         uint32_t* values = iterator.NextData<uint32_t>(5);
         for (size_t i = 0; i < 5; i++) {
             ASSERT_EQ(values[i], myValues[i]);
         }

         hasNext = iterator.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         iterator.DataWasDestroyed();
     }
 }

 // Test basic iterating several times
 TEST(CommandAllocator, MultipleIterations) {
     CommandAllocator allocator;

     uint32_t myFirst = 42;
     uint32_t myCount = 16;

     {
         CommandDraw* draw = allocator.Allocate<CommandDraw>(CommandType::Draw);
         draw->first = myFirst;
         draw->count = myCount;
     }

     {
         CommandIterator iterator(std::move(allocator));
         CommandType type;

         // First iteration
         bool hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::Draw);

         CommandDraw* draw = iterator.NextCommand<CommandDraw>();
         ASSERT_EQ(draw->first, myFirst);
         ASSERT_EQ(draw->count, myCount);

         hasNext = iterator.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         // Second iteration
         hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::Draw);

         draw = iterator.NextCommand<CommandDraw>();
         ASSERT_EQ(draw->first, myFirst);
         ASSERT_EQ(draw->count, myCount);

         hasNext = iterator.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         iterator.DataWasDestroyed();
     }
 }
 // Test large commands work
 TEST(CommandAllocator, LargeCommands) {
     CommandAllocator allocator;

     const int kCommandCount = 5;

     uint32_t count = 0;
     for (int i = 0; i < kCommandCount; i++) {
         CommandBig* big = allocator.Allocate<CommandBig>(CommandType::Big);
         for (int j = 0; j < kBigBufferSize; j++) {
             big->buffer[j] = count ++;
         }
     }

     CommandIterator iterator(std::move(allocator));
     CommandType type;
     count = 0;
     int numCommands = 0;
     while (iterator.NextCommandId(&type)) {
         ASSERT_EQ(type, CommandType::Big);

         CommandBig* big = iterator.NextCommand<CommandBig>();
         for (int i = 0; i < kBigBufferSize; i++) {
             ASSERT_EQ(big->buffer[i], count);
             count ++;
         }
         numCommands ++;
     }
     ASSERT_EQ(numCommands, kCommandCount);

     iterator.DataWasDestroyed();
 }

 // Test many small commands work
 TEST(CommandAllocator, ManySmallCommands) {
     CommandAllocator allocator;

     // Stay under max representable uint16_t
     const int kCommandCount = 50000;

     uint16_t count = 0;
     for (int i = 0; i < kCommandCount; i++) {
         CommandSmall* small = allocator.Allocate<CommandSmall>(CommandType::Small);
         small->data = count ++;
     }

     CommandIterator iterator(std::move(allocator));
     CommandType type;
     count = 0;
     int numCommands = 0;
     while (iterator.NextCommandId(&type)) {
         ASSERT_EQ(type, CommandType::Small);

         CommandSmall* small = iterator.NextCommand<CommandSmall>();
         ASSERT_EQ(small->data, count);
         count ++;
         numCommands ++;
     }
     ASSERT_EQ(numCommands, kCommandCount);

     iterator.DataWasDestroyed();
 }

 /*        ________
  *       /        \
  *       | POUIC! |
  *       \_ ______/
  *         v
  *    ()_()
  *    (O.o)
  *    (> <)o
  */

 // Test usage of iterator.Reset
 TEST(CommandAllocator, IteratorReset) {
     CommandAllocator allocator;

     uint64_t myPipeline = 0xDEADBEEFBEEFDEAD;
     uint32_t myAttachmentPoint = 2;
     uint32_t myFirst = 42;
     uint32_t myCount = 16;

     {
         CommandPipeline* pipeline = allocator.Allocate<CommandPipeline>(CommandType::Pipeline);
         pipeline->pipeline = myPipeline;
         pipeline->attachmentPoint = myAttachmentPoint;

         CommandDraw* draw = allocator.Allocate<CommandDraw>(CommandType::Draw);
         draw->first = myFirst;
         draw->count = myCount;
     }

     {
         CommandIterator iterator(std::move(allocator));
         CommandType type;

         bool hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::Pipeline);

         CommandPipeline* pipeline = iterator.NextCommand<CommandPipeline>();
         ASSERT_EQ(pipeline->pipeline, myPipeline);
         ASSERT_EQ(pipeline->attachmentPoint, myAttachmentPoint);

         iterator.Reset();

         hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::Pipeline);

         pipeline = iterator.NextCommand<CommandPipeline>();
         ASSERT_EQ(pipeline->pipeline, myPipeline);
         ASSERT_EQ(pipeline->attachmentPoint, myAttachmentPoint);

         hasNext = iterator.NextCommandId(&type);
         ASSERT_TRUE(hasNext);
         ASSERT_EQ(type, CommandType::Draw);

         CommandDraw* draw = iterator.NextCommand<CommandDraw>();
         ASSERT_EQ(draw->first, myFirst);
         ASSERT_EQ(draw->count, myCount);

         hasNext = iterator.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         iterator.DataWasDestroyed();
     }
 }

 // Test iterating empty iterators
 TEST(CommandAllocator, EmptyIterator) {
     {
         CommandAllocator allocator;
         CommandIterator iterator(std::move(allocator));

         CommandType type;
         bool hasNext = iterator.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         iterator.DataWasDestroyed();
     }
     {
         CommandAllocator allocator;
         CommandIterator iterator1(std::move(allocator));
         CommandIterator iterator2(std::move(iterator1));

         CommandType type;
         bool hasNext = iterator2.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         iterator1.DataWasDestroyed();
         iterator2.DataWasDestroyed();
     }
     {
         CommandIterator iterator1;
         CommandIterator iterator2(std::move(iterator1));

         CommandType type;
         bool hasNext = iterator2.NextCommandId(&type);
         ASSERT_FALSE(hasNext);

         iterator1.DataWasDestroyed();
         iterator2.DataWasDestroyed();
     }
 }

 template <size_t A>
 struct alignas(A) AlignedStruct {
     char dummy;
 };

 // Test for overflows in Allocate's computations, size 1 variant
 TEST(CommandAllocator, AllocationOverflow_1) {
     CommandAllocator allocator;
     AlignedStruct<1>* data =
         allocator.AllocateData<AlignedStruct<1>>(std::numeric_limits<size_t>::max() / 1);
     ASSERT_EQ(data, nullptr);
 }

 // Test for overflows in Allocate's computations, size 2 variant
 TEST(CommandAllocator, AllocationOverflow_2) {
     CommandAllocator allocator;
     AlignedStruct<2>* data =
         allocator.AllocateData<AlignedStruct<2>>(std::numeric_limits<size_t>::max() / 2);
     ASSERT_EQ(data, nullptr);
 }

 // Test for overflows in Allocate's computations, size 4 variant
 TEST(CommandAllocator, AllocationOverflow_4) {
     CommandAllocator allocator;
     AlignedStruct<4>* data =
         allocator.AllocateData<AlignedStruct<4>>(std::numeric_limits<size_t>::max() / 4);
     ASSERT_EQ(data, nullptr);
 }

 // Test for overflows in Allocate's computations, size 8 variant
 TEST(CommandAllocator, AllocationOverflow_8) {
     CommandAllocator allocator;
     AlignedStruct<8>* data =
         allocator.AllocateData<AlignedStruct<8>>(std::numeric_limits<size_t>::max() / 8);
     ASSERT_EQ(data, nullptr);
 }

 template <int DefaultValue>
 struct IntWithDefault {
     IntWithDefault() : value(DefaultValue) {
     }

     int value;
 };

 // Test that the allcator correctly defaults initalizes data for Allocate
 TEST(CommandAllocator, AllocateDefaultInitializes) {
     CommandAllocator allocator;

     IntWithDefault<42>* int42 = allocator.Allocate<IntWithDefault<42>>(CommandType::Draw);
     ASSERT_EQ(int42->value, 42);

     IntWithDefault<43>* int43 = allocator.Allocate<IntWithDefault<43>>(CommandType::Draw);
     ASSERT_EQ(int43->value, 43);

     IntWithDefault<44>* int44 = allocator.Allocate<IntWithDefault<44>>(CommandType::Draw);
     ASSERT_EQ(int44->value, 44);

     CommandIterator iterator(std::move(allocator));
     iterator.DataWasDestroyed();
 }

 // Test that the allcator correctly defaults initalizes data for AllocateData
 TEST(CommandAllocator, AllocateDataDefaultInitializes) {
     CommandAllocator allocator;

     IntWithDefault<33>* int33 = allocator.AllocateData<IntWithDefault<33>>(1);
     ASSERT_EQ(int33[0].value, 33);

     IntWithDefault<34>* int34 = allocator.AllocateData<IntWithDefault<34>>(2);
     ASSERT_EQ(int34[0].value, 34);
     ASSERT_EQ(int34[0].value, 34);

     IntWithDefault<35>* int35 = allocator.AllocateData<IntWithDefault<35>>(3);
     ASSERT_EQ(int35[0].value, 35);
     ASSERT_EQ(int35[1].value, 35);
     ASSERT_EQ(int35[2].value, 35);

     CommandIterator iterator(std::move(allocator));
     iterator.DataWasDestroyed();
 }
	// Copyright 2017 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 <gtest/gtest.h>

	#include "dawn_native/CommandAllocator.h"

	#include <limits>

	using namespace dawn_native;

	// Definition of the command types used in the tests
	enum class CommandType {
	Draw,
	Pipeline,
	PushConstants,
	Big,
	Small,
	};

	struct CommandDraw {
	uint32_t first;
	uint32_t count;
	};

	struct CommandPipeline {
	uint64_t pipeline;
	uint32_t attachmentPoint;
	};

	struct CommandPushConstants {
	uint8_t size;
	uint8_t offset;
	};

	constexpr int kBigBufferSize = 65536;

	struct CommandBig {
	uint32_t buffer[kBigBufferSize];
	};

	struct CommandSmall {
	uint16_t data;
	};

	// Test allocating nothing works
	TEST(CommandAllocator, DoNothingAllocator) {
	CommandAllocator allocator;
	}

	// Test iterating over nothing works
	TEST(CommandAllocator, DoNothingAllocatorWithIterator) {
	CommandAllocator allocator;
	CommandIterator iterator(std::move(allocator));
	iterator.DataWasDestroyed();
	}

	// Test basic usage of allocator + iterator
	TEST(CommandAllocator, Basic) {
	CommandAllocator allocator;

	uint64_t myPipeline = 0xDEADBEEFBEEFDEAD;
	uint32_t myAttachmentPoint = 2;
	uint32_t myFirst = 42;
	uint32_t myCount = 16;

	{
	CommandPipeline* pipeline = allocator.Allocate<CommandPipeline>(CommandType::Pipeline);
	pipeline->pipeline = myPipeline;
	pipeline->attachmentPoint = myAttachmentPoint;

	CommandDraw* draw = allocator.Allocate<CommandDraw>(CommandType::Draw);
	draw->first = myFirst;
	draw->count = myCount;
	}

	{
	CommandIterator iterator(std::move(allocator));
	CommandType type;

	bool hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::Pipeline);

	CommandPipeline* pipeline = iterator.NextCommand<CommandPipeline>();
	ASSERT_EQ(pipeline->pipeline, myPipeline);
	ASSERT_EQ(pipeline->attachmentPoint, myAttachmentPoint);

	hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::Draw);

	CommandDraw* draw = iterator.NextCommand<CommandDraw>();
	ASSERT_EQ(draw->first, myFirst);
	ASSERT_EQ(draw->count, myCount);

	hasNext = iterator.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	iterator.DataWasDestroyed();
	}
	}

	// Test basic usage of allocator + iterator with data
	TEST(CommandAllocator, BasicWithData) {
	CommandAllocator allocator;

	uint8_t mySize = 8;
	uint8_t myOffset = 3;
	uint32_t myValues[5] = {6, 42, 0xFFFFFFFF, 0, 54};

	{
	CommandPushConstants* pushConstants = allocator.Allocate<CommandPushConstants>(CommandType::PushConstants);
	pushConstants->size = mySize;
	pushConstants->offset = myOffset;

	uint32_t* values = allocator.AllocateData<uint32_t>(5);
	for (size_t i = 0; i < 5; i++) {
	values[i] = myValues[i];
	}
	}

	{
	CommandIterator iterator(std::move(allocator));
	CommandType type;

	bool hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::PushConstants);

	CommandPushConstants* pushConstants = iterator.NextCommand<CommandPushConstants>();
	ASSERT_EQ(pushConstants->size, mySize);
	ASSERT_EQ(pushConstants->offset, myOffset);

	uint32_t* values = iterator.NextData<uint32_t>(5);
	for (size_t i = 0; i < 5; i++) {
	ASSERT_EQ(values[i], myValues[i]);
	}

	hasNext = iterator.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	iterator.DataWasDestroyed();
	}
	}

	// Test basic iterating several times
	TEST(CommandAllocator, MultipleIterations) {
	CommandAllocator allocator;

	uint32_t myFirst = 42;
	uint32_t myCount = 16;

	{
	CommandDraw* draw = allocator.Allocate<CommandDraw>(CommandType::Draw);
	draw->first = myFirst;
	draw->count = myCount;
	}

	{
	CommandIterator iterator(std::move(allocator));
	CommandType type;

	// First iteration
	bool hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::Draw);

	CommandDraw* draw = iterator.NextCommand<CommandDraw>();
	ASSERT_EQ(draw->first, myFirst);
	ASSERT_EQ(draw->count, myCount);

	hasNext = iterator.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	// Second iteration
	hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::Draw);

	draw = iterator.NextCommand<CommandDraw>();
	ASSERT_EQ(draw->first, myFirst);
	ASSERT_EQ(draw->count, myCount);

	hasNext = iterator.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	iterator.DataWasDestroyed();
	}
	}
	// Test large commands work
	TEST(CommandAllocator, LargeCommands) {
	CommandAllocator allocator;

	const int kCommandCount = 5;

	uint32_t count = 0;
	for (int i = 0; i < kCommandCount; i++) {
	CommandBig* big = allocator.Allocate<CommandBig>(CommandType::Big);
	for (int j = 0; j < kBigBufferSize; j++) {
	big->buffer[j] = count ++;
	}
	}

	CommandIterator iterator(std::move(allocator));
	CommandType type;
	count = 0;
	int numCommands = 0;
	while (iterator.NextCommandId(&type)) {
	ASSERT_EQ(type, CommandType::Big);

	CommandBig* big = iterator.NextCommand<CommandBig>();
	for (int i = 0; i < kBigBufferSize; i++) {
	ASSERT_EQ(big->buffer[i], count);
	count ++;
	}
	numCommands ++;
	}
	ASSERT_EQ(numCommands, kCommandCount);

	iterator.DataWasDestroyed();
	}

	// Test many small commands work
	TEST(CommandAllocator, ManySmallCommands) {
	CommandAllocator allocator;

	// Stay under max representable uint16_t
	const int kCommandCount = 50000;

	uint16_t count = 0;
	for (int i = 0; i < kCommandCount; i++) {
	CommandSmall* small = allocator.Allocate<CommandSmall>(CommandType::Small);
	small->data = count ++;
	}

	CommandIterator iterator(std::move(allocator));
	CommandType type;
	count = 0;
	int numCommands = 0;
	while (iterator.NextCommandId(&type)) {
	ASSERT_EQ(type, CommandType::Small);

	CommandSmall* small = iterator.NextCommand<CommandSmall>();
	ASSERT_EQ(small->data, count);
	count ++;
	numCommands ++;
	}
	ASSERT_EQ(numCommands, kCommandCount);

	iterator.DataWasDestroyed();
	}

	/* ________
	* / \
	* \| POUIC! \|
	* \_ ______/
	* v
	* ()_()
	* (O.o)
	* (> <)o
	*/

	// Test usage of iterator.Reset
	TEST(CommandAllocator, IteratorReset) {
	CommandAllocator allocator;

	uint64_t myPipeline = 0xDEADBEEFBEEFDEAD;
	uint32_t myAttachmentPoint = 2;
	uint32_t myFirst = 42;
	uint32_t myCount = 16;

	{
	CommandPipeline* pipeline = allocator.Allocate<CommandPipeline>(CommandType::Pipeline);
	pipeline->pipeline = myPipeline;
	pipeline->attachmentPoint = myAttachmentPoint;

	CommandDraw* draw = allocator.Allocate<CommandDraw>(CommandType::Draw);
	draw->first = myFirst;
	draw->count = myCount;
	}

	{
	CommandIterator iterator(std::move(allocator));
	CommandType type;

	bool hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::Pipeline);

	CommandPipeline* pipeline = iterator.NextCommand<CommandPipeline>();
	ASSERT_EQ(pipeline->pipeline, myPipeline);
	ASSERT_EQ(pipeline->attachmentPoint, myAttachmentPoint);

	iterator.Reset();

	hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::Pipeline);

	pipeline = iterator.NextCommand<CommandPipeline>();
	ASSERT_EQ(pipeline->pipeline, myPipeline);
	ASSERT_EQ(pipeline->attachmentPoint, myAttachmentPoint);

	hasNext = iterator.NextCommandId(&type);
	ASSERT_TRUE(hasNext);
	ASSERT_EQ(type, CommandType::Draw);

	CommandDraw* draw = iterator.NextCommand<CommandDraw>();
	ASSERT_EQ(draw->first, myFirst);
	ASSERT_EQ(draw->count, myCount);

	hasNext = iterator.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	iterator.DataWasDestroyed();
	}
	}

	// Test iterating empty iterators
	TEST(CommandAllocator, EmptyIterator) {
	{
	CommandAllocator allocator;
	CommandIterator iterator(std::move(allocator));

	CommandType type;
	bool hasNext = iterator.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	iterator.DataWasDestroyed();
	}
	{
	CommandAllocator allocator;
	CommandIterator iterator1(std::move(allocator));
	CommandIterator iterator2(std::move(iterator1));

	CommandType type;
	bool hasNext = iterator2.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	iterator1.DataWasDestroyed();
	iterator2.DataWasDestroyed();
	}
	{
	CommandIterator iterator1;
	CommandIterator iterator2(std::move(iterator1));

	CommandType type;
	bool hasNext = iterator2.NextCommandId(&type);
	ASSERT_FALSE(hasNext);

	iterator1.DataWasDestroyed();
	iterator2.DataWasDestroyed();
	}
	}

	template <size_t A>
	struct alignas(A) AlignedStruct {
	char dummy;
	};

	// Test for overflows in Allocate's computations, size 1 variant
	TEST(CommandAllocator, AllocationOverflow_1) {
	CommandAllocator allocator;
	AlignedStruct<1>* data =
	allocator.AllocateData<AlignedStruct<1>>(std::numeric_limits<size_t>::max() / 1);
	ASSERT_EQ(data, nullptr);
	}

	// Test for overflows in Allocate's computations, size 2 variant
	TEST(CommandAllocator, AllocationOverflow_2) {
	CommandAllocator allocator;
	AlignedStruct<2>* data =
	allocator.AllocateData<AlignedStruct<2>>(std::numeric_limits<size_t>::max() / 2);
	ASSERT_EQ(data, nullptr);
	}

	// Test for overflows in Allocate's computations, size 4 variant
	TEST(CommandAllocator, AllocationOverflow_4) {
	CommandAllocator allocator;
	AlignedStruct<4>* data =
	allocator.AllocateData<AlignedStruct<4>>(std::numeric_limits<size_t>::max() / 4);
	ASSERT_EQ(data, nullptr);
	}

	// Test for overflows in Allocate's computations, size 8 variant
	TEST(CommandAllocator, AllocationOverflow_8) {
	CommandAllocator allocator;
	AlignedStruct<8>* data =
	allocator.AllocateData<AlignedStruct<8>>(std::numeric_limits<size_t>::max() / 8);
	ASSERT_EQ(data, nullptr);
	}

	template <int DefaultValue>
	struct IntWithDefault {
	IntWithDefault() : value(DefaultValue) {
	}

	int value;
	};

	// Test that the allcator correctly defaults initalizes data for Allocate
	TEST(CommandAllocator, AllocateDefaultInitializes) {
	CommandAllocator allocator;

	IntWithDefault<42>* int42 = allocator.Allocate<IntWithDefault<42>>(CommandType::Draw);
	ASSERT_EQ(int42->value, 42);

	IntWithDefault<43>* int43 = allocator.Allocate<IntWithDefault<43>>(CommandType::Draw);
	ASSERT_EQ(int43->value, 43);

	IntWithDefault<44>* int44 = allocator.Allocate<IntWithDefault<44>>(CommandType::Draw);
	ASSERT_EQ(int44->value, 44);

	CommandIterator iterator(std::move(allocator));
	iterator.DataWasDestroyed();
	}

	// Test that the allcator correctly defaults initalizes data for AllocateData
	TEST(CommandAllocator, AllocateDataDefaultInitializes) {
	CommandAllocator allocator;

	IntWithDefault<33>* int33 = allocator.AllocateData<IntWithDefault<33>>(1);
	ASSERT_EQ(int33[0].value, 33);

	IntWithDefault<34>* int34 = allocator.AllocateData<IntWithDefault<34>>(2);
	ASSERT_EQ(int34[0].value, 34);
	ASSERT_EQ(int34[0].value, 34);

	IntWithDefault<35>* int35 = allocator.AllocateData<IntWithDefault<35>>(3);
	ASSERT_EQ(int35[0].value, 35);
	ASSERT_EQ(int35[1].value, 35);
	ASSERT_EQ(int35[2].value, 35);

	CommandIterator iterator(std::move(allocator));
	iterator.DataWasDestroyed();
	}