src/tests/unittests/wire/WireExtensionTests.cpp - dawn - Git at Google

 // 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 "tests/unittests/wire/WireTest.h"

 using namespace testing;
 using namespace dawn_wire;

 class WireExtensionTests : public WireTest {
   public:
     WireExtensionTests() {
     }
     ~WireExtensionTests() override = default;
 };

 // Serialize/Deserializes a chained struct correctly.
 TEST_F(WireExtensionTests, ChainedStruct) {
     WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt = {};
     clientExt.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
     clientExt.chain.next = nullptr;
     clientExt.maxAnisotropy = 3.14;

     WGPUSamplerDescriptor clientDesc = {};
     clientDesc.nextInChain = &clientExt.chain;
     clientDesc.label = "sampler with anisotropic filtering";

     wgpuDeviceCreateSampler(device, &clientDesc);
     EXPECT_CALL(api, DeviceCreateSampler(apiDevice, NotNull()))
         .WillOnce(Invoke([&](Unused, const WGPUSamplerDescriptor* serverDesc) -> WGPUSampler {
             EXPECT_STREQ(serverDesc->label, clientDesc.label);

             const auto* ext = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
                 serverDesc->nextInChain);
             EXPECT_EQ(ext->chain.sType, clientExt.chain.sType);
             EXPECT_EQ(ext->maxAnisotropy, clientExt.maxAnisotropy);

             EXPECT_EQ(ext->chain.next, nullptr);

             return api.GetNewSampler();
         }));
     FlushClient();
 }

 // Serialize/Deserializes multiple chained structs correctly.
 TEST_F(WireExtensionTests, MutlipleChainedStructs) {
     WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt2 = {};
     clientExt2.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
     clientExt2.chain.next = nullptr;
     clientExt2.maxAnisotropy = 2.71828;

     WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt1 = {};
     clientExt1.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
     clientExt1.chain.next = &clientExt2.chain;
     clientExt1.maxAnisotropy = 3.14;

     WGPUSamplerDescriptor clientDesc = {};
     clientDesc.nextInChain = &clientExt1.chain;
     clientDesc.label = "sampler with anisotropic filtering";

     wgpuDeviceCreateSampler(device, &clientDesc);
     EXPECT_CALL(api, DeviceCreateSampler(apiDevice, NotNull()))
         .WillOnce(Invoke([&](Unused, const WGPUSamplerDescriptor* serverDesc) -> WGPUSampler {
             EXPECT_STREQ(serverDesc->label, clientDesc.label);

             const auto* ext1 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
                 serverDesc->nextInChain);
             EXPECT_EQ(ext1->chain.sType, clientExt1.chain.sType);
             EXPECT_EQ(ext1->maxAnisotropy, clientExt1.maxAnisotropy);

             const auto* ext2 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
                 ext1->chain.next);
             EXPECT_EQ(ext2->chain.sType, clientExt2.chain.sType);
             EXPECT_EQ(ext2->maxAnisotropy, clientExt2.maxAnisotropy);

             EXPECT_EQ(ext2->chain.next, nullptr);

             return api.GetNewSampler();
         }));
     FlushClient();

     // Swap the order of the chained structs.
     clientDesc.nextInChain = &clientExt2.chain;
     clientExt2.chain.next = &clientExt1.chain;
     clientExt1.chain.next = nullptr;

     wgpuDeviceCreateSampler(device, &clientDesc);
     EXPECT_CALL(api, DeviceCreateSampler(apiDevice, NotNull()))
         .WillOnce(Invoke([&](Unused, const WGPUSamplerDescriptor* serverDesc) -> WGPUSampler {
             EXPECT_STREQ(serverDesc->label, clientDesc.label);

             const auto* ext2 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
                 serverDesc->nextInChain);
             EXPECT_EQ(ext2->chain.sType, clientExt2.chain.sType);
             EXPECT_EQ(ext2->maxAnisotropy, clientExt2.maxAnisotropy);

             const auto* ext1 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
                 ext2->chain.next);
             EXPECT_EQ(ext1->chain.sType, clientExt1.chain.sType);
             EXPECT_EQ(ext1->maxAnisotropy, clientExt1.maxAnisotropy);

             EXPECT_EQ(ext1->chain.next, nullptr);

             return api.GetNewSampler();
         }));
     FlushClient();
 }

 // Test that a chained struct with Invalid sType is an error.
 TEST_F(WireExtensionTests, InvalidSType) {
     WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt = {};
     clientExt.chain.sType = WGPUSType_Invalid;
     clientExt.chain.next = nullptr;

     WGPUSamplerDescriptor clientDesc = {};
     clientDesc.nextInChain = &clientExt.chain;
     clientDesc.label = "sampler with anisotropic filtering";

     wgpuDeviceCreateSampler(device, &clientDesc);
     FlushClient(false);
 }

 // Test that if both an invalid and valid stype are passed on the chain, it is an error.
 TEST_F(WireExtensionTests, ValidAndInvalidSTypeInChain) {
     WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt2 = {};
     clientExt2.chain.sType = WGPUSType_Invalid;
     clientExt2.chain.next = nullptr;
     clientExt2.maxAnisotropy = 2.71828;

     WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt1 = {};
     clientExt1.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
     clientExt1.chain.next = &clientExt2.chain;
     clientExt1.maxAnisotropy = 3.14;

     WGPUSamplerDescriptor clientDesc = {};
     clientDesc.nextInChain = &clientExt1.chain;
     clientDesc.label = "sampler with anisotropic filtering";

     wgpuDeviceCreateSampler(device, &clientDesc);
     FlushClient(false);

     // Swap the order of the chained structs.
     clientDesc.nextInChain = &clientExt2.chain;
     clientExt2.chain.next = &clientExt1.chain;
     clientExt1.chain.next = nullptr;

     wgpuDeviceCreateSampler(device, &clientDesc);
     FlushClient(false);
 }

 // Test that (de)?serializing a chained struct with subdescriptors works.
 TEST_F(WireExtensionTests, ChainedStructWithSubdescriptor) {
     WGPUShaderModuleDescriptor shaderModuleDesc = {};

     WGPUShaderModule apiShaderModule1 = api.GetNewShaderModule();
     WGPUShaderModule shaderModule1 = wgpuDeviceCreateShaderModule(device, &shaderModuleDesc);
     EXPECT_CALL(api, DeviceCreateShaderModule(apiDevice, _)).WillOnce(Return(apiShaderModule1));
     FlushClient();

     WGPUShaderModule apiShaderModule2 = api.GetNewShaderModule();
     WGPUShaderModule shaderModule2 = wgpuDeviceCreateShaderModule(device, &shaderModuleDesc);
     EXPECT_CALL(api, DeviceCreateShaderModule(apiDevice, _)).WillOnce(Return(apiShaderModule2));
     FlushClient();

     WGPUProgrammableStageDescriptor extraStageDesc = {};
     extraStageDesc.module = shaderModule1;
     extraStageDesc.entryPoint = "my other module";

     WGPURenderPipelineDescriptorDummyExtension clientExt = {};
     clientExt.chain.sType = WGPUSType_RenderPipelineDescriptorDummyExtension;
     clientExt.chain.next = nullptr;
     clientExt.dummyStage = extraStageDesc;

     WGPURenderPipelineDescriptor renderPipelineDesc = {};
     renderPipelineDesc.nextInChain = &clientExt.chain;
     renderPipelineDesc.vertexStage.module = shaderModule2;
     renderPipelineDesc.vertexStage.entryPoint = "my vertex module";

     wgpuDeviceCreateRenderPipeline(device, &renderPipelineDesc);
     EXPECT_CALL(api, DeviceCreateRenderPipeline(apiDevice, NotNull()))
         .WillOnce(Invoke([&](Unused,
                              const WGPURenderPipelineDescriptor* serverDesc) -> WGPURenderPipeline {
             EXPECT_EQ(serverDesc->vertexStage.module, apiShaderModule2);
             EXPECT_STREQ(serverDesc->vertexStage.entryPoint,
                          renderPipelineDesc.vertexStage.entryPoint);

             const auto* ext = reinterpret_cast<const WGPURenderPipelineDescriptorDummyExtension*>(
                 serverDesc->nextInChain);
             EXPECT_EQ(ext->chain.sType, clientExt.chain.sType);
             EXPECT_EQ(ext->dummyStage.module, apiShaderModule1);
             EXPECT_STREQ(ext->dummyStage.entryPoint, extraStageDesc.entryPoint);

             EXPECT_EQ(ext->chain.next, nullptr);

             return api.GetNewRenderPipeline();
         }));
     FlushClient();
 }
	// 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 "tests/unittests/wire/WireTest.h"

	using namespace testing;
	using namespace dawn_wire;

	class WireExtensionTests : public WireTest {
	public:
	WireExtensionTests() {
	}
	~WireExtensionTests() override = default;
	};

	// Serialize/Deserializes a chained struct correctly.
	TEST_F(WireExtensionTests, ChainedStruct) {
	WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt = {};
	clientExt.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
	clientExt.chain.next = nullptr;
	clientExt.maxAnisotropy = 3.14;

	WGPUSamplerDescriptor clientDesc = {};
	clientDesc.nextInChain = &clientExt.chain;
	clientDesc.label = "sampler with anisotropic filtering";

	wgpuDeviceCreateSampler(device, &clientDesc);
	EXPECT_CALL(api, DeviceCreateSampler(apiDevice, NotNull()))
	.WillOnce(Invoke([&](Unused, const WGPUSamplerDescriptor* serverDesc) -> WGPUSampler {
	EXPECT_STREQ(serverDesc->label, clientDesc.label);

	const auto* ext = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
	serverDesc->nextInChain);
	EXPECT_EQ(ext->chain.sType, clientExt.chain.sType);
	EXPECT_EQ(ext->maxAnisotropy, clientExt.maxAnisotropy);

	EXPECT_EQ(ext->chain.next, nullptr);

	return api.GetNewSampler();
	}));
	FlushClient();
	}

	// Serialize/Deserializes multiple chained structs correctly.
	TEST_F(WireExtensionTests, MutlipleChainedStructs) {
	WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt2 = {};
	clientExt2.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
	clientExt2.chain.next = nullptr;
	clientExt2.maxAnisotropy = 2.71828;

	WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt1 = {};
	clientExt1.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
	clientExt1.chain.next = &clientExt2.chain;
	clientExt1.maxAnisotropy = 3.14;

	WGPUSamplerDescriptor clientDesc = {};
	clientDesc.nextInChain = &clientExt1.chain;
	clientDesc.label = "sampler with anisotropic filtering";

	wgpuDeviceCreateSampler(device, &clientDesc);
	EXPECT_CALL(api, DeviceCreateSampler(apiDevice, NotNull()))
	.WillOnce(Invoke([&](Unused, const WGPUSamplerDescriptor* serverDesc) -> WGPUSampler {
	EXPECT_STREQ(serverDesc->label, clientDesc.label);

	const auto* ext1 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
	serverDesc->nextInChain);
	EXPECT_EQ(ext1->chain.sType, clientExt1.chain.sType);
	EXPECT_EQ(ext1->maxAnisotropy, clientExt1.maxAnisotropy);

	const auto* ext2 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
	ext1->chain.next);
	EXPECT_EQ(ext2->chain.sType, clientExt2.chain.sType);
	EXPECT_EQ(ext2->maxAnisotropy, clientExt2.maxAnisotropy);

	EXPECT_EQ(ext2->chain.next, nullptr);

	return api.GetNewSampler();
	}));
	FlushClient();

	// Swap the order of the chained structs.
	clientDesc.nextInChain = &clientExt2.chain;
	clientExt2.chain.next = &clientExt1.chain;
	clientExt1.chain.next = nullptr;

	wgpuDeviceCreateSampler(device, &clientDesc);
	EXPECT_CALL(api, DeviceCreateSampler(apiDevice, NotNull()))
	.WillOnce(Invoke([&](Unused, const WGPUSamplerDescriptor* serverDesc) -> WGPUSampler {
	EXPECT_STREQ(serverDesc->label, clientDesc.label);

	const auto* ext2 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
	serverDesc->nextInChain);
	EXPECT_EQ(ext2->chain.sType, clientExt2.chain.sType);
	EXPECT_EQ(ext2->maxAnisotropy, clientExt2.maxAnisotropy);

	const auto* ext1 = reinterpret_cast<const WGPUSamplerDescriptorDummyAnisotropicFiltering*>(
	ext2->chain.next);
	EXPECT_EQ(ext1->chain.sType, clientExt1.chain.sType);
	EXPECT_EQ(ext1->maxAnisotropy, clientExt1.maxAnisotropy);

	EXPECT_EQ(ext1->chain.next, nullptr);

	return api.GetNewSampler();
	}));
	FlushClient();
	}

	// Test that a chained struct with Invalid sType is an error.
	TEST_F(WireExtensionTests, InvalidSType) {
	WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt = {};
	clientExt.chain.sType = WGPUSType_Invalid;
	clientExt.chain.next = nullptr;

	WGPUSamplerDescriptor clientDesc = {};
	clientDesc.nextInChain = &clientExt.chain;
	clientDesc.label = "sampler with anisotropic filtering";

	wgpuDeviceCreateSampler(device, &clientDesc);
	FlushClient(false);
	}

	// Test that if both an invalid and valid stype are passed on the chain, it is an error.
	TEST_F(WireExtensionTests, ValidAndInvalidSTypeInChain) {
	WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt2 = {};
	clientExt2.chain.sType = WGPUSType_Invalid;
	clientExt2.chain.next = nullptr;
	clientExt2.maxAnisotropy = 2.71828;

	WGPUSamplerDescriptorDummyAnisotropicFiltering clientExt1 = {};
	clientExt1.chain.sType = WGPUSType_SamplerDescriptorDummyAnisotropicFiltering;
	clientExt1.chain.next = &clientExt2.chain;
	clientExt1.maxAnisotropy = 3.14;

	WGPUSamplerDescriptor clientDesc = {};
	clientDesc.nextInChain = &clientExt1.chain;
	clientDesc.label = "sampler with anisotropic filtering";

	wgpuDeviceCreateSampler(device, &clientDesc);
	FlushClient(false);

	// Swap the order of the chained structs.
	clientDesc.nextInChain = &clientExt2.chain;
	clientExt2.chain.next = &clientExt1.chain;
	clientExt1.chain.next = nullptr;

	wgpuDeviceCreateSampler(device, &clientDesc);
	FlushClient(false);
	}

	// Test that (de)?serializing a chained struct with subdescriptors works.
	TEST_F(WireExtensionTests, ChainedStructWithSubdescriptor) {
	WGPUShaderModuleDescriptor shaderModuleDesc = {};

	WGPUShaderModule apiShaderModule1 = api.GetNewShaderModule();
	WGPUShaderModule shaderModule1 = wgpuDeviceCreateShaderModule(device, &shaderModuleDesc);
	EXPECT_CALL(api, DeviceCreateShaderModule(apiDevice, _)).WillOnce(Return(apiShaderModule1));
	FlushClient();

	WGPUShaderModule apiShaderModule2 = api.GetNewShaderModule();
	WGPUShaderModule shaderModule2 = wgpuDeviceCreateShaderModule(device, &shaderModuleDesc);
	EXPECT_CALL(api, DeviceCreateShaderModule(apiDevice, _)).WillOnce(Return(apiShaderModule2));
	FlushClient();

	WGPUProgrammableStageDescriptor extraStageDesc = {};
	extraStageDesc.module = shaderModule1;
	extraStageDesc.entryPoint = "my other module";

	WGPURenderPipelineDescriptorDummyExtension clientExt = {};
	clientExt.chain.sType = WGPUSType_RenderPipelineDescriptorDummyExtension;
	clientExt.chain.next = nullptr;
	clientExt.dummyStage = extraStageDesc;

	WGPURenderPipelineDescriptor renderPipelineDesc = {};
	renderPipelineDesc.nextInChain = &clientExt.chain;
	renderPipelineDesc.vertexStage.module = shaderModule2;
	renderPipelineDesc.vertexStage.entryPoint = "my vertex module";

	wgpuDeviceCreateRenderPipeline(device, &renderPipelineDesc);
	EXPECT_CALL(api, DeviceCreateRenderPipeline(apiDevice, NotNull()))
	.WillOnce(Invoke([&](Unused,
	const WGPURenderPipelineDescriptor* serverDesc) -> WGPURenderPipeline {
	EXPECT_EQ(serverDesc->vertexStage.module, apiShaderModule2);
	EXPECT_STREQ(serverDesc->vertexStage.entryPoint,
	renderPipelineDesc.vertexStage.entryPoint);

	const auto* ext = reinterpret_cast<const WGPURenderPipelineDescriptorDummyExtension*>(
	serverDesc->nextInChain);
	EXPECT_EQ(ext->chain.sType, clientExt.chain.sType);
	EXPECT_EQ(ext->dummyStage.module, apiShaderModule1);
	EXPECT_STREQ(ext->dummyStage.entryPoint, extraStageDesc.entryPoint);

	EXPECT_EQ(ext->chain.next, nullptr);

	return api.GetNewRenderPipeline();
	}));
	FlushClient();
	}