nn/runtime/test/TestMemory.cpp - platform/frameworks/ml - Git at Google

 /*
  * Copyright (C) 2017 The Android Open Source Project
  *
  * 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 "TestMemory.h"

 #include <android-base/scopeguard.h>
 #include <gtest/gtest.h>
 #include <sys/mman.h>
 #include <sys/types.h>
 #include <unistd.h>

 #include "TestNeuralNetworksWrapper.h"

 using WrapperCompilation = ::android::nn::test_wrapper::Compilation;
 using WrapperExecution = ::android::nn::test_wrapper::Execution;
 using WrapperMemory = ::android::nn::test_wrapper::Memory;
 using WrapperModel = ::android::nn::test_wrapper::Model;
 using WrapperOperandType = ::android::nn::test_wrapper::OperandType;
 using WrapperResult = ::android::nn::test_wrapper::Result;
 using WrapperType = ::android::nn::test_wrapper::Type;

 namespace {

 // Tests the various ways to pass weights and input/output data.
 class MemoryTest : public ::testing::Test {
    protected:
     void SetUp() override {}
 };

 TEST_F(MemoryTest, TestFd) {
     // Create a file that contains matrix2 and matrix3.
     char path[] = "/data/local/tmp/TestMemoryXXXXXX";
     int fd = mkstemp(path);
     const uint32_t offsetForMatrix2 = 20;
     const uint32_t offsetForMatrix3 = 200;
     static_assert(offsetForMatrix2 + sizeof(matrix2) < offsetForMatrix3, "matrices overlap");
     lseek(fd, offsetForMatrix2, SEEK_SET);
     write(fd, matrix2, sizeof(matrix2));
     lseek(fd, offsetForMatrix3, SEEK_SET);
     write(fd, matrix3, sizeof(matrix3));
     fsync(fd);

     WrapperMemory weights(offsetForMatrix3 + sizeof(matrix3), PROT_READ, fd, 0);
     ASSERT_TRUE(weights.isValid());

     WrapperModel model;
     WrapperOperandType matrixType(WrapperType::TENSOR_FLOAT32, {3, 4});
     WrapperOperandType scalarType(WrapperType::INT32, {});
     int32_t activation(0);
     auto a = model.addOperand(&matrixType);
     auto b = model.addOperand(&matrixType);
     auto c = model.addOperand(&matrixType);
     auto d = model.addOperand(&matrixType);
     auto e = model.addOperand(&matrixType);
     auto f = model.addOperand(&scalarType);

     model.setOperandValueFromMemory(e, &weights, offsetForMatrix2, sizeof(Matrix3x4));
     model.setOperandValueFromMemory(a, &weights, offsetForMatrix3, sizeof(Matrix3x4));
     model.setOperandValue(f, &activation, sizeof(activation));
     model.addOperation(ANEURALNETWORKS_ADD, {a, c, f}, {b});
     model.addOperation(ANEURALNETWORKS_ADD, {b, e, f}, {d});
     model.identifyInputsAndOutputs({c}, {d});
     ASSERT_TRUE(model.isValid());
     model.finish();

     // Test the three node model.
     Matrix3x4 actual;
     memset(&actual, 0, sizeof(actual));
     WrapperCompilation compilation2(&model);
     ASSERT_EQ(compilation2.finish(), WrapperResult::NO_ERROR);
     WrapperExecution execution2(&compilation2);
     ASSERT_EQ(execution2.setInput(0, matrix1, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
     ASSERT_EQ(execution2.setOutput(0, actual, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
     ASSERT_EQ(execution2.compute(), WrapperResult::NO_ERROR);
     ASSERT_EQ(CompareMatrices(expected3, actual), 0);

     close(fd);
     unlink(path);
 }

 // Hardware buffers are an Android concept, which aren't necessarily
 // available on other platforms such as ChromeOS, which also build NNAPI.
 #if defined(__ANDROID__)
 TEST_F(MemoryTest, TestAHardwareBuffer) {
     const uint32_t offsetForMatrix2 = 20;
     const uint32_t offsetForMatrix3 = 200;

     AHardwareBuffer_Desc desc{
             .width = offsetForMatrix3 + sizeof(matrix3),
             .height = 1,
             .layers = 1,
             .format = AHARDWAREBUFFER_FORMAT_BLOB,
             .usage = AHARDWAREBUFFER_USAGE_CPU_READ_OFTEN | AHARDWAREBUFFER_USAGE_CPU_WRITE_OFTEN,
     };
     AHardwareBuffer* buffer = nullptr;
     ASSERT_EQ(AHardwareBuffer_allocate(&desc, &buffer), 0);
     auto allocateGuard =
             android::base::make_scope_guard([buffer]() { AHardwareBuffer_release(buffer); });

     void* bufferPtr = nullptr;
     ASSERT_EQ(AHardwareBuffer_lock(buffer, desc.usage, -1, NULL, &bufferPtr), 0);
     memcpy((uint8_t*)bufferPtr + offsetForMatrix2, matrix2, sizeof(matrix2));
     memcpy((uint8_t*)bufferPtr + offsetForMatrix3, matrix3, sizeof(matrix3));
     ASSERT_EQ(AHardwareBuffer_unlock(buffer, nullptr), 0);

     WrapperMemory weights(buffer);
     ASSERT_TRUE(weights.isValid());

     WrapperModel model;
     WrapperOperandType matrixType(WrapperType::TENSOR_FLOAT32, {3, 4});
     WrapperOperandType scalarType(WrapperType::INT32, {});
     int32_t activation(0);
     auto a = model.addOperand(&matrixType);
     auto b = model.addOperand(&matrixType);
     auto c = model.addOperand(&matrixType);
     auto d = model.addOperand(&matrixType);
     auto e = model.addOperand(&matrixType);
     auto f = model.addOperand(&scalarType);

     model.setOperandValueFromMemory(e, &weights, offsetForMatrix2, sizeof(Matrix3x4));
     model.setOperandValueFromMemory(a, &weights, offsetForMatrix3, sizeof(Matrix3x4));
     model.setOperandValue(f, &activation, sizeof(activation));
     model.addOperation(ANEURALNETWORKS_ADD, {a, c, f}, {b});
     model.addOperation(ANEURALNETWORKS_ADD, {b, e, f}, {d});
     model.identifyInputsAndOutputs({c}, {d});
     ASSERT_TRUE(model.isValid());
     model.finish();

     // Test the three node model.
     Matrix3x4 actual;
     memset(&actual, 0, sizeof(actual));
     WrapperCompilation compilation2(&model);
     ASSERT_EQ(compilation2.finish(), WrapperResult::NO_ERROR);
     WrapperExecution execution2(&compilation2);
     ASSERT_EQ(execution2.setInput(0, matrix1, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
     ASSERT_EQ(execution2.setOutput(0, actual, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
     ASSERT_EQ(execution2.compute(), WrapperResult::NO_ERROR);
     ASSERT_EQ(CompareMatrices(expected3, actual), 0);
 }
 #endif

 }  // end namespace
	/*
	* Copyright (C) 2017 The Android Open Source Project
	*
	* 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 "TestMemory.h"

	#include <android-base/scopeguard.h>
	#include <gtest/gtest.h>
	#include <sys/mman.h>
	#include <sys/types.h>
	#include <unistd.h>

	#include "TestNeuralNetworksWrapper.h"

	using WrapperCompilation = ::android::nn::test_wrapper::Compilation;
	using WrapperExecution = ::android::nn::test_wrapper::Execution;
	using WrapperMemory = ::android::nn::test_wrapper::Memory;
	using WrapperModel = ::android::nn::test_wrapper::Model;
	using WrapperOperandType = ::android::nn::test_wrapper::OperandType;
	using WrapperResult = ::android::nn::test_wrapper::Result;
	using WrapperType = ::android::nn::test_wrapper::Type;

	namespace {

	// Tests the various ways to pass weights and input/output data.
	class MemoryTest : public ::testing::Test {
	protected:
	void SetUp() override {}
	};

	TEST_F(MemoryTest, TestFd) {
	// Create a file that contains matrix2 and matrix3.
	char path[] = "/data/local/tmp/TestMemoryXXXXXX";
	int fd = mkstemp(path);
	const uint32_t offsetForMatrix2 = 20;
	const uint32_t offsetForMatrix3 = 200;
	static_assert(offsetForMatrix2 + sizeof(matrix2) < offsetForMatrix3, "matrices overlap");
	lseek(fd, offsetForMatrix2, SEEK_SET);
	write(fd, matrix2, sizeof(matrix2));
	lseek(fd, offsetForMatrix3, SEEK_SET);
	write(fd, matrix3, sizeof(matrix3));
	fsync(fd);

	WrapperMemory weights(offsetForMatrix3 + sizeof(matrix3), PROT_READ, fd, 0);
	ASSERT_TRUE(weights.isValid());

	WrapperModel model;
	WrapperOperandType matrixType(WrapperType::TENSOR_FLOAT32, {3, 4});
	WrapperOperandType scalarType(WrapperType::INT32, {});
	int32_t activation(0);
	auto a = model.addOperand(&matrixType);
	auto b = model.addOperand(&matrixType);
	auto c = model.addOperand(&matrixType);
	auto d = model.addOperand(&matrixType);
	auto e = model.addOperand(&matrixType);
	auto f = model.addOperand(&scalarType);

	model.setOperandValueFromMemory(e, &weights, offsetForMatrix2, sizeof(Matrix3x4));
	model.setOperandValueFromMemory(a, &weights, offsetForMatrix3, sizeof(Matrix3x4));
	model.setOperandValue(f, &activation, sizeof(activation));
	model.addOperation(ANEURALNETWORKS_ADD, {a, c, f}, {b});
	model.addOperation(ANEURALNETWORKS_ADD, {b, e, f}, {d});
	model.identifyInputsAndOutputs({c}, {d});
	ASSERT_TRUE(model.isValid());
	model.finish();

	// Test the three node model.
	Matrix3x4 actual;
	memset(&actual, 0, sizeof(actual));
	WrapperCompilation compilation2(&model);
	ASSERT_EQ(compilation2.finish(), WrapperResult::NO_ERROR);
	WrapperExecution execution2(&compilation2);
	ASSERT_EQ(execution2.setInput(0, matrix1, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
	ASSERT_EQ(execution2.setOutput(0, actual, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
	ASSERT_EQ(execution2.compute(), WrapperResult::NO_ERROR);
	ASSERT_EQ(CompareMatrices(expected3, actual), 0);

	close(fd);
	unlink(path);
	}

	// Hardware buffers are an Android concept, which aren't necessarily
	// available on other platforms such as ChromeOS, which also build NNAPI.
	#if defined(__ANDROID__)
	TEST_F(MemoryTest, TestAHardwareBuffer) {
	const uint32_t offsetForMatrix2 = 20;
	const uint32_t offsetForMatrix3 = 200;

	AHardwareBuffer_Desc desc{
	.width = offsetForMatrix3 + sizeof(matrix3),
	.height = 1,
	.layers = 1,
	.format = AHARDWAREBUFFER_FORMAT_BLOB,
	.usage = AHARDWAREBUFFER_USAGE_CPU_READ_OFTEN \| AHARDWAREBUFFER_USAGE_CPU_WRITE_OFTEN,
	};
	AHardwareBuffer* buffer = nullptr;
	ASSERT_EQ(AHardwareBuffer_allocate(&desc, &buffer), 0);
	auto allocateGuard =
	android::base::make_scope_guard([buffer]() { AHardwareBuffer_release(buffer); });

	void* bufferPtr = nullptr;
	ASSERT_EQ(AHardwareBuffer_lock(buffer, desc.usage, -1, NULL, &bufferPtr), 0);
	memcpy((uint8_t*)bufferPtr + offsetForMatrix2, matrix2, sizeof(matrix2));
	memcpy((uint8_t*)bufferPtr + offsetForMatrix3, matrix3, sizeof(matrix3));
	ASSERT_EQ(AHardwareBuffer_unlock(buffer, nullptr), 0);

	WrapperMemory weights(buffer);
	ASSERT_TRUE(weights.isValid());

	WrapperModel model;
	WrapperOperandType matrixType(WrapperType::TENSOR_FLOAT32, {3, 4});
	WrapperOperandType scalarType(WrapperType::INT32, {});
	int32_t activation(0);
	auto a = model.addOperand(&matrixType);
	auto b = model.addOperand(&matrixType);
	auto c = model.addOperand(&matrixType);
	auto d = model.addOperand(&matrixType);
	auto e = model.addOperand(&matrixType);
	auto f = model.addOperand(&scalarType);

	model.setOperandValueFromMemory(e, &weights, offsetForMatrix2, sizeof(Matrix3x4));
	model.setOperandValueFromMemory(a, &weights, offsetForMatrix3, sizeof(Matrix3x4));
	model.setOperandValue(f, &activation, sizeof(activation));
	model.addOperation(ANEURALNETWORKS_ADD, {a, c, f}, {b});
	model.addOperation(ANEURALNETWORKS_ADD, {b, e, f}, {d});
	model.identifyInputsAndOutputs({c}, {d});
	ASSERT_TRUE(model.isValid());
	model.finish();

	// Test the three node model.
	Matrix3x4 actual;
	memset(&actual, 0, sizeof(actual));
	WrapperCompilation compilation2(&model);
	ASSERT_EQ(compilation2.finish(), WrapperResult::NO_ERROR);
	WrapperExecution execution2(&compilation2);
	ASSERT_EQ(execution2.setInput(0, matrix1, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
	ASSERT_EQ(execution2.setOutput(0, actual, sizeof(Matrix3x4)), WrapperResult::NO_ERROR);
	ASSERT_EQ(execution2.compute(), WrapperResult::NO_ERROR);
	ASSERT_EQ(CompareMatrices(expected3, actual), 0);
	}
	#endif

	} // end namespace