neuralnetworks/1.3/vts/functional/ValidateRequest.cpp - android_hardware_interfaces - Gitiles

 /*
  * Copyright (C) 2018 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.
  */

 #define LOG_TAG "neuralnetworks_hidl_hal_test"

 #include <chrono>
 #include "1.0/Utils.h"
 #include "1.2/Callbacks.h"
 #include "ExecutionBurstController.h"
 #include "GeneratedTestHarness.h"
 #include "TestHarness.h"
 #include "Utils.h"
 #include "VtsHalNeuralnetworks.h"

 namespace android::hardware::neuralnetworks::V1_3::vts::functional {

 using V1_0::ErrorStatus;
 using V1_2::MeasureTiming;
 using V1_2::OutputShape;
 using V1_2::Timing;
 using V1_2::implementation::ExecutionCallback;

 ///////////////////////// UTILITY FUNCTIONS /////////////////////////

 static bool badTiming(Timing timing) {
     return timing.timeOnDevice == UINT64_MAX && timing.timeInDriver == UINT64_MAX;
 }

 // Primary validation function. This function will take a valid request, apply a
 // mutation to it to invalidate the request, then pass it to interface calls
 // that use the request. Note that the request here is passed by value, and any
 // mutation to the request does not leave this function.
 static void validate(const sp<IPreparedModel>& preparedModel, const std::string& message,
                      Request request, const std::function<void(Request*)>& mutation) {
     mutation(&request);

     // We'd like to test both with timing requested and without timing
     // requested. Rather than running each test both ways, we'll decide whether
     // to request timing by hashing the message. We do not use std::hash because
     // it is not guaranteed stable across executions.
     char hash = 0;
     for (auto c : message) {
         hash ^= c;
     };
     MeasureTiming measure = (hash & 1) ? MeasureTiming::YES : MeasureTiming::NO;

     // asynchronous
     {
         SCOPED_TRACE(message + " [execute_1_3]");

         sp<ExecutionCallback> executionCallback = new ExecutionCallback();
         Return<ErrorStatus> executeLaunchStatus =
                 preparedModel->execute_1_3(request, measure, executionCallback);
         ASSERT_TRUE(executeLaunchStatus.isOk());
         ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, static_cast<ErrorStatus>(executeLaunchStatus));

         executionCallback->wait();
         ErrorStatus executionReturnStatus = executionCallback->getStatus();
         const auto& outputShapes = executionCallback->getOutputShapes();
         Timing timing = executionCallback->getTiming();
         ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, executionReturnStatus);
         ASSERT_EQ(outputShapes.size(), 0);
         ASSERT_TRUE(badTiming(timing));
     }

     // synchronous
     {
         SCOPED_TRACE(message + " [executeSynchronously_1_3]");

         Return<void> executeStatus = preparedModel->executeSynchronously_1_3(
                 request, measure,
                 [](ErrorStatus error, const hidl_vec<OutputShape>& outputShapes,
                    const Timing& timing) {
                     ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, error);
                     EXPECT_EQ(outputShapes.size(), 0);
                     EXPECT_TRUE(badTiming(timing));
                 });
         ASSERT_TRUE(executeStatus.isOk());
     }

     // burst
     // TODO(butlermichael): Check if we need to test burst in V1_3 if the interface remains V1_2.
     {
         SCOPED_TRACE(message + " [burst]");

         ASSERT_TRUE(nn::compliantWithV1_0(request));
         V1_0::Request request10 = nn::convertToV1_0(request);

         // create burst
         std::shared_ptr<::android::nn::ExecutionBurstController> burst =
                 android::nn::ExecutionBurstController::create(preparedModel,
                                                               std::chrono::microseconds{0});
         ASSERT_NE(nullptr, burst.get());

         // create memory keys
         std::vector<intptr_t> keys(request10.pools.size());
         for (size_t i = 0; i < keys.size(); ++i) {
             keys[i] = reinterpret_cast<intptr_t>(&request10.pools[i]);
         }

         // execute and verify
         const auto [n, outputShapes, timing, fallback] = burst->compute(request10, measure, keys);
         const ErrorStatus status = nn::convertResultCodeToErrorStatus(n);
         EXPECT_EQ(ErrorStatus::INVALID_ARGUMENT, status);
         EXPECT_EQ(outputShapes.size(), 0);
         EXPECT_TRUE(badTiming(timing));
         EXPECT_FALSE(fallback);

         // additional burst testing
         if (request10.pools.size() > 0) {
             // valid free
             burst->freeMemory(keys.front());

             // negative test: invalid free of unknown (blank) memory
             burst->freeMemory(intptr_t{});

             // negative test: double free of memory
             burst->freeMemory(keys.front());
         }
     }
 }

 ///////////////////////// REMOVE INPUT ////////////////////////////////////

 static void removeInputTest(const sp<IPreparedModel>& preparedModel, const Request& request) {
     for (size_t input = 0; input < request.inputs.size(); ++input) {
         const std::string message = "removeInput: removed input " + std::to_string(input);
         validate(preparedModel, message, request,
                  [input](Request* request) { hidl_vec_removeAt(&request->inputs, input); });
     }
 }

 ///////////////////////// REMOVE OUTPUT ////////////////////////////////////

 static void removeOutputTest(const sp<IPreparedModel>& preparedModel, const Request& request) {
     for (size_t output = 0; output < request.outputs.size(); ++output) {
         const std::string message = "removeOutput: removed Output " + std::to_string(output);
         validate(preparedModel, message, request,
                  [output](Request* request) { hidl_vec_removeAt(&request->outputs, output); });
     }
 }

 ///////////////////////////// ENTRY POINT //////////////////////////////////

 void validateRequest(const sp<IPreparedModel>& preparedModel, const Request& request) {
     removeInputTest(preparedModel, request);
     removeOutputTest(preparedModel, request);
 }

 void validateRequestFailure(const sp<IPreparedModel>& preparedModel, const Request& request) {
     SCOPED_TRACE("Expecting request to fail [executeSynchronously_1_3]");
     Return<void> executeStatus = preparedModel->executeSynchronously_1_3(
             request, MeasureTiming::NO,
             [](ErrorStatus error, const hidl_vec<OutputShape>& outputShapes, const Timing& timing) {
                 ASSERT_NE(ErrorStatus::NONE, error);
                 EXPECT_EQ(outputShapes.size(), 0);
                 EXPECT_TRUE(badTiming(timing));
             });
     ASSERT_TRUE(executeStatus.isOk());
 }

 }  // namespace android::hardware::neuralnetworks::V1_3::vts::functional
	/*
	* Copyright (C) 2018 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.
	*/

	#define LOG_TAG "neuralnetworks_hidl_hal_test"

	#include <chrono>
	#include "1.0/Utils.h"
	#include "1.2/Callbacks.h"
	#include "ExecutionBurstController.h"
	#include "GeneratedTestHarness.h"
	#include "TestHarness.h"
	#include "Utils.h"
	#include "VtsHalNeuralnetworks.h"

	namespace android::hardware::neuralnetworks::V1_3::vts::functional {

	using V1_0::ErrorStatus;
	using V1_2::MeasureTiming;
	using V1_2::OutputShape;
	using V1_2::Timing;
	using V1_2::implementation::ExecutionCallback;

	///////////////////////// UTILITY FUNCTIONS /////////////////////////

	static bool badTiming(Timing timing) {
	return timing.timeOnDevice == UINT64_MAX && timing.timeInDriver == UINT64_MAX;
	}

	// Primary validation function. This function will take a valid request, apply a
	// mutation to it to invalidate the request, then pass it to interface calls
	// that use the request. Note that the request here is passed by value, and any
	// mutation to the request does not leave this function.
	static void validate(const sp<IPreparedModel>& preparedModel, const std::string& message,
	Request request, const std::function<void(Request*)>& mutation) {
	mutation(&request);

	// We'd like to test both with timing requested and without timing
	// requested. Rather than running each test both ways, we'll decide whether
	// to request timing by hashing the message. We do not use std::hash because
	// it is not guaranteed stable across executions.
	char hash = 0;
	for (auto c : message) {
	hash ^= c;
	};
	MeasureTiming measure = (hash & 1) ? MeasureTiming::YES : MeasureTiming::NO;

	// asynchronous
	{
	SCOPED_TRACE(message + " [execute_1_3]");

	sp<ExecutionCallback> executionCallback = new ExecutionCallback();
	Return<ErrorStatus> executeLaunchStatus =
	preparedModel->execute_1_3(request, measure, executionCallback);
	ASSERT_TRUE(executeLaunchStatus.isOk());
	ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, static_cast<ErrorStatus>(executeLaunchStatus));

	executionCallback->wait();
	ErrorStatus executionReturnStatus = executionCallback->getStatus();
	const auto& outputShapes = executionCallback->getOutputShapes();
	Timing timing = executionCallback->getTiming();
	ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, executionReturnStatus);
	ASSERT_EQ(outputShapes.size(), 0);
	ASSERT_TRUE(badTiming(timing));
	}

	// synchronous
	{
	SCOPED_TRACE(message + " [executeSynchronously_1_3]");

	Return<void> executeStatus = preparedModel->executeSynchronously_1_3(
	request, measure,
	[](ErrorStatus error, const hidl_vec<OutputShape>& outputShapes,
	const Timing& timing) {
	ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, error);
	EXPECT_EQ(outputShapes.size(), 0);
	EXPECT_TRUE(badTiming(timing));
	});
	ASSERT_TRUE(executeStatus.isOk());
	}

	// burst
	// TODO(butlermichael): Check if we need to test burst in V1_3 if the interface remains V1_2.
	{
	SCOPED_TRACE(message + " [burst]");

	ASSERT_TRUE(nn::compliantWithV1_0(request));
	V1_0::Request request10 = nn::convertToV1_0(request);

	// create burst
	std::shared_ptr<::android::nn::ExecutionBurstController> burst =
	android::nn::ExecutionBurstController::create(preparedModel,
	std::chrono::microseconds{0});
	ASSERT_NE(nullptr, burst.get());

	// create memory keys
	std::vector<intptr_t> keys(request10.pools.size());
	for (size_t i = 0; i < keys.size(); ++i) {
	keys[i] = reinterpret_cast<intptr_t>(&request10.pools[i]);
	}

	// execute and verify
	const auto [n, outputShapes, timing, fallback] = burst->compute(request10, measure, keys);
	const ErrorStatus status = nn::convertResultCodeToErrorStatus(n);
	EXPECT_EQ(ErrorStatus::INVALID_ARGUMENT, status);
	EXPECT_EQ(outputShapes.size(), 0);
	EXPECT_TRUE(badTiming(timing));
	EXPECT_FALSE(fallback);

	// additional burst testing
	if (request10.pools.size() > 0) {
	// valid free
	burst->freeMemory(keys.front());

	// negative test: invalid free of unknown (blank) memory
	burst->freeMemory(intptr_t{});

	// negative test: double free of memory
	burst->freeMemory(keys.front());
	}
	}
	}

	///////////////////////// REMOVE INPUT ////////////////////////////////////

	static void removeInputTest(const sp<IPreparedModel>& preparedModel, const Request& request) {
	for (size_t input = 0; input < request.inputs.size(); ++input) {
	const std::string message = "removeInput: removed input " + std::to_string(input);
	validate(preparedModel, message, request,
	[input](Request* request) { hidl_vec_removeAt(&request->inputs, input); });
	}
	}

	///////////////////////// REMOVE OUTPUT ////////////////////////////////////

	static void removeOutputTest(const sp<IPreparedModel>& preparedModel, const Request& request) {
	for (size_t output = 0; output < request.outputs.size(); ++output) {
	const std::string message = "removeOutput: removed Output " + std::to_string(output);
	validate(preparedModel, message, request,
	[output](Request* request) { hidl_vec_removeAt(&request->outputs, output); });
	}
	}

	///////////////////////////// ENTRY POINT //////////////////////////////////

	void validateRequest(const sp<IPreparedModel>& preparedModel, const Request& request) {
	removeInputTest(preparedModel, request);
	removeOutputTest(preparedModel, request);
	}

	void validateRequestFailure(const sp<IPreparedModel>& preparedModel, const Request& request) {
	SCOPED_TRACE("Expecting request to fail [executeSynchronously_1_3]");
	Return<void> executeStatus = preparedModel->executeSynchronously_1_3(
	request, MeasureTiming::NO,
	[](ErrorStatus error, const hidl_vec<OutputShape>& outputShapes, const Timing& timing) {
	ASSERT_NE(ErrorStatus::NONE, error);
	EXPECT_EQ(outputShapes.size(), 0);
	EXPECT_TRUE(badTiming(timing));
	});
	ASSERT_TRUE(executeStatus.isOk());
	}

	} // namespace android::hardware::neuralnetworks::V1_3::vts::functional