Google Git
Sign in
android / platform / hardware / interfaces / refs/heads/main / . / neuralnetworks / 1.1 / vts / functional / BasicTests.cpp
blob: baadd1b23bb861781961b3bbaca486c51d548316 [file] [log] [blame]
/*
* 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 "VtsHalNeuralnetworks.h"
#include "1.0/Callbacks.h"
namespace android::hardware::neuralnetworks::V1_1::vts::functional {
using V1_0::DeviceStatus;
using V1_0::ErrorStatus;
using V1_0::Operand;
using V1_0::OperandLifeTime;
using V1_0::OperandType;
using V1_0::implementation::PreparedModelCallback;
// create device test
TEST_P(NeuralnetworksHidlTest, CreateDevice) {}
// status test
TEST_P(NeuralnetworksHidlTest, StatusTest) {
Return<DeviceStatus> status = kDevice->getStatus();
ASSERT_TRUE(status.isOk());
EXPECT_EQ(DeviceStatus::AVAILABLE, static_cast<DeviceStatus>(status));
}
// initialization
TEST_P(NeuralnetworksHidlTest, GetCapabilitiesTest) {
Return<void> ret =
kDevice->getCapabilities_1_1([](ErrorStatus status, const Capabilities& capabilities) {
EXPECT_EQ(ErrorStatus::NONE, status);
EXPECT_LT(0.0f, capabilities.float32Performance.execTime);
EXPECT_LT(0.0f, capabilities.float32Performance.powerUsage);
EXPECT_LT(0.0f, capabilities.quantized8Performance.execTime);
EXPECT_LT(0.0f, capabilities.quantized8Performance.powerUsage);
EXPECT_LT(0.0f, capabilities.relaxedFloat32toFloat16Performance.execTime);
EXPECT_LT(0.0f, capabilities.relaxedFloat32toFloat16Performance.powerUsage);
});
EXPECT_TRUE(ret.isOk());
}
// detect cycle
TEST_P(NeuralnetworksHidlTest, CycleTest) {
// opnd0 = TENSOR_FLOAT32 // model input
// opnd1 = TENSOR_FLOAT32 // model input
// opnd2 = INT32 // model input
// opnd3 = ADD(opnd0, opnd4, opnd2)
// opnd4 = ADD(opnd1, opnd3, opnd2)
// opnd5 = ADD(opnd4, opnd0, opnd2) // model output
//
// +-----+
// | |
// v |
// 3 = ADD(0, 4, 2) |
// | |
// +----------+ |
// | |
// v |
// 4 = ADD(1, 3, 2) |
// | |
// +----------------+
// |
// |
// +-------+
// |
// v
// 5 = ADD(4, 0, 2)
const std::vector<Operand> operands = {
{
// operands[0]
.type = OperandType::TENSOR_FLOAT32,
.dimensions = {1},
.numberOfConsumers = 2,
.scale = 0.0f,
.zeroPoint = 0,
.lifetime = OperandLifeTime::MODEL_INPUT,
.location = {.poolIndex = 0, .offset = 0, .length = 0},
},
{
// operands[1]
.type = OperandType::TENSOR_FLOAT32,
.dimensions = {1},
.numberOfConsumers = 1,
.scale = 0.0f,
.zeroPoint = 0,
.lifetime = OperandLifeTime::MODEL_INPUT,
.location = {.poolIndex = 0, .offset = 0, .length = 0},
},
{
// operands[2]
.type = OperandType::INT32,
.dimensions = {},
.numberOfConsumers = 3,
.scale = 0.0f,
.zeroPoint = 0,
.lifetime = OperandLifeTime::MODEL_INPUT,
.location = {.poolIndex = 0, .offset = 0, .length = 0},
},
{
// operands[3]
.type = OperandType::TENSOR_FLOAT32,
.dimensions = {1},
.numberOfConsumers = 1,
.scale = 0.0f,
.zeroPoint = 0,
.lifetime = OperandLifeTime::TEMPORARY_VARIABLE,
.location = {.poolIndex = 0, .offset = 0, .length = 0},
},
{
// operands[4]
.type = OperandType::TENSOR_FLOAT32,
.dimensions = {1},
.numberOfConsumers = 2,
.scale = 0.0f,
.zeroPoint = 0,
.lifetime = OperandLifeTime::TEMPORARY_VARIABLE,
.location = {.poolIndex = 0, .offset = 0, .length = 0},
},
{
// operands[5]
.type = OperandType::TENSOR_FLOAT32,
.dimensions = {1},
.numberOfConsumers = 0,
.scale = 0.0f,
.zeroPoint = 0,
.lifetime = OperandLifeTime::MODEL_OUTPUT,
.location = {.poolIndex = 0, .offset = 0, .length = 0},
},
};
const std::vector<Operation> operations = {
{.type = OperationType::ADD, .inputs = {0, 4, 2}, .outputs = {3}},
{.type = OperationType::ADD, .inputs = {1, 3, 2}, .outputs = {4}},
{.type = OperationType::ADD, .inputs = {4, 0, 2}, .outputs = {5}},
};
const Model model = {
.operands = operands,
.operations = operations,
.inputIndexes = {0, 1, 2},
.outputIndexes = {5},
.operandValues = {},
.pools = {},
};
// ensure that getSupportedOperations_1_1() checks model validity
ErrorStatus supportedOpsErrorStatus = ErrorStatus::GENERAL_FAILURE;
Return<void> supportedOpsReturn = kDevice->getSupportedOperations_1_1(
model, [&model, &supportedOpsErrorStatus](ErrorStatus status,
const hidl_vec<bool>& supported) {
supportedOpsErrorStatus = status;
if (status == ErrorStatus::NONE) {
ASSERT_EQ(supported.size(), model.operations.size());
}
});
ASSERT_TRUE(supportedOpsReturn.isOk());
ASSERT_EQ(supportedOpsErrorStatus, ErrorStatus::INVALID_ARGUMENT);
// ensure that prepareModel_1_1() checks model validity
sp<PreparedModelCallback> preparedModelCallback = new PreparedModelCallback;
Return<ErrorStatus> prepareLaunchReturn = kDevice->prepareModel_1_1(
model, ExecutionPreference::FAST_SINGLE_ANSWER, preparedModelCallback);
ASSERT_TRUE(prepareLaunchReturn.isOk());
// Note that preparation can fail for reasons other than an
// invalid model (invalid model should result in
// INVALID_ARGUMENT) -- for example, perhaps not all
// operations are supported, or perhaps the device hit some
// kind of capacity limit.
EXPECT_NE(prepareLaunchReturn, ErrorStatus::NONE);
EXPECT_NE(preparedModelCallback->getStatus(), ErrorStatus::NONE);
EXPECT_EQ(preparedModelCallback->getPreparedModel(), nullptr);
}
} // namespace android::hardware::neuralnetworks::V1_1::vts::functional