#include "lite_build_config.h"
#if LITE_BUILD_WITH_MGE
#include "./test_common.h"
#include "megbrain/tensor.h"
#ifndef WIN32
#include <dirent.h>
#include <string.h>
#endif
#include <chrono>
#include <memory>
#include <random>
#include <unordered_map>
using namespace lite;
namespace {
class CheckAllocator : public lite::Allocator {
public:
void* allocate(LiteDeviceType device, int, size_t size, size_t align) override {
LITE_ASSERT(device == LiteDeviceType::LITE_CPU);
m_nr_left++;
m_nr_allocated++;
#ifdef WIN32
return _aligned_malloc(size, align);
#elif defined(__ANDROID__) || defined(ANDROID)
return memalign(align, size);
#else
void* ptr = nullptr;
auto err = posix_memalign(&ptr, align, size);
mgb_assert(!err, "failed to malloc %zubytes with align %zu", size, align);
return ptr;
#endif
};
void free(LiteDeviceType device, int, void* ptr) override {
m_nr_left--;
LITE_ASSERT(device == LiteDeviceType::LITE_CPU);
#ifdef WIN32
_aligned_free(ptr);
#else
::free(ptr);
#endif
};
std::atomic_size_t m_nr_left{0};
std::atomic_size_t m_nr_allocated{0};
};
}
TEST(TestNetWork, Basic) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_lite = mgelite_lar(model_path, config, "data", lite_tensor);
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
compare_lite_tensor<float>(result_lite, result_mgb);
}
TEST(TestNetWork, RefCount) {
Config config;
ASSERT_EQ(NetworkRefCount::Instance().refcount(), 0);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
ASSERT_EQ(NetworkRefCount::Instance().refcount(), 1);
std::shared_ptr<Network> network_s = std::make_shared<Network>(config);
ASSERT_EQ(NetworkRefCount::Instance().refcount(), 2);
network.reset();
ASSERT_EQ(NetworkRefCount::Instance().refcount(), 1);
network_s.reset();
ASSERT_EQ(NetworkRefCount::Instance().refcount(), 0);
}
TEST(TestNetWork, SetDeviceId) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->set_device_id(4);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
network->forward();
network->wait();
ASSERT_EQ(input_tensor->get_device_id(), 4);
ASSERT_EQ(output_tensor->get_device_id(), 4);
}
TEST(TestNetWork, GetAllName) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
auto input_names = network->get_all_input_name();
auto output_names = network->get_all_output_name();
auto output_tensor = network->get_output_tensor(0);
auto out_layout = output_tensor->get_layout();
ASSERT_EQ(out_layout.ndim, 2);
ASSERT_EQ(out_layout.shapes[0], 1);
ASSERT_EQ(out_layout.shapes[1], 1000);
ASSERT_EQ(input_names.size(), 1);
ASSERT_EQ(output_names.size(), 1);
ASSERT_TRUE(input_names[0] == "data");
ASSERT_TRUE(output_names[0] == "TRUE_DIV(EXP[12065],reduce0[12067])[12077]");
}
TEST(TestNetWork, GetAllIoInfoAhead) {
Config config;
std::string model_path = "./shufflenet.mge";
auto ios = Runtime::get_model_io_info(model_path);
FILE* fin = fopen(model_path.c_str(), "rb");
ASSERT_TRUE(fin);
fseek(fin, 0, SEEK_END);
size_t size = ftell(fin);
fseek(fin, 0, SEEK_SET);
void* ptr = malloc(size);
std::shared_ptr<void> buf{ptr, ::free};
auto nr = fread(buf.get(), 1, size, fin);
LITE_ASSERT(nr == size);
fclose(fin);
auto ios_mem = Runtime::get_model_io_info(ptr, size);
ASSERT_EQ(ios.inputs.size(), ios_mem.inputs.size());
ASSERT_EQ(ios.inputs.size(), 1);
ASSERT_EQ(ios.outputs.size(), ios_mem.outputs.size());
ASSERT_EQ(ios.outputs.size(), 1);
ASSERT_TRUE(ios.inputs[0].name == "data");
ASSERT_TRUE(ios.outputs[0].name == "TRUE_DIV(EXP[12065],reduce0[12067])[12077]");
ASSERT_TRUE(ios_mem.inputs[0].name == "data");
ASSERT_TRUE(
ios_mem.outputs[0].name == "TRUE_DIV(EXP[12065],reduce0[12067])[12077]");
ASSERT_EQ(ios.inputs[0].config_layout.ndim, 4);
ASSERT_EQ(ios.inputs[0].config_layout.shapes[1], 3);
ASSERT_EQ(ios.inputs[0].config_layout.shapes[2], 224);
ASSERT_EQ(ios.outputs[0].config_layout.ndim, 2);
ASSERT_EQ(ios.outputs[0].config_layout.shapes[0], 1);
ASSERT_EQ(ios.outputs[0].config_layout.shapes[1], 1000);
ASSERT_EQ(ios_mem.inputs[0].config_layout.ndim, 4);
ASSERT_EQ(ios_mem.inputs[0].config_layout.shapes[1], 3);
ASSERT_EQ(ios_mem.inputs[0].config_layout.shapes[2], 224);
ASSERT_EQ(ios_mem.outputs[0].config_layout.ndim, 2);
ASSERT_EQ(ios_mem.outputs[0].config_layout.shapes[0], 1);
ASSERT_EQ(ios_mem.outputs[0].config_layout.shapes[1], 1000);
}
TEST(TestNetWork, LoadFBSModel) {
Config config;
std::string model_path = "./ax.mge";
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
auto output_tensor = network->get_output_tensor(0);
auto out_layout = output_tensor->get_layout();
ASSERT_EQ(out_layout.ndim, 4);
ASSERT_EQ(out_layout.shapes[0], 1);
ASSERT_EQ(out_layout.shapes[1], 1);
ASSERT_EQ(out_layout.shapes[2], 40);
ASSERT_EQ(out_layout.shapes[3], 180);
}
TEST(TestNetWork, BasicInplaceAndSingleThreadAffinity) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
Runtime::set_cpu_inplace_mode(network);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
int affinity_set = false;
Runtime::set_runtime_thread_affinity(network, [&affinity_set](int id) {
ASSERT_EQ(id, 0);
affinity_set = true;
});
auto src_ptr = lite_tensor->get_memory_ptr();
auto src_layout = lite_tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
ASSERT_THROW(network->set_async_callback([]() {}), std::exception);
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
ASSERT_EQ(affinity_set, true);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, NetworkShareWeights) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
std::shared_ptr<Network> network2 = std::make_shared<Network>(config);
Runtime::set_cpu_inplace_mode(network2);
Runtime::shared_weight_with_network(network2, network);
std::shared_ptr<Tensor> input_tensor2 = network2->get_input_tensor(0);
auto src_ptr = lite_tensor->get_memory_ptr();
auto src_layout = lite_tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
input_tensor2->reset(src_ptr, src_layout);
ASSERT_NE(input_tensor, input_tensor2);
network->forward();
network->wait();
network2->forward();
network2->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
std::shared_ptr<Tensor> output_tensor2 = network2->get_output_tensor(0);
ASSERT_NE(output_tensor->get_memory_ptr(), output_tensor2->get_memory_ptr());
compare_lite_tensor<float>(output_tensor, result_mgb);
compare_lite_tensor<float>(output_tensor2, result_mgb);
}
TEST(TestNetWork, SharedRuntimeMem) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
std::shared_ptr<Network> network_src = std::make_shared<Network>(config);
std::shared_ptr<Network> network_dst = std::make_shared<Network>(config);
Runtime::share_runtime_memory_with(network_dst, network_src);
network_src->load_model(model_path);
network_dst->load_model(model_path);
}
TEST(TestNetWork, UserAllocator) {
auto allocator = std::make_shared<CheckAllocator>();
{
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
Runtime::set_memory_allocator(network, allocator);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
auto src_ptr = lite_tensor->get_memory_ptr();
auto src_layout = lite_tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
ASSERT_GE(allocator->m_nr_allocated, 1);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
ASSERT_EQ(allocator->m_nr_left, 0);
}
TEST(TestNetWork, BasicMultiThread) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
Runtime::set_cpu_threads_number(network, 2);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
auto src_ptr = lite_tensor->get_memory_ptr();
auto src_layout = lite_tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, ThreadAffinity) {
size_t nr_threads = 4;
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
Runtime::set_cpu_threads_number(network, nr_threads);
ASSERT_THROW(
Runtime::set_runtime_thread_affinity(network, [](int) {}), std::exception);
network->load_model(model_path);
std::vector<std::thread::id> thread_ids(nr_threads);
auto affinity = [&](int id) { thread_ids[id] = std::this_thread::get_id(); };
Runtime::set_runtime_thread_affinity(network, affinity);
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
auto src_ptr = lite_tensor->get_memory_ptr();
auto src_layout = lite_tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
for (size_t i = 0; i < nr_threads; i++) {
for (size_t j = i + 1; j < nr_threads; j++) {
ASSERT_NE(thread_ids[i], thread_ids[j]);
}
}
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, BasicCryptAes) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string model_crypt_path = "./shufflenet_crypt_aes.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
config.bare_model_cryption_name = "AES_default";
auto result_lite = mgelite_lar(model_crypt_path, config, "data", lite_tensor);
compare_lite_tensor<float>(result_lite, result_mgb);
}
TEST(TestNetWork, BasicCryptRc4) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string model_crypt_path = "./shufflenet_crypt_rc4.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
config.bare_model_cryption_name = "RC4_default";
auto result_lite = mgelite_lar(model_crypt_path, config, "data", lite_tensor);
compare_lite_tensor<float>(result_lite, result_mgb);
}
TEST(TestNetWork, PackedCryptRc4) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string model_crypt_path = "./test_packed_model_rc4.lite";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
auto result_lite = mgelite_lar(model_crypt_path, config, "data", lite_tensor);
compare_lite_tensor<float>(result_lite, result_mgb);
}
TEST(TestNetWork, BasicCryptSfRc4) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string model_crypt_path = "./shufflenet_crypt_sfrc4.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
config.bare_model_cryption_name = "SIMPLE_FAST_RC4_default";
auto result_lite = mgelite_lar(model_crypt_path, config, "data", lite_tensor);
compare_lite_tensor<float>(result_lite, result_mgb);
}
TEST(TestNetWork, ResetInput) {
Config config;
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, ChangeInputShape) {
Config config;
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_layout = Layout{{2, 3, 200, 200}, 4, LiteDataType::LITE_FLOAT};
input_tensor->set_layout(src_layout);
std::shared_ptr<Tensor> input_tensor2 = network->get_io_tensor(input_name);
ASSERT_EQ(input_tensor->get_memory_ptr(), input_tensor2->get_memory_ptr());
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
auto output_layout = output_tensor->get_layout();
ASSERT_EQ(output_layout.shapes[0], 2);
ASSERT_EQ(output_layout.shapes[1], 1000);
}
TEST(TestNetWork, ResetOutput) {
Config config;
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
auto result_tensor = std::make_shared<Tensor>(
LiteDeviceType::LITE_CPU, Layout{{1, 1000}, 2, LiteDataType::LITE_FLOAT});
void* out_data = result_tensor->get_memory_ptr();
output_tensor->reset(out_data, result_tensor->get_layout());
network->forward();
network->wait();
compare_lite_tensor<float>(output_tensor, result_mgb);
}
namespace {
void test_output_no_copy(int record) {
Config config;
config.options.force_output_use_user_specified_memory = true;
config.options.comp_node_seq_record_level = record;
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
size_t times = 5;
std::vector<std::shared_ptr<Tensor>> result_tensors;
for (size_t i = 0; i < times; i++) {
auto tmp = std::make_shared<Tensor>(
LiteDeviceType::LITE_CPU,
Layout{{1, 1000}, 2, LiteDataType::LITE_FLOAT});
result_tensors.push_back(tmp);
}
for (size_t i = 0; i < times; i++) {
void* out_data = result_tensors[i]->get_memory_ptr();
output_tensor->reset(out_data, result_tensors[i]->get_layout());
network->forward();
network->wait();
ASSERT_EQ(output_tensor->get_memory_ptr(), out_data);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
for (size_t i = 0; i < times; i++) {
compare_lite_tensor<float>(result_tensors[i], result_mgb);
}
}
void test_input_no_copy(int record) {
Config config;
config.options.force_output_use_user_specified_memory = true;
config.options.comp_node_seq_record_level = record;
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
Layout layout_in{{1, 3, 224, 224}, 4};
std::vector<std::shared_ptr<Tensor>> inputs;
std::vector<std::shared_ptr<Tensor>> outputs;
for (int i = 0; i < 3; i++) {
auto tmp_in = std::make_shared<Tensor>(LiteDeviceType::LITE_CPU, layout_in);
auto ptr = static_cast<float*>(tmp_in->get_memory_ptr());
for (size_t id = 0; id < 2 * 224 * 224; id++) {
ptr[id] = i + 1;
}
inputs.push_back(tmp_in);
outputs.push_back(mgb_lar(model_path, config, input_name, tmp_in));
}
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
for (int i = 0; i < 3; i++) {
auto ptr = inputs[i]->get_memory_ptr();
input_tensor->reset(ptr, layout_in);
auto tmp_out = std::make_shared<Tensor>(
LiteDeviceType::LITE_CPU,
Layout{{1, 1000}, 2, LiteDataType::LITE_FLOAT});
output_tensor->reset(tmp_out->get_memory_ptr(), output_tensor->get_layout());
network->forward();
network->wait();
compare_lite_tensor<float>(output_tensor, outputs[i]);
}
}
void test_io_no_copy_ax(std::string model_name, int record = 1) {
std::string model_path = model_name;
std::vector<std::string> input_names, output_names;
std::vector<std::vector<std::shared_ptr<Tensor>>> inputs;
std::vector<std::vector<std::shared_ptr<Tensor>>> outputs;
Config config;
config.options.graph_opt_level = 0;
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
input_names = network->get_all_input_name();
output_names = network->get_all_output_name();
for (int i = 0; i < 3; i++) {
std::vector<std::shared_ptr<Tensor>> net_inputs;
std::vector<std::shared_ptr<Tensor>> net_outputs;
for (size_t j = 0; j < input_names.size(); j++) {
auto in_tesnor = network->get_io_tensor(input_names[j]);
auto in_layout = in_tesnor->get_layout();
auto tmp_in = std::make_shared<Tensor>(LiteDeviceType::LITE_CPU, in_layout);
auto size = in_tesnor->get_tensor_total_size_in_byte() /
in_layout.get_elem_size();
if (in_layout.data_type == LiteDataType::LITE_INT16) {
auto ptr = static_cast<short*>(tmp_in->get_memory_ptr());
for (size_t id = 0; id < size; id++) {
ptr[id] = i + 1;
}
} else if (in_layout.data_type == LiteDataType::LITE_UINT8) {
auto ptr = static_cast<uint8_t*>(tmp_in->get_memory_ptr());
for (size_t id = 0; id < size; id++) {
ptr[id] = i + 1;
}
}
net_inputs.push_back(tmp_in);
in_tesnor->copy_from(*tmp_in);
}
inputs.push_back(net_inputs);
network->forward();
network->wait();
for (size_t j = 0; j < output_names.size(); j++) {
auto out_tesnor = network->get_io_tensor(output_names[j]);
auto out_layout = out_tesnor->get_layout();
auto tmp_out =
std::make_shared<Tensor>(LiteDeviceType::LITE_CPU, out_layout);
tmp_out->copy_from(*out_tesnor);
net_outputs.push_back(tmp_out);
}
outputs.push_back(net_outputs);
}
config.options.force_output_use_user_specified_memory = true;
config.options.comp_node_seq_record_level = record;
config.options.const_shape = true;
config.options.graph_opt_level = 2;
std::shared_ptr<Network> network_record = std::make_shared<Network>(config);
network_record->load_model(model_path);
for (int i = 0; i < 3; i++) {
for (size_t j = 0; j < inputs[i].size(); j++) {
auto input_tensor = network_record->get_io_tensor(input_names[j]);
input_tensor->reset(
inputs[i][j]->get_memory_ptr(), inputs[i][j]->get_layout());
}
std::vector<std::shared_ptr<Tensor>> net_outputs;
for (size_t j = 0; j < outputs[i].size(); j++) {
auto output_tensor = network_record->get_io_tensor(output_names[j]);
auto tmp_out = std::make_shared<Tensor>(
LiteDeviceType::LITE_CPU, output_tensor->get_layout());
output_tensor->reset(
tmp_out->get_memory_ptr(), output_tensor->get_layout());
net_outputs.push_back(tmp_out);
}
network_record->forward();
network_record->wait();
for (size_t j = 0; j < outputs[i].size(); j++) {
auto output_tensor = network_record->get_io_tensor(output_names[j]);
compare_lite_tensor<float>(output_tensor, outputs[i][j]);
}
}
printf("profile the model %s run\n", model_path.c_str());
std::vector<std::shared_ptr<Tensor>> net_outputs;
for (size_t j = 0; j < outputs[0].size(); j++) {
auto output_tensor = network_record->get_io_tensor(output_names[j]);
auto tmp_out = std::make_shared<Tensor>(
LiteDeviceType::LITE_CPU, output_tensor->get_layout());
output_tensor->reset(tmp_out->get_memory_ptr(), output_tensor->get_layout());
net_outputs.push_back(tmp_out);
}
lite::Timer timer("profile");
for (int i = 0; i < 10; i++) {
network_record->forward();
network_record->wait();
}
auto sum_time = timer.get_used_time();
printf("model %s used time average %f ms\n", model_path.c_str(), sum_time / 10);
}
}
TEST(TestNetWork, OutputNoCopy) {
test_output_no_copy(0);
}
TEST(TestNetWork, OutputNoCopyRecord) {
test_output_no_copy(1);
}
TEST(TestNetWork, IONoCopy) {
test_input_no_copy(0);
}
TEST(TestNetWork, IONoCopyRecord) {
test_input_no_copy(1);
}
TEST(TestNetWork, IONoCopyRecordAx) {
std::vector<std::string> file_names;
#ifndef WIN32
DIR* dirptr = NULL;
struct dirent* dirp;
std::string model_dir = "./ax_models";
dirptr = opendir(model_dir.c_str());
while (dirptr != NULL && (dirp = readdir(dirptr)) != NULL) {
std::string file_name(dirp->d_name);
if (file_name.find(".axe", 0) != std::string::npos) {
file_names.push_back(model_dir + "/" + file_name);
}
}
closedir(dirptr);
#endif
for (auto file_name : file_names) {
printf("test model: %s\n", file_name.c_str());
test_io_no_copy_ax(file_name);
}
}
TEST(TestNetWork, OutputDynamicAlloc) {
Config config;
config.options.force_output_dynamic_alloc = true;
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
size_t times = 5;
for (size_t i = 0; i < times; i++) {
network->forward();
network->wait();
compare_lite_tensor<float>(output_tensor, result_mgb);
}
}
TEST(TestNetWork, AsyncExec) {
Config config;
config.options.var_sanity_check_first_run = false;
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
auto result_tensor = std::make_shared<Tensor>(
LiteDeviceType::LITE_CPU, Layout{{1, 1000}, 2, LiteDataType::LITE_FLOAT});
void* out_data = result_tensor->get_memory_ptr();
output_tensor->reset(out_data, result_tensor->get_layout());
volatile bool finished = false;
network->set_async_callback([&finished]() { finished = true; });
network->forward();
size_t count = 0;
while (finished == false) {
count++;
}
ASSERT_GT(count, 0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, CPUDeviceInput) {
auto tensor = get_input_data("./input_data.npy");
Layout layout{{1, 3, 224, 224}, 4, LiteDataType::LITE_FLOAT};
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, {}, input_name, tensor);
NetworkIO IO;
bool is_host = false;
IO.inputs.push_back({input_name, is_host});
std::shared_ptr<Network> network = std::make_shared<Network>(IO);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
input_tensor->reset(src_ptr, layout);
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, ShareTensorWith) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, {}, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>();
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
input_tensor->share_memory_with(*tensor);
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, InputCallBack) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, {}, input_name, tensor);
NetworkIO ios;
bool is_host = false;
ios.inputs.push_back({input_name, is_host});
std::shared_ptr<Network> network = std::make_shared<Network>(ios);
network->load_model(model_path);
volatile bool finised_check_input = false;
auto input_callback =
[&tensor, &finised_check_input,
input_name](const std::unordered_map<
std::string, std::pair<IO, std::shared_ptr<Tensor>>>&
input_map) {
ASSERT_EQ(input_map.size(), 1);
auto tensor_input = input_map.at(input_name).second;
compare_lite_tensor<float>(tensor_input, tensor);
finised_check_input = true;
};
network->set_start_callback(input_callback);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
input_tensor->share_memory_with(*tensor);
network->forward();
network->wait();
ASSERT_TRUE(finised_check_input);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, OutputCallBack) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, {}, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>();
network->load_model(model_path);
auto output_name = network->get_output_name(0);
volatile bool finised_check_output = false;
auto output_callback =
[&result_mgb, &finised_check_output,
output_name](const std::unordered_map<
std::string, std::pair<IO, std::shared_ptr<Tensor>>>&
output_map) {
ASSERT_EQ(output_map.size(), 1);
auto tensor_output = output_map.at(output_name).second;
compare_lite_tensor<float>(tensor_output, result_mgb);
finised_check_output = true;
};
network->set_finish_callback(output_callback);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
input_tensor->share_memory_with(*tensor);
network->forward();
network->wait();
ASSERT_TRUE(finised_check_output);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, OutputShapeOnly) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
std::string output_name = "TRUE_DIV(EXP[12065],reduce0[12067])[12077]";
NetworkIO IO;
bool is_host = true;
IO.outputs.push_back({output_name, is_host, LiteIOType::LITE_IO_SHAPE});
Config config;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
std::shared_ptr<Tensor> output_tensor = network->get_io_tensor(output_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
ASSERT_EQ(output_tensor->get_tensor_total_size_in_byte() / sizeof(float), 1000);
}
TEST(TestNetWork, ProfileIOdump) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
NetworkIO IO;
Config config;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->enable_profile_performance("./profile.json");
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
ASSERT_TRUE(fopen("./profile.json", "r"));
Runtime::enable_io_txt_dump(network, "./io_txt_dump.txt");
network->forward();
network->wait();
ASSERT_TRUE(fopen("./io_txt_dump.txt", "r"));
}
TEST(TestNetWork, LoadPackedModel) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./test_packed_model.lite";
std::string input_name = "data";
NetworkIO IO;
Config config;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
}
TEST(TestNetWork, GlabalLayoutTransform) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
std::string dump_model_name = "./shufflenet_after_trans.mge";
NetworkIO IO;
Config config;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
Runtime::enable_global_layout_transform(network);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
Runtime::dump_layout_transform_model(network, dump_model_name);
network->forward();
network->wait();
ASSERT_TRUE(fopen(dump_model_name.c_str(), "r"));
remove(dump_model_name.c_str());
}
TEST(TestNetWork, GetDeviceType) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
Config config;
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
ASSERT_TRUE(network->get_device_type() == LiteDeviceType::LITE_CPU);
}
TEST(TestNetWork, GetModelExtraInfo) {
std::string model_path = "./track_640_320_pack_model_rc4_with_info.lite";
Config config;
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
auto& extra_info = network->get_model_extra_info();
ASSERT_TRUE(extra_info.size() > 0);
printf("extra_info %s \n", extra_info.c_str());
}
#ifndef __IN_TEE_ENV__
#if MGB_ENABLE_JSON
TEST(TestNetWork, GetMemoryInfo) {
Config config;
auto lite_tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
Runtime::set_cpu_threads_number(network, 2);
network->load_model(model_path);
network->get_static_memory_alloc_info();
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
auto src_ptr = lite_tensor->get_memory_ptr();
auto src_layout = lite_tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
#endif
#endif
#if LITE_WITH_CUDA
TEST(TestNetWork, BasicDevice) {
auto lite_tensor = get_input_data("./input_data.npy");
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
std::string model_path = "./shufflenet.mge";
auto result_lite = mgelite_lar(model_path, config, "data", lite_tensor);
auto result_mgb = mgb_lar(model_path, config, "data", lite_tensor);
compare_lite_tensor<float>(result_lite, result_mgb);
}
TEST(TestNetWork, DeviceInput) {
auto tensor = get_input_data("./input_data.npy");
Layout layout{{1, 3, 224, 224}, 4, LiteDataType::LITE_FLOAT};
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, {}, input_name, tensor);
NetworkIO IO;
bool is_host = false;
IO.inputs.push_back({input_name, is_host});
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto tensor_cuda = Tensor(LiteDeviceType::LITE_CUDA, layout);
tensor_cuda.copy_from(*tensor);
auto src_ptr = tensor_cuda.get_memory_ptr();
input_tensor->reset(src_ptr, layout);
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, ChangeInputShapeDevice) {
Config config;
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
config.device_type = LiteDeviceType::LITE_CUDA;
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_layout = Layout{{2, 3, 200, 200}, 4, LiteDataType::LITE_FLOAT};
input_tensor->set_layout(src_layout);
std::shared_ptr<Tensor> input_tensor2 = network->get_io_tensor(input_name);
ASSERT_EQ(input_tensor->get_memory_ptr(), input_tensor2->get_memory_ptr());
network->forward();
network->wait();
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
auto output_layout = output_tensor->get_layout();
ASSERT_EQ(output_layout.shapes[0], 2);
ASSERT_EQ(output_layout.shapes[1], 1000);
}
TEST(TestNetWork, DeviceOutput) {
auto tensor = get_input_data("./input_data.npy");
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
std::string output_name = "TRUE_DIV(EXP[12065],reduce0[12067])[12077]";
auto result_mgb = mgb_lar(model_path, {}, input_name, tensor);
NetworkIO IO;
bool is_host = false;
IO.outputs.push_back({output_name, is_host});
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
std::shared_ptr<Tensor> output_tensor_cuda = network->get_io_tensor(output_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
network->forward();
network->wait();
auto output_tensor = std::make_shared<Tensor>();
output_tensor->copy_from(*output_tensor_cuda);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, WrongIONameDevice) {
auto tensor = get_input_data("./input_data.npy");
Layout layout{{1, 3, 224, 224}, 4, LiteDataType::LITE_FLOAT};
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
std::string input_name_wrong = "data0";
std::string output_name = "TRUE_DIV(EXP[12065],reduce0[12067])[12077]";
std::string output_name_wrong = "w_TRUE_DIV(EXP[12065],reduce0[12067])[12077]";
auto result_mgb = mgb_lar(model_path, {}, input_name, tensor);
NetworkIO IO;
bool is_host = false;
IO.inputs.push_back({input_name, is_host});
IO.outputs.push_back({output_name, is_host});
IO.outputs.push_back({output_name_wrong, is_host});
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->load_model(model_path);
auto tensor_cuda = Tensor(LiteDeviceType::LITE_CUDA, layout);
tensor_cuda.copy_from(*tensor);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor_cuda.get_memory_ptr();
auto src_layout = tensor_cuda.get_layout();
input_tensor->reset(src_ptr, src_layout);
std::shared_ptr<Tensor> output_tensor_cuda = network->get_io_tensor(output_name);
network->forward();
network->wait();
auto output_tensor = std::make_shared<Tensor>();
output_tensor->copy_from(*output_tensor_cuda);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
TEST(TestNetWork, ConfigIONameDevice) {
std::string model_path = "./model.mgb";
NetworkIO IO;
bool is_host = false;
IO.outputs.push_back({"clsfy", is_host});
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->compute_only_configured_output();
network->load_model(model_path);
ASSERT_EQ(network->get_all_output_name().size(), 1);
ASSERT_EQ(network->get_all_output_name()[0], "clsfy");
std::shared_ptr<Network> network2 = std::make_shared<Network>(config, IO);
network2->load_model(model_path);
ASSERT_EQ(network2->get_all_output_name().size(), 2);
}
TEST(TestNetWork, SetDeviceIdDeviceTest) {
#if LITE_WITH_CUDA
if (get_device_count(LITE_CUDA) <= 1)
return;
#endif
std::string model_path = "./model.mgb";
NetworkIO IO;
bool is_host = false;
IO.inputs.push_back({"data", is_host});
IO.outputs.push_back({"clsfy", is_host});
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->set_device_id(1);
network->load_model(model_path);
auto inputs_names = network->get_all_input_name();
for (auto name : inputs_names) {
auto tensor = network->get_io_tensor(name);
ASSERT_EQ(tensor->get_device_id(), 1);
if (name == "idx") {
int* index_ptr = static_cast<int*>(tensor->get_memory_ptr());
for (int i = 0; i < 23; i++) {
index_ptr[i] = i % 3;
}
}
if (name == "landmark") {
float* landmakrk_ptr = static_cast<float*>(tensor->get_memory_ptr());
for (int i = 0; i < 23 * 18 * 2; i++) {
landmakrk_ptr[i] = 0.1f;
}
}
}
auto outputs_names = network->get_all_output_name();
for (auto name : outputs_names) {
auto tensor = network->get_io_tensor(name);
ASSERT_EQ(tensor->get_device_id(), 1);
}
network->forward();
network->wait();
}
TEST(TestNetWork, SetStreamIdDeviceTest) {
std::string model_path = "./model.mgb";
NetworkIO IO;
bool is_host = false;
IO.inputs.push_back({"data", is_host});
IO.outputs.push_back({"clsfy", is_host});
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
std::shared_ptr<Network> network = std::make_shared<Network>(config, IO);
network->set_stream_id(1);
network->load_model(model_path);
auto inputs_names = network->get_all_input_name();
for (auto name : inputs_names) {
auto tensor = network->get_io_tensor(name);
if (name == "idx") {
int* index_ptr = static_cast<int*>(tensor->get_memory_ptr());
for (int i = 0; i < 23; i++) {
index_ptr[i] = i % 3;
}
}
if (name == "landmark") {
float* landmakrk_ptr = static_cast<float*>(tensor->get_memory_ptr());
for (int i = 0; i < 23 * 18 * 2; i++) {
landmakrk_ptr[i] = 0.1f;
}
}
}
network->forward();
network->wait();
}
#if CUDART_VERSION >= 10000
TEST(TestNetWork, DeviceAsyncExec) {
auto tensor = get_input_data("./input_data.npy");
Config config;
config.device_type = LiteDeviceType::LITE_CUDA;
config.options.var_sanity_check_first_run = false;
std::string model_path = "./shufflenet.mge";
std::string input_name = "data";
auto result_mgb = mgb_lar(model_path, config, input_name, tensor);
std::shared_ptr<Network> network = std::make_shared<Network>(config);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_io_tensor(input_name);
auto src_ptr = tensor->get_memory_ptr();
auto src_layout = tensor->get_layout();
input_tensor->reset(src_ptr, src_layout);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
auto result_tensor = std::make_shared<Tensor>(
LiteDeviceType::LITE_CPU, Layout{{1, 1000}, 2, LiteDataType::LITE_FLOAT});
void* out_data = result_tensor->get_memory_ptr();
output_tensor->reset(out_data, result_tensor->get_layout());
volatile bool finished = false;
network->set_async_callback([&finished]() { finished = true; });
network->forward();
size_t count = 0;
while (finished == false) {
count++;
}
ASSERT_GT(count, 0);
compare_lite_tensor<float>(output_tensor, result_mgb);
}
#endif
#endif
#if MGB_ATLAS || MGB_CAMBRICON
namespace {
void load_no_device(LiteDeviceType device_type, const std::string& model_path) {
lite::Config config;
config.device_type = device_type;
auto network = std::make_shared<lite::Network>(config);
network->load_model(model_path);
network->forward();
network->wait();
}
void load_device_input(
LiteDeviceType device_type, const std::string& model_path,
const std::vector<std::string>& inputs) {
lite::NetworkIO networkio;
lite::IO input_data_io = {};
input_data_io.name = inputs[0];
input_data_io.is_host = false;
networkio.inputs.emplace_back(input_data_io);
lite::IO input_input0_io = {};
input_input0_io.name = inputs[1];
input_input0_io.is_host = false;
networkio.inputs.emplace_back(input_input0_io);
lite::Config config;
config.device_type = device_type;
auto network = std::make_shared<lite::Network>(config, networkio);
network->load_model(model_path);
network->forward();
network->wait();
}
void load_device_id(
LiteDeviceType device_type, int device_id, const std::string& model_path) {
lite::Config config;
config.device_type = device_type;
auto network = std::make_shared<lite::Network>(config);
network->set_device_id(device_id);
network->load_model(model_path);
std::shared_ptr<Tensor> input_tensor = network->get_input_tensor(0);
std::shared_ptr<Tensor> output_tensor = network->get_output_tensor(0);
network->forward();
network->wait();
ASSERT_EQ(output_tensor->get_device_id(), device_id);
}
} #endif
#if MGB_ATLAS
TEST(TestNetWork, AtlasLoadNoDevice) {
load_no_device(LiteDeviceType::LITE_DEVICE_DEFAULT, "./model_atlas.mgb");
}
TEST(TestNetWork, AtlasLoadDeviceInput) {
load_device_input(
LiteDeviceType::LITE_DEVICE_DEFAULT, "./model_atlas.mgb",
{"data", "input0"});
}
TEST(TestNetWork, AtlasLoadAtlas) {
load_no_device(LiteDeviceType::LITE_ATLAS, "./model_atlas.mgb");
}
TEST(TestNetWork, AtlasLoadAtlasDeviceInput) {
load_device_input(
LiteDeviceType::LITE_ATLAS, "./model_atlas.mgb", {"data", "input0"});
}
TEST(TestNetWork, AtlasDeviceID) {
load_device_id(LiteDeviceType::LITE_ATLAS, 1, "./model_atlas.mgb");
}
#endif
#if MGB_CAMBRICON
TEST(TestNetWork, CambriconLoadNoDevice) {
load_no_device(LiteDeviceType::LITE_DEVICE_DEFAULT, "./model_magicmind.mgb");
}
TEST(TestNetWork, CambriconLoadDeviceInput) {
load_device_input(
LiteDeviceType::LITE_DEVICE_DEFAULT, "./model_magicmind.mgb",
{"data", "input0"});
}
TEST(TestNetWork, CambriconLoadCambricon) {
load_no_device(LiteDeviceType::LITE_CAMBRICON, "./model_magicmind.mgb");
}
TEST(TestNetWork, CambriconLoadCambriconDeviceInput) {
load_device_input(
LiteDeviceType::LITE_CAMBRICON, "./model_magicmind.mgb",
{"data", "input0"});
}
TEST(TestNetWork, CambriconDeviceID) {
load_device_id(LiteDeviceType::LITE_CAMBRICON, 0, "./model_magicmind.mgb");
}
#endif
#endif