void* thread_main(void* gm_ptr) { paddle_gradient_machine machine = (paddle_gradient_machine)(gm_ptr); paddle_arguments in_args = paddle_arguments_create_none(); // Create input matrix. paddle_matrix mat = paddle_matrix_create(/* sample_num */ 1, /* size */ 784, /* useGPU */ false); paddle_arguments out_args = paddle_arguments_create_none(); paddle_matrix prob = paddle_matrix_create_none(); for (int iter = 0; iter < NUM_ITER; ++iter) { // There is only one input of this network. CHECK(paddle_arguments_resize(in_args, 1)); paddle_real* array; // Get First row. CHECK(paddle_matrix_get_row(mat, 0, &array)); for (int i = 0; i < 784; ++i) { array[i] = rand() / ((float)RAND_MAX); } CHECK(paddle_arguments_set_value(in_args, 0, mat)); CHECK(paddle_gradient_machine_forward(machine, in_args, out_args, /* isTrain */ false)); CHECK(paddle_arguments_get_value(out_args, 0, prob)); CHECK(paddle_matrix_get_row(prob, 0, &array)); pthread_mutex_lock(&mutex); printf("Prob: "); for (int i = 0; i < 10; ++i) { printf("%.2f ", array[i]); } printf("\n"); pthread_mutex_unlock(&mutex); } CHECK(paddle_matrix_destroy(prob)); CHECK(paddle_arguments_destroy(out_args)); CHECK(paddle_matrix_destroy(mat)); CHECK(paddle_arguments_destroy(in_args)); CHECK(paddle_gradient_machine_destroy(machine)); return NULL; }
TEST(GradientMachine, testPredict) { //! TODO(yuyang18): Test GPU Code. paddle::TrainerConfigHelper config("./test_predict_network.py"); std::string buffer; ASSERT_TRUE(config.getModelConfig().SerializeToString(&buffer)); paddle_gradient_machine machine; ASSERT_EQ(kPD_NO_ERROR, paddle_gradient_machine_create_for_inference( &machine, &buffer[0], (int)buffer.size())); std::unique_ptr<paddle::GradientMachine> gm( paddle::GradientMachine::create(config.getModelConfig())); ASSERT_NE(nullptr, gm); gm->randParameters(); gm->saveParameters("./"); ASSERT_EQ(kPD_NO_ERROR, paddle_gradient_machine_load_parameter_from_disk(machine, "./")); paddle_gradient_machine machineSlave; ASSERT_EQ(kPD_NO_ERROR, paddle_gradient_machine_create_shared_param( machine, &buffer[0], (int)buffer.size(), &machineSlave)); std::swap(machineSlave, machine); paddle_arguments outArgs = paddle_arguments_create_none(); paddle_arguments inArgs = paddle_arguments_create_none(); ASSERT_EQ(kPD_NO_ERROR, paddle_arguments_resize(inArgs, 1)); paddle_matrix mat = paddle_matrix_create(1, 100, false); static_assert(std::is_same<paddle_real, paddle::real>::value, ""); auto data = randomBuffer(100); paddle_real* rowPtr; ASSERT_EQ(kPD_NO_ERROR, paddle_matrix_get_row(mat, 0, &rowPtr)); memcpy(rowPtr, data.data(), data.size() * sizeof(paddle_real)); ASSERT_EQ(kPD_NO_ERROR, paddle_arguments_set_value(inArgs, 0, mat)); ASSERT_EQ(kPD_NO_ERROR, paddle_gradient_machine_forward(machine, inArgs, outArgs, false)); uint64_t sz; ASSERT_EQ(kPD_NO_ERROR, paddle_arguments_get_size(outArgs, &sz)); ASSERT_EQ(1UL, sz); ASSERT_EQ(kPD_NO_ERROR, paddle_arguments_get_value(outArgs, 0, mat)); std::vector<paddle::Argument> paddleInArgs; std::vector<paddle::Argument> paddleOutArgs; paddleInArgs.resize(1); paddleInArgs[0].value = paddle::Matrix::create(data.data(), 1, 100, false, false); gm->forward(paddleInArgs, &paddleOutArgs, paddle::PASS_TEST); auto matPaddle = paddleOutArgs[0].value; uint64_t height, width; ASSERT_EQ(kPD_NO_ERROR, paddle_matrix_get_shape(mat, &height, &width)); ASSERT_EQ(matPaddle->getHeight(), height); ASSERT_EQ(matPaddle->getWidth(), width); ASSERT_EQ(kPD_NO_ERROR, paddle_matrix_get_row(mat, 0, &rowPtr)); for (size_t i = 0; i < width; ++i) { ASSERT_NEAR(matPaddle->getData()[i], rowPtr[i], 1e-5); } ASSERT_EQ(kPD_NO_ERROR, paddle_matrix_destroy(mat)); ASSERT_EQ(kPD_NO_ERROR, paddle_arguments_destroy(inArgs)); ASSERT_EQ(kPD_NO_ERROR, paddle_arguments_destroy(outArgs)); std::swap(machineSlave, machine); ASSERT_EQ(kPD_NO_ERROR, paddle_gradient_machine_destroy(machineSlave)); ASSERT_EQ(kPD_NO_ERROR, paddle_gradient_machine_destroy(machine)); }
int main() { // Initalize Paddle char* argv[] = {"--use_gpu=False"}; CHECK(paddle_init(1, (char**)argv)); // Reading config binary file. It is generated by `convert_protobin.sh` long size; void* buf = read_config(CONFIG_BIN, &size); // Create a gradient machine for inference. paddle_gradient_machine machine; CHECK(paddle_gradient_machine_create_for_inference(&machine, buf, (int)size)); CHECK(paddle_gradient_machine_randomize_param(machine)); // Loading parameter. Uncomment the following line and change the directory. // CHECK(paddle_gradient_machine_load_parameter_from_disk(machine, // "./some_where_to_params")); paddle_arguments in_args = paddle_arguments_create_none(); // There is only one input of this network. CHECK(paddle_arguments_resize(in_args, 1)); // Create input matrix. paddle_matrix mat = paddle_matrix_create(/* sample_num */ 1, /* size */ 784, /* useGPU */ false); srand(time(0)); paddle_real* array; // Get First row. CHECK(paddle_matrix_get_row(mat, 0, &array)); for (int i = 0; i < 784; ++i) { array[i] = rand() / ((float)RAND_MAX); } CHECK(paddle_arguments_set_value(in_args, 0, mat)); paddle_arguments out_args = paddle_arguments_create_none(); CHECK(paddle_gradient_machine_forward(machine, in_args, out_args, /* isTrain */ false)); paddle_matrix prob = paddle_matrix_create_none(); CHECK(paddle_arguments_get_value(out_args, 0, prob)); uint64_t height; uint64_t width; CHECK(paddle_matrix_get_shape(prob, &height, &width)); CHECK(paddle_matrix_get_row(prob, 0, &array)); printf("Prob: \n"); for (int i = 0; i < height * width; ++i) { printf("%.4f ", array[i]); if ((i + 1) % width == 0) { printf("\n"); } } printf("\n"); CHECK(paddle_matrix_destroy(prob)); CHECK(paddle_arguments_destroy(out_args)); CHECK(paddle_matrix_destroy(mat)); CHECK(paddle_arguments_destroy(in_args)); CHECK(paddle_gradient_machine_destroy(machine)); return 0; }
int main() { // Initalize Paddle char* argv[] = {"--use_gpu=False"}; CHECK(paddle_init(1, (char**)argv)); // Read the binary configuration file which is generated by // `convert_protobin.sh` long size; void* buf = read_config(CONFIG_BIN, &size); // Create the gradient machine for inference. paddle_gradient_machine machine; CHECK(paddle_gradient_machine_create_for_inference(&machine, buf, (int)size)); CHECK(paddle_gradient_machine_randomize_param(machine)); // Load the trained parameters. Uncomment the following line and change the // directory as needed. // CHECK(paddle_gradient_machine_load_parameter_from_disk(machine, // "./some_where_to_params")); paddle_arguments in_args = paddle_arguments_create_none(); // There is only one input of this network. CHECK(paddle_arguments_resize(in_args, 1)); // Create the input matrix. paddle_matrix mat = paddle_matrix_create_sparse(1, 784, 3, true, false); srand(time(0)); paddle_real* array; int colBuf[] = {9, 93, 109}; int rowBuf[] = {0, sizeof(colBuf) / sizeof(int)}; CHECK(paddle_matrix_sparse_copy_from(mat, rowBuf, sizeof(rowBuf) / sizeof(int), colBuf, sizeof(colBuf) / sizeof(int), NULL, 0)); CHECK(paddle_arguments_set_value(in_args, 0, mat)); paddle_arguments out_args = paddle_arguments_create_none(); CHECK(paddle_gradient_machine_forward(machine, in_args, out_args, /* isTrain */ false)); paddle_matrix prob = paddle_matrix_create_none(); CHECK(paddle_arguments_get_value(out_args, 0, prob)); CHECK(paddle_matrix_get_row(prob, 0, &array)); printf("Prob: "); for (int i = 0; i < 10; ++i) { printf("%.2f ", array[i]); } printf("\n"); CHECK(paddle_matrix_destroy(prob)); CHECK(paddle_arguments_destroy(out_args)); CHECK(paddle_matrix_destroy(mat)); CHECK(paddle_arguments_destroy(in_args)); CHECK(paddle_gradient_machine_destroy(machine)); return 0; }