tests/lib/cmsis_dsp/matrix/src/unary_f32.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2020 Stephanos Ioannidis <root@stephanos.io>
  * Copyright (C) 2010-2020 ARM Limited or its affiliates. All rights reserved.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <ztest.h>
 #include <zephyr.h>
 #include <stdlib.h>
 #include <arm_math.h>
 #include "../../common/test_common.h"

 #include "unary_f32.pat"

 #define SNR_ERROR_THRESH	((float32_t)120)
 #define REL_ERROR_THRESH	(1.0e-6)
 #define ABS_ERROR_THRESH	(1.0e-5)

 #define SNR_ERROR_THRESH_INV	((float32_t)70)
 #define REL_ERROR_THRESH_INV	(1.0e-3)
 #define ABS_ERROR_THRESH_INV	(1.0e-3)

 #define NUM_MATRICES		(ARRAY_SIZE(in_dims) / 2)
 #define NUM_MATRICES_INV	ARRAY_SIZE(in_inv_dims)
 #define MAX_MATRIX_DIM		(40)

 #define OP2_ADD			(0)
 #define OP2_SUB			(1)
 #define OP1_SCALE		(0)
 #define OP1_TRANS		(1)

 static void test_op2(int op, const uint32_t *ref, size_t length)
 {
 	size_t index;
 	uint16_t *dims = (uint16_t *)in_dims;
 	float32_t *tmp1, *tmp2, *output;
 	uint16_t rows, columns;

 	arm_matrix_instance_f32 mat_in1;
 	arm_matrix_instance_f32 mat_in2;
 	arm_matrix_instance_f32 mat_out;

 	/* Allocate buffers */
 	tmp1 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
 	zassert_not_null(tmp1, ASSERT_MSG_BUFFER_ALLOC_FAILED);

 	tmp2 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
 	zassert_not_null(tmp2, ASSERT_MSG_BUFFER_ALLOC_FAILED);

 	output = malloc(length * sizeof(float32_t));
 	zassert_not_null(output, ASSERT_MSG_BUFFER_ALLOC_FAILED);

 	/* Initialise contexts */
 	mat_in1.pData = tmp1;
 	mat_in2.pData = tmp2;
 	mat_out.pData = output;

 	/* Iterate matrices */
 	for (index = 0; index < NUM_MATRICES; index++) {
 		rows = *dims++;
 		columns = *dims++;

 		/* Initialise matrix dimensions */
 		mat_in1.numRows = mat_in2.numRows = mat_out.numRows = rows;
 		mat_in1.numCols = mat_in2.numCols = mat_out.numCols = columns;

 		/* Load matrix data */
 		memcpy(mat_in1.pData, in_com1,
 		       rows * columns * sizeof(float32_t));

 		memcpy(mat_in2.pData, in_com2,
 		       rows * columns * sizeof(float32_t));

 		/* Run test function */
 		switch (op) {
 		case OP2_ADD:
 			arm_mat_add_f32(&mat_in1, &mat_in2, &mat_out);
 			break;
 		case OP2_SUB:
 			arm_mat_sub_f32(&mat_in1, &mat_in2, &mat_out);
 			break;
 		default:
 			zassert_unreachable("invalid operation");
 		}

 		/* Increment output pointer */
 		mat_out.pData += (rows * columns);
 	}

 	/* Validate output */
 	zassert_true(
 		test_snr_error_f32(length, output, (float32_t *)ref,
 			SNR_ERROR_THRESH),
 		ASSERT_MSG_SNR_LIMIT_EXCEED);

 	zassert_true(
 		test_close_error_f32(length, output, (float32_t *)ref,
 			ABS_ERROR_THRESH, REL_ERROR_THRESH),
 		ASSERT_MSG_ERROR_LIMIT_EXCEED);

 	/* Free buffers */
 	free(tmp1);
 	free(tmp2);
 	free(output);
 }

 DEFINE_TEST_VARIANT3(op2, arm_mat_add_f32, OP2_ADD,
 	ref_add, ARRAY_SIZE(ref_add));
 DEFINE_TEST_VARIANT3(op2, arm_mat_sub_f32, OP2_SUB,
 	ref_sub, ARRAY_SIZE(ref_sub));

 static void test_op1(int op, const uint32_t *ref, size_t length,
 	bool transpose)
 {
 	size_t index;
 	uint16_t *dims = (uint16_t *)in_dims;
 	float32_t *tmp1, *output;
 	uint16_t rows, columns;

 	arm_matrix_instance_f32 mat_in1;
 	arm_matrix_instance_f32 mat_out;

 	/* Allocate buffers */
 	tmp1 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
 	zassert_not_null(tmp1, ASSERT_MSG_BUFFER_ALLOC_FAILED);

 	output = malloc(length * sizeof(float32_t));
 	zassert_not_null(output, ASSERT_MSG_BUFFER_ALLOC_FAILED);

 	/* Initialise contexts */
 	mat_in1.pData = tmp1;
 	mat_out.pData = output;

 	/* Iterate matrices */
 	for (index = 0; index < NUM_MATRICES; index++) {
 		rows = *dims++;
 		columns = *dims++;

 		/* Initialise matrix dimensions */
 		mat_in1.numRows = rows;
 		mat_in1.numCols = columns;
 		mat_out.numRows = transpose ? columns : rows;
 		mat_out.numCols = transpose ? rows : columns;

 		/* Load matrix data */
 		memcpy(mat_in1.pData, in_com1,
 		       rows * columns * sizeof(float32_t));

 		/* Run test function */
 		switch (op) {
 		case OP1_SCALE:
 			arm_mat_scale_f32(&mat_in1, 0.5f, &mat_out);
 			break;
 		case OP1_TRANS:
 			arm_mat_trans_f32(&mat_in1, &mat_out);
 			break;
 		default:
 			zassert_unreachable("invalid operation");
 		}

 		/* Increment output pointer */
 		mat_out.pData += (rows * columns);
 	}

 	/* Validate output */
 	zassert_true(
 		test_snr_error_f32(length, output, (float32_t *)ref,
 			SNR_ERROR_THRESH),
 		ASSERT_MSG_SNR_LIMIT_EXCEED);

 	zassert_true(
 		test_close_error_f32(length, output, (float32_t *)ref,
 			ABS_ERROR_THRESH, REL_ERROR_THRESH),
 		ASSERT_MSG_ERROR_LIMIT_EXCEED);

 	/* Free buffers */
 	free(tmp1);
 	free(output);
 }

 DEFINE_TEST_VARIANT4(op1, arm_mat_scale_f32, OP1_SCALE,
 	ref_scale, ARRAY_SIZE(ref_scale), false);
 DEFINE_TEST_VARIANT4(op1, arm_mat_trans_f32, OP1_TRANS,
 	ref_trans, ARRAY_SIZE(ref_trans), true);

 static void test_arm_mat_inverse_f32(void)
 {
 	size_t index;
 	size_t length = ARRAY_SIZE(ref_inv);
 	uint16_t *dims = (uint16_t *)in_inv_dims;
 	float32_t *input, *tmp1, *output;
 	arm_status status;
 	uint16_t rows, columns;

 	arm_matrix_instance_f32 mat_in1;
 	arm_matrix_instance_f32 mat_out;

 	/* Allocate buffers */
 	tmp1 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
 	zassert_not_null(tmp1, ASSERT_MSG_BUFFER_ALLOC_FAILED);

 	output = malloc(length * sizeof(float32_t));
 	zassert_not_null(output, ASSERT_MSG_BUFFER_ALLOC_FAILED);

 	/* Initialise contexts */
 	input = (float32_t *)in_inv;
 	mat_in1.pData = tmp1;
 	mat_out.pData = output;

 	/* Iterate matrices */
 	for (index = 0; index < NUM_MATRICES_INV; index++) {
 		rows = columns = *dims++;

 		/* Initialise matrix dimensions */
 		mat_in1.numRows = mat_out.numRows = rows;
 		mat_in1.numCols = mat_out.numCols = columns;

 		/* Load matrix data */
 		memcpy(mat_in1.pData,
 		       input, rows * columns * sizeof(float32_t));

 		/* Run test function */
 		status = arm_mat_inverse_f32(&mat_in1, &mat_out);

 		zassert_equal(status, ARM_MATH_SUCCESS,
 			ASSERT_MSG_INCORRECT_COMP_RESULT);

 		/* Increment pointers */
 		input += (rows * columns);
 		mat_out.pData += (rows * columns);
 	}

 	/* Validate output */
 	zassert_true(
 		test_snr_error_f32(length, output, (float32_t *)ref_inv,
 			SNR_ERROR_THRESH_INV),
 		ASSERT_MSG_SNR_LIMIT_EXCEED);

 	zassert_true(
 		test_close_error_f32(length, output, (float32_t *)ref_inv,
 			ABS_ERROR_THRESH_INV, REL_ERROR_THRESH_INV),
 		ASSERT_MSG_ERROR_LIMIT_EXCEED);

 	/* Free buffers */
 	free(tmp1);
 	free(output);
 }

 void test_matrix_unary_f32(void)
 {
 	ztest_test_suite(matrix_unary_f32,
 		ztest_unit_test(test_op2_arm_mat_add_f32),
 		ztest_unit_test(test_op2_arm_mat_sub_f32),
 		ztest_unit_test(test_op1_arm_mat_scale_f32),
 		ztest_unit_test(test_op1_arm_mat_trans_f32),
 		ztest_unit_test(test_arm_mat_inverse_f32)
 		);

 	ztest_run_test_suite(matrix_unary_f32);
 }
	/*
	* Copyright (c) 2020 Stephanos Ioannidis <root@stephanos.io>
	* Copyright (C) 2010-2020 ARM Limited or its affiliates. All rights reserved.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <ztest.h>
	#include <zephyr.h>
	#include <stdlib.h>
	#include <arm_math.h>
	#include "../../common/test_common.h"

	#include "unary_f32.pat"

	#define SNR_ERROR_THRESH ((float32_t)120)
	#define REL_ERROR_THRESH (1.0e-6)
	#define ABS_ERROR_THRESH (1.0e-5)

	#define SNR_ERROR_THRESH_INV ((float32_t)70)
	#define REL_ERROR_THRESH_INV (1.0e-3)
	#define ABS_ERROR_THRESH_INV (1.0e-3)

	#define NUM_MATRICES (ARRAY_SIZE(in_dims) / 2)
	#define NUM_MATRICES_INV ARRAY_SIZE(in_inv_dims)
	#define MAX_MATRIX_DIM (40)

	#define OP2_ADD (0)
	#define OP2_SUB (1)
	#define OP1_SCALE (0)
	#define OP1_TRANS (1)

	static void test_op2(int op, const uint32_t *ref, size_t length)
	{
	size_t index;
	uint16_t dims = (uint16_t )in_dims;
	float32_t tmp1, tmp2, *output;
	uint16_t rows, columns;

	arm_matrix_instance_f32 mat_in1;
	arm_matrix_instance_f32 mat_in2;
	arm_matrix_instance_f32 mat_out;

	/* Allocate buffers */
	tmp1 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
	zassert_not_null(tmp1, ASSERT_MSG_BUFFER_ALLOC_FAILED);

	tmp2 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
	zassert_not_null(tmp2, ASSERT_MSG_BUFFER_ALLOC_FAILED);

	output = malloc(length * sizeof(float32_t));
	zassert_not_null(output, ASSERT_MSG_BUFFER_ALLOC_FAILED);

	/* Initialise contexts */
	mat_in1.pData = tmp1;
	mat_in2.pData = tmp2;
	mat_out.pData = output;

	/* Iterate matrices */
	for (index = 0; index < NUM_MATRICES; index++) {
	rows = *dims++;
	columns = *dims++;

	/* Initialise matrix dimensions */
	mat_in1.numRows = mat_in2.numRows = mat_out.numRows = rows;
	mat_in1.numCols = mat_in2.numCols = mat_out.numCols = columns;

	/* Load matrix data */
	memcpy(mat_in1.pData, in_com1,
	rows * columns * sizeof(float32_t));

	memcpy(mat_in2.pData, in_com2,
	rows * columns * sizeof(float32_t));

	/* Run test function */
	switch (op) {
	case OP2_ADD:
	arm_mat_add_f32(&mat_in1, &mat_in2, &mat_out);
	break;
	case OP2_SUB:
	arm_mat_sub_f32(&mat_in1, &mat_in2, &mat_out);
	break;
	default:
	zassert_unreachable("invalid operation");
	}

	/* Increment output pointer */
	mat_out.pData += (rows * columns);
	}

	/* Validate output */
	zassert_true(
	test_snr_error_f32(length, output, (float32_t *)ref,
	SNR_ERROR_THRESH),
	ASSERT_MSG_SNR_LIMIT_EXCEED);

	zassert_true(
	test_close_error_f32(length, output, (float32_t *)ref,
	ABS_ERROR_THRESH, REL_ERROR_THRESH),
	ASSERT_MSG_ERROR_LIMIT_EXCEED);

	/* Free buffers */
	free(tmp1);
	free(tmp2);
	free(output);
	}

	DEFINE_TEST_VARIANT3(op2, arm_mat_add_f32, OP2_ADD,
	ref_add, ARRAY_SIZE(ref_add));
	DEFINE_TEST_VARIANT3(op2, arm_mat_sub_f32, OP2_SUB,
	ref_sub, ARRAY_SIZE(ref_sub));

	static void test_op1(int op, const uint32_t *ref, size_t length,
	bool transpose)
	{
	size_t index;
	uint16_t dims = (uint16_t )in_dims;
	float32_t tmp1, output;
	uint16_t rows, columns;

	arm_matrix_instance_f32 mat_in1;
	arm_matrix_instance_f32 mat_out;

	/* Allocate buffers */
	tmp1 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
	zassert_not_null(tmp1, ASSERT_MSG_BUFFER_ALLOC_FAILED);

	output = malloc(length * sizeof(float32_t));
	zassert_not_null(output, ASSERT_MSG_BUFFER_ALLOC_FAILED);

	/* Initialise contexts */
	mat_in1.pData = tmp1;
	mat_out.pData = output;

	/* Iterate matrices */
	for (index = 0; index < NUM_MATRICES; index++) {
	rows = *dims++;
	columns = *dims++;

	/* Initialise matrix dimensions */
	mat_in1.numRows = rows;
	mat_in1.numCols = columns;
	mat_out.numRows = transpose ? columns : rows;
	mat_out.numCols = transpose ? rows : columns;

	/* Load matrix data */
	memcpy(mat_in1.pData, in_com1,
	rows * columns * sizeof(float32_t));

	/* Run test function */
	switch (op) {
	case OP1_SCALE:
	arm_mat_scale_f32(&mat_in1, 0.5f, &mat_out);
	break;
	case OP1_TRANS:
	arm_mat_trans_f32(&mat_in1, &mat_out);
	break;
	default:
	zassert_unreachable("invalid operation");
	}

	/* Increment output pointer */
	mat_out.pData += (rows * columns);
	}

	/* Validate output */
	zassert_true(
	test_snr_error_f32(length, output, (float32_t *)ref,
	SNR_ERROR_THRESH),
	ASSERT_MSG_SNR_LIMIT_EXCEED);

	zassert_true(
	test_close_error_f32(length, output, (float32_t *)ref,
	ABS_ERROR_THRESH, REL_ERROR_THRESH),
	ASSERT_MSG_ERROR_LIMIT_EXCEED);

	/* Free buffers */
	free(tmp1);
	free(output);
	}

	DEFINE_TEST_VARIANT4(op1, arm_mat_scale_f32, OP1_SCALE,
	ref_scale, ARRAY_SIZE(ref_scale), false);
	DEFINE_TEST_VARIANT4(op1, arm_mat_trans_f32, OP1_TRANS,
	ref_trans, ARRAY_SIZE(ref_trans), true);

	static void test_arm_mat_inverse_f32(void)
	{
	size_t index;
	size_t length = ARRAY_SIZE(ref_inv);
	uint16_t dims = (uint16_t )in_inv_dims;
	float32_t input, tmp1, *output;
	arm_status status;
	uint16_t rows, columns;

	arm_matrix_instance_f32 mat_in1;
	arm_matrix_instance_f32 mat_out;

	/* Allocate buffers */
	tmp1 = malloc(MAX_MATRIX_DIM * MAX_MATRIX_DIM * sizeof(float32_t));
	zassert_not_null(tmp1, ASSERT_MSG_BUFFER_ALLOC_FAILED);

	output = malloc(length * sizeof(float32_t));
	zassert_not_null(output, ASSERT_MSG_BUFFER_ALLOC_FAILED);

	/* Initialise contexts */
	input = (float32_t *)in_inv;
	mat_in1.pData = tmp1;
	mat_out.pData = output;

	/* Iterate matrices */
	for (index = 0; index < NUM_MATRICES_INV; index++) {
	rows = columns = *dims++;

	/* Initialise matrix dimensions */
	mat_in1.numRows = mat_out.numRows = rows;
	mat_in1.numCols = mat_out.numCols = columns;

	/* Load matrix data */
	memcpy(mat_in1.pData,
	input, rows * columns * sizeof(float32_t));

	/* Run test function */
	status = arm_mat_inverse_f32(&mat_in1, &mat_out);

	zassert_equal(status, ARM_MATH_SUCCESS,
	ASSERT_MSG_INCORRECT_COMP_RESULT);

	/* Increment pointers */
	input += (rows * columns);
	mat_out.pData += (rows * columns);
	}

	/* Validate output */
	zassert_true(
	test_snr_error_f32(length, output, (float32_t *)ref_inv,
	SNR_ERROR_THRESH_INV),
	ASSERT_MSG_SNR_LIMIT_EXCEED);

	zassert_true(
	test_close_error_f32(length, output, (float32_t *)ref_inv,
	ABS_ERROR_THRESH_INV, REL_ERROR_THRESH_INV),
	ASSERT_MSG_ERROR_LIMIT_EXCEED);

	/* Free buffers */
	free(tmp1);
	free(output);
	}

	void test_matrix_unary_f32(void)
	{
	ztest_test_suite(matrix_unary_f32,
	ztest_unit_test(test_op2_arm_mat_add_f32),
	ztest_unit_test(test_op2_arm_mat_sub_f32),
	ztest_unit_test(test_op1_arm_mat_scale_f32),
	ztest_unit_test(test_op1_arm_mat_trans_f32),
	ztest_unit_test(test_arm_mat_inverse_f32)
	);

	ztest_run_test_suite(matrix_unary_f32);
	}