tests/vadd_vv_test.cpp - sw/vec - Git at Google

 #include <limits.h>
 #include <riscv_vector.h>
 #include <springbok.h>
 #include <stdio.h>
 #include <stdlib.h>

 #include <bit>
 #include <tuple>

 #include "pw_unit_test/framework.h"
 #include "test_v_helpers.h"

 namespace vadd_vv_test {
 namespace {

 using namespace test_v_helpers;

 uint8_t test_vector_1[MAXVL_BYTES];
 uint8_t test_vector_2[MAXVL_BYTES];

 class VaddVxTest : public ::testing::Test {
  protected:
   void SetUp() override { zero_vector_registers(); }
   void TearDown() override { zero_vector_registers(); }
 };

 TEST_F(VaddVxTest, vadd_vv_demo) {
   for (int i = 0; i < AVL_COUNT; i++) {
     int32_t avl = AVLS[i];
     int vlmax;
     int vl;
     std::tie(vlmax, vl) = vector_test_setup<uint8_t>(
         VLMUL::LMUL_M1, avl, test_vector_1, test_vector_2);
     if (avl > vlmax) {
       continue;
     }
     int8_t *ptr_vec_1 = reinterpret_cast<int8_t *>(test_vector_1);
     int8_t *ptr_vec_2 = reinterpret_cast<int8_t *>(test_vector_2);

     // set up values to test up to index of the AVL
     for (int idx = 0; idx < avl; idx++) {
       // restrict values to valid int8_t range
       ptr_vec_1[idx] = idx % (INT8_MAX) + (INT8_MIN);
     }
     __asm__ volatile("vle8.v v8, (%0)" : : "r"(ptr_vec_1));
     __asm__ volatile("vadd.vv v8, v8, v8");
     for (int idx = 0; idx < vl; idx++) {
       ptr_vec_1[idx] =
           ptr_vec_1[idx] + ptr_vec_1[idx];  // restrict values to valid int8
     }
     __asm__ volatile("vse8.v v8, (%0)" : : "r"(ptr_vec_2));
     assert_vec_elem_eq<int8_t>(vlmax, test_vector_1, test_vector_2);
   }
 }

 #define DEFINE_TEST_VADD_VV(_SEW_, _LMUL_)                                     \
   TEST_F(VaddVxTest, vadd_vv##_SEW_##m##_LMUL_) {                              \
     for (int i = 0; i < AVL_COUNT; i++) {                                      \
       int32_t avl = AVLS[i];                                                   \
       int vlmax;                                                               \
       int vl;                                                                  \
       std::tie(vlmax, vl) = vector_test_setup<int##_SEW_##_t>(                 \
           VLMUL::LMUL_M##_LMUL_, avl, test_vector_1, test_vector_2);           \
       if (avl > vlmax) {                                                       \
         continue;                                                              \
       }                                                                        \
       int##_SEW_##_t *ptr_vec_1 =                                              \
           reinterpret_cast<int##_SEW_##_t *>(test_vector_1);                   \
       int##_SEW_##_t *ptr_vec_2 =                                              \
           reinterpret_cast<int##_SEW_##_t *>(test_vector_2);                   \
                                                                                \
       for (long long idx = 0; idx < avl; idx++) {                              \
         ptr_vec_1[idx] = idx % INT##_SEW_##_MAX + INT##_SEW_##_MIN;            \
       }                                                                        \
                                                                                \
       __asm__ volatile("vle" #_SEW_ ".v v8, (%0)" : : "r"(ptr_vec_1));         \
       __asm__ volatile("vadd.vv v8, v8, v8");                                  \
       for (int idx = 0; idx < vl; idx++) {                                     \
         ptr_vec_1[idx] = ptr_vec_1[idx] + ptr_vec_1[idx];                      \
       }                                                                        \
       __asm__ volatile("vse" #_SEW_ ".v v8, (%0)" : : "r"(ptr_vec_2));         \
       assert_vec_elem_eq<int##_SEW_##_t>(vlmax, test_vector_1, test_vector_2); \
     }                                                                          \
   }

 // TODO(gkielian): modify macro to permit more than one test per sew/lmul pair
 DEFINE_TEST_VADD_VV(8, 1)
 DEFINE_TEST_VADD_VV(8, 2)
 DEFINE_TEST_VADD_VV(8, 4)
 DEFINE_TEST_VADD_VV(8, 8)

 DEFINE_TEST_VADD_VV(16, 1)
 DEFINE_TEST_VADD_VV(16, 2)
 DEFINE_TEST_VADD_VV(16, 4)
 DEFINE_TEST_VADD_VV(16, 8)

 DEFINE_TEST_VADD_VV(32, 1)
 DEFINE_TEST_VADD_VV(32, 2)
 DEFINE_TEST_VADD_VV(32, 4)
 DEFINE_TEST_VADD_VV(32, 8)

 }  // namespace
 }  // namespace vadd_vv_test
	#include <limits.h>
	#include <riscv_vector.h>
	#include <springbok.h>
	#include <stdio.h>
	#include <stdlib.h>

	#include <bit>
	#include <tuple>

	#include "pw_unit_test/framework.h"
	#include "test_v_helpers.h"

	namespace vadd_vv_test {
	namespace {

	using namespace test_v_helpers;

	uint8_t test_vector_1[MAXVL_BYTES];
	uint8_t test_vector_2[MAXVL_BYTES];

	class VaddVxTest : public ::testing::Test {
	protected:
	void SetUp() override { zero_vector_registers(); }
	void TearDown() override { zero_vector_registers(); }
	};

	TEST_F(VaddVxTest, vadd_vv_demo) {
	for (int i = 0; i < AVL_COUNT; i++) {
	int32_t avl = AVLS[i];
	int vlmax;
	int vl;
	std::tie(vlmax, vl) = vector_test_setup<uint8_t>(
	VLMUL::LMUL_M1, avl, test_vector_1, test_vector_2);
	if (avl > vlmax) {
	continue;
	}
	int8_t ptr_vec_1 = reinterpret_cast<int8_t >(test_vector_1);
	int8_t ptr_vec_2 = reinterpret_cast<int8_t >(test_vector_2);

	// set up values to test up to index of the AVL
	for (int idx = 0; idx < avl; idx++) {
	// restrict values to valid int8_t range
	ptr_vec_1[idx] = idx % (INT8_MAX) + (INT8_MIN);
	}
	__asm__ volatile("vle8.v v8, (%0)" : : "r"(ptr_vec_1));
	__asm__ volatile("vadd.vv v8, v8, v8");
	for (int idx = 0; idx < vl; idx++) {
	ptr_vec_1[idx] =
	ptr_vec_1[idx] + ptr_vec_1[idx]; // restrict values to valid int8
	}
	__asm__ volatile("vse8.v v8, (%0)" : : "r"(ptr_vec_2));
	assert_vec_elem_eq<int8_t>(vlmax, test_vector_1, test_vector_2);
	}
	}

	#define DEFINE_TEST_VADD_VV(_SEW_, _LMUL_) \
	TEST_F(VaddVxTest, vadd_vv##_SEW_##m##_LMUL_) { \
	for (int i = 0; i < AVL_COUNT; i++) { \
	int32_t avl = AVLS[i]; \
	int vlmax; \
	int vl; \
	std::tie(vlmax, vl) = vector_test_setup<int##_SEW_##_t>( \
	VLMUL::LMUL_M##_LMUL_, avl, test_vector_1, test_vector_2); \
	if (avl > vlmax) { \
	continue; \
	} \
	int##_SEW_##_t *ptr_vec_1 = \
	reinterpret_cast<int##_SEW_##_t *>(test_vector_1); \
	int##_SEW_##_t *ptr_vec_2 = \
	reinterpret_cast<int##_SEW_##_t *>(test_vector_2); \
	\
	for (long long idx = 0; idx < avl; idx++) { \
	ptr_vec_1[idx] = idx % INT##_SEW_##_MAX + INT##_SEW_##_MIN; \
	} \
	\
	__asm__ volatile("vle" #_SEW_ ".v v8, (%0)" : : "r"(ptr_vec_1)); \
	__asm__ volatile("vadd.vv v8, v8, v8"); \
	for (int idx = 0; idx < vl; idx++) { \
	ptr_vec_1[idx] = ptr_vec_1[idx] + ptr_vec_1[idx]; \
	} \
	__asm__ volatile("vse" #_SEW_ ".v v8, (%0)" : : "r"(ptr_vec_2)); \
	assert_vec_elem_eq<int##_SEW_##_t>(vlmax, test_vector_1, test_vector_2); \
	} \
	}

	// TODO(gkielian): modify macro to permit more than one test per sew/lmul pair
	DEFINE_TEST_VADD_VV(8, 1)
	DEFINE_TEST_VADD_VV(8, 2)
	DEFINE_TEST_VADD_VV(8, 4)
	DEFINE_TEST_VADD_VV(8, 8)

	DEFINE_TEST_VADD_VV(16, 1)
	DEFINE_TEST_VADD_VV(16, 2)
	DEFINE_TEST_VADD_VV(16, 4)
	DEFINE_TEST_VADD_VV(16, 8)

	DEFINE_TEST_VADD_VV(32, 1)
	DEFINE_TEST_VADD_VV(32, 2)
	DEFINE_TEST_VADD_VV(32, 4)
	DEFINE_TEST_VADD_VV(32, 8)

	} // namespace
	} // namespace vadd_vv_test