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/* ************************************************************************
* Copyright (C) 2018-2025 Advanced Micro Devices, Inc. All rights reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell cop-
* ies of the Software, and to permit persons to whom the Software is furnished
* to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IM-
* PLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
* FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
* COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
* IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNE-
* CTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
* ************************************************************************ */
#pragma once
#include "testing_common.hpp"
template <typename T>
void testing_symv_bad_arg(const Arguments& arg)
{
auto rocblas_symv_fn = arg.api & c_API_FORTRAN ? rocblas_symv<T, true> : rocblas_symv<T, false>;
auto rocblas_symv_fn_64
= arg.api & c_API_FORTRAN ? rocblas_symv_64<T, true> : rocblas_symv_64<T, false>;
for(auto pointer_mode : {rocblas_pointer_mode_host, rocblas_pointer_mode_device})
{
rocblas_local_handle handle{arg};
CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, pointer_mode));
const rocblas_fill uplo = rocblas_fill_upper;
const int64_t N = 100;
const int64_t incx = 1;
const int64_t incy = 1;
const int64_t lda = 100;
DEVICE_MEMCHECK(device_vector<T>, alpha_d, (1));
DEVICE_MEMCHECK(device_vector<T>, beta_d, (1));
DEVICE_MEMCHECK(device_vector<T>, one_d, (1));
DEVICE_MEMCHECK(device_vector<T>, zero_d, (1));
const T alpha_h(1), beta_h(2), one_h(1), zero_h(0);
const T* alpha = &alpha_h;
const T* beta = &beta_h;
const T* one = &one_h;
const T* zero = &zero_h;
if(pointer_mode == rocblas_pointer_mode_device)
{
CHECK_HIP_ERROR(hipMemcpy(alpha_d, alpha, sizeof(*alpha), hipMemcpyHostToDevice));
alpha = alpha_d;
CHECK_HIP_ERROR(hipMemcpy(beta_d, beta, sizeof(*beta), hipMemcpyHostToDevice));
beta = beta_d;
CHECK_HIP_ERROR(hipMemcpy(one_d, one, sizeof(*one), hipMemcpyHostToDevice));
one = one_d;
CHECK_HIP_ERROR(hipMemcpy(zero_d, zero, sizeof(*zero), hipMemcpyHostToDevice));
zero = zero_d;
}
// Allocate device memory
DEVICE_MEMCHECK(device_matrix<T>, dA, (N, N, lda));
DEVICE_MEMCHECK(device_vector<T>, dx, (N, incx));
DEVICE_MEMCHECK(device_vector<T>, dy, (N, incy));
DAPI_EXPECT(rocblas_status_invalid_handle,
rocblas_symv_fn,
(nullptr, uplo, N, alpha, dA, lda, dx, incx, beta, dy, incy));
DAPI_EXPECT(rocblas_status_invalid_value,
rocblas_symv_fn,
(handle, rocblas_fill_full, N, alpha, dA, lda, dx, incx, beta, dy, incy));
DAPI_EXPECT(rocblas_status_invalid_pointer,
rocblas_symv_fn,
(handle, uplo, N, nullptr, dA, lda, dx, incx, beta, dy, incy));
DAPI_EXPECT(rocblas_status_invalid_pointer,
rocblas_symv_fn,
(handle, uplo, N, alpha, dA, lda, dx, incx, nullptr, dy, incy));
if(pointer_mode == rocblas_pointer_mode_host)
{
DAPI_EXPECT(rocblas_status_invalid_pointer,
rocblas_symv_fn,
(handle, uplo, N, alpha, nullptr, lda, dx, incx, beta, dy, incy));
DAPI_EXPECT(rocblas_status_invalid_pointer,
rocblas_symv_fn,
(handle, uplo, N, alpha, dA, lda, nullptr, incx, beta, dy, incy));
DAPI_EXPECT(rocblas_status_invalid_pointer,
rocblas_symv_fn,
(handle, uplo, N, alpha, dA, lda, dx, incx, beta, nullptr, incy));
}
// If N==0, all pointers can be nullptr without error
DAPI_EXPECT(
rocblas_status_success,
rocblas_symv_fn,
(handle, uplo, 0, nullptr, nullptr, lda, nullptr, incx, nullptr, nullptr, incy));
// If alpha==0, then A and x may be nullptr without error
DAPI_EXPECT(rocblas_status_success,
rocblas_symv_fn,
(handle, uplo, N, zero, nullptr, lda, nullptr, incx, beta, dy, incy));
// If alpha==0 && beta==1, then A, x and y may be nullptr without error
DAPI_EXPECT(rocblas_status_success,
rocblas_symv_fn,
(handle, uplo, N, zero, nullptr, lda, nullptr, incx, one, nullptr, incy));
if(arg.api & c_API_64)
{
int64_t n_large = 2147483649;
DAPI_EXPECT(rocblas_status_invalid_size,
rocblas_symv_fn,
(handle, uplo, n_large, alpha, dA, lda, dx, incx, beta, dy, incy));
}
}
}
template <typename T>
void testing_symv(const Arguments& arg)
{
auto rocblas_symv_fn = arg.api & c_API_FORTRAN ? rocblas_symv<T, true> : rocblas_symv<T, false>;
auto rocblas_symv_fn_64
= arg.api & c_API_FORTRAN ? rocblas_symv_64<T, true> : rocblas_symv_64<T, false>;
int64_t N = arg.N;
int64_t lda = arg.lda;
int64_t incx = arg.incx;
int64_t incy = arg.incy;
HOST_MEMCHECK(host_vector<T>, alpha, (1));
HOST_MEMCHECK(host_vector<T>, beta, (1));
alpha[0] = arg.get_alpha<T>();
beta[0] = arg.get_beta<T>();
rocblas_fill uplo = char2rocblas_fill(arg.uplo);
rocblas_local_handle handle{arg};
// argument sanity check before allocating invalid memory
if(N < 0 || lda < 1 || lda < N || !incx || !incy)
{
DAPI_EXPECT(
rocblas_status_invalid_size,
rocblas_symv_fn,
(handle, uplo, N, nullptr, nullptr, lda, nullptr, incx, nullptr, nullptr, incy));
return;
}
// Naming: `h` is in CPU (host) memory(eg hA), `d` is in GPU (device) memory (eg dA).
// Allocate host memory
HOST_MEMCHECK(host_matrix<T>, hA, (N, N, lda));
HOST_MEMCHECK(host_vector<T>, hx, (N, incx));
HOST_MEMCHECK(host_vector<T>, hy, (N, incy));
HOST_MEMCHECK(host_vector<T>, hy_gold, (N, incy)); // gold standard
// Allocate device memory
DEVICE_MEMCHECK(device_matrix<T>, dA, (N, N, lda));
DEVICE_MEMCHECK(device_vector<T>, dx, (N, incx));
DEVICE_MEMCHECK(device_vector<T>, dy, (N, incy));
DEVICE_MEMCHECK(device_vector<T>, d_alpha, (1));
DEVICE_MEMCHECK(device_vector<T>, d_beta, (1));
// Initialize data on host memory
rocblas_init_matrix(
hA, arg, rocblas_client_alpha_sets_nan, rocblas_client_symmetric_matrix, true);
rocblas_init_vector(hx, arg, rocblas_client_alpha_sets_nan, false, true);
rocblas_init_vector(hy, arg, rocblas_client_beta_sets_nan);
// Make copy in hy_gold which will later be used with CPU BLAS
hy_gold = hy;
// copy data from CPU to device
CHECK_HIP_ERROR(dx.transfer_from(hx));
CHECK_HIP_ERROR(dy.transfer_from(hy));
CHECK_HIP_ERROR(dA.transfer_from(hA));
double cpu_time_used;
double h_error, d_error;
if(arg.unit_check || arg.norm_check)
{
if(arg.pointer_mode_host)
{
// rocblas_pointer_mode_host test
CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host));
handle.pre_test(arg);
DAPI_CHECK(rocblas_symv_fn,
(handle, uplo, N, alpha, dA, lda, dx, incx, beta, dy, incy));
handle.post_test(arg);
// copy output from device to CPU
CHECK_HIP_ERROR(hy.transfer_from(dy));
}
if(arg.pointer_mode_device)
{
// rocblas_pointer_mode_device test
CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_device));
CHECK_HIP_ERROR(d_alpha.transfer_from(alpha));
CHECK_HIP_ERROR(d_beta.transfer_from(beta));
dy.transfer_from(hy_gold);
handle.pre_test(arg);
DAPI_CHECK(rocblas_symv_fn,
(handle, uplo, N, d_alpha, dA, lda, dx, incx, d_beta, dy, incy));
handle.post_test(arg);
if(arg.repeatability_check)
{
// copy output from device to CPU
CHECK_HIP_ERROR(hy.transfer_from(dy));
HOST_MEMCHECK(host_vector<T>, hy_copy, (N, incy));
// multi-GPU support
int device_id, device_count;
CHECK_HIP_ERROR(limit_device_count(device_count, (int)arg.devices));
for(int dev_id = 0; dev_id < device_count; dev_id++)
{
CHECK_HIP_ERROR(hipGetDevice(&device_id));
if(device_id != dev_id)
CHECK_HIP_ERROR(hipSetDevice(dev_id));
//New rocblas handle for new device
rocblas_local_handle handle_copy{arg};
// Allocate device memory
DEVICE_MEMCHECK(device_matrix<T>, dA_copy, (N, N, lda));
DEVICE_MEMCHECK(device_vector<T>, dx_copy, (N, incx));
DEVICE_MEMCHECK(device_vector<T>, dy_copy, (N, incy));
DEVICE_MEMCHECK(device_vector<T>, d_alpha_copy, (1));
DEVICE_MEMCHECK(device_vector<T>, d_beta_copy, (1));
// copy data from CPU to device
CHECK_HIP_ERROR(dx_copy.transfer_from(hx));
CHECK_HIP_ERROR(dA_copy.transfer_from(hA));
CHECK_HIP_ERROR(d_alpha_copy.transfer_from(alpha));
CHECK_HIP_ERROR(d_beta_copy.transfer_from(beta));
CHECK_ROCBLAS_ERROR(
rocblas_set_pointer_mode(handle_copy, rocblas_pointer_mode_device));
for(int runs = 0; runs < arg.iters; runs++)
{
CHECK_HIP_ERROR(dy_copy.transfer_from(hy_gold));
CHECK_ROCBLAS_ERROR(rocblas_symv_fn(handle_copy,
uplo,
N,
d_alpha_copy,
dA_copy,
lda,
dx_copy,
incx,
d_beta_copy,
dy_copy,
incy));
CHECK_HIP_ERROR(hy_copy.transfer_from(dy_copy));
unit_check_general<T>(1, N, incy, hy, hy_copy);
}
}
return;
}
}
cpu_time_used = get_time_us_no_sync();
// cpu reference
ref_symv<T>(uplo, N, alpha[0], hA, lda, hx, incx, beta[0], hy_gold, incy);
cpu_time_used = get_time_us_no_sync() - cpu_time_used;
if(arg.pointer_mode_host)
{
if(arg.unit_check)
{
if(std::is_same_v<T, float> || std::is_same_v<T, double>)
{
unit_check_general<T>(1, N, incy, hy_gold, hy);
}
else
{
const double tol = N * sum_error_tolerance<T>;
near_check_general<T>(1, N, incy, hy_gold, hy, tol);
}
}
if(arg.norm_check)
{
h_error = norm_check_general<T>('F', 1, N, incy, hy_gold, hy);
}
}
if(arg.pointer_mode_device)
{
// copy output from device to CPU
CHECK_HIP_ERROR(hy.transfer_from(dy));
if(arg.unit_check)
{
if(std::is_same_v<T, float> || std::is_same_v<T, double>)
{
unit_check_general<T>(1, N, incy, hy_gold, hy);
}
else
{
const double tol = N * sum_error_tolerance<T>;
near_check_general<T>(1, N, incy, hy_gold, hy, tol);
}
}
if(arg.norm_check)
{
d_error = norm_check_general<T>('F', 1, N, incy, hy_gold, hy);
}
}
}
if(arg.timing)
{
CHECK_ROCBLAS_ERROR(rocblas_set_pointer_mode(handle, rocblas_pointer_mode_host));
double gpu_time_used;
int number_cold_calls = arg.cold_iters;
int total_calls = number_cold_calls + arg.iters;
hipStream_t stream;
CHECK_ROCBLAS_ERROR(rocblas_get_stream(handle, &stream));
for(int iter = 0; iter < total_calls; iter++)
{
if(iter == number_cold_calls)
gpu_time_used = get_time_us_sync(stream);
DAPI_DISPATCH(rocblas_symv_fn,
(handle, uplo, N, alpha, dA, lda, dx, incx, beta, dy, incy));
}
gpu_time_used = get_time_us_sync(stream) - gpu_time_used;
ArgumentModel<e_uplo, e_N, e_alpha, e_lda, e_incx, e_beta, e_incy>{}.log_args<T>(
rocblas_cout,
arg,
gpu_time_used,
symv_gflop_count<T>(N),
symv_gbyte_count<T>(N),
cpu_time_used,
h_error,
d_error);
}
}
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