* Copyright (c) 2025 Huawei Technologies Co., Ltd.
* This program is free software, you can redistribute it and/or modify it under the terms and conditions of
* CANN Open Software License Agreement Version 2.0 (the "License").
* Please refer to the License for details. You may not use this file except in compliance with the License.
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, EITHER EXPRESS OR IMPLIED,
* INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, MERCHANTABILITY, OR FITNESS FOR A PARTICULAR PURPOSE.
* See LICENSE in the root of the software repository for the full text of the License.
*/
#include "aclnn_erf.h"
#include "erf.h"
#include "aclnn_kernels/contiguous.h"
#include "aclnn_kernels/cast.h"
#include "opdev/op_dfx.h"
#include "opdev/make_op_executor.h"
#include "opdev/platform.h"
#include "aclnn_kernels/common/op_error_check.h"
#include "op_api/level2_base.h"
using namespace op;
static const std::initializer_list<DataType> DTYPE_SUPPORT_LIST_910 = {
DataType::DT_DOUBLE, DataType::DT_FLOAT, DataType::DT_FLOAT16, DataType::DT_BOOL, op::DataType::DT_INT64};
static const std::initializer_list<DataType> DTYPE_SUPPORT_LIST_910B = {DataType::DT_DOUBLE, DataType::DT_FLOAT,
DataType::DT_FLOAT16, DataType::DT_BF16,
DataType::DT_BOOL, op::DataType::DT_INT64};
static const std::initializer_list<DataType> ASCEND910_DTYPE_SELFREF_LIST = {
op::DataType::DT_DOUBLE, op::DataType::DT_FLOAT, op::DataType::DT_FLOAT16};
static const std::initializer_list<DataType> ASCEND910B_DTYPE_SELFREF_LIST = {
op::DataType::DT_DOUBLE, op::DataType::DT_FLOAT, op::DataType::DT_FLOAT16, op::DataType::DT_BF16};
static bool CheckDtypeValid(const aclTensor* self, const aclTensor* out)
{
bool is910BSocVersion =
(GetCurrentPlatformInfo().GetSocVersion() == SocVersion::ASCEND910B ||
GetCurrentPlatformInfo().GetSocVersion() == SocVersion::ASCEND910_93);
const std::initializer_list<DataType> DTYPE_SUPPORT_LIST =
is910BSocVersion ? DTYPE_SUPPORT_LIST_910B : DTYPE_SUPPORT_LIST_910;
OP_CHECK_DTYPE_NOT_SUPPORT(self, DTYPE_SUPPORT_LIST, return false);
if (self->GetDataType() == op::DataType::DT_BOOL || self->GetDataType() == op::DataType::DT_INT64) {
OP_CHECK_RESULT_DTYPE_CAST_FAILED(op::DataType::DT_FLOAT, out->GetDataType(), return false);
}
if (self->GetDataType() != op::DataType::DT_BOOL && self->GetDataType() != op::DataType::DT_INT64) {
OP_CHECK_RESULT_DTYPE_CAST_FAILED(self->GetDataType(), out->GetDataType(), return false);
}
return true;
}
static bool CheckInplaceDtypeValid(const aclTensor* selfRef)
{
auto inplaceSupportList = GetDtypeSupportListV2(ASCEND910B_DTYPE_SELFREF_LIST, ASCEND910_DTYPE_SELFREF_LIST);
OP_CHECK_DTYPE_NOT_SUPPORT(selfRef, inplaceSupportList, return false);
return true;
}
static aclnnStatus CheckParamsErf(const aclTensor* self, const aclTensor* out)
{
CHECK_RET(CheckNotNull2Tensor(self, out), ACLNN_ERR_PARAM_NULLPTR);
CHECK_RET(CheckDtypeValid(self, out), ACLNN_ERR_PARAM_INVALID);
CHECK_RET(CheckSameShape1In1Out(self, out), ACLNN_ERR_PARAM_INVALID);
return ACLNN_SUCCESS;
}
static aclnnStatus CheckInplaceParamsErf(aclTensor* selfRef)
{
OP_CHECK_NULL(selfRef, return ACLNN_ERR_PARAM_NULLPTR);
CHECK_RET(CheckInplaceDtypeValid(selfRef), ACLNN_ERR_PARAM_INVALID);
return ACLNN_SUCCESS;
}
static aclnnStatus GetWorkspaceSizeCommon(
const aclTensor* self, aclTensor* out, uint64_t* workspaceSize, aclOpExecutor** executor)
{
auto uniqueExecutor = CREATE_EXECUTOR();
CHECK_RET(uniqueExecutor.get() != nullptr, ACLNN_ERR_INNER_CREATE_EXECUTOR);
auto ret = CheckParamsErf(self, out);
CHECK_RET(ret == ACLNN_SUCCESS, ret);
if (self->IsEmpty()) {
*workspaceSize = 0;
uniqueExecutor.ReleaseTo(executor);
return ACLNN_SUCCESS;
}
auto selfContiguous = l0op::Contiguous(self, uniqueExecutor.get());
CHECK_RET(selfContiguous != nullptr, ACLNN_ERR_INNER_NULLPTR);
auto castSelf = selfContiguous;
if (self->GetDataType() == op::DataType::DT_BOOL || self->GetDataType() == op::DataType::DT_INT64) {
castSelf = l0op::Cast(selfContiguous, op::DataType::DT_FLOAT, uniqueExecutor.get());
}
auto erfResult = l0op::Erf(castSelf, uniqueExecutor.get());
CHECK_RET(erfResult != nullptr, ACLNN_ERR_INNER_NULLPTR);
auto castErfResult = l0op::Cast(erfResult, out->GetDataType(), uniqueExecutor.get());
CHECK_RET(castErfResult != nullptr, ACLNN_ERR_INNER_NULLPTR);
auto viewCopyResult = l0op::ViewCopy(castErfResult, out, uniqueExecutor.get());
CHECK_RET(viewCopyResult != nullptr, ACLNN_ERR_INNER_NULLPTR);
*workspaceSize = uniqueExecutor->GetWorkspaceSize();
uniqueExecutor.ReleaseTo(executor);
return ACLNN_SUCCESS;
}
aclnnStatus aclnnErfGetWorkspaceSize(
const aclTensor* self, aclTensor* out, uint64_t* workspaceSize, aclOpExecutor** executor)
{
L2_DFX_PHASE_1(aclnnErf, DFX_IN(self), DFX_OUT(out));
return GetWorkspaceSizeCommon(self, out, workspaceSize, executor);
}
aclnnStatus aclnnErf(void* workspace, uint64_t workspaceSize, aclOpExecutor* executor, aclrtStream stream)
{
L2_DFX_PHASE_2(aclnnErf);
return CommonOpExecutorRun(workspace, workspaceSize, executor, stream);
}
aclnnStatus aclnnInplaceErfGetWorkspaceSize(aclTensor* selfRef, uint64_t* workspaceSize, aclOpExecutor** executor)
{
L2_DFX_PHASE_1(aclnnInplaceErf, DFX_IN(selfRef), DFX_OUT(selfRef));
auto ret = CheckInplaceParamsErf(selfRef);
CHECK_RET(ret == ACLNN_SUCCESS, ret);
return GetWorkspaceSizeCommon(selfRef, selfRef, workspaceSize, executor);
}
aclnnStatus aclnnInplaceErf(void* workspace, uint64_t workspaceSize, aclOpExecutor* executor, aclrtStream stream)
{
L2_DFX_PHASE_2(aclnnInplaceErf);
return CommonOpExecutorRun(workspace, workspaceSize, executor, stream);
}
