aclnnForeachMinimumScalarList
支持的产品型号
- Atlas A2训练系列产品/Atlas 800I A2推理产品。
接口原型
每个算子分为两段式接口,必须先调用“aclnnForeachMinimumScalarListGetWorkspaceSize” 接口获取入参并根据计算流程计算所需workspace大小,再调用“aclnnForeachMinimumScalarList”接口执行计算。
aclnnStatus aclnnForeachMinimumScalarListGetWorkspaceSize(const aclTensorList *x, const aclScalarList *scalars, aclTensorList *out, uint64_t *workspaceSize, aclOpExecutor **executor)
aclnnStatus aclnnForeachMinimumScalarList(void *workspace, uint64_t workspaceSize, aclOpExecutor *executor, aclrtStream stream)
功能描述
算子功能:返回一个和输入张量列表同样形状大小的新张量列表, 对张量列表x和标量列表scalar执行逐元素比较,返回最小值的张量。
计算公式:
aclnnForeachMinimumScalarListGetWorkspaceSize
参数说明:
- x(aclTensorList*,计算输入):公式中的
x
,Device侧的aclTensorList,数据类型支持FLOAT、FLOAT16、BFLOAT16、INT32。数据格式支持ND,shape维度不高于8维。支持非连续的Tensor。 - scalars(aclScalarList*,计算输入):公式中的
scalars
,Host侧的aclScalarList,数据格式支持ND。支持非连续的Tensor。数据类型仅支持FLOAT和INT64,且与输入参数的数据类型具有一定对应关系:- 当入参
x
的数据类型为FLOAT、FLOAT16、BFLOAT16时,scalars
的数据类型仅支持FLOAT。 - 当入参
x
的数据类型为INT32时,scalars
的数据类型仅支持INT64。
- 当入参
- out(aclTensorList*,计算输出):公式中的
out
,Device侧的aclTensorList,数据类型支持FLOAT、FLOAT16、BFLOAT16、INT32,数据格式支持ND,shape维度不高于8维。数据类型、数据格式和shape跟入参x
的数据类型、数据格式和shape一致。支持非连续的Tensor。 - workspaceSize(uint64_t*,出参):返回用户需要在Device侧申请的workspace大小。
- executor(aclOpExecutor**,出参):返回op执行器,包含了算子计算流程。
- x(aclTensorList*,计算输入):公式中的
返回值:
aclnnStatus:返回状态码,具体参见aclnn返回码。
第一段接口完成入参校验,出现以下场景时报错: 返回161001(ACLNN_ERR_PARAM_NULLPTR): 1. 传入的x、scalrs和out是空指针。 返回161002(ACLNN_ERR_PARAM_INVALID): 1. x、scalrs和out的数据类型不在支持的范围之内。
aclnnForeachMinimumScalarList
参数说明:
- workspace(void*,入参):在Device侧申请的workspace内存地址。
- workspaceSize(uint64_t,入参):在Device侧申请的workspace大小,由第一段接口aclnnForeachMinimumScalarListGetWorkspaceSize获取。
- executor(aclOpExecutor*,入参):op执行器,包含了算子计算流程。
- stream(aclrtStream,入参):指定执行任务的AscendCL Stream流。
返回值:
aclnnStatus:返回状态码,具体参见aclnn返回码。
约束与限制
无。
调用示例
示例代码如下,仅供参考,具体编译和执行过程请参考编译与运行样例。
#include <iostream>
#include <vector>
#include "acl/acl.h"
#include "aclnnop/aclnn_foreach_minimum_scalar_list.h"
#define CHECK_RET(cond, return_expr) \
do { \
if (!(cond)) { \
return_expr; \
} \
} while (0)
#define LOG_PRINT(message, ...) \
do { \
printf(message, ##__VA_ARGS__); \
} while (0)
int64_t GetShapeSize(const std::vector<int64_t>& shape) {
int64_t shapeSize = 1;
for (auto i : shape) {
shapeSize *= i;
}
return shapeSize;
}
int Init(int32_t deviceId, aclrtStream* stream) {
// 固定写法,AscendCL初始化
auto ret = aclInit(nullptr);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclInit failed. ERROR: %d\n", ret); return ret);
ret = aclrtSetDevice(deviceId);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclrtSetDevice failed. ERROR: %d\n", ret); return ret);
ret = aclrtCreateStream(stream);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclrtCreateStream failed. ERROR: %d\n", ret); return ret);
return 0;
}
template <typename T>
int CreateAclTensor(const std::vector<T>& hostData, const std::vector<int64_t>& shape, void** deviceAddr,
aclDataType dataType, aclTensor** tensor) {
auto size = GetShapeSize(shape) * sizeof(T);
// 调用aclrtMalloc申请device侧内存
auto ret = aclrtMalloc(deviceAddr, size, ACL_MEM_MALLOC_HUGE_FIRST);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclrtMalloc failed. ERROR: %d\n", ret); return ret);
// 调用aclrtMemcpy将host侧数据复制到device侧内存上
ret = aclrtMemcpy(*deviceAddr, size, hostData.data(), size, ACL_MEMCPY_HOST_TO_DEVICE);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclrtMemcpy failed. ERROR: %d\n", ret); return ret);
// 计算连续tensor的strides
std::vector<int64_t> strides(shape.size(), 1);
for (int64_t i = shape.size() - 2; i >= 0; i--) {
strides[i] = shape[i + 1] * strides[i + 1];
}
// 调用aclCreateTensor接口创建aclTensor
*tensor = aclCreateTensor(shape.data(), shape.size(), dataType, strides.data(), 0, aclFormat::ACL_FORMAT_ND,
shape.data(), shape.size(), *deviceAddr);
return 0;
}
int main() {
// 1. (固定写法)device/stream初始化,参考AscendCL对外接口列表
// 根据自己的实际device填写deviceId
int32_t deviceId = 0;
aclrtStream stream;
auto ret = Init(deviceId, &stream);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("Init acl failed. ERROR: %d\n", ret); return ret);
// 2. 构造输入与输出,需要根据API的接口自定义构造
std::vector<int64_t> selfShape1 = {2, 3};
std::vector<int64_t> selfShape2 = {1, 3};
std::vector<int64_t> outShape1 = {2, 3};
std::vector<int64_t> outShape2 = {1, 3};
void* input1DeviceAddr = nullptr;
void* input2DeviceAddr = nullptr;
void* out1DeviceAddr = nullptr;
void* out2DeviceAddr = nullptr;
aclTensor* input1 = nullptr;
aclTensor* input2 = nullptr;
aclScalar* alpha1 = nullptr;
aclScalar* alpha2 = nullptr;
aclTensor* out1 = nullptr;
aclTensor* out2 = nullptr;
std::vector<float> input1HostData = {1, 2, 3, 4, 5, 6};
std::vector<float> input2HostData = {7, 8, 9};
std::vector<float> out1HostData(6, 0);
std::vector<float> out2HostData(3, 0);
float alpha1Value = 4.2f;
float alpha2Value = 8.2f;
// 创建input1 aclTensor
ret = CreateAclTensor(input1HostData, selfShape1, &input1DeviceAddr, aclDataType::ACL_FLOAT, &input1);
CHECK_RET(ret == ACL_SUCCESS, return ret);
// 创建input2 aclTensor
ret = CreateAclTensor(input2HostData, selfShape2, &input2DeviceAddr, aclDataType::ACL_FLOAT, &input2);
CHECK_RET(ret == ACL_SUCCESS, return ret);
// 创建alpha1 aclScalar
alpha1 = aclCreateScalar(&alpha1Value, aclDataType::ACL_FLOAT);
CHECK_RET(alpha1 != nullptr, return ret);
// 创建alpha2 aclScalar
alpha2 = aclCreateScalar(&alpha2Value, aclDataType::ACL_FLOAT);
CHECK_RET(alpha2 != nullptr, return ret);
// 创建out1 aclTensor
ret = CreateAclTensor(out1HostData, outShape1, &out1DeviceAddr, aclDataType::ACL_FLOAT, &out1);
CHECK_RET(ret == ACL_SUCCESS, return ret);
// 创建out2 aclTensor
ret = CreateAclTensor(out2HostData, outShape2, &out2DeviceAddr, aclDataType::ACL_FLOAT, &out2);
CHECK_RET(ret == ACL_SUCCESS, return ret);
std::vector<aclTensor*> tempInput{input1, input2};
aclTensorList* tensorListInput = aclCreateTensorList(tempInput.data(), tempInput.size());
std::vector<aclTensor*> tempOutput{out1, out2};
aclTensorList* tensorListOutput = aclCreateTensorList(tempOutput.data(), tempOutput.size());
std::vector<aclScalar*> tempscalar{alpha1, alpha2};
aclScalarList* scalarlist = aclCreateScalarList(tempscalar.data(), tempscalar.size());
// 3. 调用CANN算子库API,需要修改为具体的Api名称
uint64_t workspaceSize = 0;
aclOpExecutor* executor;
// 调用aclnnForeachMinimumScalarList第一段接口
ret = aclnnForeachMinimumScalarListGetWorkspaceSize(tensorListInput, scalarlist, tensorListOutput, &workspaceSize, &executor);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclnnForeachMinimumScalarListGetWorkspaceSize failed. ERROR: %d\n", ret); return ret);
// 根据第一段接口计算出的workspaceSize申请device内存
void* workspaceAddr = nullptr;
if (workspaceSize > 0) {
ret = aclrtMalloc(&workspaceAddr, workspaceSize, ACL_MEM_MALLOC_HUGE_FIRST);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("allocate workspace failed. ERROR: %d\n", ret); return ret);
}
// 调用aclnnForeachMinimumScalarList第二段接口
ret = aclnnForeachMinimumScalarList(workspaceAddr, workspaceSize, executor, stream);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclnnForeachMinimumScalarList failed. ERROR: %d\n", ret); return ret);
// 4. (固定写法)同步等待任务执行结束
ret = aclrtSynchronizeStream(stream);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclrtSynchronizeStream failed. ERROR: %d\n", ret); return ret);
// 5. 获取输出的值,将device侧内存上的结果复制至host侧,需要根据具体API的接口定义修改
auto size = GetShapeSize(outShape1);
std::vector<float> out1Data(size, 0);
ret = aclrtMemcpy(out1Data.data(), out1Data.size() * sizeof(out1Data[0]), out1DeviceAddr,
size * sizeof(out1Data[0]), ACL_MEMCPY_DEVICE_TO_HOST);
for (int64_t i = 0; i < size; i++) {
LOG_PRINT("out1 result[%ld] is: %f\n", i, out1Data[i]);
}
size = GetShapeSize(outShape2);
std::vector<float> out2Data(size, 0);
ret = aclrtMemcpy(out2Data.data(), out2Data.size() * sizeof(out2Data[0]), out2DeviceAddr,
size * sizeof(out2Data[0]), ACL_MEMCPY_DEVICE_TO_HOST);
CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("copy result from device to host failed. ERROR: %d\n", ret); return ret);
for (int64_t i = 0; i < size; i++) {
LOG_PRINT("out2 result[%ld] is: %f\n", i, out2Data[i]);
}
// 6. 释放aclTensor和aclScalar,需要根据具体API的接口定义修改
aclDestroyTensorList(tensorListInput);
aclDestroyTensorList(tensorListOutput);
aclDestroyScalarList(scalarlist);
// 7.释放device资源,需要根据具体API的接口定义修改
aclrtFree(input1DeviceAddr);
aclrtFree(input2DeviceAddr);
aclrtFree(out1DeviceAddr);
aclrtFree(out2DeviceAddr);
if (workspaceSize > 0) {
aclrtFree(workspaceAddr);
}
aclrtDestroyStream(stream);
aclrtResetDevice(deviceId);
aclFinalize();
return 0;
}