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aclnnGlu

接口原型

每个算子有两段接口,必须先调用“aclnnXxxGetWorkspaceSize”接口获取入参并根据计算流程计算所需workspace大小,再调用“aclnnXxx”接口执行计算。两段式接口如下:

  • 第一段接口:aclnnStatus aclnnGluGetWorkspaceSize(const aclTensor *self, int64_t dim, const aclTensor *out, uint64_t *workspaceSize, aclOpExecutor **executor)
  • 第二段接口:aclnnStatus aclnnGlu(void *workspace, uint64_t workspaceSize, aclOpExecutor *executor, aclrtStream stream)

功能描述

  • 算子功能:GLU是一个门控线性单元函数,它将输入张量沿着指定维度dim平均分成两个张量,并将其前部分张量与后部分张量的Sigmoid函数输出的结果逐元素相乘。
  • 计算公式:

    a表示输入张量在指定维度dim进行均分后的前部分张量,b表示后半部分张量。

aclnnGluGetWorkspaceSize

  • 接口定义:

    aclnnStatus aclnnGluGetWorkspaceSize(const aclTensor *self, int64_t dim, const aclTensor *out, uint64_t *workspaceSize, aclOpExecutor **executor)

  • 参数说明:
    • self:Device侧的aclTensor,输入张量,数据类型支持DOUBLE、FLOAT、FLOAT16。输入维度必须大于0,且shape必须在入参dim对应的维度上可以整除2,shape为(∗1​, N, ∗2​),其中∗表示任何数量的附加维,N表示dim指定的维度大小。支持非连续的Tensor,数据格式支持ND。
    • dim:表示要拆分输入self的维度,数据类型支持INT64,取值范围[-self.dim(), self.dim()-1]。
    • out:Device侧的aclTensor,数据类型支持DOUBLE、FLOAT、FLOAT16,数据类型必须可以由self cast得到。shape为(∗1, M, ∗2​),其中∗表示self中对应维度,M=N/2。支持非连续的Tensor,数据格式支持ND。
    • workspaceSize:返回用户需要在Device侧申请的workspace大小。
    • executor:返回op执行器,包含了算子计算流程。
  • 返回值:

    返回aclnnStatus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):传入的self或out是空指针。
    • 返回161002(ACLNN_ERR_PARAM_INVALID):
      • self和out的数据类型不在支持的范围之内。
      • dim取值不在支持的范围内。
      • self在指定的dim所对应的维度不能整除2。
      • out的shape不等于self根据dim拆分后的shape。
      • out的dtype不与self一致。
      • self、out的维度大于8。
      • self的维度等于0。

aclnnGlu

  • 接口定义:

    aclnnStatus aclnnGlu(void *workspace, uint64_t workspaceSize, aclOpExecutor *executor, aclrtStream stream)

  • 参数说明:
    • workspace:在Device侧申请的workspace内存起址。
    • workspaceSize:在Device侧申请的workspace大小,由第一段接口aclnnGluGetWorkspaceSize获取。
    • executor:op执行器,包含了算子计算流程。
    • stream:指定执行任务的AscendCL stream流。
  • 返回值:

    返回aclnnStatus状态码,具体参见aclnn返回码

调用示例

#include <iostream>
#include <vector>
#include "acl/acl.h"
#include "aclnnop/aclnn_glu.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 shape_size = 1;
  for (auto i : shape) {
    shape_size *= i;
  }
  return shape_size;
}

int Init(int32_t deviceId, aclrtContext* context, 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 = aclrtCreateContext(context, deviceId);
  CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclrtCreateContext failed. ERROR: %d\n", ret); return ret);
  ret = aclrtSetCurrentContext(*context);
  CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclrtSetCurrentContext 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侧数据拷贝到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/context/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;
  aclrtContext context;
  aclrtStream stream;
  auto ret = Init(deviceId, &context, &stream);
  // check根据自己的需要处理
  CHECK_RET(ret == 0, 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> selfShape = {2,4,6};
  std::vector<int64_t> outShape = {1,4,6};
  void* selfDeviceAddr = nullptr;
  void* outDeviceAddr = nullptr;
  aclTensor* self = nullptr;
  aclTensor* out = nullptr;
  std::vector<float> selfHostData = {
    1.4021, -2.2242, -0.2267,  1.0049, -0.9057, -1.2181,
    1.4031, -0.1750, -0.2705, -1.3884,  0.2565, -0.7543,
    -0.3368,  0.3036,  0.4370,  1.9198,  0.0974,  0.9725,
    -1.7963, -1.9863,  2.2742,  1.0436,  1.6882,  0.7845,
    0.5129,  0.7107, -0.0894, -1.7567,  1.5542,  1.5608,
    -1.0318, -0.5742,  0.1330, -1.4514, -2.5802, -0.4738,
    0.2548, -1.7638,  0.8152,  0.5531,  0.1251,  0.8516,
    -0.0048, -0.9011, -0.4680,  0.2906, -0.0880,  0.3975
  };
  std::vector<float> outHostData = {
    0, 0, 0, 0, 0, 0,
    0, 0, 0, 0, 0, 0,
    0, 0, 0, 0, 0, 0,
    0, 0, 0, 0, 0, 0
  };

  // 创建self aclTensor
  ret = CreateAclTensor(selfHostData, selfShape, &selfDeviceAddr, aclDataType::ACL_FLOAT, &self);
  CHECK_RET(ret == ACL_SUCCESS, return ret);
  // 创建out aclTensor
  ret = CreateAclTensor(outHostData, outShape, &outDeviceAddr, aclDataType::ACL_FLOAT, &out);
  CHECK_RET(ret == ACL_SUCCESS, return ret);
  int64_t dim = 0;

  // 3.调用CANN算子库API,需要修改为具体的算子接口
  uint64_t workspaceSize = 0;
  aclOpExecutor* executor;
  // 调用aclnnGlu第一段接口
  ret = aclnnGluGetWorkspaceSize(self, dim, out, &workspaceSize, &executor);
  CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclnnGluGetWorkspaceSize 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aclnnGlu第二段接口
  ret = aclnnGlu(workspaceAddr, workspaceSize, executor, stream);
  CHECK_RET(ret == ACL_SUCCESS, LOG_PRINT("aclnnGlu 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侧内存上的结果拷贝至Host侧,需要根据具体API的接口定义修改
  auto size = GetShapeSize(outShape);
  std::vector<float> resultData(size, 0);
  ret = aclrtMemcpy(resultData.data(), resultData.size() * sizeof(resultData[0]), outDeviceAddr, size * sizeof(float),
                    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("result[%ld] is: %f\n", i, resultData[i]);
  }

  // 6. 释放aclTensor,需要根据具体API的接口定义修改
  aclDestroyTensor(self);
  aclDestroyTensor(out);
  return 0;
}
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