Commit bc49d32a by xuchen

Merge with liyinqiao brach and add the max/min function

parent cadda317
......@@ -71,6 +71,9 @@ void BackwardTest()
XTensor a;
XTensor b;
XTensor c;
a.enableGrad = true;
b.enableGrad = false;
c.enableGrad = false;
XTensor mean;
XTensor origin;
InitTensor2D(&a, 2, 3);
......@@ -88,14 +91,15 @@ void BackwardTest()
b.Set1D(2.0F, 0);
b.Set1D(1.0F, 1);
c = DivDim(a, b, 0);
DivDim(a, b, c, 0);
c.Dump(stderr, "c:");
auto loss = CrossEntropy(c, a);
//XLink::ShowNetwork(stderr, &c);
net.Backward(c);
net.Backward(loss);
net.Dump(stderr);
a.grad->Dump(stderr);
}
......
......@@ -26,183 +26,9 @@
*
*/
#ifdef WIN32
#include <wtypes.h>
#endif
#include <stdlib.h>
#include <stdio.h>
#include "XBLAS.h"
#include "XGlobal.h"
/* the nts (NiuTrans.Tensor) namespace */
namespace nts{
#ifdef WIN32
HINSTANCE hBLASDll;
#endif
/* single-precision floating matrix-matrix multiplication */
void (*XBLAS_SGEMM)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST enum CBLAS_TRANSPOSE, OPENBLAS_CONST enum CBLAS_TRANSPOSE,
OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST float,
OPENBLAS_CONST float *, OPENBLAS_CONST BLASINT,
OPENBLAS_CONST float *, OPENBLAS_CONST BLASINT, OPENBLAS_CONST float,
float *, OPENBLAS_CONST BLASINT);
/* double-precision floating matrix-matrix multiplication */
void (*XBLAS_DGEMM)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST enum CBLAS_TRANSPOSE, OPENBLAS_CONST enum CBLAS_TRANSPOSE,
OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST double,
OPENBLAS_CONST double *, OPENBLAS_CONST BLASINT,
OPENBLAS_CONST double *, OPENBLAS_CONST BLASINT, OPENBLAS_CONST double,
double *, OPENBLAS_CONST BLASINT);
/* single-precision floating vector-vector multiplication (rank-1) */
void (*XBLAS_SGER)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST float alpha,
OPENBLAS_CONST float *Y, OPENBLAS_CONST BLASINT, OPENBLAS_CONST float *, OPENBLAS_CONST BLASINT,
float *, OPENBLAS_CONST BLASINT);
/* double-precision floating vector-vector multiplication (rank-1) */
void (*XBLAS_DGER)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST double alpha,
OPENBLAS_CONST double *Y, OPENBLAS_CONST BLASINT, OPENBLAS_CONST double *, OPENBLAS_CONST BLASINT,
double *, OPENBLAS_CONST BLASINT);
/* set the number of threads */
void (*XBLAS_SET_THREAD_NUM)(int);
/* get the number of threads */
//int (*XBLAS_GET_THREAD_NUM)();
/* get the number of physical processors (cores).*/
int (*XBLAS_GET_CORE_NUM)();
/* get the CPU corename */
//char * (*XBLAS_GET_CORE_NAME)();
/* get the parallelization type used by OpenBLAS */
//int (*XBLAS_GET_PARALLEL_TYPE)(void);
#if defined(USE_BLAS)
/* load some stuff for BLAS */
void LoadBLAS(const char * dllFileName)
{
#ifndef CUDA_BLAS
#ifdef _WIN32
#if defined(OPENBLAS)
/* non-ascii characters are not supported yet */
wchar_t * fn = new wchar_t[strlen(dllFileName) + 1];
memset(fn, 0, sizeof(wchar_t) * (strlen(dllFileName) + 1));
for(int i = 0; i < strlen(dllFileName); i++)
fn[i] = dllFileName[i];
hBLASDll = LoadLibrary((LPCWSTR)fn);
if(!hBLASDll){
XPRINT1(0, stderr, "[LoadBLAS] Error! Cannot load dll %s!\n", dllFileName);
exit(1);
}
/* matrix-matrix multiplicatoin */
(FARPROC&)XBLAS_SGEMM = GetProcAddress(hBLASDll, "cblas_sgemm");
(FARPROC&)XBLAS_DGEMM = GetProcAddress(hBLASDll, "cblas_dgemm");
/* vector-vector multiplication */
(FARPROC&)XBLAS_SGER = GetProcAddress(hBLASDll, "cblas_sger");
(FARPROC&)XBLAS_DGER = GetProcAddress(hBLASDll, "cblas_dger");
/* multi-threading */
(FARPROC&)XBLAS_SET_THREAD_NUM = GetProcAddress(hBLASDll, "openblas_set_num_threads");
//(FARPROC&)XBLAS_SET_THREAD_NUM = GetProcAddress(hBLASDll, "goto_set_num_threads");
//(FARPROC&)XBLAS_GET_THREAD_NUM = GetProcAddress(hBLASDll, "openblas_get_num_threads");
(FARPROC&)XBLAS_GET_CORE_NUM = GetProcAddress(hBLASDll, "openblas_get_num_procs");
//(FARPROC&)XBLAS_GET_CORE_NAME = GetProcAddress(hBLASDll, "openblas_get_corename");
//(FARPROC&)XBLAS_GET_PARALLEL_TYPE = GetProcAddress(hBLASDll, "openblas_get_parallel");
delete[] fn;
#endif // defined(OPENBLAS)
#if defined(MKL)
/* non-ascii characters are not supported yet */
wchar_t * fn = new wchar_t[strlen(dllFileName) + 1];
memset(fn, 0, sizeof(wchar_t) * (strlen(dllFileName) + 1));
for(int i = 0; i < strlen(dllFileName); i++)
fn[i] = dllFileName[i];
hBLASDll = LoadLibrary((LPCWSTR)fn);
if(!hBLASDll){
XPRINT1(0, stderr, "[LoadBLAS] Error! Cannot load dll %s!\n", dllFileName);
exit(1);
}
/* matrix-matrix multiplicatoin */
(FARPROC&)XBLAS_SGEMM = GetProcAddress(hBLASDll, "cblas_sgemm");
(FARPROC&)XBLAS_DGEMM = GetProcAddress(hBLASDll, "cblas_dgemm");
/* vector-vector multiplication */
(FARPROC&)XBLAS_SGER = GetProcAddress(hBLASDll, "cblas_sger");
(FARPROC&)XBLAS_DGER = GetProcAddress(hBLASDll, "cblas_dger");
/* multi-threading */
(FARPROC&)XBLAS_SET_THREAD_NUM = GetProcAddress(hBLASDll, "MKL_Set_Num_Threads");
(FARPROC&)XBLAS_GET_CORE_NUM = GetProcAddress(hBLASDll, "MKL_Get_Max_Threads");
#endif // defined(MKL)
#else // _WIN32
XBLAS_SGEMM = &cblas_sgemm;
XBLAS_DGEMM = &cblas_dgemm;
XBLAS_SGER = &cblas_sger;
XBLAS_DGER = &cblas_dger;
#if defined(OPENBLAS)
XBLAS_SET_THREAD_NUM = &openblas_set_num_threads;
XBLAS_GET_CORE_NUM = &openblas_get_num_procs;
#endif // defined(OPENBLAS)
#if defined(MKL)
XBLAS_SET_THREAD_NUM = &mkl_set_num_threads;
XBLAS_GET_CORE_NUM = &mkl_get_max_num_threads;
#endif // defined(MKL)
#endif // _WIN32
XBLAS_SET_THREAD_NUM(1);
#endif // ndef(CUDA_BLAS)
}
/* unload the libs */
void UnloadBLAS()
{
#ifdef _WIN32
if(!FreeLibrary(hBLASDll)){
XPRINT(0, stderr, "[UnloadBLAS] Error! Cannot free the BLAS dll!\n");
exit(1);
}
#else
#endif
}
#else // undefined(USE_BLAS) || undefined(OPENBLAS)
void LoadBLAS(const char * dllFileName)
{
XPRINT(0, stderr, "[LoadBLAS] Error! No Blas lib is available. Please use OPENBLAS or MKL!\n");
exit(1);
}
void UnloadBLAS()
{
XPRINT(0, stderr, "[UnloadBLAS] Error! No Blas lib is available. Please use OPENBLAS or MKL!\n");
exit(1);
}
#endif // defined(USE_BLAS) && defined(OPENBLAS)
} /* end of the nts (NiuTrans.Tensor) namespace */
\ No newline at end of file
......@@ -34,7 +34,6 @@ namespace nts{
/* some of the code below is from OpenBLAS (https://github.com/xianyi/OpenBLAS) */
//#define OPENBLAS
#define OPENBLAS_CONST const
typedef int BLASINT;
......@@ -46,7 +45,26 @@ typedef enum CBLAS_SIDE {CblasLeft=141, CblasRight=142} CBLAS_SIDE;
#if defined(USE_BLAS)
#ifdef OPENBLAS
#define XBLAS_SGEMM cblas_sgemm
#define XBLAS_DGEMM cblas_dgemm
#define XBLAS_SGER cblas_sger
#define XBLAS_DGER cblas_dger
#define XBLAS_SAXPY cblas_saxpy
#define XBLAS_DAXPY cblas_daxpy
#define XBLAS_SET_THREAD_NUM openblas_set_num_threads
#define XBLAS_GET_CORE_NUM openblas_get_num_procs
#endif
#ifdef MKL
#define XBLAS_SGEMM cblas_sgemm
#define XBLAS_DGEMM cblas_dgemm
#define XBLAS_SGER cblas_sger
#define XBLAS_DGER cblas_dger
#define XBLAS_SAXPY cblas_saxpy
#define XBLAS_DAXPY cblas_daxpy
#define XBLAS_SET_THREAD_NUM MKL_Set_Num_Threads
#define XBLAS_GET_CORE_NUM MKL_Get_Max_Threads
#endif
/*
single/double-precision floating matrix-matrix multiplication (rank-3)
- SGEMM (ORDER, TRANSA, TRANSB, M, N, K, ALPHA, A, LDA, B, LDB, BETA, C, LDC)
......@@ -62,14 +80,14 @@ where A, B and C are matrices,
LDB(=N) specifies the size of the first dimension of B as declared in the calling (sub) program,
and LDC(=N) specifies the size of the first dimension of C as declared in the calling (sub) program.
*/
extern "C" void (*XBLAS_SGEMM)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST enum CBLAS_TRANSPOSE, OPENBLAS_CONST enum CBLAS_TRANSPOSE,
extern "C" void XBLAS_SGEMM(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST enum CBLAS_TRANSPOSE, OPENBLAS_CONST enum CBLAS_TRANSPOSE,
OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST float,
OPENBLAS_CONST float *, OPENBLAS_CONST BLASINT,
OPENBLAS_CONST float *, OPENBLAS_CONST BLASINT, OPENBLAS_CONST float,
float *, OPENBLAS_CONST BLASINT);
/* double-precision floating matrix-matrix multiplication */
extern "C" void (*XBLAS_DGEMM)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST enum CBLAS_TRANSPOSE, OPENBLAS_CONST enum CBLAS_TRANSPOSE,
extern "C" void XBLAS_DGEMM(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST enum CBLAS_TRANSPOSE, OPENBLAS_CONST enum CBLAS_TRANSPOSE,
OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST BLASINT, OPENBLAS_CONST double,
OPENBLAS_CONST double *, OPENBLAS_CONST BLASINT,
OPENBLAS_CONST double *, OPENBLAS_CONST BLASINT, OPENBLAS_CONST double,
......@@ -88,24 +106,33 @@ where X and Y are vectors with m and n elements respectively,
E.g., if we are using CblasRowMajor, the leading dimension is the number of columns of A.
*/
extern "C" void (*XBLAS_SGER)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST float alpha,
extern "C" void XBLAS_SGER(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST float alpha,
OPENBLAS_CONST float *Y, OPENBLAS_CONST BLASINT, OPENBLAS_CONST float *, OPENBLAS_CONST BLASINT,
float *, OPENBLAS_CONST BLASINT);
/* double-precision floating vector-vector multiplication (rank-1) */
extern "C" void (*XBLAS_DGER)(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST double alpha,
extern "C" void XBLAS_DGER(OPENBLAS_CONST enum CBLAS_ORDER, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST double alpha,
OPENBLAS_CONST double *Y, OPENBLAS_CONST BLASINT, OPENBLAS_CONST double *, OPENBLAS_CONST BLASINT,
double *, OPENBLAS_CONST BLASINT);
/*
some description
*/
extern "C" void XBLAS_SAXPY(OPENBLAS_CONST BLASINT n, OPENBLAS_CONST float a, OPENBLAS_CONST float *x, OPENBLAS_CONST BLASINT incx, OPENBLAS_CONST float *y, OPENBLAS_CONST BLASINT incy);
/* double-precision floating sumMe function */
extern "C" void XBLAS_DAXPY(OPENBLAS_CONST BLASINT n, OPENBLAS_CONST double a, OPENBLAS_CONST double *x, OPENBLAS_CONST BLASINT incx, OPENBLAS_CONST double *y, OPENBLAS_CONST BLASINT incy);
/* set the number of threads */
extern "C" void (*XBLAS_SET_THREAD_NUM)(int);
extern "C" void XBLAS_SET_THREAD_NUM(int);
/* get the number of threads */
//extern "C" int (*XBLAS_GET_THREAD_NUM)();
/* get the number of physical processors (cores).*/
extern "C" int (*XBLAS_GET_CORE_NUM)();
extern "C" int XBLAS_GET_CORE_NUM();
/* get the CPU corename */
//extern "C" char * (*XBLAS_GET_CORE_NAME)();
......@@ -113,58 +140,6 @@ extern "C" int (*XBLAS_GET_CORE_NUM)();
/* get the parallelization type used by OpenBLAS */
//extern "C" int (*XBLAS_GET_PARALLEL_TYPE)(void);
/* linux systems */
#ifndef _WIN32
/* cblas functions that are imported from the lib. See cblas.h in OpenBlas for more information */
extern "C" void cblas_sgemm(OPENBLAS_CONST enum CBLAS_ORDER Order, OPENBLAS_CONST enum CBLAS_TRANSPOSE TransA, OPENBLAS_CONST enum CBLAS_TRANSPOSE TransB,
OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST BLASINT K, OPENBLAS_CONST float alpha,
OPENBLAS_CONST float *A, OPENBLAS_CONST BLASINT lda,
OPENBLAS_CONST float *B, OPENBLAS_CONST BLASINT ldb,
OPENBLAS_CONST float beta, float *C, OPENBLAS_CONST BLASINT ldc);
extern "C" void cblas_dgemm(OPENBLAS_CONST enum CBLAS_ORDER Order, OPENBLAS_CONST enum CBLAS_TRANSPOSE TransA, OPENBLAS_CONST enum CBLAS_TRANSPOSE TransB,
OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST BLASINT K, OPENBLAS_CONST double alpha,
OPENBLAS_CONST double *A, OPENBLAS_CONST BLASINT lda,
OPENBLAS_CONST double *B, OPENBLAS_CONST BLASINT ldb,
OPENBLAS_CONST double beta, double *C, OPENBLAS_CONST BLASINT ldc);
extern "C" void cblas_sger (OPENBLAS_CONST enum CBLAS_ORDER order, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST float alpha,
OPENBLAS_CONST float *X, OPENBLAS_CONST BLASINT incX, OPENBLAS_CONST float *Y, OPENBLAS_CONST BLASINT incY,
float *A, OPENBLAS_CONST BLASINT lda);
extern "C" void cblas_dger (OPENBLAS_CONST enum CBLAS_ORDER order, OPENBLAS_CONST BLASINT M, OPENBLAS_CONST BLASINT N, OPENBLAS_CONST double alpha,
OPENBLAS_CONST double *X, OPENBLAS_CONST BLASINT incX, OPENBLAS_CONST double *Y, OPENBLAS_CONST BLASINT incY,
double *A, OPENBLAS_CONST BLASINT lda);
#if defined(OPENBLAS)
/* better control of multi-threading */
extern "C" void openblas_set_num_threads(int num_threads);
extern "C" void goto_set_num_threads(int num_threads);
//extern "C" int openblas_get_num_threads(void);
extern "C" int openblas_get_num_procs(void);
//extern "C" char* openblas_get_config(void);
//extern "C" char* openblas_get_corename(void);
//extern "C" int openblas_get_parallel(void);
#endif
#endif
#if defined(MKL)
/* better control of multi-threading */
//_Mkl_Api(void,MKL_Set_Num_Threads,(int nth))
//_Mkl_Api(int,MKL_Get_Max_Threads,(void))
extern "C" void MKL_Set_Num_Threads(int num_threads);
extern "C" int MKL_Get_Max_Threads();
#define mkl_set_num_threads MKL_Set_Num_Threads
#define mkl_get_max_num_threads MKL_Get_Max_Threads
//extern "C" void mkl_set_num_threads(int num_threads);
//extern "C" void omp_set_num_threads(int num_threads);
//extern "C" int mkl_get_max_num_threads();
#endif
#if defined(CUDA_BLAS)
......@@ -186,24 +161,8 @@ extern void BLASMatrixMULD(int deviceID, double * a, double * b, double * c, int
#endif
#endif
#ifdef _WIN32
#include "windows.h"
extern HINSTANCE hBLASDll;
#else
#endif
/* load some stuff for BLAS */
extern void LoadBLAS(const char * dllFileName);
/* unload the libs */
extern void UnloadBLAS();
} /* end of the nts (NiuTrans.Tensor) namespace */
#endif
......@@ -160,8 +160,10 @@ extern bool useCUDA;
/* BLAS interfaces */
#ifdef DOUBELPRICSION
#define GEMM XBLAS_DGEMM
#define AXPY XBLAS_DAXPY
#else
#define GEMM XBLAS_SGEMM
#define AXPY XBLAS_SAXPY
#endif
extern void InitGlobalAll();
......
......@@ -300,6 +300,9 @@ void XLink::MakeLink(const XTensor * t1, const XTensor * t2, XTensor * h, int id
if(h == NULL)
return;
if (!t1->enableGrad)
return;
TensorList list(2);
list.Add((XTensor*)t1);
list.Add((XTensor*)t2);
......@@ -320,6 +323,9 @@ void XLink::MakeLink(const XTensor * t1, const XTensor * t2, const XTensor * t3,
if (h == NULL)
return;
if (!t1->enableGrad || !t2->enableGrad)
return;
TensorList list(3);
list.Add((XTensor*)t1);
list.Add((XTensor*)t2);
......@@ -370,6 +376,9 @@ create a hyper edge with a input tensors and a list of output tensors
*/
void XLink::MakeLink(XTensor * t, TensorList * list, int id)
{
if (!t->enableGrad)
return;
/* forward */
for(int i = 0; i < list->count; i++){
XTensor * h = (XTensor*)list->GetItem(i);
......
......@@ -23,15 +23,11 @@
*
*/
#include "XList.h"
#include "time.h"
#include "XMem.h"
#include "XList.h"
#include "XGlobal.h"
#include <ctime>
#include <utility>
#include <algorithm>
/* the nts (NiuTrans.Tensor) namespace */
namespace nts {
......@@ -78,6 +74,7 @@ TensorListBase<T>::TensorListBase(int myMaxNum, XMem* myMem)
template <typename T>
TensorListBase<T>::~TensorListBase()
{
if(items && mem)
delete[] items;
}
......@@ -101,7 +98,13 @@ void TensorListBase<T>::Add(T&& item)
maxNum = maxNum * 2 + 1;
}
items[count++] = item;
}
/* return number of elements */
template<typename T>
size_t TensorListBase<T>::Size()
{
return count;
}
/*
......@@ -131,7 +134,7 @@ add a number of items into the list
>> inputItemCount - number of input items
*/
template <typename T>
void TensorListBase<T>::Add(T* inputItems, int inputItemCount)
void TensorListBase<T>::Add(const T* inputItems, int inputItemCount)
{
if (count + inputItemCount >= maxNum) {
int newMaxNum = (count + inputItemCount) * 2 + 1;
......@@ -207,10 +210,10 @@ void TensorListBase<T>::Insert(int pos, T&& item)
template <typename T>
T& TensorListBase<T>::GetItem(int i) const
{
CheckNTErrors(i >= -1 && i < count, "Index of a list item is out of scope!");
CheckNTErrors(i >= -count && i < count, "Index of a list item is out of scope!");
CheckNTErrors(count > 0, "Cannt index the item in an empty list!");
if (i == -1)
return items[count - 1];
if (i < 0)
return items[count + i];
else
return items[i];
}
......@@ -227,7 +230,7 @@ template<typename T>
inline void TensorListBase<T>::SetItem(int i, T&& item)
{
if (i >= 0 && i < count)
items[i] = std::move(item);
items[i] = item;
}
/*
......@@ -246,6 +249,26 @@ inline int TensorListBase<T>::FindFirst(const T& item)
return -1;
}
template <>
inline int TensorListBase<Example>::FindFirst(const Example& item)
{
for (int i = 0; i < count; i++) {
if (item.id == items[i].id)
return i;
}
return -1;
}
template <>
inline int TensorListBase<Result>::FindFirst(const Result& item)
{
for (int i = 0; i < count; i++) {
if (item.id == items[i].id)
return i;
}
return -1;
}
/* clear the data array */
template <typename T>
void TensorListBase<T>::Clear()
......@@ -295,6 +318,17 @@ void TensorListBase<T>::Remove(int i)
count--;
}
template<typename T>
void TensorListBase<T>::Reserve(int n)
{
if (items) {
/* reserve failed */
return;
}
items = new T[n];
}
/*
copy the list
>> myMem - memory pool used for allocating the data in the new list
......@@ -349,6 +383,8 @@ template struct TensorListBase<long>;
template struct TensorListBase<float>;
template struct TensorListBase<short>;
template struct TensorListBase<XTensor*>;
template struct TensorListBase<Result>;
template struct TensorListBase<Example>;
template struct TensorListBase<void*>;
} /* end of the nts (NiuTrans.Tensor) namespace */
\ No newline at end of file
......@@ -66,11 +66,14 @@ public:
/* add an item into the list */
void Add(T&& item);
/* return number of elements */
size_t Size();
/* add an item into the list */
void Add(const T& item);
/* add a number of items into the list */
void Add(T* inputItems, int inputItemCount);
void Add(const T* inputItems, int inputItemCount);
/* append a list to the current list */
void AddList(TensorListBase* l);
......@@ -105,6 +108,9 @@ public:
/* remove the item at position i */
void Remove(int i);
/* reserve space for data entry */
void Reserve(int n);
/* copy the list */
TensorListBase* Copy(XMem* myMem);
......@@ -112,22 +118,33 @@ public:
void Shuffle(int nround = 10, int beg = -1, int len = 0);
/* short */
T& operator[] (int i) {
return GetItem(i);
};
T& operator[] (int i) { return GetItem(i); };
T& Get(int i) { return GetItem(i); };
void Set(int i, T item) { SetItem(i, item); };
};
struct XTensor;
typedef TensorListBase<void*> XList;
typedef TensorListBase<int> IntList;
typedef TensorListBase<char> CharList;
typedef TensorListBase<char*> StrList;
typedef TensorListBase<long> LongList;
typedef TensorListBase<float> FloatList;
typedef TensorListBase<short> ShortList;
typedef TensorListBase<void*> XList;
struct Example {
int id;
IntList data;
};
struct Result {
int id;
IntList data;
};
typedef TensorListBase<Result> ResultList;
typedef TensorListBase<Example> ExampleList;
typedef TensorListBase<XTensor*> TensorList;
} /* end of the nts (NiuTrans.Tensor) namespace */
......
......@@ -51,7 +51,9 @@ namespace nts { // namespace nts(NiuTrans.Tensor)
#define MATH_MASK MATH_DIVDIM + 1
#define MATH_MATRIXMUL MATH_MASK + 1
#define MATH_MATRIXMULBATCHED MATH_MATRIXMUL + 1
#define MATH_MULTIPLY MATH_MATRIXMULBATCHED + 1
#define MATH_MAX MATH_MATRIXMULBATCHED + 1
#define MATH_MIN MATH_MAX + 1
#define MATH_MULTIPLY MATH_MIN + 1
#define MATH_MULTIPLYDIM MATH_MULTIPLY + 1
#define MATH_MULTIPLYBROADCAST MATH_MULTIPLYDIM + 1
#define MATH_NEGATE MATH_MULTIPLYBROADCAST + 1
......
......@@ -280,7 +280,7 @@ void XTensor::Init()
isTmp = false;
isGrad = false;
isVar = false;
enableGrad = false;
enableGrad = true;
visitMark = 0;
grad = NULL;
}
......@@ -397,7 +397,7 @@ XTensor& XTensor::operator= (const XTensor& tensor)
CheckNTErrors(outgo.tailNum == 0, "The node has outgoing edge to other nodes!");
/* create tensor links for the new tensor */
XLink::Replace(&tensor, this);
XLink::Copy(&tensor, this);
}
return *this;
......@@ -445,7 +445,7 @@ XTensor& XTensor::operator= (const XTensor&& tensor)
This is VERY tricky and there might be better solutions :) */
*tensor.dataP = NULL;
XLink::Replace(&tensor, this);
XLink::Copy(&tensor, this);
return *this;
}
......@@ -720,7 +720,7 @@ int XTensor::GetSize() const
}
/* get the size of the memory space used */
int XTensor::GetDataSizeInChar()
int XTensor::GetDataSizeInChar() const
{
if(isSparse){
int num = int(unitNum * denseRatio + 1);
......@@ -738,7 +738,7 @@ get unit size in terms of "dataType"
>> myDataType - type of unit
<< return - unit size
*/
int XTensor::GetUnitSize(TENSOR_DATA_TYPE myDataType)
int XTensor::GetUnitSize(TENSOR_DATA_TYPE myDataType) const
{
if(myDataType == X_INT)
return sizeof(int);
......@@ -758,7 +758,7 @@ get offset (2D)
>> row - index of demension 0
>> col - index of demension 1
*/
MTYPE XTensor::GetOffset2D(int row, int col)
MTYPE XTensor::GetOffset2D(int row, int col) const
{
CheckNTErrors(order == 2, "Cannot get a 2d cell for a tensor whose order is not 2!");
CheckNTErrors(row >= 0 && row < dimSize[0], "dimension 0 is out of range!");
......@@ -773,7 +773,7 @@ get offset (3D)
>> d1 - index of demension 1
>> d2 - index of demension 2
*/
MTYPE XTensor::GetOffset3D(int d0, int d1, int d2)
MTYPE XTensor::GetOffset3D(int d0, int d1, int d2) const
{
CheckNTErrors(order == 3, "Cannot get a 3d cell for a tensor whose order is not 2!");
CheckNTErrors(d0 >= 0 && d0 < dimSize[0], "dimension 0 is out of range!");
......@@ -856,6 +856,16 @@ void XTensor::Rand(int rNum, int cNum)
_SetDataRand(this, rNum, cNum);
}
/* generate data items with a range by start, end and the step
>> start - the begin of the array
>> end - the end of the array (not included self)
>> step - the step of two items
*/
void XTensor::Range(DTYPE lower, DTYPE upper, DTYPE step)
{
_SetDataRange(this, lower, upper, step);
}
/*
set the tensor items by a uniform distribution in range [lower, upper]
>> lower - lower value of the range
......@@ -929,9 +939,11 @@ set the tensor items by a normal distribution
void XTensor::SetDataRandn(DTYPE mean, DTYPE standardDeviation)
{
// TODO: cuda code!!!!!!!
if (data == NULL)
return;
// srand((unsigned)time(0));
void * d = NULL;
if (dataType == X_FLOAT) {
d = new float[unitNum];
......@@ -986,7 +998,7 @@ void XTensor::SetDataBatchedWithValues(MTYPE * offsets, void * values, int num)
>> num - number of data items
>> beg - where we start this in the data array of the tensor
*/
bool XTensor::CheckData(const void * d, int num, int beg)
bool XTensor::CheckData(const void * d, int num, int beg) const
{
if (data == NULL || d == NULL)
return false;
......@@ -1030,7 +1042,7 @@ bool IsFloatEqual(DTYPE a, DTYPE b, float absError, float relError)
}
/* check whether the data array is the same as the "answer" */
bool XTensor::CheckData(const void * d, int num, float tolerance, int beg)
bool XTensor::CheckData(const void * d, int num, float tolerance, int beg) const
{
if (data == NULL || d == NULL)
return false;
......@@ -1106,7 +1118,7 @@ get the value of a cell with the index
>> size - size of the index
<< return - cell value
*/
DTYPE XTensor::Get(int index[], int size)
DTYPE XTensor::Get(int index[], int size) const
{
CheckNTErrors(dataType == DEFAULT_DTYPE, "The tensor is not in the default type.");
......@@ -1118,7 +1130,7 @@ get the value of a cell with its offset
>> offset - offset in the array
<< return - cell value
*/
DTYPE XTensor::Get(int offset)
DTYPE XTensor::Get(int offset) const
{
CheckNTErrors(dataType == DEFAULT_DTYPE, "The tensor is not in the default type.");
CheckNTErrors(offset >= 0 && offset < unitNum, "Invalid index!");
......@@ -1170,7 +1182,7 @@ get the value of a cell in a 1d tensor in default type
>> i - idex
<< return - value of cell(i) in float
*/
DTYPE XTensor::Get1D(int i)
DTYPE XTensor::Get1D(int i) const
{
CheckNTErrors((order == 1), "Cannot get a 2d cell for a tensor whose order is not 2!");
CheckNTErrors((i >= 0 && i < dimSize[0]), "dimension 0 is out of range!");
......@@ -1207,7 +1219,7 @@ get the value of a cell in a 3d tensor
>> d1 - index of dimension 1
>> d2 - index of dimension 2
*/
DTYPE XTensor::Get3D(int d0, int d1, int d2)
DTYPE XTensor::Get3D(int d0, int d1, int d2) const
{
CheckNTErrors((order == 3), "Cannot get a 2d cell for a tensor whose order is not 2!");
CheckNTErrors((d0 >= 0 && d0 < dimSize[0]), "dimension 0 is out of range!");
......@@ -1225,7 +1237,7 @@ DTYPE XTensor::Get3D(int d0, int d1, int d2)
get the int value of a cell by its offset
>> offset - offset of the item
*/
int XTensor::GetInt(int offset)
int XTensor::GetInt(int offset) const
{
CheckNTErrors(dataType == X_INT, "The tensor is not in the integer type.");
CheckNTErrors(offset >= 0 && offset < unitNum, "Invalid index!");
......@@ -1242,7 +1254,7 @@ get the value of a cell in a 1d tensor in int type
>> i - index
<< return - value of cell(i) in int
*/
int XTensor::Get1DInt(int i)
int XTensor::Get1DInt(int i) const
{
CheckNTErrors(order == 1, "Cannot get a 2d cell for a tensor whose order is not 2!");
CheckNTErrors(i >= 0 && i < dimSize[0], "dimension 0 is out of range!");
......@@ -1260,7 +1272,7 @@ get the value of a cell in a 2d tensor in int type
>> mi - column index
<< return - value of cell(ni, mi) in int
*/
int XTensor::Get2DInt(int ni, int mi)
int XTensor::Get2DInt(int ni, int mi) const
{
CheckNTErrors(order == 2, "Cannot get a 2d cell for a tensor whose order is not 2!");
CheckNTErrors(ni >= 0 && ni < dimSize[0], "dimension 0 is out of range!");
......@@ -1280,7 +1292,7 @@ get the value of a cell in a 3d tensor in int type
>> d2 - index of dimension 2
<< return - value of cell(d0, d1, d2) in int
*/
int XTensor::Get3DInt(int d0, int d1, int d2)
int XTensor::Get3DInt(int d0, int d1, int d2) const
{
CheckNTErrors(order == 3, "Cannot get a 2d cell for a tensor whose order is not 2!");
CheckNTErrors(d0 >= 0 && d0 < dimSize[0], "dimension 0 is out of range!");
......@@ -1299,7 +1311,7 @@ get the value of a cell in the sparse tensor
>> i - i-th tuple in the tuple list of the sparse tensor
<< return - value of the tuple
*/
DTYPE XTensor::GetInSparse(int i)
DTYPE XTensor::GetInSparse(int i) const
{
CheckNTErrors(i >= 0 && i < unitNum, "Index is out of range!");
CheckNTErrors(dataType == DEFAULT_DTYPE, "The tensor is not in default type.");
......@@ -1315,7 +1327,7 @@ get the key value of a tuple in a sparse tensor
>> i - i-th tuple in the tuple list of the sparse tensor
<< return - key of the tuple
*/
int XTensor::GetKeyInSparse(int i)
int XTensor::GetKeyInSparse(int i) const
{
CheckNTErrors(i >= 0 && i < unitNum, "Index is out of range!");
CheckNTErrors(dataType == DEFAULT_DTYPE, "The tensor is not in default type.");
......@@ -1528,7 +1540,7 @@ increase the value of a cell in a 2d tensor
}
/* get the number of non-zero elements (in a sparse tensor) */
int XTensor::GetNonzeroSize()
int XTensor::GetNonzeroSize() const
{
if(!isSparse){
XPRINT(1, stderr, "WARNING! Counting non-zero elements in a dense tensor might be slow!\n");
......@@ -1893,148 +1905,6 @@ void XTensor::Dump(FILE * file, const char * label, const int n, const int beg,
}
}
void * RecursionData(XTensor * s, int dim, int * index, void * d, FILE * file)
{
if (dim == s->order - 2) {
/* print index */
printf("Index: ");
for (int i = 0; i < s->order-2; i++)
printf("[%d]", index[i]);
int dimSize1 = s->dimSize[dim];
int dimSize2 = s->dimSize[dim+1];
printf(" %d * %d\n", dimSize1, dimSize2);
/* print 2D data */
if (s->dataType == X_FLOAT) {
float * data = (float*)d;
for (int i = 0; i < dimSize1; i++) {
printf("\t");
for (int j = 0; j < dimSize2; j++)
fprintf(file, "%e ", *data++);
fprintf(file, "\n");
}
d = (float*)d + dimSize1 *dimSize2;
}
else if (s->dataType == X_INT) {
int * data = (int*)d;
for (int i = 0; i < dimSize1; i++) {
printf("\t");
for (int j = 0; j < dimSize2; j++)
fprintf(file, "%d ", *data++);
fprintf(file, "\n");
}
d = (int*)d + dimSize1 *dimSize2;
}
else
ShowNTErrors("TODO!");
return d;
}
/* recursion for deeper dimsion */
int levelSize = s->dimSize[dim];
for (int k = 0; k < levelSize; k++) {
index[dim] = k;
d = RecursionData(s, dim+1, index, d, file);
}
return d;
}
/*
dump data to a file
>> file - where to domp the data
>> label - label of the tensor
>> n - number of items to dump
>> beg - the first item id
>> verbose - verbose level
*/
void XTensor::DumpFormat(FILE * file, const char * label, const int n, const int beg, const int verbose)
{
if (verbose > verboseLevel)
return;
void * d = data;
bool isNewData = false;
#ifdef USE_CUDA
if (devID >= 0) {
CudaGPUToCPUFlush(this);
d = dataHost;
isNewData = true;
}
#endif
if (d == NULL) {
if (isSparse) {
int num = 0;
for (int i = 0; i < order; i++)
num *= dimSizeRDI[i];
num = int(num * denseRatio + 1);
int tupleSize = sizeof(int) + sizeof(DTYPE);
int size = sizeof(int) + tupleSize*(num);
d = new char[size];
memset(d, 0, size);
}
else {
d = new char[unitNum * unitSize];
memset(d, 0, unitNum * unitSize);
}
isNewData = true;
}
if (label != NULL)
fprintf(file, "%s ", label);
if(isInit){
fprintf(file, "id=%d ", id);
fprintf(file, "order=%d dimsize=", order);
for (int i = 0; i < order; i++) {
fprintf(file, "%d", dimSize[i]);
if (i < order - 1)
fprintf(file, ",");
}
}
else{
fprintf(file, "order=-1 dimsize=-1");
}
fprintf(file, " dtype=%s dense=%f\n", GetDataTypeName(dataType), denseRatio);
if(!isInit){
fprintf(file, "NULL");
}
if (order == 1) {
for (int i = 0; i < unitNum; i++) {
if (dataType == X_FLOAT)
fprintf(file, "%e ", ((float*)d)[i]);
else if (dataType == X_INT)
fprintf(file, "%d ", ((int*)d)[i]);
else
ShowNTErrors("TODO!");
}
printf("\n");
}
/* print multi-dimensional tensor */
else {
int * index = new int[order];
RecursionData(this, 0, index, d, file);
delete[] index;
}
fprintf(file, "\n");
if (isNewData) {
delete[](char*)d;
#ifdef USE_CUDA
if (devID >= 0)
dataHost = NULL;
#endif
}
}
/*
dump data to a file
>> tensor - the tensor for dumping
......@@ -2052,6 +1922,26 @@ void XTensor::Dump(const XTensor * tensor, FILE * file, const char * label, cons
}
/*
dump data to a binary file
>> file - where to dump the data
*/
void XTensor::BinaryDump(FILE* file)
{
XTensor tmp;
InitTensorOnCPU(&tmp, this);
_CopyValues(this, &tmp);
switch (dataType) {
case X_INT: {
fwrite(tmp.data, sizeof(int), unitNum, file);
}
default: {
fwrite(tmp.data, sizeof(float), unitNum, file);
}
}
}
/*
read data from a file
>> file - where to load the data
>> label - label of the tensor
......@@ -2164,6 +2054,30 @@ void XTensor::Read(FILE * file, const char * label)
}
/*
read data from a binary file
>>> file - the file stream pointer
>>> offset - the distance from the start to this tensor
*/
void XTensor::BinaryRead(FILE* file, size_t offset)
{
fseek(file, offset, 0);
switch (dataType) {
case X_INT: {
int * d = new int[unitNum];
fread(d, sizeof(int), unitNum, file);
SetData(d, unitNum);
delete[] d;
}
default: {
float * d = new float[unitNum];
fread(d, sizeof(float), unitNum, file);
SetData(d, unitNum);
delete[] d;
}
}
}
/*
flush the data to the target device
>> targetMem - memory pool on the target device
*/
......@@ -2327,7 +2241,7 @@ initialize a dense tensor V2
void InitTensorV2(XTensor * tensor,
const int myOrder, const int * myDimSize, const TENSOR_DATA_TYPE myDataType,
const int myDevID)
const int myDevID, const bool isEnableGrad)
{
if (tensor->mem == NULL) {
XMem * myMem = GMems.GetMem(myDevID);
......@@ -2359,6 +2273,7 @@ void InitTensorV2(XTensor * tensor,
if(allocated)
XTensor::AllocateData(tensor);
}
tensor->enableGrad = isEnableGrad;
}
/*
......@@ -2392,12 +2307,12 @@ initialize a dense tensor V2
*/
void InitTensor1DV2(XTensor * tensor, const int num,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[1];
dims[0] = num;
InitTensorV2(tensor, 1, dims, myDataType, myDevID);
InitTensorV2(tensor, 1, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2434,13 +2349,13 @@ initialize a dense matrix V2
*/
void InitTensor2DV2(XTensor * tensor, const int rowNum, const int colNum,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[2];
dims[0] = rowNum;
dims[1] = colNum;
InitTensorV2(tensor, 2, dims, myDataType, myDevID);
InitTensorV2(tensor, 2, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2480,14 +2395,14 @@ initialize a dense 3d tensor V2
*/
void InitTensor3DV2(XTensor * tensor, const int d0, const int d1, const int d2,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[3];
dims[0] = d0;
dims[1] = d1;
dims[2] = d2;
InitTensorV2(tensor, 3, dims, myDataType, myDevID);
InitTensorV2(tensor, 3, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2530,7 +2445,7 @@ initialize a dense 4d tensor V2
*/
void InitTensor4DV2(XTensor * tensor, const int d0, const int d1, const int d2, const int d3,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[4];
dims[0] = d0;
......@@ -2538,7 +2453,7 @@ void InitTensor4DV2(XTensor * tensor, const int d0, const int d1, const int d2,
dims[2] = d2;
dims[3] = d3;
InitTensorV2(tensor, 4, dims, myDataType, myDevID);
InitTensorV2(tensor, 4, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2584,7 +2499,7 @@ initialize a dense 5d tensor V2
*/
void InitTensor5DV2(XTensor * tensor, const int d0, const int d1, const int d2, const int d3, const int d4,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[5];
dims[0] = d0;
......@@ -2593,7 +2508,7 @@ void InitTensor5DV2(XTensor * tensor, const int d0, const int d1, const int d2,
dims[3] = d3;
dims[4] = d4;
InitTensorV2(tensor, 5, dims, myDataType, myDevID);
InitTensorV2(tensor, 5, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2685,10 +2600,12 @@ generate a dense XTensor V2
*/
XTensor * NewTensorV2(const int myOrder, const int * myDimSize, const TENSOR_DATA_TYPE myDataType,
const int myDevID)
const int myDevID, const bool isEnableGrad)
{
XMem * myMem = GMems.GetMem(myDevID);
return new XTensor(myOrder, myDimSize, myDataType, 1.0F, myDevID, myMem);
XTensor * tensor = new XTensor(myOrder, myDimSize, myDataType, 1.0F, myDevID, myMem);
tensor->enableGrad = isEnableGrad;
return tensor;
}
/*
......@@ -2714,6 +2631,9 @@ XTensor * NewTensorBuf(const int myOrder, const int * myDimSize,
XTensor * tensor = NewTensor(myOrder, dims, myDataType, myDenseRatio, devID, myMem);
if (tensor->unitNum * tensor->unitSize == 176657664) {
tensor->Dump(stderr, "", 200);
}
if(myMem != NULL)
tensor->data = myMem->AllocBuf(myMem->devID, tensor->unitNum * tensor->unitSize);
else
......@@ -2732,14 +2652,14 @@ generate a dense XTensor which allocates data on the buffer V2
*/
XTensor * NewTensorBufV2(const int myOrder, const int * myDimSize,
const TENSOR_DATA_TYPE myDataType, const int devID)
const TENSOR_DATA_TYPE myDataType, const int devID, const bool isEnableGrad)
{
int dims[MAX_TENSOR_DIM_NUM];
memcpy(dims, myDimSize, sizeof(int) * myOrder);
dims[0] = -abs(dims[0]);
XTensor * tensor = NewTensorV2(myOrder, dims, myDataType, devID);
XTensor * tensor = NewTensorV2(myOrder, dims, myDataType, devID, isEnableGrad);
if (tensor->unitNum * tensor->unitSize == 176657664) {
tensor->Dump(stderr, "", 200);
......@@ -2771,10 +2691,10 @@ generate a XTensor which allocates data on the buffer V2
>> reference - reference tensor
>> devID - device id
*/
XTensor * NewTensorBufV2(const XTensor * reference, int devID)
XTensor * NewTensorBufV2(const XTensor * reference, int devID, const bool isEnableGrad)
{
return NewTensorBufV2(reference->order, reference->dimSize,
reference->dataType, devID);
reference->dataType, devID, isEnableGrad);
}
/*
......@@ -2806,12 +2726,12 @@ generate a dense vector V2
*/
XTensor * NewTensor1DV2(const int num,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[1];
dims[0] = num;
return NewTensorV2(1, dims, myDataType, myDevID);
return NewTensorV2(1, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2846,13 +2766,13 @@ generate a dense matrix V2
*/
XTensor * NewTensor2DV2(const int rowNum, const int colNum,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[2];
dims[0] = rowNum;
dims[1] = colNum;
return NewTensorV2(2, dims, myDataType, myDevID);
return NewTensorV2(2, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2890,14 +2810,14 @@ generate a dense 3d tensor V2
*/
XTensor * NewTensor3DV2(const int d0, const int d1, const int d2,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[3];
dims[0] = d0;
dims[1] = d1;
dims[2] = d2;
return NewTensorV2(3, dims, myDataType, myDevID);
return NewTensorV2(3, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2938,7 +2858,7 @@ generate a dense 4d tensor V2
*/
XTensor * NewTensor4DV2(const int d0, const int d1, const int d2, const int d3,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[4];
dims[0] = d0;
......@@ -2946,7 +2866,7 @@ XTensor * NewTensor4DV2(const int d0, const int d1, const int d2, const int d3,
dims[2] = d2;
dims[3] = d3;
return NewTensorV2(4, dims, myDataType, myDevID);
return NewTensorV2(4, dims, myDataType, myDevID, isEnableGrad);
}
/*
......@@ -2990,7 +2910,7 @@ generate a dense 5d tensor V2
*/
XTensor * NewTensor5DV2(const int d0, const int d1, const int d2, const int d3, const int d4,
const TENSOR_DATA_TYPE myDataType, const int myDevID)
const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int dims[5];
dims[0] = d0;
......@@ -2999,7 +2919,17 @@ XTensor * NewTensor5DV2(const int d0, const int d1, const int d2, const int d3,
dims[3] = d3;
dims[4] = d4;
return NewTensorV2(5, dims, myDataType, myDevID);
return NewTensorV2(5, dims, myDataType, myDevID, isEnableGrad);
}
XTensor * NewTensorRange(int lower, int upper, int step, const TENSOR_DATA_TYPE myDataType, const int myDevID, const bool isEnableGrad)
{
int size = abs(upper - lower);
int unitNum = ceil(1.0 * size / abs(step));
XTensor * tensor = NewTensor1DV2(unitNum, myDataType, myDevID, isEnableGrad);
tensor->Range(lower, upper, step);
return tensor;
}
/*
......
......@@ -290,16 +290,16 @@ public:
int GetSize() const;
/* get size of the memory used */
int GetDataSizeInChar();
int GetDataSizeInChar() const;
/* get unit size in terms of "dataType" */
int GetUnitSize(TENSOR_DATA_TYPE myDataType);
int GetUnitSize(TENSOR_DATA_TYPE myDataType) const;
/* get offset (2D) */
MTYPE GetOffset2D(int row, int col);
MTYPE GetOffset2D(int row, int col) const;
/* get offset (3D) */
MTYPE GetOffset3D(int d0, int d1, int d2);
MTYPE GetOffset3D(int d0, int d1, int d2) const;
/* a tensor with all entries of 0 */
void SetZeroAll(XStream * stream = NULL);
......@@ -310,6 +310,9 @@ public:
/* generate data items with a uniform distribution in [0, 1] */
void Rand(int rNum, int cNum);
/* generate data items with a range by start, end and the step */
void Range(DTYPE lower, DTYPE upper, DTYPE step);
/* set tensor items by a uniform distribution */
void SetDataRand(DTYPE lower = 0.0F, DTYPE upper = 1.0F);
......@@ -323,10 +326,10 @@ public:
void SetDataBatchedWithValues(MTYPE * offsets, void * values, int num);
/* check whether the data array is the same as the answer */
bool CheckData(const void * answer, int num, int beg = 0);
bool CheckData(const void * answer, int num, int beg = 0) const;
/* check whether the data array is the same as the answer */
bool CheckData(const void * answer, int num, float tolerance, int beg = 0);
bool CheckData(const void * answer, int num, float tolerance, int beg = 0) const;
/* set the pointer to "data" */
void SetDataPointer();
......@@ -335,40 +338,40 @@ public:
void SetAscendingOrder(int dim);
/* get the value of a cell with the index */
DTYPE Get(int index[], int size = -1);
DTYPE Get(int index[], int size = -1) const;
/* get the value of a cell with the offset */
DTYPE Get(int offset);
DTYPE Get(int offset) const;
/* get the pointer to a cell */
void * GetCell(int index[], int size = -1) const;
/* get the default type value of a cell in a 1d tensor */
DTYPE Get1D(int i);
DTYPE Get1D(int i) const;
/* get the default type value of a cell in a 2d tensor */
DTYPE Get2D(int ni, int mi) const;
/* get the default type value of a cell in a 3d tensor */
DTYPE Get3D(int d0, int d1, int d2);
DTYPE Get3D(int d0, int d1, int d2) const;
/* get the int value of a cell by its offset */
int GetInt(int offset);
int GetInt(int offset) const;
/* get the int value of a cell in a 1d tensor */
int Get1DInt(int i);
int Get1DInt(int i) const;
/* get the int value of a cell in a 2d tensor */
int Get2DInt(int ni, int mi);
int Get2DInt(int ni, int mi) const;
/* get the int value of a cell in a 3d tensor */
int Get3DInt(int d0, int d1, int d2);
int Get3DInt(int d0, int d1, int d2) const;
/* get the value of a cell in a sparse tensor */
DTYPE GetInSparse(int i);
DTYPE GetInSparse(int i) const;
/* get the key value of a tuple in a sparse tensor */
int GetKeyInSparse(int i);
int GetKeyInSparse(int i) const;
/* set the value of a cell */
bool Set(DTYPE value, int index[], int size = -1);
......@@ -404,7 +407,7 @@ public:
bool Add2D(DTYPE value, int ni, int mi);
/* get the number of non-zero elements (in a sparse tensor) */
int GetNonzeroSize();
int GetNonzeroSize() const;
/* set the tensor as "temporary" */
void SetTMPFlag(bool myIsTmp = true);
......@@ -430,15 +433,18 @@ public:
void Dump(FILE * file, const char * label = NULL, const int n = -1, const int beg = 0, const int verbose = 0);
/* dump data to a file */
void DumpFormat(FILE * file, const char * label = NULL, const int n = -1, const int beg = 0, const int verbose = 0);
/* dump data to a file */
static
void Dump(const XTensor * tensor, FILE * file, const char * label = NULL, const int n = -1, const int beg = 0, const int verbose = 0);
/* dump data to a binary file */
void BinaryDump(FILE * file);
/* read data from a file */
void Read(FILE * file, const char * label = NULL);
/* read data from a binary file */
void BinaryRead(FILE * file, size_t offset);
/* flush the data to the target device */
void FlushToMem(XMem * targetMem);
......@@ -469,7 +475,7 @@ void InitTensor(XTensor * tensor,
/* initialize a dense XTensor V2 */
void InitTensorV2(XTensor * tensor,
const int myOrder, const int * myDimSize, const TENSOR_DATA_TYPE myDataType = X_FLOAT,
const int myDevID = -1);
const int myDevID = -1, const bool isEnableGrad = true);
/* initialize a dense vector */
void InitTensor1D(XTensor * tensor, const int num,
......@@ -477,7 +483,7 @@ void InitTensor1D(XTensor * tensor, const int num,
/* initialize a dense vector V2 */
void InitTensor1DV2(XTensor * tensor, const int num,
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1);
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1, const bool isEnableGrad = true);
/* initialize a dense matrix */
void InitTensor2D(XTensor * tensor, const int rowNum, const int colNum,
......@@ -485,7 +491,7 @@ void InitTensor2D(XTensor * tensor, const int rowNum, const int colNum,
/* initialize a dense matrix V2 */
void InitTensor2DV2(XTensor * tensor, const int rowNum, const int colNum,
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1);
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1, const bool isEnableGrad = true);
/* initialize a dense 3d tensor */
void InitTensor3D(XTensor * tensor, const int d0, const int d1, const int d2,
......@@ -493,7 +499,7 @@ void InitTensor3D(XTensor * tensor, const int d0, const int d1, const int d2,
/* initialize a dense 3d tensor V2 */
void InitTensor3DV2(XTensor * tensor, const int d0, const int d1, const int d2,
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1);
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1, const bool isEnableGrad = true);
/* initialize a dense 4d tensor */
void InitTensor4D(XTensor * tensor, const int d0, const int d1, const int d2, const int d3,
......@@ -501,7 +507,7 @@ void InitTensor4D(XTensor * tensor, const int d0, const int d1, const int d2, co
/* initialize a dense 4d tensor V2 */
void InitTensor4DV2(XTensor * tensor, const int d0, const int d1, const int d2, const int d3,
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1);
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1, const bool isEnableGrad = true);
/* initialize a dense 5d tensor */
void InitTensor5D(XTensor * tensor, const int d0, const int d1, const int d2, const int d3, const int d4,
......@@ -509,7 +515,7 @@ void InitTensor5D(XTensor * tensor, const int d0, const int d1, const int d2, co
/* initialize a dense 5d tensor V2 */
void InitTensor5DV2(XTensor * tensor, const int d0, const int d1, const int d2, const int d3, const int d4,
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1);
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1, const bool isEnableGrad = true);
/* initialize a tensor with a reference tensor */
void InitTensor(XTensor * tensor, const XTensor * reference);
......@@ -529,7 +535,7 @@ XTensor * NewTensor(const int myOrder, const int * myDimSize, const TENSOR_DATA_
/* generate a dense XTensor V2 */
XTensor * NewTensorV2(const int myOrder, const int * myDimSize, const TENSOR_DATA_TYPE myDataType = X_FLOAT,
const int myDevID = -1);
const int myDevID = -1, const bool isEnableGrad = true);
/* generate a XTensor which allocates data on the buffer */
XTensor * NewTensorBuf(const int myOrder, const int * myDimSize,
......@@ -538,20 +544,20 @@ XTensor * NewTensorBuf(const int myOrder, const int * myDimSize,
/* generate a dense XTensor which allocates data on the buffer V2 */
XTensor * NewTensorBufV2(const int myOrder, const int * myDimSize,
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1);
const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1, const bool isEnableGrad = true);
/* generate a XTensor which allocates data on the buffer */
XTensor * NewTensorBuf(const XTensor * reference, int devID, XMem * myMem);
/* generate a XTensor which allocates data on the buffer V2 */
XTensor * NewTensorBufV2(const XTensor * reference, int devID);
XTensor * NewTensorBufV2(const XTensor * reference, int devID, const bool isEnableGrad = true);
/* generate a dense vector */
XTensor * NewTensor1D(const int num, const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1,
XMem * myMem = NULL);
/* generate a dense vector V2 */
XTensor * NewTensor1DV2(const int num, const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1);
XTensor * NewTensor1DV2(const int num, const TENSOR_DATA_TYPE myDataType = X_FLOAT, const int myDevID = -1, const bool isEnableGrad = true);
/* generate a dense matrix */
XTensor * NewTensor2D(const int rowNum, const int colNum,
......@@ -561,7 +567,7 @@ XTensor * NewTensor2D(const int rowNum, const int colNum,
/* generate a dense matrix V2 */
XTensor * NewTensor2DV2(const int rowNum, const int colNum,
const TENSOR_DATA_TYPE myDataType = X_FLOAT,
const int myDevID = -1);
const int myDevID = -1, const bool isEnableGrad = true);
/* generate a dense 3d tensor */
XTensor * NewTensor3D(const int d0, const int d1, const int d2,
......@@ -571,7 +577,7 @@ XTensor * NewTensor3D(const int d0, const int d1, const int d2,
/* generate a dense 3d tensor V2 */
XTensor * NewTensor3DV2(const int d0, const int d1, const int d2,
const TENSOR_DATA_TYPE myDataType = X_FLOAT,
const int myDevID = -1);
const int myDevID = -1, const bool isEnableGrad = true);
/* generate a dense 4d tensor */
XTensor * NewTensor4D(const int d0, const int d1, const int d2, const int d3,
......@@ -581,7 +587,7 @@ XTensor * NewTensor4D(const int d0, const int d1, const int d2, const int d3,
/* generate a dense 4d tensor V2 */
XTensor * NewTensor4DV2(const int d0, const int d1, const int d2, const int d3,
const TENSOR_DATA_TYPE myDataType = X_FLOAT,
const int myDevID = -1);
const int myDevID = -1, const bool isEnableGrad = true);
/* generate a dense 5d tensor */
XTensor * NewTensor5D(const int d0, const int d1, const int d2, const int d3, const int d4,
......@@ -591,7 +597,10 @@ XTensor * NewTensor5D(const int d0, const int d1, const int d2, const int d3, co
/* generate a dense 5d tensor V2 */
XTensor * NewTensor5DV2(const int d0, const int d1, const int d2, const int d3, const int d4,
const TENSOR_DATA_TYPE myDataType = X_FLOAT,
const int myDevID = -1);
const int myDevID = -1, const bool isEnableGrad = true);
/* generate a dense vector by range */
XTensor * NewTensorRange(int lower, int upper, int step, const TENSOR_DATA_TYPE myDataType = X_INT, const int myDevID = -1, const bool isEnableGrad = true);
/* generate a copy of XTensor (with a reference to a given tensor) */
XTensor * NewTensor(const XTensor * a, bool isFilledData = true);
......
......@@ -215,19 +215,23 @@ XTensor Div(const XTensor &a, const XTensor &b, DTYPE alpha, int leadingDim)
_Div(&a, &b, &c, alpha, leadingDim);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_DIV);
XLink::AddParamToHead(&c, alpha);
XLink::AddParamToHeadInt(&c, leadingDim);
}
}
else if(n >= 0 && n < a.order){
/* call _DivDim function */
_DivDim(&a, &b, &c, n, alpha);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_DIVDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, alpha);
}
}
else{
ShowNTErrors("Something is wrong!");
}
......@@ -261,7 +265,7 @@ void Div(const XTensor &a, const XTensor &b, XTensor &c, DTYPE alpha, int leadin
/* call _Div function */
_Div(&a, &b, &c, 0, leadingDim);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_DIV);
XLink::AddParamToHead(&c, alpha);
......@@ -272,7 +276,7 @@ void Div(const XTensor &a, const XTensor &b, XTensor &c, DTYPE alpha, int leadin
/* call _DivDim function */
_DivDim(&a, &b, &c, n, alpha);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_DIVDIM);
XLink::AddParamToHeadInt(&c, n);
......
......@@ -164,9 +164,11 @@ XTensor DivDim(const XTensor &a, const XTensor &b, int n, DTYPE alpha)
_DivDim(&a, &b, &c, n, alpha);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_DIVDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, alpha);
}
return c;
}
......@@ -193,7 +195,7 @@ void DivDim(const XTensor &a, const XTensor &b, XTensor &c, int n, DTYPE alpha)
/* call _Div function */
_DivDim(&a, &b, &c, n, alpha);
if (c.enableGrad == true) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_DIVDIM);
XLink::AddParamToHeadInt(&c, n);
......
......@@ -155,8 +155,10 @@ XTensor Mask(const XTensor &a, const XTensor &mask, DTYPE alpha)
_Mask(&a, &mask, &c, alpha);
/* tensor connections */
if (a.enableGrad) {
XLink::MakeLink(&a, &mask, &c, MATH_MASK);
XLink::AddParamToHead(&c, alpha);
}
return c;
}
......@@ -176,7 +178,7 @@ void Mask(const XTensor &a, const XTensor &mask, XTensor &c, DTYPE alpha)
/* call _Mask function */
_Mask(&a, &mask, &c, alpha);
if (c.enableGrad) {
if (a.enableGrad) {
XLink::MakeLink(&a, &mask, &c, MATH_MASK);
XLink::AddParamToHead(&c, alpha);
}
......
......@@ -296,10 +296,12 @@ XTensor MatrixMul(const XTensor &a, MATRIX_TRANS_TYPE transposedA,
_MatrixMul(&a, transposedA, &b, transposedB, &c, alpha, 0, parallelRunner);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MATRIXMUL);
XLink::AddParamToHeadTrans(&c, transposedA);
XLink::AddParamToHeadTrans(&c, transposedB);
XLink::AddParamToHead(&c, alpha);
}
/* destroy variables */
delete[] dimSize;
......@@ -344,7 +346,7 @@ void MatrixMul(const XTensor &a, MATRIX_TRANS_TYPE transposedA,
/* call _MatrixMul function */
_MatrixMul(&a, transposedA, &b, transposedB, &c, alpha, beta, parallelRunner);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_MATRIXMUL);
XLink::AddParamToHeadTrans(&c, transposedA);
......@@ -393,10 +395,12 @@ XTensor MatrixMul(const XTensor &a, const XTensor &b,
_MatrixMul(&a, X_NOTRANS, &b, X_NOTRANS, &c, alpha, 0, parallelRunner);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MATRIXMUL);
XLink::AddParamToHeadTrans(&c, X_NOTRANS);
XLink::AddParamToHeadTrans(&c, X_NOTRANS);
XLink::AddParamToHead(&c, alpha);
}
/* destroy variables */
delete[] dimSize;
......@@ -440,7 +444,7 @@ void MatrixMul(const XTensor &a, const XTensor &b, XTensor &c,
/* call _MatrixMul function */
_MatrixMul(&a, X_NOTRANS, &b, X_NOTRANS, &c, alpha, 0, parallelRunner);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_MATRIXMUL);
XLink::AddParamToHeadTrans(&c, X_NOTRANS);
......
......@@ -82,10 +82,11 @@ void _MatrixMul2D(const XTensor * a, MATRIX_TRANS_TYPE transposedA,
b->dataType == DEFAULT_DTYPE &&
c->dataType == DEFAULT_DTYPE)
{
if (useBLAS)
#if defined(USE_BLAS)
_MatrixMULCPU(a, transposedA, b, transposedB, c, alpha, beta);
else
#else
_MatrixMul2DParallel(a, transposedA, b, transposedB, c, alpha, beta, parallelRunner);
#endif
}
else {
// TODO!!
......
......@@ -199,10 +199,7 @@ void _MatrixMulBatchedCPU(const XTensor * a, MATRIX_TRANS_TYPE transposedA,
bi->data = (char*)b->data + i * bRealBlockSize;
ci->data = (char*)c->data + i * cRealBlockSize;
#ifdef USE_BLAS
if (useBLAS)
_MatrixMULCPU(ai, transposedA, bi, transposedB, ci, alpha, beta);
else
_MatrixMul2D(ai, transposedA, bi, transposedB, ci, alpha, beta);
#else
_MatrixMul2D(ai, transposedA, bi, transposedB, ci, alpha, beta);
#endif
......@@ -262,10 +259,7 @@ void _MatrixMulBatchedCPU(const TensorList * a, MATRIX_TRANS_TYPE transposedA,
CheckNTErrors((bi->order == 2), "2d tensor (i.e., matrix) is required!");
CheckNTErrors((ci->order == 2), "2d tensor (i.e., matrix) is required!");
#ifdef USE_BLAS
if (useBLAS)
_MatrixMULCPU(ai, transposedA, bi, transposedB, ci, alpha, beta);
else
_MatrixMul2D(ai, transposedA, bi, transposedB, ci, alpha, beta);
#else
_MatrixMul2D(ai, transposedA, bi, transposedB, ci, alpha, beta);
#endif
......@@ -320,10 +314,12 @@ XTensor MatrixMulBatched(const XTensor &a, MATRIX_TRANS_TYPE transposedA, const
_MatrixMulBatched(&a, transposedA, &b, transposedB, &c, alpha, 0, parallelRunner);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MATRIXMULBATCHED);
XLink::AddParamToHeadTrans(&c, transposedA);
XLink::AddParamToHeadTrans(&c, transposedB);
XLink::AddParamToHead(&c, alpha);
}
/* destroy variables */
delete[] dimSize;
......@@ -376,10 +372,12 @@ XTensor MatrixMulBatched(const XTensor &a, const XTensor &b,
_MatrixMulBatched(&a, X_NOTRANS, &b, X_NOTRANS, &c, alpha, 0, parallelRunner);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MATRIXMULBATCHED);
XLink::AddParamToHeadTrans(&c, X_NOTRANS);
XLink::AddParamToHeadTrans(&c, X_NOTRANS);
XLink::AddParamToHead(&c, alpha);
}
/* destroy variables */
delete[] dimSize;
......
......@@ -118,11 +118,87 @@ XTensor MulAndShift(const XTensor &x, const XTensor &w, const XTensor &b,
}
/* tensor connections */
if (w.enableGrad && b.enableGrad) {
XLink::MakeLink(&x, &w, &b, &c, MATH_MULANDSHIFT);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHeadTrans(&c, X_NOTRANS);
XLink::AddParamToHeadTrans(&c, X_NOTRANS);
//XLink::AddParamToHead(&c, beta);
}
/* destroy variables */
delete[] dimSize;
DelTensorBuf(tmp);
return c;
}
/*
operation c = x * w + b MulAndShift
>> x - tensor x
>> w - tensor w
>> b - tensor b
>> parallelRunner - parallel processing module
<< return - the result of matrix multiplication
*/
XTensor MulAndShift(const XTensor& x, MATRIX_TRANS_TYPE transposedA,
const XTensor& w, MATRIX_TRANS_TYPE transposedB,
const XTensor& b, DTYPE alpha, XPRunner* parallelRunner)
{
CheckNTErrors(x.dataType == w.dataType, "Input tensors should have the same data type!");
CheckNTErrors(x.order >= 2 && w.order >= 2, "Input tensors must have a order >= 2!");
int xn = transposedA == X_TRANS ? x.dimSizeRDI[0] : x.dimSizeRDI[1];
int xm = transposedA == X_TRANS ? x.dimSizeRDI[1] : x.dimSizeRDI[0];
int wn = transposedB == X_TRANS ? w.dimSizeRDI[0] : w.dimSizeRDI[1];
int wm = transposedB == X_TRANS ? w.dimSizeRDI[1] : w.dimSizeRDI[0];
int order = x.order + w.order - 2;
int sub = 0;
int * dimSize = new int[order];
for (int i = 2; i < x.order; i++)
dimSize[sub++] = x.dimSizeRDI[x.order + 1 - i];
for (int i = 2; i < w.order; i++)
dimSize[sub++] = w.dimSizeRDI[w.order + 1 - i];
dimSize[sub++] = xn;
dimSize[sub++] = wm;
float dr = (!x.isSparse || !w.isSparse) ? 1.0F : MAX(x.denseRatio, w.denseRatio);
XTensor * tmp = NewTensorBuf(order, dimSize, x.dataType, dr, x.devID, x.mem);
/* call _MatrixMul function */
_MatrixMul(&x, transposedA, &w, transposedB, tmp, alpha, 0, parallelRunner);
XTensor c(tmp);
c.SetTMPFlag();
int n = GetSumIndex(tmp, b);
if (n == -1) {
/* call _Sum function */
_Sum(tmp, &b, &c);
// TODO!!
ShowNTErrors("TODO!");
}
else if (n >= 0 && n < tmp->order) {
/* call _SumDim function */
_SumDim(tmp, &b, &c, n);
}
else {
ShowNTErrors("Something is wrong!");
}
/* tensor connections */
if (w.enableGrad && b.enableGrad) {
XLink::MakeLink(&x, &w, &b, &c, MATH_MULANDSHIFT);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHeadTrans(&c, transposedA);
XLink::AddParamToHeadTrans(&c, transposedB);
}
/* destroy variables */
delete[] dimSize;
......
......@@ -31,6 +31,9 @@ namespace nts { // namespace nts(NiuTrans.Tensor)
XTensor MulAndShift(const XTensor &x, const XTensor &w, const XTensor &b,
DTYPE alpha = (DTYPE)1.0, XPRunner * parallelRunner = NULL);
XTensor MulAndShift(const XTensor &x, MATRIX_TRANS_TYPE transposedA,
const XTensor &w, MATRIX_TRANS_TYPE transposedB,
const XTensor &b, DTYPE alpha = (DTYPE)1.0, XPRunner * parallelRunner = NULL);
} // namespace nts(NiuTrans.Tensor)
......
......@@ -216,19 +216,23 @@ XTensor Multiply(const XTensor &a, const XTensor &b, DTYPE alpha, int leadingDim
_Multiply(&a, &b, &c, 0, leadingDim);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLY);
XLink::AddParamToHead(&c, alpha);
XLink::AddParamToHeadInt(&c, leadingDim);
}
}
else if(n >= 0 && n < a.order){
/* call _MultiplyDim function */
_MultiplyDim(&a, &b, &c, n, alpha);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLYDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, alpha);
}
}
else{
ShowNTErrors("Something is wrong!");
}
......@@ -262,7 +266,7 @@ void Multiply(const XTensor &a, const XTensor &b, XTensor &c, DTYPE alpha, int l
/* call _Multiply function */
_Multiply(&a, &b, &c, 0, leadingDim);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLY);
XLink::AddParamToHead(&c, alpha);
......@@ -273,7 +277,7 @@ void Multiply(const XTensor &a, const XTensor &b, XTensor &c, DTYPE alpha, int l
/* call _MultiplyDim function */
_MultiplyDim(&a, &b, &c, n, alpha);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLYDIM);
XLink::AddParamToHeadInt(&c, n);
......
......@@ -180,9 +180,11 @@ XTensor MultiplyDim(const XTensor &a, const XTensor &b, int n)
_MultiplyDim(&a, &b, &c, n, 0);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLYDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, 0);
}
return c;
}
......@@ -208,7 +210,7 @@ void MultiplyDim(const XTensor &a, const XTensor &b, XTensor &c, int n)
/* call _Multiply function */
_MultiplyDim(&a, &b, &c, n, 0);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLYDIM);
XLink::AddParamToHeadInt(&c, n);
......@@ -350,8 +352,10 @@ XTensor MultiplyBroadcast(const XTensor &a, const XTensor &b)
_MultiplyBroadcast(&a, &b, &c, 0);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLYBROADCAST);
XLink::AddParamToHead(&c, 0);
}
return c;
}
......@@ -374,7 +378,7 @@ void MultiplyBroadcast(const XTensor &a, const XTensor &b, XTensor &c)
/* call _SumBroadcast function */
_MultiplyBroadcast(&a, &b, &c, 0);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_MULTIPLYBROADCAST);
XLink::AddParamToHead(&c, 0);
......
......@@ -190,18 +190,22 @@ XTensor Sub(const XTensor &a, const XTensor &b, DTYPE beta)
_Sub(&a, &b, &c, beta);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUB);
XLink::AddParamToHead(&c, beta);
}
}
else if(n >= 0 && n < a.order){
/* call _SubDim function */
_SubDim(&a, &b, &c, n, beta);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUBDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, beta);
}
}
else{
ShowNTErrors("Something is wrong!");
}
......@@ -229,7 +233,7 @@ void Sub(const XTensor &a, const XTensor &b, XTensor &c, DTYPE beta)
/* call _Sub function */
_Sub(&a, &b, &c, beta);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_SUB);
XLink::AddParamToHead(&c, beta);
......@@ -239,7 +243,7 @@ void Sub(const XTensor &a, const XTensor &b, XTensor &c, DTYPE beta)
/* call _SubDim function */
_SubDim(&a, &b, &c, n, beta);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_SUBDIM);
XLink::AddParamToHeadInt(&c, n);
......
......@@ -164,9 +164,11 @@ XTensor SubDim(const XTensor &a, const XTensor &b, int n, DTYPE beta)
_SubDim(&a, &b, &c, n, beta);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUBDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, beta);
}
return c;
}
......@@ -193,7 +195,7 @@ void SubDim(const XTensor &a, const XTensor &b, XTensor &c, int n, DTYPE beta)
/* call _Sub function */
_SubDim(&a, &b, &c, n, beta);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_SUBDIM);
XLink::AddParamToHeadInt(&c, n);
......
......@@ -22,6 +22,7 @@
#include "../../XTensor.h"
#include "../../XName.h"
#include "../../XUtility.h"
#include "../../XBLAS.h"
#include "../movement/CopyValues.h"
#include "Sum.h"
#include "Sum.cuh"
......@@ -84,7 +85,34 @@ void _Sum(const XTensor * a, const XTensor * b, XTensor * c, DTYPE beta)
DTYPE * ap = (DTYPE*)a->data;
DTYPE * bp = (DTYPE*)b->data;
DTYPE * cp = (DTYPE*)c->data;
/* when c != a, OpenBLAS needs to copy a to c first. This operation
slow down the speed, so just use OpenBLAS when c == a */
#if defined(USE_BLAS)
if( c == a){
AXPY(a->unitNum,beta,bp,1,cp,1);
} else{
int num = a->unitNum;
if (num % 4 == 0) {
for (int i = 0; i < num; i += 4) {
cp[i] = ap[i] + bp[i] * beta;
cp[i + 1] = ap[i + 1] + bp[i + 1] * beta;
cp[i + 2] = ap[i + 2] + bp[i + 2] * beta;
cp[i + 3] = ap[i + 3] + bp[i + 3] * beta;
}
}
else if (num % 2 == 0) {
for (int i = 0; i < num; i += 2) {
cp[i] = ap[i] + bp[i] * beta;
cp[i + 1] = ap[i + 1] + bp[i + 1] * beta;
}
}
else {
for (int i = 0; i < num; i++) {
cp[i] = ap[i] + bp[i] * beta;
}
}
}
#else
/* unrolling */
int num = a->unitNum;
if (num % 4 == 0) {
......@@ -106,6 +134,7 @@ void _Sum(const XTensor * a, const XTensor * b, XTensor * c, DTYPE beta)
cp[i] = ap[i] + bp[i] * beta;
}
}
#endif
}
else {
// TODO!!
......@@ -195,18 +224,22 @@ XTensor Sum(const XTensor &a, const XTensor &b, DTYPE beta)
_Sum(&a, &b, &c, beta);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUM);
XLink::AddParamToHead(&c, beta);
}
}
else if(n >= 0 && n < a.order){
/* call _SumDim function */
_SumDim(&a, &b, &c, n, beta);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUMDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, beta);
}
}
else{
ShowNTErrors("Something is wrong!");
}
......@@ -233,8 +266,8 @@ void Sum(const XTensor &a, const XTensor &b, XTensor &c, DTYPE beta)
/* call _Sum function */
_Sum(&a, &b, &c, beta);
if (c.enableGrad) {
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUM);
XLink::AddParamToHead(&c, beta);
}
......@@ -243,8 +276,8 @@ void Sum(const XTensor &a, const XTensor &b, XTensor &c, DTYPE beta)
/* call _SumDim function */
_SumDim(&a, &b, &c, n, beta);
if (c.enableGrad) {
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUMDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, beta);
......
......@@ -181,9 +181,11 @@ XTensor SumDim(const XTensor &a, const XTensor &b, int n, DTYPE beta)
_SumDim(&a, &b, &c, n, beta);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUMDIM);
XLink::AddParamToHeadInt(&c, n);
XLink::AddParamToHead(&c, beta);
}
return c;
}
......@@ -210,7 +212,7 @@ void SumDim(const XTensor &a, const XTensor &b, XTensor &c, int n, DTYPE beta)
/* call _SumDim function */
_SumDim(&a, &b, &c, n, beta);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_SUMDIM);
XLink::AddParamToHeadInt(&c, n);
......@@ -353,8 +355,10 @@ XTensor SumBroadcast(const XTensor &a, const XTensor &b, DTYPE beta)
_SumBroadcast(&a, &b, &c, beta);
/* tensor connections */
if (a.enableGrad && b.enableGrad) {
XLink::MakeLink(&a, &b, &c, MATH_SUMBROADCAST);
XLink::AddParamToHead(&c, beta);
}
return c;
}
......@@ -377,7 +381,7 @@ void SumBroadcast(const XTensor &a, const XTensor &b, XTensor &c, DTYPE beta)
/* call _SumBroadcast function */
_SumBroadcast(&a, &b, &c, beta);
if (c.enableGrad) {
if (a.enableGrad && b.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, &b, &c, MATH_SUMBROADCAST);
XLink::AddParamToHead(&c, beta);
......
......@@ -121,6 +121,7 @@ XTensor ConvertDataType(const XTensor & input, TENSOR_DATA_TYPE dataType)
_ConvertDataType(&input, &output);
/* tensor connection */
if(input.enableGrad)
XLink::MakeLink(&input, NULL, &output, GETANDSET_CONVERTDATATYPE);
return output;
......@@ -136,7 +137,7 @@ void ConvertDataType(const XTensor & input, XTensor & output, TENSOR_DATA_TYPE d
_ConvertDataType(&input, &output);
/* tensor connection */
if (output.enableGrad)
if (input.enableGrad)
XLink::MakeLink(&input, NULL, &output, GETANDSET_CONVERTDATATYPE);
}
......
......@@ -32,65 +32,43 @@ convert onehot tensor to index tensor
>> index - index tensor, which value is an integer num
>> size - the last dimension size of the onehot tensor
*/
void _OnehotToIndex(XTensor * onehot, XTensor * index, int dim)
void _OnehotToIndex(const XTensor * onehot, XTensor * index, int size)
{
dim = (dim < 0 ? onehot->GetDim(-1) : dim);
CheckNTErrors(onehot->GetDim(-1) == size, "Illegal tensor dimension!");
CheckNTErrors(onehot->order == index->order + 1, "Illegal tensor order!");
CheckNTErrors(dim < onehot->order, "Illegal speficied dimension!")
CheckNTErrors(onehot->dataType == X_INT, "The onehot tensor must be in X_INT!")
CheckNTErrors(index->dataType == X_INT, "The index tensor must be in X_INT!")
for (int i = 0; i < index->order; i++) {
if (i < dim) {
for (int i = 0; i < index->order; i++)
CheckNTErrors(index->GetDim(i) == onehot->GetDim(i), "Illegal tensor order!");
}
else {
CheckNTErrors(index->GetDim(i) == onehot->GetDim(i + 1), "Illegal tensor order!");
}
}
#ifdef USE_CUDA
if(onehot->devID >= 0 && index->devID >= 0) {
_CudaOnehotToIndex(onehot, index, dim);
_CudaOnehotToIndex(onehot, index, size);
return;
}
#endif
int blockNum = 1;
int blockSize = 1;
int dimSize = 1;
int stride = 1;
for (int i = 0; i < dim; i++)
blockNum *= onehot->GetDim(i);
blockSize = onehot->unitNum / blockNum;
dimSize = onehot->GetDim(dim);
for (int i = dim + 1; i < onehot->order; i++)
stride *= onehot->GetDim(i);
int blockNum = index->unitNum;
int stride = size;
int * onehotData = (int *)onehot->data;
int * indexData = (int *)index->data;
for (int i = 0; i < blockNum; i++) {
for (int j = 0; j < stride; j++) {
int * od = onehotData + i * blockSize + j;
int * index = indexData + i * stride + j;
int * od = onehotData + i * stride;
int record = -1;
for (int j = 0; j < dimSize; j++) {
if (od[j*stride] != 0) {
for (int j = 0; j < stride; j++) {
if (od[j] != 0) {
if (record == -1)
record = j;
else
ShowNTErrors("The value of onehot tensor is illegal!");
}
}
*index = record;
}
indexData[i] = record;
}
}
/*
......@@ -101,7 +79,7 @@ make a new tensor to keep the result and return it
>> size - the last dimension size of the onehot tensor
<< return - the index tensor
*/
XTensor OnehotToIndex(XTensor & onehot, int size)
XTensor OnehotToIndex(const XTensor & onehot, int size)
{
CheckNTErrors(onehot.GetDim(-1) == size, "Illegal tensor dimension!");
CheckNTErrors(onehot.dataType == X_INT, "The onehot tensor must be in X_INT!")
......@@ -123,10 +101,9 @@ convert index tensor to onehot tensor
>> size - the last dimension size of the onehot tensor
*/
void _IndexToOnehot(const XTensor * index, XTensor * onehot,
float labelSmoothingP)
int size, float labelSmoothingP)
{
int size = onehot->GetDim(-1);
CheckNTErrors(onehot->GetDim(-1) == size, "Illegal tensor dimension!");
CheckNTErrors(onehot->order == index->order + 1, "Illegal tensor order!");
//CheckNTErrors(onehot->dataType == X_INT, "The onehot tensor must be in X_INT!")
CheckNTErrors(index->dataType == X_INT, "The index tensor must be in X_INT!")
......@@ -171,7 +148,7 @@ make a new tensor to keep the result and return it
>> confidence - labelsmoothing
<< return - the onehot tensor
*/
XTensor IndexToOnehot(XTensor & index, int size, float labelSmoothingP)
XTensor IndexToOnehot(const XTensor & index, int size, float labelSmoothingP)
{
CheckNTErrors(index.dataType == X_INT, "The onehot tensor must be in X_INT!")
......@@ -184,7 +161,7 @@ XTensor IndexToOnehot(XTensor & index, int size, float labelSmoothingP)
dim[order] = size;
InitTensor(&onehot, index.order + 1, dim, X_FLOAT, 1.0F, index.devID, index.mem);
_IndexToOnehot(&index, &onehot, labelSmoothingP);
_IndexToOnehot(&index, &onehot, size, labelSmoothingP);
delete[] dim;
......
......@@ -61,7 +61,7 @@ convert onehot tensor to index tensor (cuda version)
>> index - index tensor, which value is an integer num
>> size - the last dimension size of the onehot tensor
*/
void _CudaOnehotToIndex(XTensor * onehot, XTensor * index, int size)
void _CudaOnehotToIndex(const XTensor * onehot, XTensor * index, int size)
{
int devID = onehot->devID;
......
......@@ -27,10 +27,11 @@
namespace nts{ // namespace nts(NiuTrans.Tensor)
/* convert onehot tensor to index tensor (cuda version) */
void _CudaOnehotToIndex(XTensor * onehot, XTensor * index, int size);
void _CudaOnehotToIndex(const XTensor * onehot, XTensor * index, int size);
/* convert index tensor to onehot tensor (cuda version) */
void _CudaIndexToOnehot(const XTensor * index, XTensor * onehot, int size, float confidence, float lowconfidence);
void _CudaIndexToOnehot(const XTensor * index, XTensor * onehot,
int size, float confidence, float lowconfidence);
} // namespace nts(NiuTrans.Tensor)
......
......@@ -27,19 +27,18 @@
namespace nts{ // namespace nts(NiuTrans.Tensor)
/* convert onehot tensor to index tensor */
void _OnehotToIndex(XTensor * onehot, XTensor * index, int dim);
void _OnehotToIndex(const XTensor * onehot, XTensor * index, int size);
/* convert onehot tensor to index tensor (return an XTensor structure)
make a new tensor to keep the result and return it */
XTensor OnehotToIndex(XTensor & onehot, int size);
XTensor OnehotToIndex(const XTensor & onehot, int num);
/* convert index tensor to onehot tensor */
void _IndexToOnehot(const XTensor * index, XTensor * onehot,
float labelSmoothingP = 0.0F);
void _IndexToOnehot(const XTensor * index, XTensor * onehot, int size, float labelSmoothingP);
/* convert index tensor to onehot tensor (return an XTensor structure)
make a new tensor to keep the result and return it */
XTensor IndexToOnehot(XTensor & index, int size, float labelSmoothingP = 0.0F);
XTensor IndexToOnehot(const XTensor & index, int num, float labelSmoothingP);
} // namespace nts(NiuTrans.Tensor)
......
......@@ -117,10 +117,12 @@ XTensor SelectRange(const XTensor &a, int dim, int low, int high)
_SelectRange(&a, &c, dim, low, high);
/* tensor connection */
if (a.enableGrad) {
XLink::MakeLink(&a, NULL, &c, GETANDSET_SELECT);
XLink::AddParamToHeadInt(&c, dim);
XLink::AddParamToHeadInt(&c, low);
XLink::AddParamToHeadInt(&c, high);
}
/* destroy variables */
delete[] dimSize;
......
......@@ -526,6 +526,43 @@ void _SetDataRand(XTensor * tensor, DTYPE lower, DTYPE upper)
}
}
/* generate data items with a range by start, end and the step
>> tensor - the tensor whose data array would be initialized
>> start - the begin of the array
>> end - the end of the array (not included self)
>> step - the step of two items
*/
void _SetDataRange(XTensor * tensor, DTYPE lower, DTYPE upper, DTYPE step)
{
CheckNTErrors((tensor->order == 1), "Tensor must be 1 dimension!");
/* compute the true length according to the (start, end, step) */
DTYPE size = fabs(upper - lower);
int num = ceil(size / fabs(step));
CheckNTErrors((tensor->unitNum == num), "Unit number of the tensor is not matched.");
/* init a integer array to store the sequence */
void * data = NULL;
if (tensor->dataType == X_INT) {
data = new int[num];
for (int i = 0; i < num; i++)
*((int*)data + i) = lower + i * step;
}
else if (tensor->dataType == X_FLOAT) {
data = new float[num];
for (int i = 0; i < num; i++)
*((float*)data + i) = lower + i * step;
}
else {
ShowNTErrors("TODO!");
}
/* set the data from the array */
tensor->SetData(data, num);
delete[] data;
}
/*
generate data items with a uniform distribution in [lower, upper] and set
the item to a pre-defined value if the item >= p, set the item to 0 otherwise
......
......@@ -69,6 +69,9 @@ void _SetDataRand(XTensor * tensor, int rNum, int cNum);
/* generate data items with a uniform distribution in [lower, upper] */
void _SetDataRand(XTensor * tensor, DTYPE lower, DTYPE upper);
/* generate data items with a range by start, end and the step */
void _SetDataRange(XTensor * tensor, DTYPE lower, DTYPE upper, DTYPE step);
/* generate data items with a uniform distribution in [lower, upper] and set
the item to a pre-defined value if the item >= p, set the item to 0 otherwise */
void _SetDataRandP(XTensor * tensor, DTYPE lower, DTYPE upper, DTYPE p, DTYPE value);
......
......@@ -167,7 +167,9 @@ XTensor funcName(const XTensor &a, T num)
XTensor b(&a); \
b.SetTMPFlag(); \
_funcName(&a, &b, num); \
if(a.enableGrad){ \
XLink::MakeLink(&a, NULL, &b, operationId); \
} \
XLink::AddParamToHead(&b, num); \
return b; \
} \
......@@ -183,7 +185,7 @@ void funcName(const XTensor &a, XTensor &b, T num)
InitTensor(&b, &a); \
} \
_funcName(&a, &b, num); \
if (b.enableGrad) { \
if (a.enableGrad) { \
XLink::MakeLink(&a, NULL, &b, operationId); \
XLink::AddParamToHead(&b, num); \
} \
......
......@@ -99,9 +99,11 @@ XTensor Clip(const XTensor & a, DTYPE lower, DTYPE upper)
_Clip(&a, &b, lower, upper);
/* tensor connections */
if (a.enableGrad) {
XLink::MakeLink(&a, NULL, &b, MATH_CLIP);
XLink::AddParamToHead(&b, lower);
XLink::AddParamToHead(&b, upper);
}
return b;
}
......@@ -115,8 +117,8 @@ void Clip(const XTensor & a, XTensor & b, DTYPE lower, DTYPE upper)
/* call _Clip function */
_Clip(&a, &b, lower, upper);
if (b.enableGrad) {
/* tensor connections */
if (a.enableGrad) {
XLink::MakeLink(&a, NULL, &b, MATH_CLIP);
XLink::AddParamToHead(&b, lower);
XLink::AddParamToHead(&b, upper);
......
......@@ -20,6 +20,7 @@
*/
#include "../../XTensor.h"
#include "../../XDevice.h"
#include "../../XName.h"
#include "Compare.h"
#include "Compare.cuh"
......@@ -123,4 +124,95 @@ SIMPLE_COMPARE_FUNCTION_ME(NotEqualMe, _NotEqual)
SIMPLE_COMPARE_FUNCTION(NotEqual, _NotEqual, MATH_NOTEQUAL)
SIMPLE_COMPARE_FUNCTION_VOID(NotEqual, _NotEqual, MATH_NOTEQUAL)
/* define three marco separately, specify the respective function names */
#ifdef USE_CUDA
#define _SIMPLE_MAX_MIN_FUNCTION(_funcName, _cudaFuncName, origFunc) \
void _funcName(const XTensor * a, const XTensor * b, XTensor * c) \
{ \
CheckNTErrors((XTensor::IsSameShaped(a, b, c)), \
"Input and output tensors should have the same type!"); \
CheckNTErrors((a->dataType == DEFAULT_DTYPE), "TODO!"); \
CheckDev(a->devID, b->devID); \
CheckDev(a->devID, c->devID); \
/* run it on GPUs */ \
if (a->devID >= 0) { \
_cudaFuncName(a, b, c); \
return; \
} \
DTYPE * da = (DTYPE*)a->data; \
DTYPE * db = (DTYPE*)b->data; \
DTYPE * dc = (DTYPE*)c->data; \
for (int i = 0; i < a->unitNum; i++) \
dc[i] = (DTYPE)origFunc(da[i], db[i]); \
}
#else
#define _SIMPLE_MAX_MIN_FUNCTION(_funcName, origFunc) \
void _funcName(const XTensor * a, const XTensor * b, XTensor *c) \
{ \
CheckNTErrors((XTensor::IsSameShaped(a, b, c)), \
"Input and output tensors should have the same type!"); \
CheckNTErrors((a->dataType == DEFAULT_DTYPE), "TODO!"); \
CheckDev(a, b); \
CheckDev(a, c); \
/* run it on GPUs */ \
if (a->devID >= 0) { \
ShowNTErrors("No GPU devices support!") \
} \
DTYPE * da = (DTYPE*)a->data; \
DTYPE * db = (DTYPE*)b->data; \
DTYPE * dc = (DTYPE*)c->data; \
for (int i = 0; i < a->unitNum; i++) \
dc[i] = (DTYPE)origFunc(da[i], db[i]); \
}
#endif
#define _SIMPLE_MAX_MIN_FUNCTION_ME(_funcNameMe, _funcName) \
void _funcNameMe(XTensor * a, const XTensor * b) \
{ \
_funcName(a, b, a); \
}
#define SIMPLE_MAX_MIN_FUNCTION_ME(funcNameMe, _funcName) \
void funcNameMe(XTensor & a, const XTensor & b) \
{ \
_funcName(&a, &b, &a); \
}
#define SIMPLE_MAX_MIN_FUNCTION(funcName, _funcName, operationId) \
XTensor funcName(const XTensor & a, const XTensor & b) \
{ \
XTensor c(&a); \
c.SetTMPFlag(); \
_funcName(&a, &b, &c); \
return c; \
}
#define SIMPLE_MAX_MIN_FUNCTION_VOID(funcName, _funcName, operationId) \
void funcName(const XTensor &a, const XTensor &b, XTensor c) \
{ \
if (!c.isInit || !XTensor::IsSameShaped(&a, &c)) { \
InitTensor(&c, &a); \
} \
_funcName(&a, &b, &c); \
}
#ifdef USE_CUDA
_SIMPLE_MAX_MIN_FUNCTION(_Max, _CudaMax, max)
_SIMPLE_MAX_MIN_FUNCTION(_Min, _CudaMin, min)
#else
_SIMPLE_MAX_MIN_FUNCTION(_Max, max)
_SIMPLE_MAX_MIN_FUNCTION(_Min, min)
#endif
_SIMPLE_MAX_MIN_FUNCTION_ME(_MaxMe, _Max)
SIMPLE_MAX_MIN_FUNCTION_ME(MaxMe, _Max)
SIMPLE_MAX_MIN_FUNCTION(Max, _Max, MATH_MAX)
SIMPLE_MAX_MIN_FUNCTION_VOID(Max, _Max, MATH_MAX)
_SIMPLE_MAX_MIN_FUNCTION_ME(_MinMe, _Min)
SIMPLE_MAX_MIN_FUNCTION_ME(MinMe, _Min)
SIMPLE_MAX_MIN_FUNCTION(Min, _Min, MATH_MIN)
SIMPLE_MAX_MIN_FUNCTION_VOID(Min, _Min, MATH_MIN)
} // namespace nts(NiuTrans.Tensor)
\ No newline at end of file
......@@ -89,6 +89,53 @@ void _Cuda##funcName(const XTensor * a, XTensor * b, DTYPE number) \
SIMPLE_COMPARE_FUNCTION_GPU(Equal, cudaIsEqual)
SIMPLE_COMPARE_FUNCTION_GPU(NotEqual, cudaIsNotEqual)
#define SIMPLE_MAX_MIN_FUNCTION_GPU(funcName, origFunc) \
__global__ \
void Kernel##funcName(DTYPE * a, DTYPE * b, DTYPE * c, int size) \
{ \
int i = blockDim.x * blockIdx.x + threadIdx.x; \
\
if (i < size) \
c[i] = (DTYPE)origFunc(a[i], b[i]); \
} \
__global__ \
void Kernel##funcName(__half * a, __half * b, __half * c, int size) \
{ \
return; \
} \
void _Cuda##funcName(const XTensor * a, const XTensor * b, XTensor * c) \
{ \
\
int gridSize[3]; \
int blockSize[3]; \
\
GDevs.GetCudaThread(a->devID, a->unitNum, gridSize, blockSize); \
\
dim3 blocks(gridSize[0]); \
dim3 threads(blockSize[0]); \
\
int devIDBackup; \
ProtectCudaDev(a->devID, devIDBackup); \
\
if (a->dataType == DEFAULT_DTYPE) { \
Kernel##funcName<<<blocks, threads>>> \
((DTYPE*)a->data, (DTYPE*)b->data, \
(DTYPE*)c->data, a->unitNum); \
} \
else if (a->dataType == X_FLOAT16) { \
Kernel##funcName<<<blocks, threads>>> \
((__half*)a->data, (__half*)b->data, \
(__half*)c->data, a->unitNum); \
} \
else { \
ShowNTErrors("TODO!"); \
} \
\
BacktoCudaDev(a->devID, devIDBackup); \
}
SIMPLE_MAX_MIN_FUNCTION_GPU(Max, max)
SIMPLE_MAX_MIN_FUNCTION_GPU(Min, min)
#endif // USE_CUDA
......
......@@ -34,6 +34,12 @@ void _CudaEqual(const XTensor * a, XTensor * b, DTYPE value);
/* check whether every entry is not equal to the given value (cuda version) */
void _CudaNotEqual(const XTensor * a, XTensor * b, DTYPE value);
/* return maximum of two tensor for each items (cuda version) */
void _CudaMax(const XTensor * a, const XTensor * b, XTensor *c);
/* return minimum of two tensor for each items (cuda version) */
void _CudaMin(const XTensor * a, const XTensor * b, XTensor *c);
#endif // USE_CUDA
} // namespace nts(NiuTrans.Tensor)
......
......@@ -56,6 +56,36 @@ XTensor NotEqual(const XTensor & a, DTYPE value);
/* check whether every entry is not equal to the given value */
void NotEqual(const XTensor & a, XTensor & b, DTYPE value);
/* return maximum of two tensor for each items */
void _Max(const XTensor * a, const XTensor * b, XTensor * c);
/* return maximum of two tensor for each items (do it on site) */
void _MaxMe(XTensor * a, const XTensor * b);
/* return maximum of two tensor for each items (do it on site) */
void MaxMe(XTensor & a, const XTensor & b);
/* return maximum of two tensor for each items (return an XTensor structure) */
XTensor Max(const XTensor & a, const XTensor & b);
/* return maximum of two tensor for each items */
void Max(const XTensor & a, const XTensor & b, XTensor & c);
/* return minimum of two tensor for each items */
void _Min(const XTensor * a, const XTensor * b, XTensor * c);
/* return minimum of two tensor for each items (do it on site) */
void _MinMe(XTensor * a, const XTensor * b);
/* return minimum of two tensor for each items (do it on site) */
void MinMe(XTensor & a, const XTensor & b);
/* return minimum of two tensor for each items (return an XTensor structure) */
XTensor Min(const XTensor & a, const XTensor & b);
/* return minimum of two tensor for each items */
void Min(const XTensor & a, const XTensor & b, XTensor & c);
} // namespace nts(NiuTrans.Tensor)
#endif // end __COMPARE_H__
\ No newline at end of file
......@@ -173,9 +173,11 @@ XTensor Normalize(const XTensor &input, int dim,
list.Add((XTensor*)&var);
list.Add((XTensor*)&a);
list.Add((XTensor*)&b);
if (input.enableGrad) {
XLink::MakeLink(&list, &output, MATH_NORMALIZE);
XLink::AddParamToHeadInt(&output, dim);
XLink::AddParamToHead(&output, epsilon);
}
return output;
}
......@@ -208,7 +210,7 @@ void Normalize(const XTensor &input, XTensor &output, int dim,
/* call _Normalize function */
_Normalize(&input, &output, dim, &mean, &var, &a, &b, epsilon);
if (output.enableGrad == true) {
if (input.enableGrad == true) {
/* tensor connections */
TensorList list(5);
list.Add((XTensor*)&input);
......
......@@ -126,9 +126,11 @@ XTensor ScaleAndShift(const XTensor &a, DTYPE scale, DTYPE shift)
_ScaleAndShift(&a, &b, scale, shift);
/* tensor connections */
if (a.enableGrad) {
XLink::MakeLink(&a, NULL, &b, MATH_SCALEANDSHIFT);
XLink::AddParamToHead(&b, scale);
XLink::AddParamToHead(&b, shift);
}
return b;
}
......@@ -152,7 +154,7 @@ void ScaleAndShift(const XTensor & a, XTensor & b, DTYPE scale, DTYPE shift)
/* call _ScaleAndShift function */
_ScaleAndShift(&a, &b, scale, shift);
if (b.enableGrad) {
if (a.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, NULL, &b, MATH_SCALEANDSHIFT);
XLink::AddParamToHead(&b, scale);
......
......@@ -151,7 +151,9 @@ XTensor funcName(const XTensor & a)
XTensor b(&a); \
b.SetTMPFlag(); \
_funcName(&a, &b); \
if(a.enableGrad){ \
XLink::MakeLink(&a, NULL, &b, operationId); \
} \
return b; \
}
......@@ -162,7 +164,7 @@ void funcName(const XTensor & a, XTensor & b)
InitTensor(&b, &a); \
} \
_funcName(&a, &b); \
if (b.enableGrad) { \
if (a.enableGrad) { \
XLink::MakeLink(&a, NULL, &b, operationId); \
} \
}
......
......@@ -258,9 +258,11 @@ XTensor CopyIndexed(const XTensor & s, int dim,
list.Add((XTensor*)&tgtIndex);
/* tensor connection */
if (s.enableGrad) {
XLink::MakeLink(&list, &t, MOVEMENT_COPYINDEXED);
XLink::AddParamToHeadInt(&t, dim);
XLink::AddParamToHeadInt(&t, copyNum);
}
/* destroy variables */
delete[] dimSize;
......@@ -314,12 +316,14 @@ XTensor CopyIndexed(const XTensor &s, int dim, int * srcIndex, int indexSize, in
memcpy(saveTgtIndex, tgtIndex, indexSize * sizeof(int));
/* tensor connection */
if (s.enableGrad) {
XLink::MakeLink(&s, NULL, &t, MOVEMENT_COPYINDEXED);
XLink::AddParamToHeadInt(&t, dim);
XLink::AddParamToHeadPointer(&t, saveSrcIndex);
XLink::AddParamToHeadInt(&t, indexSize);
XLink::AddParamToHeadPointer(&t, saveTgtIndex);
XLink::AddParamToHeadInt(&t, copyNum);
}
/* destroy variables */
delete[] dimSize;
......
......@@ -134,7 +134,9 @@ XTensor CopyValues(const XTensor &s, XStream * stream)
_CopyValues(&s, &t, stream);
/* tensor connection */
if (s.enableGrad) {
XLink::MakeLink(&s, NULL, &t, MOVEMENT_COPYVALUES);
}
return t;
}
......
......@@ -93,7 +93,9 @@ XTensor Gather(XTensor &s, XTensor &index)
_Gather(&s, &t, &index);
/* tensor connection */
if (s.enableGrad) {
XLink::MakeLink(&s, &index, &t, MOVEMENT_GATHER);
}
return t;
}
......
......@@ -21,6 +21,8 @@
#include "../../XTensor.h"
#include "../../XName.h"
#include "../../XBLAS.h"
#include "VectorBuffer.h"
#include "ReduceMax.h"
#include "ReduceMax.cuh"
......@@ -76,11 +78,67 @@ void _ReduceMax(const XTensor * input, XTensor * output, int dim)
}
blockSize = stride * strideNum;
if(input->dimSizeRDI[0] % (4 * 32 / sizeof(DTYPE)) == 0 && input->dimSizeRDI[0] >= 32){
int vecBufLength = 32 / sizeof(DTYPE);
if(dimRDI == 0){
//data is contiguous in dim 0
for(int i = 0; i < blockNum; i++){
DTYPE * ip = (DTYPE*)input->data + blockSize * i;
DTYPE * op = (DTYPE*)output->data + i;
VectorBuffer vecBuf[4];
for(int j = 0; j < 4; j++){
vecBuf[j] = VectorBuffer::loadu((DTYPE*)(ip) + j * vecBufLength);
}
for(int j = 1; j < strideNum / 32; j++){
const DTYPE* ptr = (DTYPE*)(ip + j * vecBufLength);
vecBuf[0] = vecBuf[0].maxData(VectorBuffer::loadu(ptr + 0 * vecBufLength));
vecBuf[1] = vecBuf[1].maxData(VectorBuffer::loadu(ptr + 1 * vecBufLength));
vecBuf[2] = vecBuf[2].maxData(VectorBuffer::loadu(ptr + 2 * vecBufLength));
vecBuf[3] = vecBuf[3].maxData(VectorBuffer::loadu(ptr + 3 * vecBufLength));
}
vecBuf[0] = vecBuf[0].maxData(vecBuf[1]);
vecBuf[0] = vecBuf[0].maxData(vecBuf[2]);
vecBuf[0] = vecBuf[0].maxData(vecBuf[3]);
DTYPE maxN = DTYPE_MIN;
for(int k = 0; k < vecBufLength; k++){
maxN = MAX(maxN,vecBuf[0][k]);
}
*op = maxN;
}
} else{
//data is separated
for(int i = 0; i < blockNum; i++){
for(int j = 0; j < input->dimSizeRDI[0] / 32; j++){
DTYPE * ip = (DTYPE*)input->data + blockSize * i;
DTYPE * op = (DTYPE*)output->data + stride * i;
VectorBuffer vecBuf[4];
for(int k = 0; k < 4; k++){
vecBuf[k] = VectorBuffer::loadu((DTYPE*)(ip) + (j * 4 + k) * 32 / sizeof(DTYPE));
}
for(int k = 1; k < strideNum; k++){
DTYPE * ptr = ip + k * stride + (j * 4) * vecBufLength;
vecBuf[0] = vecBuf[0].maxData(VectorBuffer::loadu(ptr + 0 * vecBufLength));
vecBuf[1] = vecBuf[1].maxData(VectorBuffer::loadu(ptr + 1 * vecBufLength));
vecBuf[2] = vecBuf[2].maxData(VectorBuffer::loadu(ptr + 2 * vecBufLength));
vecBuf[3] = vecBuf[3].maxData(VectorBuffer::loadu(ptr + 3 * vecBufLength));
}
for(int k = 0; k < 4; k++){
for(int l = 0; l < vecBufLength; l++)
*(op + j * 32 + 8 * k + l) = vecBuf[k][l];
}
}
}
}
}//run vector buffer
else{
for(int k = 0; k < blockNum; k++){
DTYPE * ip = (DTYPE*)input->data + blockSize * k;
DTYPE * op = (DTYPE*)output->data + stride * k;
for(int i = 0; i < stride; i++){
DTYPE max = FLOAT_MIN;
DTYPE max = DTYPE_MIN;
DTYPE * ipe = ip + blockSize;
for(DTYPE * ipb = ip + i; ipb < ipe; ipb += stride){
DTYPE v = *ipb;
......@@ -91,6 +149,7 @@ void _ReduceMax(const XTensor * input, XTensor * output, int dim)
}
}
}
}
}
/*
......@@ -122,8 +181,10 @@ XTensor ReduceMax(const XTensor &input, int dim)
_ReduceMax(&input, &output, dim);
/* tensor connection */
if (input.enableGrad) {
XLink::MakeLink(&input, NULL, &output, REDUCE_REDUCEMAX);
XLink::AddParamToHeadInt(&output, dim);
}
/* destroy variables */
delete[] dimSize;
......@@ -162,7 +223,7 @@ void ReduceMax(const XTensor &input, XTensor &output, int dim)
/* call _ReduceMax function */
_ReduceMax(&input, &output, dim);
if (output.enableGrad) {
if (input.enableGrad) {
/* tensor connections */
XLink::MakeLink(&input, NULL, &output, REDUCE_REDUCEMAX);
XLink::AddParamToHeadInt(&output, dim);
......
......@@ -77,8 +77,10 @@ XTensor ReduceMean(const XTensor &input, int dim)
_ReduceMean(&input, &output, dim);
/* tensor connection */
if (input.enableGrad) {
XLink::MakeLink(&input, NULL, &output, REDUCE_REDUCEMEAN);
XLink::AddParamToHeadInt(&output, dim);
}
/* destroy variables */
delete[] dimSize;
......@@ -119,7 +121,7 @@ void ReduceMean(const XTensor &input, XTensor &output, int dim)
/* call _ReduceMean function */
_ReduceMean(&input, &output, dim);
if (output.enableGrad) {
if (input.enableGrad) {
/* tensor connections */
XLink::MakeLink(&input, NULL, &output, REDUCE_REDUCEMEAN);
XLink::AddParamToHeadInt(&output, dim);
......
......@@ -23,6 +23,9 @@
#include "ReduceSum.h"
#include "ReduceSum.cuh"
#include "../../XName.h"
#include "../../XBLAS.h"
#include "VectorBuffer.h"
#include <iostream>
namespace nts{ // namespace nts(NiuTrans.Tensor)
......@@ -82,6 +85,74 @@ void _ReduceSum(const XTensor * input, XTensor * output, int dim, const XTensor
}
blockSize = stride * strideNum;
if(input->dimSizeRDI[0] % (4 * 32 / sizeof(DTYPE)) == 0 && input->dimSizeRDI[0] >= 32){
int vecBufLength = 32 / sizeof(DTYPE);
if(dimRDI == 0){
//data is contiguous in dim 0
for(int i = 0; i < blockNum; i++){
// stride = 1
DTYPE * ip = (DTYPE*)input->data + blockSize * i;
DTYPE * op = (DTYPE*)output->data + i;
DTYPE * sp = shift != NULL ? (DTYPE*)shift->data + i : NULL;
DTYPE bias[32 / sizeof(DTYPE)] = {0};
if(shift != NULL){
for(int k = 0; k < 32 / sizeof(DTYPE); k++)
bias[k] = *(sp);
}
VectorBuffer vecBuf[4];
for(int j = 0; j < 4; j++){
vecBuf[j] = VectorBuffer::loadu((DTYPE*)(ip) + j * vecBufLength, isExp, power, bias);
}
for(int j = 1; j < strideNum / 32; j++){
const DTYPE* ptr = (DTYPE*)(ip + j * vecBufLength);
vecBuf[0] = vecBuf[0] + VectorBuffer::loadu(ptr + 0 * vecBufLength, isExp, power, bias);
vecBuf[1] = vecBuf[1] + VectorBuffer::loadu(ptr + 1 * vecBufLength, isExp, power, bias);
vecBuf[2] = vecBuf[2] + VectorBuffer::loadu(ptr + 2 * vecBufLength, isExp, power, bias);
vecBuf[3] = vecBuf[3] + VectorBuffer::loadu(ptr + 3 * vecBufLength, isExp, power, bias);
}
vecBuf[0] = ((vecBuf[0] + vecBuf[1]) + (vecBuf[2] + vecBuf[3]));
DTYPE sum = (DTYPE) 0.0;
for(int k = 0; k < vecBufLength; k++){
sum = sum + vecBuf[0][k];
}
*op = sum;
}
} else{
//data is separated
for(int i = 0; i < blockNum; i++){
for(int j = 0; j < input->dimSizeRDI[0] / 32; j++){
DTYPE * ip = (DTYPE*)input->data + blockSize * i;
DTYPE * op = (DTYPE*)output->data + stride * i;
DTYPE * sp = shift != NULL ? (DTYPE*)shift->data + stride * i : NULL;
DTYPE bias[4 * 32 / sizeof(DTYPE)] = {0};
if(shift != NULL){
for(int k = 0; k < 4 * 32 / sizeof(DTYPE); k++)
bias[k] = *(sp + k);
}
VectorBuffer vecBuf[4];
for(int k = 0; k < 4; k++){
vecBuf[k] = VectorBuffer::loadu((DTYPE*)(ip) + (j * 4 + k) * 32 / sizeof(DTYPE), isExp, power, bias + j * 32 / sizeof(DTYPE));
}
for(int k = 1; k < strideNum; k++){
DTYPE * ptr = ip + k * stride + (j * 4) * vecBufLength;
vecBuf[0] = vecBuf[0] + VectorBuffer::loadu(ptr + 0 * vecBufLength, isExp, power, bias);
vecBuf[1] = vecBuf[1] + VectorBuffer::loadu(ptr + 1 * vecBufLength, isExp, power, bias + 1 * vecBufLength);
vecBuf[2] = vecBuf[2] + VectorBuffer::loadu(ptr + 2 * vecBufLength, isExp, power, bias + 2 * vecBufLength);
vecBuf[3] = vecBuf[3] + VectorBuffer::loadu(ptr + 3 * vecBufLength, isExp, power, bias + 3 * vecBufLength);
}
for(int k = 0; k < 4; k++){
for(int l = 0; l < vecBufLength; l++)
*(op + j * 32 + 8 * k + l) = vecBuf[k][l];
}
}
}
}
}//run vector buffer
else{
for(int k = 0; k < blockNum; k++){
DTYPE * ip = (DTYPE*)input->data + blockSize * k;
DTYPE * op = (DTYPE*)output->data + stride * k;
......@@ -195,6 +266,8 @@ void _ReduceSum(const XTensor * input, XTensor * output, int dim, const XTensor
}
}
}
}
}
/*
......@@ -233,10 +306,12 @@ XTensor ReduceSum(const XTensor &input, int dim, const XTensor &shift, DTYPE pow
_ReduceSum(&input, &output, dim, &shift, power, isExp);
/* tensor connection */
if (input.enableGrad) {
XLink::MakeLink(&input, &shift, &output, REDUCE_REDUCESUM);
XLink::AddParamToHeadInt(&output, dim);
XLink::AddParamToHead(&output, power);
XLink::AddParamToHeadBool(&output, isExp);
}
/* destroy variables */
delete[] dimSize;
......@@ -268,7 +343,7 @@ void ReduceSum(const XTensor &input, XTensor &output, int dim, const XTensor &sh
/* call _ReduceSum function */
_ReduceSum(&input, &output, dim, &shift, power, isExp);
if (output.enableGrad) {
if (input.enableGrad) {
/* tensor connections */
XLink::MakeLink(&input, &shift, &output, REDUCE_REDUCESUM);
XLink::AddParamToHeadInt(&output, dim);
......@@ -312,10 +387,12 @@ XTensor ReduceSum(const XTensor &input, int dim, DTYPE power, bool isExp)
_ReduceSum(&input, &output, dim, NULL, power, isExp);
/* tensor connection */
if (input.enableGrad) {
XLink::MakeLink(&input, NULL, &output, REDUCE_REDUCESUM);
XLink::AddParamToHeadInt(&output, dim);
XLink::AddParamToHead(&output, power);
XLink::AddParamToHeadBool(&output, isExp);
}
/* destroy variables */
delete[] dimSize;
......@@ -361,7 +438,7 @@ void ReduceSum(const XTensor &input, XTensor &output, int dim, DTYPE power, bool
/* call _ReduceSum function */
_ReduceSum(&input, &output, dim, NULL, power, isExp);
if (output.enableGrad) {
if (input.enableGrad) {
/* tensor connections */
XLink::MakeLink(&input, NULL, &output, REDUCE_REDUCESUM);
XLink::AddParamToHeadInt(&output, dim);
......
......@@ -73,8 +73,10 @@ XTensor ReduceSumSquared(const XTensor &input, int dim, const XTensor &shift)
_ReduceSumSquared(&input, &output, dim, &shift);
/* tensor connection */
if (input.enableGrad) {
XLink::MakeLink(&input, &shift, &output, REDUCE_REDUCESUMSQUARED);
XLink::AddParamToHeadInt(&output, dim);
}
/* destroy variables */
delete[] dimSize;
......@@ -116,7 +118,7 @@ void ReduceSumSquared(const XTensor &input, XTensor &output, int dim, const XTen
/* call _ReduceSumSquared function */
_ReduceSumSquared(&input, &output, dim, &shift);
if (output.enableGrad) {
if (input.enableGrad) {
/* tensor connections */
XLink::MakeLink(&input, &shift, &output, REDUCE_REDUCESUMSQUARED);
XLink::AddParamToHeadInt(&output, dim);
......
......@@ -76,8 +76,10 @@ XTensor ReduceVariance(const XTensor &input, int dim, const XTensor &mean)
_ReduceVariance(&input, &output, dim, &mean);
/* tensor connection */
if (input.enableGrad) {
XLink::MakeLink(&input, &mean, &output, REDUCE_REDUCEVARIANCE);
XLink::AddParamToHeadInt(&output, dim);
}
/* destroy variables */
delete[] dimSize;
......@@ -119,7 +121,7 @@ void ReduceVariance(const XTensor &input, XTensor &output, int dim, const XTenso
/* call _ReduceVariance function */
_ReduceVariance(&input, &output, dim, &mean);
if (output.enableGrad) {
if (input.enableGrad) {
/* tensor connection */
XLink::MakeLink(&input, &mean, &output, REDUCE_REDUCEVARIANCE);
XLink::AddParamToHeadInt(&output, dim);
......
/* NiuTrans.Tensor - an open-source tensor library
* Copyright (C) 2017, Natural Language Processing Lab, Northestern University.
* All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*
* $Created by: ZHANG Yuhao (email: zhangyuhao@stu.neu.edu.cn) 2019-07-23
*/
#include "VectorBuffer.h"
namespace nts {
/* data size for each buffer */
int VectorBuffer::size()
{
return 32 / sizeof(DTYPE);
}
/* constructor */
VectorBuffer::VectorBuffer()
{
}
/*
constructor
initial values with val
*/
VectorBuffer::VectorBuffer(DTYPE val)
{
for (int i = 0; i != size(); i++) {
values[i] = val;
}
}
/* load data */
VectorBuffer VectorBuffer::loadu(const DTYPE* ptr, bool isExp , DTYPE power , DTYPE* bias )
{
int count = 32 / sizeof(DTYPE);
VectorBuffer vec;
if (isExp) {
if (bias == NULL) {
if (power == (DTYPE)1.0) {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)exp(*(ptr + i));
}
}
else if (power == (DTYPE)2.0) {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)exp((*(ptr + i)) * (*(ptr + i)));
}
}
else if (power == (DTYPE)0.5) {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)exp(sqrt(*(ptr + i)));
}
}
else {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)exp(pow(*(ptr + i), power));
}
}
}/*is bias == NULL*/
else {
if (power == (DTYPE)1.0) {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)exp(*(ptr + i) - bias[i]);
}
}
else if (power == (DTYPE)2.0) {
for (int i = 0; i != count; i++) {
DTYPE value = *(ptr + i) - bias[i];
vec.values[i] = (DTYPE)exp(value * value);
}
}
else if (power == (DTYPE)0.5) {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)exp(sqrt(*(ptr + i) - bias[i]));
}
}
else {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)exp(pow(*(ptr + i) - bias[i], power));
}
}
}
}//isExp
else {
if (bias == NULL) {
if (power == (DTYPE)1.0) {
memcpy(vec.values, ptr, count * sizeof(DTYPE));
}
else if (power == (DTYPE)2.0) {
for (int i = 0; i != count; i++) {
vec.values[i] = (*(ptr + i)) * (*(ptr + i));
}
}
else if (power == (DTYPE)0.5) {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)sqrt(*(ptr + i));
}
}
else {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)pow(*(ptr + i), power);
}
}
}// if bias == NULL
else {
if (power == (DTYPE)1.0) {
for (int i = 0; i != count; i++) {
vec.values[i] = *(ptr + i) - bias[i];
}
}
else if (power == (DTYPE)2.0) {
for (int i = 0; i != count; i++) {
DTYPE value = *(ptr + i) - bias[i];
vec.values[i] = value * value;
}
}
else if (power == (DTYPE)0.5) {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)sqrt(*(ptr + i) - bias[i]);
}
}
else {
for (int i = 0; i != count; i++) {
vec.values[i] = (DTYPE)pow(*(ptr + i) - bias[i], power);
}
}
}
}
return vec;
}
/* overloading [] */
const DTYPE& VectorBuffer::operator[](int idx)const
{
return values[idx];
}
/* overloading + */
VectorBuffer VectorBuffer::operator+(const VectorBuffer &a)
{
for (int i = 0; i != a.size(); i++) {
this->values[i] = a[i] + this->values[i];
}
return *this;
}
/* conculte the max of two buffer */
VectorBuffer VectorBuffer::maxData(const VectorBuffer &a) {
for (int i = 0; i != a.size(); i++) {
this->values[i] = MAX(a[i], this->values[i]);
}
return *this;
}
}/* end of the nts (NiuTrans.Tensor) namespace */
\ No newline at end of file
/* NiuTrans.Tensor - an open-source tensor library
* Copyright (C) 2017, Natural Language Processing Lab, Northestern University.
* All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*
* $Created by: ZHANG Yuhao (email: zhangyuhao@stu.neu.edu.cn) 2019-07-23
*/
//#include <cstring>
#include <math.h>
#include "../../XGlobal.h"
namespace nts {
class VectorBuffer {
private:
/* buffer for concluter */
DTYPE values[32 / sizeof(DTYPE)] = { 0 };
public:
/* data size for each buffer */
static int size();
/* constructor */
VectorBuffer();
/* constructor */
VectorBuffer(DTYPE val);
/* load data */
static VectorBuffer loadu(const DTYPE* ptr, bool isExp = false, DTYPE power = (DTYPE)1.0F, DTYPE* bias = NULL);
/* overloading [] */
const DTYPE& operator[](int idx)const;
/* overloading + */
VectorBuffer operator+(const VectorBuffer &a);
/* conculte the max of two buffer */
VectorBuffer maxData(const VectorBuffer &a);
};
}
\ No newline at end of file
......@@ -99,8 +99,10 @@ XTensor Concatenate(const TensorList &smalls, int dim)
_Merge(&smalls, &big, dim);
/* tensor connection */
if (tensor->enableGrad) {
XLink::MakeLink(&smalls, &big, SHAPE_MERGE);
XLink::AddParamToHeadInt(&big, dim);
}
/* destroy variables */
delete[] dimSize;
......@@ -127,8 +129,10 @@ XTensor Concatenate(const TensorList &smalls, int dim)
_ConcatenateSolely(&smalls, &big, dim);
/* tensor connection */
if (tensor->enableGrad) {
XLink::MakeLink(&smalls, &big, SHAPE_CONCATENATE);
XLink::AddParamToHeadInt(&big, dim);
}
/* destroy variables */
delete[] dimSize;
......@@ -309,8 +313,10 @@ XTensor Concatenate(const XTensor &smallA, const XTensor &smallB, int dim)
_Merge(&smalls, &big, dim);
/* tensor connection */
if (tensor->enableGrad) {
XLink::MakeLink(&smalls, &big, SHAPE_MERGE);
XLink::AddParamToHeadInt(&big, dim);
}
/* destroy variables */
delete[] dimSize;
......@@ -337,8 +343,10 @@ XTensor Concatenate(const XTensor &smallA, const XTensor &smallB, int dim)
_ConcatenateSolely(&smalls, &big, dim);
/* tensor connection */
if (tensor->enableGrad) {
XLink::MakeLink(&smalls, &big, SHAPE_CONCATENATE);
XLink::AddParamToHeadInt(&big, dim);
}
/* destroy variables */
delete[] dimSize;
......
......@@ -222,9 +222,11 @@ XTensor Merge(const XTensor &s, int whereToMerge, int leadingDim)
_Merge(&s, &t, whereToMerge, leadingDim);
/* tensor connections */
if (s.enableGrad) {
XLink::MakeLink(&s, NULL, &t, SHAPE_MERGE);
XLink::AddParamToHeadInt(&t, whereToMerge);
XLink::AddParamToHeadInt(&t, leadingDim);
}
/* destroy variables */
delete[] dimSize;
......@@ -261,7 +263,7 @@ void Merge(const XTensor &s, XTensor &t, int whereToMerge, int leadingDim)
/* call _Merge function */
_Merge(&s, &t, whereToMerge, leadingDim);
if (t.enableGrad) {
if (s.enableGrad) {
/* tensor connections */
XLink::MakeLink(&s, NULL, &t, SHAPE_MERGE);
XLink::AddParamToHeadInt(&t, whereToMerge);
......@@ -412,8 +414,10 @@ XTensor Merge(const TensorList &smalls, int whereToMerge)
_Merge(&smalls, &big, whereToMerge);
/* tensor connections */
if (tensor->enableGrad) {
XLink::MakeLink(&smalls, &big, SHAPE_MERGE_LIST);
XLink::AddParamToHeadInt(&big, whereToMerge);
}
/* destroy variables */
delete[] dimSize;
......@@ -453,8 +457,10 @@ XTensor Merge(const XTensor &smallA, const XTensor &smallB, int whereToMerge)
_Merge(&smalls, &big, whereToMerge);
/* tensor connections */
if (smallA.enableGrad) {
XLink::MakeLink(&smalls, &big, SHAPE_MERGE_LIST);
XLink::AddParamToHeadInt(&big, whereToMerge);
}
/* destroy variables */
delete[] dimSize;
......
......@@ -43,7 +43,9 @@ XTensor Reshape(XTensor &s, int order, int * dimSize)
t.Reshape(order, dimSize);
/* tensor connections */
if (s.enableGrad) {
XLink::MakeLink(&s, NULL, &t, SHAPE_RESHAPE);
}
return t;
}
......@@ -57,7 +59,7 @@ void Reshape(XTensor &s, XTensor &t, int order, int * dimSize)
/* call Reshape function */
t.Reshape(order, dimSize);
if (t.enableGrad) {
if (s.enableGrad) {
/* tensor connections */
XLink::MakeLink(&s, NULL, &t, SHAPE_RESHAPE);
}
......
......@@ -217,9 +217,11 @@ XTensor Split(const XTensor &s, int whereToSplit, int splitNum)
_Split(&s, &t, whereToSplit, splitNum);
/* tensor connections */
if (s.enableGrad) {
XLink::MakeLink(&s, NULL, &t, SHAPE_SPLIT);
XLink::AddParamToHeadInt(&t, whereToSplit);
XLink::AddParamToHeadInt(&t, splitNum);
}
/* destroy variables */
delete[] dimSize;
......@@ -251,7 +253,7 @@ void Split(const XTensor &s, XTensor &t, int whereToSplit, int splitNum)
/* call _Split function */
_Split(&s, &t, whereToSplit, splitNum);
if (t.enableGrad) {
if (s.enableGrad) {
/* tensor connections */
XLink::MakeLink(&s, NULL, &t, SHAPE_SPLIT);
XLink::AddParamToHeadInt(&t, whereToSplit);
......@@ -409,6 +411,8 @@ void Split(const XTensor &big, TensorList &smalls, int whereToSplit, int splitNu
/* tensor connections */
for(int i = 0; i < smalls.count; i++){
XTensor * s = (XTensor*)smalls.Get(i);
if (s->enableGrad) {
XLink::MakeLink(&big, NULL, s, SHAPE_SPLIT_LIST);
XLink::AddParamToHeadInt(s, whereToSplit);
......@@ -416,6 +420,7 @@ void Split(const XTensor &big, TensorList &smalls, int whereToSplit, int splitNu
block, rather than the total number of the splits */
XLink::AddParamToHeadInt(s, i);
}
}
}
} // namespace nts(NiuTrans.Tensor)
......@@ -121,7 +121,9 @@ XTensor Squeeze(XTensor & source, int leadingDim)
_Squeeze(&source, &target, leadingDim);
/* tensor connections */
if (source.enableGrad) {
XLink::MakeLink(&source, NULL, &target, SHAPE_SQUEEZE);
}
return target;
}
......@@ -135,7 +137,7 @@ void Squeeze(XTensor & source, XTensor & target, int leadingDim)
/* call _Squeeze function */
_Squeeze(&source, &target, leadingDim);
if (target.enableGrad) {
if (source.enableGrad) {
/* tensor connections */
XLink::MakeLink(&source, NULL, &target, SHAPE_SQUEEZE);
}
......
......@@ -144,9 +144,11 @@ XTensor Transpose(const XTensor &a, const int i, const int j)
_Transpose(&a, &b, i, j);
/* tensor connection */
if (a.enableGrad) {
XLink::MakeLink(&a, NULL, &b, SHAPE_TRANSPOSE);
XLink::AddParamToHeadInt(&b, i);
XLink::AddParamToHeadInt(&b, j);
}
/* destroy variables */
delete[] dimSize;
......
......@@ -156,9 +156,11 @@ XTensor Unsqueeze(const XTensor &a, int dim, int dSize)
_Unsqueeze(&a, &b, dim, dSize);
/* tensor connections */
if (a.enableGrad) {
XLink::MakeLink(&a, NULL, &b, SHAPE_UNSQUEEZE);
XLink::AddParamToHeadInt(&b, dim);
XLink::AddParamToHeadInt(&b, dSize);
}
/* destroy variables */
delete[] dimSize;
......@@ -191,7 +193,7 @@ void Unsqueeze(const XTensor &a, XTensor &b, int dim, int dSize)
/* call _Unsqueeze function */
_Unsqueeze(&a, &b, dim, dSize);
if (b.enableGrad) {
if (a.enableGrad) {
/* tensor connections */
XLink::MakeLink(&a, NULL, &b, SHAPE_UNSQUEEZE);
XLink::AddParamToHeadInt(&b, dim);
......
......@@ -377,8 +377,8 @@ get the top-k items
template<class T> __global__
void KernelTopK3(T * input, int stride, int strideNum, int blockNum, int k, T minValue, T * output, int * index)
{
__shared__ CudaHeapNode<T> heapData[(SHARED_MEMORY_SIZE - 1024 * sizeof(T)) / sizeof(CudaHeapNode<T>)];
__shared__ T eachHeapMaxValue[1024];
__shared__ CudaHeapNode<T> heapData[(SHARED_MEMORY_SIZE - 512 * sizeof(T)) / sizeof(CudaHeapNode<T>)];
__shared__ T eachHeapMaxValue[512];
/*optimization k size the parameter must more than half of k*/
int parameter = 0;
......@@ -429,7 +429,7 @@ void KernelTopK3(T * input, int stride, int strideNum, int blockNum, int k, T mi
}
__syncthreads();
/*to merge the heap use another way*/
/* to merge the heap use another way */
T minData = minValue;
int heapLimit = heap.count / 2;
if (heapLimit % 2 == 0 && heapLimit != 0) heapLimit -= 1;
......@@ -438,12 +438,13 @@ void KernelTopK3(T * input, int stride, int strideNum, int blockNum, int k, T mi
minData = heap.items[counter].value;
}
eachHeapMaxValue[threadIdx.y * blockDim.x + threadIdx.x] = minData;
//need more optimation
if (i == 0) {
int threadLimit = (threadIdx.y + 1) * blockDim.x;
int threadLimit = threadIdx.y * blockDim.x + min(blockDim.x,strideNum);
CudaXHeap<MIN_HEAP, T> chooseHeap(k, heapData + k * ((blockDim.x * blockDim.y) + threadIdx.y));
int counter = threadIdx.y * blockDim.x;
for (; counter < threadIdx.y * blockDim.x + k; ++counter) {
for (; counter < threadIdx.y * blockDim.x + min(k, blockDim.x); ++counter) {
chooseHeap.Push(counter, eachHeapMaxValue[counter]);
}
for (; counter < threadLimit; ++counter) {
......@@ -451,15 +452,16 @@ void KernelTopK3(T * input, int stride, int strideNum, int blockNum, int k, T mi
chooseHeap.ReplaceTop(counter, eachHeapMaxValue[counter]);
}
}
int heapNum = chooseHeap.count;
CudaXHeap<MIN_HEAP, T> ansHeapData(k, k - parameter, heapData + k * chooseHeap.items[0].index);
int miss = parameter;
for (counter = 1; counter < k; ++counter) {
for (counter = 1; counter < heapNum; ++counter) {
chooseHeap.items[0] = chooseHeap.items[chooseHeap.count - 1];
chooseHeap.count--;
chooseHeap.Down(0);
CudaHeapNode<T> * cmpHeapData = heapData + k * (chooseHeap.items[0].index);
int cmpHeapLimit = 0;
if (counter + heapLimit <= k - parameter){
if (counter + heapLimit <= k - parameter && heapNum == k){
cmpHeapLimit = heapLimit;
}
/* take the max data from the minHeap,so start search from the leaf node */
......@@ -840,7 +842,7 @@ void _CudaTopK(const XTensor * a, XTensor * b, XTensor * index, int dim, int k)
/* we run the kernel if the heaps can fit into the shared memory */
cudaGrids[1] *= cudaBlocks[1];
cudaBlocks[1] = 1;
if ((cudaBlocks[0] * cudaBlocks[1] + 1) * k * (a->unitSize + sizeof(int)) < SHARED_MEMORY_SIZE) {
if ((cudaBlocks[0] * cudaBlocks[1] + 1) * k * (a->unitSize + sizeof(int)) + (512 * sizeof(int))< SHARED_MEMORY_SIZE) {
if (a->dataType == DEFAULT_DTYPE) {
KernelTopK3<DTYPE> <<<dim3(cudaGrids[0], cudaGrids[1]), dim3(cudaBlocks[0], cudaBlocks[1]) >>>
((DTYPE*)a->data, stride, strideNumA, blockNum, k, DTYPE_MIN,
......@@ -869,7 +871,7 @@ void _CudaTopK(const XTensor * a, XTensor * b, XTensor * index, int dim, int k)
//delete indexA;
int workerNum = WORKERSNUM;
GDevs.GetCudaThread2D(a->mem->devID,
GDevs.GetCudaThread2D(a->devID,
workerNum, stride * blockNum, MAX_INT,
cudaGrids, cudaBlocks);
if (a->dataType == DEFAULT_DTYPE) {
......
......@@ -81,8 +81,10 @@ XTensor DropoutWithIndex(const XTensor &x, XTensor &maskIndex, DTYPE scale)
_ScaleAndShiftMe(&c, scale);
/* tensor connections */
if (x.enableGrad) {
XLink::MakeLink(&x, &maskIndex, &c, MOVEMENT_DROPOUTWITHINDEX);
XLink::AddParamToHead(&c, scale);
}
return c;
}
......
......@@ -78,7 +78,9 @@ XTensor HardTanH(const XTensor &x)
_HardTanH(&x, &y);
/* tensor connection */
if (x.enableGrad) {
XLink::MakeLink(&x, NULL, &y, FUNC_HARDTANH);
}
return y;
}
......@@ -92,7 +94,7 @@ void HardTanH(const XTensor &x, XTensor &y)
/* call _HardTanH function */
_HardTanH(&x, &y);
if (y.enableGrad) {
if (x.enableGrad) {
/* tensor connection */
XLink::MakeLink(&x, NULL, &y, FUNC_HARDTANH);
}
......
......@@ -54,7 +54,9 @@ XTensor Identity(const XTensor &x)
_Identity(&x, &y);
/* tensor connection */
if (x.enableGrad) {
XLink::MakeLink(&x, NULL, &y, FUNC_IDENTITY);
}
return y;
}
......@@ -68,7 +70,7 @@ void Identity(const XTensor &x, XTensor &y)
/* call _Identity function */
_Identity(&x, &y);
if (y.enableGrad) {
if (x.enableGrad) {
/* tensor connection */
XLink::MakeLink(&x, NULL, &y, FUNC_IDENTITY);
}
......
......@@ -188,8 +188,10 @@ XTensor LogSoftmax(const XTensor &x, int leadDim)
_LogSoftmax(&x, &y, ld);
/* tensor connection */
if (x.enableGrad) {
XLink::MakeLink(&x, NULL, &y, FUNC_LOGSOFTMAX);
XLink::AddParamToHeadInt(&y, ld);
}
return y;
}
......@@ -215,7 +217,7 @@ void LogSoftmax(const XTensor &x, XTensor &y, int leadDim)
/* call _LogSoftmax function */
_LogSoftmax(&x, &y, ld);
if (y.enableGrad) {
if (x.enableGrad) {
/* tensor connection */
XLink::MakeLink(&x, NULL, &y, FUNC_LOGSOFTMAX);
XLink::AddParamToHeadInt(&y, ld);
......
......@@ -70,7 +70,9 @@ XTensor Rectify(const XTensor &x)
_Rectify(&x, &y);
/* tensor connection */
if (x.enableGrad) {
XLink::MakeLink(&x, NULL, &y, FUNC_RECTIFY);
}
return y;
}
......@@ -84,7 +86,7 @@ void Rectify(const XTensor &x, XTensor &y)
/* call _Rectify function */
_Rectify(&x, &y);
if (y.enableGrad) {
if (x.enableGrad) {
/* tensor connection */
XLink::MakeLink(&x, NULL, &y, FUNC_RECTIFY);
}
......
......@@ -73,7 +73,9 @@ XTensor Sigmoid(const XTensor &x)
_Sigmoid(&x, &y);
/* tensor connection */
if (x.enableGrad) {
XLink::MakeLink(&x, NULL, &y, FUNC_SIGMOID);
}
return y;
}
......@@ -87,7 +89,7 @@ void Sigmoid(const XTensor &x, XTensor &y)
/* call _Sigmoid function */
_Sigmoid(&x, &y);
if (y.enableGrad) {
if (x.enableGrad) {
/* tensor connection */
XLink::MakeLink(&x, NULL, &y, FUNC_SIGMOID);
}
......
......@@ -142,8 +142,10 @@ XTensor Softmax(const XTensor &x, int leadDim)
_Softmax(&x, &y, ld);
/* tensor connection */
if (x.enableGrad) {
XLink::MakeLink(&x, NULL, &y, FUNC_SOFTMAX);
XLink::AddParamToHeadInt(&y, ld);
}
return y;
}
......@@ -161,7 +163,7 @@ void Softmax(const XTensor &x, XTensor &y, int leadDim)
/* call _Softmax function */
_Softmax(&x, &y, ld);
if (y.enableGrad) {
if (x.enableGrad) {
/* tensor connection */
XLink::MakeLink(&x, NULL, &y, FUNC_SOFTMAX);
XLink::AddParamToHeadInt(&y, ld);
......
......@@ -277,8 +277,11 @@ XTensor CrossEntropy(const XTensor & output, const XTensor & gold,
tails.Add((XTensor*)&gold);
tails.Add(weight);
tails.Add(padding);
if (output.enableGrad) {
XLink::MakeLink(&tails, &loss, LOSS_CROSSENTROPY);
XLink::AddParamToHeadInt(&loss, dim);
}
return loss;
}
......@@ -302,8 +305,11 @@ XTensor CrossEntropy(const XTensor & output, const XTensor & gold,
tails.Add((XTensor*)&gold);
tails.Add(weight);
tails.Add((XTensor*)&padding);
if (output.enableGrad) {
XLink::MakeLink(&tails, &loss, LOSS_CROSSENTROPY);
XLink::AddParamToHeadInt(&loss, dim);
}
return loss;
}
......
......@@ -406,6 +406,68 @@ bool TestSetData5()
#endif // USE_CUDA
}
/*
case 6: test SetDataRange function.
generate data items with a range by start, end and the step
*/
bool TestSetData6()
{
/* a input tensor of size (5) */
int order = 1;
int * dimSize = new int[order];
dimSize[0] = 5;
int unitNum = 1;
for (int i = 0; i < order; i++)
unitNum *= dimSize[i];
DTYPE answer[5] = {5.2F, 3.2F, 1.2F, -0.8F, -2.8F};
/* CPU test */
bool cpuTest = true;
/* create tensors */
XTensor * s = NewTensor(order, dimSize);
/* initialize variables */
s->SetZeroAll();
/* call _SetDataRange function */
_SetDataRange(s, 5.2, -3.2, -2);
/* check results */
cpuTest = s->CheckData(answer, unitNum, 1e-4F);
#ifdef USE_CUDA
/* GPU test */
bool gpuTest = true;
/* create tensors */
XTensor * sGPU = NewTensor(order, dimSize, X_FLOAT, 1.0F, 0);
/* initialize variables */
sGPU->SetZeroAll();
/* call _SetDataRange function */
_SetDataRange(sGPU, 5.2, -3.2, -2);
gpuTest = sGPU->CheckData(answer, unitNum, 1e-4F);
/* destroy variables */
delete s;
delete sGPU;
delete[] dimSize;
return cpuTest && gpuTest;
#else
/* destroy variables */
delete s;
delete[] dimSize;
return cpuTest;
#endif // USE_CUDA
}
/* other cases */
/*
TODO!!
......@@ -462,6 +524,15 @@ bool TestSetData()
else
XPRINT(0, stdout, ">> case 5 passed!\n");
/* case 6 test */
caseFlag = TestSetData6();
if (!caseFlag) {
returnFlag = false;
XPRINT(0, stdout, ">> case 6 failed!\n");
}
else
XPRINT(0, stdout, ">> case 6 passed!\n");
/* other cases test */
/*
TODO!!
......
......@@ -105,10 +105,62 @@ bool TestTopK1()
TopK(sUser, tUser2, indexUser2, dim, k);
/* check results */
cpuTest = t1->CheckData(tAnswer1, tUnitNum) && tUser1.CheckData(tAnswer1, tUnitNum)
&& t2->CheckData(tAnswer2, tUnitNum) && tUser2.CheckData(tAnswer2, tUnitNum)
&& index1->CheckData(indexAnswer1, tUnitNum) && indexUser1.CheckData(indexAnswer1, tUnitNum)
&& index2->CheckData(indexAnswer2, tUnitNum) && indexUser2.CheckData(indexAnswer2, tUnitNum);
for (int i = 0; i < tDimSize[1]; ++i)
{
for (int j = 0; j < tDimSize[0]; ++j)
{
float tmpData = ((float *)t1->data)[i + tDimSize[1] * j];
int tmpIndex = ((int *)index1->data)[i + tDimSize[1] * j];
float tmpDataUser = ((float *)tUser1.data)[i + tDimSize[1] * j];
int tmpIndexUser = ((int *)indexUser1.data)[i + tDimSize[1] * j];
bool flag = false;
bool flagUser = false;
for (int k = 0; k < tDimSize[0]; ++k)
{
float* ans = tAnswer1[0];
int* ansIndex = indexAnswer1[0];
if (tmpData == ans[i + tDimSize[1] * k] && tmpIndex == ansIndex[i + tDimSize[1] * k])
{
flag = true;
}
if (tmpDataUser == ans[i + tDimSize[1] * k] && tmpIndexUser == ansIndex[i + tDimSize[1] * k])
{
flagUser = true;
}
}
cpuTest = cpuTest&&flag&&flagUser;
}
}
for (int i = 0; i < tDimSize[0]; ++i)
{
for (int j = 0; j < tDimSize[1]; ++j)
{
float tmpData = ((float *)t2->data)[i * tDimSize[1] + j];
int tmpIndex = ((int *)index2->data)[i * tDimSize[1] + j];
float tmpDataUser = ((float *)tUser2.data)[i * tDimSize[1] + j];
int tmpIndexUser = ((int *)indexUser2.data)[i * tDimSize[1] + j];
bool flag = false;
bool flagUser = false;
for (int k = 0; k < tDimSize[1]; ++k)
{
float* ans = tAnswer2[0];
int* ansIndex = indexAnswer2[0];
if (tmpData == ans[i * tDimSize[1] + k] && tmpIndex == ansIndex[i * tDimSize[1] + k])
{
flag = true;
}
if (tmpDataUser == ans[i * tDimSize[1] + k] && tmpIndexUser == ansIndex[i * tDimSize[1] + k])
{
flagUser = true;
}
}
cpuTest = cpuTest&&flag&&flagUser;
}
}
#ifdef USE_CUDA
/* GPU test */
......@@ -152,10 +204,74 @@ bool TestTopK1()
TopK(sUserGPU, tUserGPU2, indexUserGPU2, dim, k);
/* check results */
gpuTest = tGPU1->CheckData(tAnswer1, tUnitNum) && tUserGPU1.CheckData(tAnswer1, tUnitNum)
&& tGPU2->CheckData(tAnswer2, tUnitNum) && tUserGPU2.CheckData(tAnswer2, tUnitNum)
&& indexGPU1->CheckData(indexAnswer1, tUnitNum) && indexUserGPU1.CheckData(indexAnswer1, tUnitNum)
&& indexGPU2->CheckData(indexAnswer2, tUnitNum) && indexUserGPU2.CheckData(indexAnswer2, tUnitNum);
float* checkData = new float[tUnitNum];
int* checkIndex = new int[tUnitNum];
float* checkDataUser = new float[tUnitNum];
int* checkIndexUser = new int[tUnitNum];
cudaMemcpy(checkData, tGPU1->data, sizeof(DTYPE)*tUnitNum,cudaMemcpyDeviceToHost);
cudaMemcpy(checkIndex, indexGPU1->data, sizeof(int)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkDataUser, tUserGPU1.data, sizeof(DTYPE)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkIndexUser, indexUserGPU1.data, sizeof(int)*tUnitNum, cudaMemcpyDeviceToHost);
for (int i = 0; i < tDimSize[1]; ++i)
{
for (int j = 0; j < tDimSize[0]; ++j)
{
float tmpData = ((float *)checkData)[i + tDimSize[1] * j];
int tmpIndex = ((int *)checkIndex)[i + tDimSize[1] * j];
float tmpDataUser = ((float *)checkDataUser)[i + tDimSize[1] * j];
int tmpIndexUser = ((int *)checkIndexUser)[i + tDimSize[1] * j];
bool flag = false;
bool flagUser = false;
for (int k = 0; k < tDimSize[0]; ++k)
{
float* ans = tAnswer1[0];
int* ansIndex = indexAnswer1[0];
if (tmpData == ans[i + tDimSize[1] * k] && tmpIndex == ansIndex[i + tDimSize[1] * k])
{
flag = true;
}
if (tmpDataUser == ans[i + tDimSize[1] * k] && tmpIndexUser == ansIndex[i + tDimSize[1] * k])
{
flagUser = true;
}
}
gpuTest = gpuTest&&flag&&flagUser;
}
}
cudaMemcpy(checkData, tGPU2->data, sizeof(DTYPE)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkIndex, indexGPU2->data, sizeof(int)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkDataUser, tUserGPU2.data, sizeof(DTYPE)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkIndexUser, indexUserGPU2.data, sizeof(int)*tUnitNum, cudaMemcpyDeviceToHost);
for (int i = 0; i < tDimSize[0]; ++i)
{
for (int j = 0; j < tDimSize[1]; ++j)
{
float tmpData = ((float *)checkData)[i * tDimSize[1] + j];
int tmpIndex = ((int *)checkIndex)[i * tDimSize[1] + j];
float tmpDataUser = ((float *)checkDataUser)[i * tDimSize[1] + j];
int tmpIndexUser = ((int *)checkIndexUser)[i * tDimSize[1] + j];
bool flag = false;
bool flagUser = false;
for (int k = 0; k < tDimSize[1]; ++k)
{
float* ans = tAnswer2[0];
int* ansIndex = indexAnswer2[0];
if (tmpData == ans[i * tDimSize[1] + k] && tmpIndex == ansIndex[i * tDimSize[1] + k])
{
flag = true;
}
if (tmpDataUser == ans[i * tDimSize[1] + k] && tmpIndexUser == ansIndex[i * tDimSize[1] + k])
{
flagUser = true;
}
}
gpuTest = gpuTest&&flag&&flagUser;
}
}
/* destroy variables */
delete s;
......@@ -170,6 +286,10 @@ bool TestTopK1()
delete indexGPU2;
delete[] sDimSize;
delete[] tDimSize;
delete[] checkData;
delete[] checkIndex;
delete[] checkDataUser;
delete[] checkIndexUser;
return cpuTest && gpuTest;
#else
......@@ -247,8 +367,33 @@ bool TestTopK2()
TopK(sUser, tUser, indexUser, dim, k);
/* check results */
cpuTest = t->CheckData(tAnswer, tUnitNum) && tUser.CheckData(tAnswer, tUnitNum)
&& index->CheckData(indexAnswer, tUnitNum) && indexUser.CheckData(indexAnswer, tUnitNum);
for (int i = 0; i < tDimSize[0]; ++i)
{
for (int j = 0; j < tDimSize[1]; ++j)
{
float tmpData = ((float *)t->data)[i * tDimSize[1] + j];
int tmpIndex = ((int *)index->data)[i * tDimSize[1] + j];
float tmpDataUser = ((float *)tUser.data)[i * tDimSize[1] + j];
int tmpIndexUser = ((int *)indexUser.data)[i * tDimSize[1] + j];
bool flag = false;
bool flagUser = false;
for (int k = 0; k < tDimSize[1]; ++k)
{
float* ans = tAnswer[0];
int* ansIndex = indexAnswer[0];
if (tmpData == ans[i * tDimSize[1] + k] && tmpIndex == ansIndex[i * tDimSize[1] + k])
{
flag = true;
}
if (tmpDataUser == ans[i * tDimSize[1] + k] && tmpIndexUser == ansIndex[i * tDimSize[1] + k])
{
flagUser = true;
}
}
cpuTest = cpuTest&&flag&&flagUser;
}
}
#ifdef USE_CUDA
/* GPU test */
......@@ -279,8 +424,42 @@ bool TestTopK2()
TopK(sUserGPU, tUserGPU, indexUserGPU, dim, k);
/* check results */
gpuTest = tGPU->CheckData(tAnswer, tUnitNum) && tUserGPU.CheckData(tAnswer, tUnitNum)
&& indexGPU->CheckData(indexAnswer, tUnitNum) && indexUserGPU.CheckData(indexAnswer, tUnitNum);
float* checkData = new float[tUnitNum];
int* checkIndex = new int[tUnitNum];
float* checkDataUser = new float[tUnitNum];
int* checkIndexUser = new int[tUnitNum];
cudaMemcpy(checkData, tGPU->data, sizeof(DTYPE)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkIndex, indexGPU->data, sizeof(int)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkDataUser, tUserGPU.data, sizeof(DTYPE)*tUnitNum, cudaMemcpyDeviceToHost);
cudaMemcpy(checkIndexUser, indexUserGPU.data, sizeof(int)*tUnitNum, cudaMemcpyDeviceToHost);
for (int i = 0; i < tDimSize[0]; ++i)
{
for (int j = 0; j < tDimSize[1]; ++j)
{
float tmpData = ((float *)checkData)[i * tDimSize[1] + j];
int tmpIndex = ((int *)checkIndex)[i * tDimSize[1] + j];
float tmpDataUser = ((float *)checkDataUser)[i * tDimSize[1] + j];
int tmpIndexUser = ((int *)checkIndexUser)[i * tDimSize[1] + j];
bool flag = false;
bool flagUser = false;
for (int k = 0; k < tDimSize[1]; ++k)
{
float* ans = tAnswer[0];
int* ansIndex = indexAnswer[0];
if (tmpData == ans[i * tDimSize[1] + k] && tmpIndex == ansIndex[i * tDimSize[1] + k])
{
flag = true;
}
if (tmpDataUser == ans[i * tDimSize[1] + k] && tmpIndexUser == ansIndex[i * tDimSize[1] + k])
{
flagUser = true;
}
}
gpuTest = gpuTest&&flag&&flagUser;
}
}
/* destroy variables */
delete s;
......@@ -291,6 +470,10 @@ bool TestTopK2()
delete indexGPU;
delete[] sDimSize;
delete[] tDimSize;
delete[] checkData;
delete[] checkIndex;
delete[] checkDataUser;
delete[] checkIndexUser;
return cpuTest && gpuTest;
#else
......
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