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trying TEMPLATE C

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fanasina
2023-07-16 00:15:15 +02:00
commit 8e529cb426
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.vscode/c_cpp_properties.json
Vendored
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{
"configurations": [
{
"name": "Linux",
"includePath": [
"${workspaceFolder}/**",
"/home/fanasina/progr_/ptens0neD/**",
"/usr/include/boost/predef/language"
],
"defines": [],
"compilerPath": "/usr/bin/clang-13",
"cStandard": "c17",
"cppStandard": "c++14",
"intelliSenseMode": "linux-clang-x64"
}
],
"version": 4
}
.vscode/settings.json
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{
"files.associations": {
"array": "cpp",
"string_view": "cpp",
"initializer_list": "cpp",
"utility": "cpp"
}
}
Makefile
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CC=nvcc
LDFLAGS=-lgtest -lpthread
ROOT_DIR=$(shell pwd)
INCLUDE_DIR=$(ROOT_DIR)
CFLAGS=-I$(INCLUDE_DIR)
SRC_DIR=$(ROOT_DIR)/src
SRC=$(wildcard src/*/*.c*) $(wildcard src/*/*/*.c*)
OBJPP=$(SRC:.cpp=.o)
OBJS=$(OBJPP:.cu=.o)
#HEADS=$(OBJS:.o=.h)
TEST_DIR=$(ROOT_DIR)/test
EXEC=$(TEST_DIR)/isgood
PERMSRC=$(wildcard src/*/*perm*.cpp)
PERMSRC_O=$(PERMSRC:.cpp=.o)
DIMSRC=$(wildcard src/*/*dim*.cpp)
DIMSRC_O=$(DIMSRC:.cpp=.o)
TENSRCPP=$(wildcard src/*/*/tens*.cpp)
TENSRCPP_O=$(TENSRCPP:.cpp=.o)
TENSRCU=$(wildcard src/*/*/tens*.cu)
TENSRCU_O=$(TENSRCU:.cu=.o)
DTENSRCU=$(wildcard src/*/*/d_tens*.cu)
DTENSRCU_O=$(DTENSRCU:.cu=.o)
TENSRC=$(TENSRCPP) $(TENSRCU)
all: $(EXEC)
$(EXEC): $(EXEC).cu $(OBJS)
$(CC) -o $@ $^ -I$(INCLUDE_DIR) $(LDFLAGS)
$(DIMSRC_O): $(DIMSRC) $(PERMSRC_O)
$(CC) -o $@ -c $< $(CFLAGS)
$(TENSRCPP_O): $(TENSRCPP) $(DIMSRC_O)
$(CC) -o $@ -c $< $(CFLAGS)
$(TENSRCU_O): $(TENSRCU) $(DTENSRCU_O) $(DIMSRC_O)
$(CC) -o $@ -c $< $(CFLAGS)
$(PERMSRC_O): $(PERMSRC)
$(CC) -o $@ -c $< $(CFLAGS)
$(DTENSRCU_O) : $(DTENSRCU)
$(CC) -o $@ -c $< $(CFLAGS)
.PHONY: clean mrproper
clean:
rm -f $(OBJS)
mrproper: clean
rm -f $(EXEC)
cmdcreate.sh
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#!/bin/bash
nvcc isgood.cu tensor.cu cudatensor.cu ../permutation/permutation.cpp -o isgood -lgtest -lpthread -g --relocatable-device-code=true
create.sh
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#!/bin/bash
make "$@"
kmemcheck.sh
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#!/bin/bash
make "$@"
compute-sanitizer --tool memcheck ./test/isgood
krun.sh
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#!/bin/bash
make "$@"
./test/isgood
memcheck.sh
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#!/bin/bash
compute-sanitizer --tool memcheck ./build/isgood
run.sh
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#!/bin/bash
./test/isgood
src/coordinate/coordinate.h
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#ifndef __COORDINATE_C__H__
#define __COORDINATE_C__H__
#include "src/dimension/dimension.h"
struct coordinate
{
size_t lin_coo;
unsigned int *coord;
struct dimension *dimension;
};
typedef coordinate coordinate;
void LinearToCoord(struct coordinate *coor);
void CoordToLinear(struct coordinate *coor);
#endif
src/dimension/dimension.cpp
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#include <cstdio>
#include <cstdlib>
#include <stdexcept>
#include <vector>
#include <algorithm>
//#include "/home/fanasina/progr_/ptens0neD/src/dimension/dimension.h"
//#include "/home/fanasina/progr_/ptens0neD/src/permutation/permutation.h"
#include "src/dimension/dimension.hpp"
#include "src/permutation/permutation.hpp"
//#include "permutation.h"
/*void dimension::initDim(int* arr, bool end = true) {
endian = end;
delete[]dim;
dim = new int[rank];
size = 1;
for (int i = 0; i < rank; ++i) {
dim[i] = arr[i];
size *= dim[i];
}
}*/
dimension& dimension::operator=(const dimension& d) {
int oldRank = rank;
rank = d.rank;
size = d.size;
initDim(d.dim, oldRank);
//for (int i = 0; i < rank; i++) dim[i] = d.dim[i];
return *this;
}
dimension& dimension::operator+=(const dimension& d) {
int oldRank = rank;
int* t = new int[rank + d.rank];
for (int i = 0; i < rank; i++) t[i] = dim[i];
for (int i = 0; i < d.rank; i++) t[rank + i] = d.dim[i];
size *= d.size;
rank += d.rank;
initDim(t, oldRank);
return *this;
}
void dimension::LinearToCoord(int* ret, int lin) const {
int begin = 0, end = rank - 1;
int (*iter)(int) = incr;
bool (*cond)(int, int) = isLessThan;
if (endian == false) {
//if (endian) {
begin = rank - 1; end = 0;
iter = decr; cond = isGreatThan;
}
//printf("to coor begin = %d end = %d \n", begin, end);
int sm = lin;
int pp = size;
for (int i = begin; cond(i, end); i = iter(i)) {
//printf(" i: %d ", i);
pp /= dim[i];
ret[i] = sm / pp;
sm %= pp;
//printf("sm[%d] = %d , pp=%d ; ", i, sm, pp);
}
ret[end] = sm;
}
int dimension::CoordToLinear(int* coo) const {
int begin = 0;
int end = rank - 1;
int (*iter)(int); iter = &incr;
bool (*cond)(int, int); cond = &isLessEqThan;
if (endian) {
begin = rank - 1; end = 0;
iter = &decr; cond = &isGreatEqThan;
}
int pp = 1;
int sm = 0;
for (int i = begin; cond(i, end); i = iter(i)) {
sm += (coo[i] * pp);
pp *= dim[i];
}
return sm;
}
bool isLessEqThan(int a, int b) { return a <= b; }
bool isLessThan(int a, int b) { return a < b; }
bool isGreatEqThan(int a, int b) { return a >= b; }
bool isGreatThan(int a, int b) { return a > b; }
int incr(int i) { return i + 1; }
int decr(int i) { return i - 1; }
void add(dimension& d, const dimension& d0, const dimension& d1) {
int oldRank = d.rank;
int* t = new int[d0.rank + d1.rank];
for (int i = 0; i < d0.rank; i++) t[i] = d0.dim[i];
for (int i = 0; i < d1.rank; i++) t[d0.rank + i] = d1.dim[i];
d.rank = d0.rank + d1.rank;
d.initDim(t, oldRank);
}
void max(dimension& d, const dimension& d0, const dimension& d1) {
if (d0.rank > d1.rank) {
d = d0;
}
else if (d0.rank < d1.rank) {
d = d1;
}
else {// d0.rank = d1.rank
d = d0;
for (int i = 0; i < d.rank; i++) {
if (d.dim[i] < d1.dim[i]) d.dim[i] = d1.dim[i];
}
}
}
void min(dimension& d, const dimension& d0, const dimension& d1) {
if (d0.rank > d1.rank) {
d = d1;
}
else if (d0.rank < d1.rank) {
d = d0;
}
else {// d0.rank = d1.rank
d = d0;
for (int i = 0; i < d.rank; i++) {
if (d.dim[i] > d1.dim[i]) d.dim[i] = d1.dim[i];
}
}
}
void minReverse(dimension& d, const dimension& d0, const dimension& d1, bool& rev) {
if (d0.rank > d1.rank) {
d = d1;
rev = true;
}
else if (d0.rank < d1.rank) {
d = d0;
rev = false;
}
else {// d0.rank = d1.rank
d = d0;
for (int i = 0; i < d.rank; i++) {
if (d.dim[i] > d1.dim[d.rank - 1 - i]) d.dim[i] = d1.dim[d.rank - 1 - i];
}
rev = false;
}
}
void reverseArray(int* arr, int sz) {
int tmp[sz], i = 0;
for (; i < sz / 2; i++) {
tmp[i] = arr[i];
arr[i] = arr[sz - 1 - i];
}
for (; i < sz; i++) {
arr[i] = tmp[sz - 1 - i];
}
}
void transform(dimension& dDst, const dimension& dSrc, int* perm, int sz) {
dDst = dSrc;
setInit setIn(sz);
if (sz == dSrc.rank) {
if (isPermutation(perm, setIn, sz)) {
for (int i = 0; i < sz; i++) dDst.dim[i] = dSrc.dim[perm[i]];
}
}
}
src/dimension/dimension.h
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#ifndef __DIM__
#define __DIM__
#include <stdio.h>
#include <stdlib.h>
struct dimension
{
unsigned int rank;
unsigned int* dim;
size_t size;
};
typedef dimension dimension;
void print_dimension(dimension d);
void add(dimension* d, const dimension* d0, const dimension* d1);
void max(dimension* d, const dimension* d0, const dimension* d1);
void min(dimension* d, const dimension* d0, const dimension* d1);
bool minReverse(dimension* d, const dimension* d0, const dimension* d1);
void transform(dimension* dDst, const dimension* dSrc, int* perm);
#endif
src/dimension/dimension.hpp
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#ifndef __DIMENSION__
#define __DIMENSION__
#include <cstdio>
#include <cstdlib>
#include <stdexcept>
//#include "tensor.h"
//#include "dimension.h"
static int iArray1[1] = { 1 };
struct dimension {
//friend dimension& operator+(const dimension& d, const dimension& d1);
friend void add(dimension& d, const dimension& d0, const dimension& d1);
friend void max(dimension& d, const dimension& d0, const dimension& d1);
friend void min(dimension& d, const dimension& d0, const dimension& d1);
friend void minReverse(dimension& d, const dimension& d0, const dimension& d1, bool& Rev);
friend bool checkMatchProdTensor(dimension& d0, const dimension& d1, int nestingDepth);
friend bool checkMatchProdTensorReverse(dimension& d0, const dimension& d1, int nestingDepth);
friend void extractDimNestingDepth(dimension& dM, const dimension& d0, const dimension& d1, int nestingDepth);
int rank;
int* dim;
size_t size;
bool endian; //LitleEndian : true, BigEndian : false,
void initDim(int* arr, int oldRank) {
//delete[]dim;
//dim = new int[rank];
if (rank > oldRank) {
free(dim);
dim = (int*)malloc(rank * sizeof(int));
}
size = 1;
for (int i = 0; i < rank; ++i) {
dim[i] = arr[i];
size *= dim[i];
}
}
void initDim(bool end = true) {
endian = end;
//delete[]dim;
//dim = new int[rank];
if (dim != NULL) free(dim);
dim = (int*)malloc(rank * sizeof(int));
}
dimension& operator=(const dimension& d);
dimension& operator+=(const dimension& d);
//dimension& operator*=(const dimension& d);
dimension(int d = 1, int* arr = iArray1, bool end = true) {
endian = end;
rank = d;
//dim = new int[d];
dim = (int*)malloc(d * sizeof(int));
initDim(arr, rank);
}
void print() const { printf(" rank: %d\n", rank);for (int i = 0; i < rank; i++) printf(" %d ", dim[i]);printf("\nsize:%ld\n", size); }
void LinearToCoord(int* ret, int lin) const;
int CoordToLinear(int* coo) const;
};
bool isLessEqThan(int a, int b); // { return a <= b; }
bool isLessThan(int a, int b); // { return a < b; }
bool isGreatEqThan(int a, int b); // { return a >= b; }
bool isGreatThan(int a, int b); // { return a > b; }
int incr(int i); // { return i + 1; }
int decr(int i); // { return i - 1; }
void add(dimension& d, const dimension& d0, const dimension& d1);
void max(dimension& d, const dimension& d0, const dimension& d1);
void min(dimension& d, const dimension& d0, const dimension& d1);
void minReverse(dimension& d, const dimension& d0, const dimension& d1, bool& rev);
void transform(dimension& dDst, const dimension& dSrc, int* perm, int sz);
#endif
src/permutation/permutation.c
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#include "src/permutation/permutation.h"
permutation*
create_permutation(size_t sz)
{
if(sz == 0) return NULL;
permutation *p=malloc(sizeof(permutation));
p->size = sz;
p->perm = malloc(sz*sizeof(unsigned int));
}
/*void
copy_array_unsigned(unsigned int *dst, const unsigned int *src, size_t size)
{
for(size_t i = 0; i < size ; ++i)
dst[i]=src[i];
}*/
void
assign_permutation(permutation *p, unsigned int *arr)
{
copy_array_unsigned(p->perm, arr, p->size);
}
bool
is_permutation_set_theoric(const permutation *p)
{
if(p==NULL) return false;
size_t size = p->size, j;
unsigned int *count_array_i = calloc(size, sizeof(unsigned int));
if(count_array_i == NULL)
{
printf("can't allocate count_array_i\n");
return false;
}
for(size_t i = 0; i < size; ++i)
{
j = p->perm[i];
if((j >= size) || count_array_i[j])
{
free(count_array_i);
return false;
}
count_array_i[j]++;
}
return true;
}
/* 2,7,4,1 is a permutation of 1,2,4,7
*it is equivalent of 1,3,2,0 in set_theoric(4)=0,1,2,3
this function calculate the permutation equivalent in set_theoric
* */
permutation *
translate_set_theoric(const permutation *p, permutation *translate_p)
{
if(p==NULL) return NULL;
size_t size = p->size;
permutation *translate_p = create_permutation(size);
unsigned int *temperm = malloc(size*sizeof(unsigned int));
unsigned int *tmperm = malloc(size*sizeof(unsigned int));
copy_array_unsigned_int(tmperm, p->perm, p->size); // copy
qsort(tmperm, size, sizeof(unsigned int), compare_unsigned_int);
// tmperm contain p->perm ordered
size_t cur=0;
for(size_t i=0; i< size; ++i)
{
for(size_t j=0; j<size; ++j)
{
if(p->perm[j] == tmperm[i])
{
bool found = false;
for(size_t c=0; c<cur; ++c)
{
if(j==temperm[c])
{
found = true;
break;
}
}
if(found == false)
{
translate_p->perm[i]=j;
temperm[cur++]=j;
break;
}
}
}
}
free(tmperm);
free(temperm);
return translate_p;
}
bool
is_permutation(const permutation *p)
{
bool ret = is_permutation_set_theoric(p);
if(ret == false)
{
permutation *t_p = translate_set_theoric(p);
ret = is_permutation_set_theoric(t_p);
free(t_p);
}
return ret;
}
src/permutation/permutation.cpp
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#include <stdio.h>
#include <stdlib.h>
#include <vector>
#include <algorithm>
//#include "/home/fanasina/progr_/ptens0neD/src/permutation/permutation.h"
#include "src/permutation/permutation.h"
int sign(int a) {
if (a < 0) return -1;
return 1;
}
bool isPermutation(int* perm, setInit se, int sz) {
std::vector<int> tmp;
for (int i = 0; i < sz; i++) {
for (int j = 0; j < sz; j++) {
if (perm[i] == se.setinit[j]) {
if (find(tmp.begin(), tmp.end(), j) == tmp.end()) {
tmp.push_back(j);
break;
}
}
}
}
return tmp.size() == sz;
}
int permutation::signature() {
int ss = 1;
for (int i = 0; i < size; i++) {
for (int j = i + 1; j < size; j++) {
ss *= sign(perm[j] - perm[i]);// * sign(j - i);
}
}
return ss;
}
int signature(int* tab, int sz) {
int ss = 1;
for (int i = 0; i < sz; i++) {
for (int j = i + 1; j < sz; j++) {
ss *= sign(tab[j] - tab[i]) * sign(j - i);
}
}
return ss;
}
template<typename T>
void permutation::permute(T* dst, T* src) {
for (int i = 0; i < size;i++) {
dst[i] = src[perm[i]];
}
}
template
void permutation::permute(int* dst, int* src);
template
void permutation::permute(float* dst, float* src);
// complexité sz*(sz+1)/2
size_t TabToPlaceAlgo(int* tb, int sz) {
int cnt = 0;
int pl;
int* tPlace = new int[sz];
for (int i = sz - 1; i >= 0; i--) {
cnt++;
pl = 0;
for (int j = i + 1; j < sz; j++) {
cnt++;
if (tb[j] < tb[i]) {
pl++;
}
if (pl == tb[i]) break;
}
tPlace[tb[i]] = pl;
}
size_t q = 0;
for (int i = 0; i < sz;i++) {
cnt++;
//printf("tPlace[%d] == %d et tb[%d] == %d\n", i, tPlace[i], i, tb[i]);
q = (i + 1) * q + tPlace[i];
}
//printf("algo cnt = %d ", cnt);
return q;
}
// complexité sz*(sz+1)/2
size_t TabToPlaceOpt1(int* tb, int sz) {
int cnt = 0;
int mx;
int* tPlace = new int[sz];
for (int i = sz - 1; i >= 0; i--) {
cnt++;
if (i == sz - 1) {
mx = tb[i];
tPlace[mx] = 0;
}
else if (mx > tb[i]) {
int pli = 0; // si c est le plus à droite 0 si pas de superieur à lui, on incremente si on trouve plus petit
for (int j = sz - 1; j > i; j--) {
cnt++;
if (tb[i] > tb[j]) {
pli++;
}
else if (tb[i] == tb[j]) {
//return -1; // something wrong
throw "something wrong here, tb[i]==tb[j]";
}
}
tPlace[tb[i]] = pli;
}
else if (mx < tb[i]) {
mx = tb[i];
tPlace[mx] = sz - 1 - i;
}
else {
//return -1; // something wrong
throw "something wrong here, tb[i]==mx";
}
}
size_t q = 0;
for (int i = 0; i < sz; i++) {
cnt++;
//printf("tab tPlace[%d] == %d et tb[%d] == %d [ q=%d, cnt = %d\n", i, tPlace[i], i, tb[i], q, cnt);
q = (i + 1) * q + tPlace[i];
}
//printf("Opt cnt = %d ", cnt);
return q;
}
// complexité sz*(sz+1)
size_t TabToPlaceNotab(int* tb, int sz) {
int cnt = 0;
int mx = sz - 1;
size_t q = 0;
int pl;
for (int i = 0; i < sz; i++) {
cnt++;
int j;
for (j = 0; j < sz;j++) {
cnt++;
if (tb[j] == i) break;
}
pl = 0;
j++;
for (;j < sz;j++) {
cnt++;
if (tb[j] < i) {
pl++;
}
if (pl == i) break;
}
q = (i + 1) * q + pl;
//q = (sz - tb[i]) * q + pl;
//printf("notab tPlace[tb[%d]] == %d et tb[%d] == %d [ q=%d, cnt = %d\n", i, pl, i, tb[i], q, cnt);
}
//printf(" notab cnt = %d ", cnt);
return q;
}
//complexité sz*sz/2
void PlaceToTab(int* tb, size_t pl, int sz) {
int cnt = 0;
size_t a = pl;
int pltbi;
int size = 1;
// s'assurer que tb soit null
for (int i = 0;i < sz;i++) tb[i] = 0;
for (int i = sz - 1; i >= 0; i--) {
cnt++;
pltbi = a % (i + 1);
a /= (i + 1);
if (i == sz - 1) {
tb[sz - 1 - pltbi] = i;
}
else {
int lt = 0, j = sz - 1;
while (lt < pltbi && j >= 0) {
cnt++;
if (tb[j--] < i) {
lt++;
}
}
while (tb[j] > i) {
cnt++;
j--;
}
tb[j] = i;
}
}
//printf("cnt PlaceToTab :%d ", cnt);
}
size_t factorial(int n) {
size_t ret = 1;
for (size_t i = 2; i <= n; i++) {
ret *= i;
}
return ret;
}
// src1 o src0 = dst; dst(i) = src1(src0(i))
void compose(int* dst, int* src0, int* src1, int sz) {
for (int i = 0; i < sz; i++) {
dst[i] = src1[src0[i]];
}
}
// src1 o src0 = dst; dst(i) = src1(src0(i))
void compose(size_t& rdst, size_t psrc0, size_t psrc1, int sz) {
int dst[sz], src0[sz], src1[sz];
PlaceToTab(src0, psrc0, sz);
PlaceToTab(src1, psrc1, sz);
for (int i = 0; i < sz; i++) {
dst[i] = src1[src0[i]];
}
rdst = TabToPlaceOpt1(dst, sz);
}
/*
template<typename T>
void transform(T* dst, T* src, int* perm, int sz) {
for (int i = 0; i < sz; i++) {
dst[i] = src[perm[i]];
}
}
template<typename T>
void transform(T* dst, T* src, size_t pl, int sz) {
int perm[sz];
PlaceToTab(perm, pl, sz);
for (int i = 0; i < sz; i++) {
dst[i] = src[perm[i]];
}
}
*/
void permuteArray(int* dst, int* src, int* perm, int sz) {
for (int i = 0; i < sz; i++) {
dst[i] = src[perm[i]];
}
}
void inverseArray(int* dst, int* src, int sz) {
for (int i = 0; i < sz; i++) {
dst[src[i]] = i;
}
}
// seek?/ seek o src = seek(src)=dst => seek = dst o inv(src)
void permCorrespondance(int* sk, int* dst, int* src, int sz) {
int inv[sz];
inverseArray(inv, src, sz);
compose(sk, dst, inv, sz);
}
// SRC o transf = DST, SRC:{a,b,c,d,g,f} o transf = DST:{g,b,d,f,c,a}
// SRC[0]=a, SRC[1]=b, SRC[2]=c SRC[3]=d SRC[4]=g SRC[5]=f
// DST[0]=g=SRC[4] DST[1]=b=SRC[1] DST[2]=d=SRC[3] DST[3]=f=SRC[5] DST[4]=c=SRC[2] DST[5]=a=SRC[1]
// trans[0]=4 trans[1]=1 trans[2]=3 trans[3]=5 trans[4]=2 trans[5]=0
// (*cmp) (a,b) = 0 if a==b, -1 if a<b , 1 if a>b
template<typename T>
void CorrespondacePerm(T* src, T* dst, int* transf, int sz, int (*cmp)(T, T)) {
int tmp[sz];
std::vector<int> tmpV;
int curt = 0;
for (int i = 0; i < sz; i++) {
for (int j = 0; j < sz; j++) {
if (cmp(dst[i], src[j]) == 0) {
if (std::find(tmpV.begin(), tmpV.end(), j) == tmpV.end()) {// not found
transf[i] = j;
tmpV.push_back(j);
break;
}
}
}
}
}
template void CorrespondacePerm<char>(char* src, char* dst, int* transf, int sz, int (*cmp)(char, char));
src/permutation/permutation.h
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#ifndef __PERMUTATION_C_H__
#define __PERMUTATION_C_H__
#include "src/set_theoric/set_theoric.h"
/* struct of permutation of unsigned int array, not necessarly set_theoric
*
* */
struct permutation
{
size_t size;
unsigned int *perm;
};
typedef struct permutation permutation;
permutation * create_permutation(size_t sz);
void assign_permutation(permutation *p, unsigned int *arr);
bool is_permutation_set_theoric(const permutation *p);
// more general! need translation and use is_permutation_set_theoric
bool is_permutation(const permutation *p);
#endif /*__PERMUTATION_C_H__*/
src/permutation/permutation.hpp
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#ifndef __PERMUTATION_H__
#define __PERMUTATION_H__
#include <stdlib.h>
struct setInit {
int size;
int* setinit;
setInit(int sz = 1, int beg = 0) {
size = sz;
setinit = new int[sz];
for (int i = 0; i < sz; i++) setinit[i] = beg + i;
}
};
struct permutation {
int size;// type
int rang; //place;//rang;
int* perm;
permutation(int sz, bool b) {
size = sz;
perm = new int[size];
}
permutation(int sz = 1, int* tb = { 0 }) {
size = sz;
perm = new int[size];
for (int i = 0; i < size; i++) perm[i] = tb[i];
}
//int TabToPlace(int* tb , int sz );
//void PlaceToTab(int* tb , int pl , int sz);
int signature();
template<typename T>
void permute(T* dst, T* src);
};
bool isPermutation(int* perm, setInit se, int sz);
int signature(int* tab, int sz);
// complexité sz*(sz+1)/2
size_t TabToPlaceAlgo(int* tb, int sz);
// complexité sz*(sz+1)/2
size_t TabToPlaceOpt1(int* tb, int sz);
// complexité sz*(sz+1)
size_t TabToPlaceNotab(int* tb, int sz);
//complexité sz*sz/2
void PlaceToTab(int* tb, size_t pl, int sz);
size_t factorial(int n);
// src1 o src0 = dst; dst(i) = src1(src0(i))
void compose(int* dst, int* src0, int* src1, int sz);
// src1 o src0 = dst; dst(i) = src1(src0(i))
void compose(size_t& rdst, size_t psrc0, size_t psrc1, int sz);
/*template<typename T>
void transform(T* dst, T* src, int* perm, int sz);
template<typename T>
void transform(T* dst, T* src, size_t pl, int sz);
template<typename T>
void transform(T* dst, T* src, int* perm, int sz) {
for (int i = 0; i < sz; i++) {
dst[i] = src[perm[i]];
}
}
template<typename T>
void transform(T* dst, T* src, size_t pl, int sz) {
int perm[sz];
PlaceToTab(perm, pl, sz);
for (int i = 0; i < sz; i++) {
dst[i] = src[perm[i]];
}
}*/
void permuteArray(int* dst, int* src, int* perm, int sz);
void inverseArray(int* dst, int* src, int sz);
// seek?/ seek o src = seek(src)=dst => seek = dst o inv(src)
void permCorrespondance(int* sk, int* dst, int* src, int sz);
// SRC o transf = DST, SRC:{a,b,c,d,g,f} o transf = DST:{g,b,d,f,c,a}
// SRC[0]=a, SRC[1]=b, SRC[2]=c SRC[3]=d SRC[4]=g SRC[5]=f
// DST[0]=g=SRC[4] DST[1]=b=SRC[1] DST[2]=d=SRC[3] DST[3]=f=SRC[5] DST[4]=c=SRC[2] DST[5]=a=SRC[0]
// trans[0]=4 trans[1]=1 trans[2]=3 trans[3]=5 trans[4]=2 trans[5]=0
// (*cmp) (a,b) = 0 if a==b, -1 if a<b , 1 if a>b
template<typename T>
void CorrespondacePerm(T* src, T* dst, int* transf, int sz, int (*cmp)(T, T));
#endif
src/permutation_t/permutation_t.c
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#include "src/permutation_t/permutation_t.h"
#define CREATE_PERMUTATION(type, size)\
type * CREATE_PERMUTATION_##type(size_t size){\
if (sz == 0) return NULL;\
PERMUTATION_##type *p = malloc(sizeof(PERMUTATION_##type));\
p->size = size;\
p->perm = malloc(size * sizeof(type));\
return p; }\
permutation*
create_permutation(size_t sz)
{
if(sz == 0) return NULL;
permutation *p=malloc(sizeof(permutation));
p->size = sz;
p->perm = malloc(sz*sizeof(unsigned int));
return p;
}
/*void
copy_array_unsigned(unsigned int *dst, const unsigned int *src, size_t size)
{
for(size_t i = 0; i < size ; ++i)
dst[i]=src[i];
}*/
void
assign_permutation(permutation *p, unsigned int *arr)
{
copy_array_unsigned(p->perm, arr, p->size);
}
bool
is_permutation_set_theoric(const permutation *p)
{
if(p==NULL) return false;
size_t size = p->size, j;
unsigned int *count_array_i = calloc(size, sizeof(unsigned int));
if(count_array_i == NULL)
{
printf("can't allocate count_array_i\n");
return false;
}
for(size_t i = 0; i < size; ++i)
{
j = p->perm[i];
if((j >= size) || count_array_i[j])
{
free(count_array_i);
return false;
}
count_array_i[j]++;
}
return true;
}
/* 2,7,4,1 is a permutation of 1,2,4,7
*it is equivalent of 1,3,2,0 in set_theoric(4)=0,1,2,3
this function calculate the permutation equivalent in set_theoric
* */
permutation *
translate_set_theoric(const permutation *p, permutation *translate_p)
{
if(p==NULL) return NULL;
size_t size = p->size;
permutation *translate_p = create_permutation(size);
unsigned int *temperm = malloc(size*sizeof(unsigned int));
unsigned int *tmperm = malloc(size*sizeof(unsigned int));
copy_array_unsigned_int(tmperm, p->perm, p->size); // copy
qsort(tmperm, size, sizeof(unsigned int), compare_unsigned_int);
// tmperm contain p->perm ordered
size_t cur=0;
for(size_t i=0; i< size; ++i)
{
for(size_t j=0; j<size; ++j)
{
if(p->perm[j] == tmperm[i])
{
bool found = false;
for(size_t c=0; c<cur; ++c)
{
if(j==temperm[c])
{
found = true;
break;
}
}
if(found == false)
{
translate_p->perm[i]=j;
temperm[cur++]=j;
break;
}
}
}
}
free(tmperm);
free(temperm);
return translate_p;
}
bool
is_permutation(const permutation *p)
{
bool ret = is_permutation_set_theoric(p);
if(ret == false)
{
permutation *t_p = translate_set_theoric(p);
ret = is_permutation_set_theoric(t_p);
free(t_p);
}
return ret;
}
src/permutation_t/permutation_t.h
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#ifndef __PERMUTATION_T_C_H__
#define __PERMUTATION_T_C_H__
#include "src/tools_t/tools_t.h"
#include "src/set_theoric_t/set_theoric_t.h"
#define STRUCT_PERMUTATION(type)\
struct PERMUTATION_##type{\
size_t size;\
type * perm; };
STRUCT_PERMUTATION(TYPE_CHAR)
STRUCT_PERMUTATION(TYPE_U_CHAR)
STRUCT_PERMUTATION(TYPE_INT)
STRUCT_PERMUTATION(TYPE_U_INT)
STRUCT_PERMUTATION(TYPE_L_INT)
STRUCT_PERMUTATION(TYPE_U_L_INT)
STRUCT_PERMUTATION(TYPE_FLOAT)
STRUCT_PERMUTATION(TYPE_DOUBLE)
STRUCT_PERMUTATION(TYPE_L_DOUBLE)
STRUCT_PERMUTATION(TYPE_STRING)
typedef struct PERMUTATION_TYPE_CHAR PERMUTATION_TYPE_CHAR;
typedef struct PERMUTATION_TYPE_U_CHAR PERMUTATION_TYPE_U_CHAR;
typedef struct PERMUTATION_TYPE_INT PERMUTATION_TYPE_INT;
typedef struct PERMUTATION_TYPE_U_INT PERMUTATION_TYPE_U_INT;
typedef struct PERMUTATION_TYPE_L_INT PERMUTATION_TYPE_L_INT;
typedef struct PERMUTATION_TYPE_U_L_INT PERMUTATION_TYPE_U_L_INT;
typedef struct PERMUTATION_TYPE_FLOAT PERMUTATION_TYPE_FLOAT;
typedef struct PERMUTATION_TYPE_DOUBLE PERMUTATION_TYPE_DOUBLE;
typedef struct PERMUTATION_TYPE_L_DOUBLE PERMUTATION_TYPE_L_DOUBLE;
typedef struct PERMUTATION_TYPE_STRING PERMUTATION_TYPE_STRING;
/* struct of permutation of unsigned int array, not necessarly set_theoric
*
* */
struct permutation
{
size_t size;
unsigned int *perm;
};
typedef struct permutation permutation;
permutation * create_permutation(size_t sz);
void assign_permutation(permutation *p, unsigned int *arr);
bool is_permutation_set_theoric(const permutation *p);
// more general! need translation and use is_permutation_set_theoric
bool is_permutation(const permutation *p);
#endif /*__PERMUTATION_T_C_H__*/
src/set_theoric/set_theoric.c
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#include "src/set_theoric/set_theoric.h"
set_theoric * create_set_theoric(unsigned int id)
{
if(id == 0) return NULL;
set_theoric *ret_set = malloc(sizeof(set_theoric));
ret_set.set=malloc(id*sizeof(unsigned int));
ret_set.id = id;
for(int i = 0; i < id; ++i)
ret_set.set[i] = i;
return ret_set;
}
bool is_set_theoric(set_theoric *st)
{
if(st == NULL) return true;
for(int i = 0; i < st->id; ++i)
if(st->set[i] != i) return false;
return true;
}
src/set_theoric/set_theoric.h
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#ifndef __SET_THEORIC_C__H
#define __SET_THEORIC_C__H
#include <stdlib.h>
#include "src/tools/tools.h"
struct set_theoric
{
unsigned int id;
unsigned int *set;
};
typedef set_theoric set_theoric;
set_theoric * create_set_theoric(unsigned int id);
bool is_set_theoric(set_theoric *st);
#endif /*__SET_THEORIC_C__H*/
src/set_theoric_t/set_theoric_t.c
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#include "src/set_theoric_t/set_theoric_t.h"
#define CREATE_SET_THEORIC(type, id)\
type * CREATE_SET_THEORIC_##type(type id){\
if(id == 0) return NULL;\
SET_THEORIC_##type *ret_set = malloc(sizeof(SET_THEORIC_##type));\
ret_set->id = id;\
ret_set->set = malloc(id*sizeof(type));\
for(type i = 0; i < id; ++i) ret_set->set[i]=i;\
return ret_set; }
CREATE_SET_THEORIC(TYPE_U_CHAR)
CREATE_SET_THEORIC(TYPE_U_INT)
CREATE_SET_THEORIC(TYPE_U_LONG_INT)
#define IS_SET_THEORIC(type, st)\
bool IS_SET_THEORIC_##type(type *st){\
for(type i = 0; i < st->id; ++i){\
if(st->set[i] != i) return false;\
return true; }
IS_SET_THEORIC(TYPE_U_CHAR,st)
IS_SET_THEORIC(TYPE_U_INT,st)
IS_SET_THEORIC(TYPE_U_LONG_INT,st)
src/set_theoric_t/set_theoric_t.h
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#ifndef __SET_THEORIC_T_C__H
#define __SET_THEORIC_T_C__H
#include <stdlib.h>
#include "src/tools_t/tools_t.h"
#define STRUCT_SET_THEORIC(type)\
struct SET_THEORIC_##type{\
type id;\
type *set;};
STRUCT_SET_THEORIC(TYPE_U_CHAR)
STRUCT_SET_THEORIC(TYPE_U_INT)
STRUCT_SET_THEORIC(TYPE_U_LONG_INT)
typedef struct SET_THEORIC_TYPE_U_CHAR SET_THEORIC_TYPE_U_CHAR;
typedef struct SET_THEORIC_TYPE_U_INT SET_THEORIC_TYPE_U_INT;
typedef struct SET_THEORIC_TYPE_U_LONG_INT SET_THEORIC_TYPE_U_LONG_INT;
SET_THEORIC_TYPE_U_CHAR * CREATE_SET_THEORIC_TYPE_U_CHAR(TYPE_U_CHAR);
SET_THEORIC_TYPE_U_INT * CREATE_SET_THEORIC_TYPE_U_INT(TYPE_U_INT);
SET_THEORIC_TYPE_U_LONG_INT * CREATE_SET_THEORIC_TYPE_U_LONG_INT(TYPE_U_LONG_INT);
bool IS_SET_THEORIC_TYPE_U_CHAR(SET_THEORIC_TYPE_U_CHAR *st);
bool IS_SET_THEORIC_TYPE_U_INT(SET_THEORIC_TYPE_U_INT *st);
bool IS_SET_THEORIC_TYPE_U_LONG_INT(SET_THEORIC_TYPE_U_LONG_INT *st);
#endif /*__SET_THEORIC_T_C__H*/
src/tensor/tens0neD/tens0neD.cpp
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#include <cstdio>
#include <cstdlib>
#include <stdexcept>
#include <vector>
#include <algorithm>
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tens0neD/tens0neD.h"
#include "src/tensor/tens0neD/tens0neD.h"
//#include "include/tens0neD.h"
//#include "cudatensor.h"
//#include "/home/fanasina/progr_/ptens0neD/src/permutation/permutation.h"
#include "src/permutation/permutation.h"
template<typename T>
void transform(Tensor<T>& Dst, const Tensor<T>& Src, int* perm, int sz) {
transform(Dst.Dim, Src.Dim, perm, sz);
dimension dsrc = Src.Dim;
dimension ddst = Dst.Dim;
int coor[dsrc.rank];
int dcoor[ddst.rank], ldst;
for (int i = 0; i < Src.Dim.size; i++) {
dsrc.LinearToCoord(coor, i);
for (int j = 0; j < dsrc.rank; j++) dcoor[j] = coor[perm[j]];
ldst = ddst.CoordToLinear(dcoor);
Dst.elements[ldst] = Src.elements[i];
}
}
template void transform<float>(Tensor<float>& Dst, const Tensor<float>& Src, int* perm, int sz);
template void transform<double>(Tensor<double>& Dst, const Tensor<double>& Src, int* perm, int sz);
template<typename T>
Tensor<T>& Tensor<T>::operator=(const Tensor<T>& M) {
Dim = M.Dim;
for (int i = 0; i < Dim.size; ++i) elements[i] = M.elements[i];
return *this;
}
template<typename T>
Tensor<T>& Tensor<T>::operator*=(const T& val) {
//for (int i = 0; i < rank.size; ++i) elements[i] *= val;
return *this;
}
template<typename T>
Tensor<T>& operator*(const Tensor<T>& M0, const Tensor<T>& M1) {
struct dimension d; add(d, M0.Dim, M1.Dim);
Tensor<T> Mret(d);
for (int i = 0; i < M0.Dim.size; ++i) Mret.elements[i] = M0.elements[i];
Mret.Dim += M0.Dim;
return Mret;
}
void subArray(int* dst, int* src, int debDst, int finDst, int debSrc) {
for (int i = debDst; i < finDst; i++) {
dst[i] = src[i + debSrc];
}
}
void concatArray(int* dst, int* src0, int* src1, int debDst, int debSrc0, int finSrc0, int debSrc1, int finSrc1) {
int i = debDst;
for (int j = debSrc0; j < finSrc0; j++) {
dst[i++] = src0[j];
}
for (int j = debSrc1; j < finSrc1; j++) {
dst[i++] = src1[j];
}
}
template<typename T>
void Tensor<T>::initVal(T val) {
int* coord = new int[Dim.rank];
T pp, mult = 0.5;
for (int i = 0; i < Dim.size; i++) {
Dim.LinearToCoord(coord, i);
elements[i] = val;
pp = mult;
for (int j = 0; j < Dim.rank; j++) {
elements[i] += (coord[j] + 1) * pp;
pp *= mult;
}
}
}
template
void Tensor<float>::initVal(float val);
template
void Tensor<double>::initVal(double val);
template<typename T>
void Tensor<T>::print() {
Dim.print();
int* coord = new int[Dim.rank];
int begin = 0, end = Dim.rank - 1;
//int beginInv = Dim.rank - 1, endInv = 0;
int (*iter)(int) = incr;
//int (*iterInv)(int) = decr;
bool (*cond)(int, int) = isLessEqThan;
//bool (*condInv)(int, int) = isGreatEqThan;
if (Dim.endian == false) {
begin = Dim.rank - 1; end = 0;
//beginInv = 0; endInv = Dim.rank - 1;
iter = decr; cond = isGreatEqThan;
//iterInv = incr; condInv = isLessEqThan;
}
for (int i = 0; i < Dim.size; i++) {
Dim.LinearToCoord(coord, i);
//if (coord[Dim.rank - 1] == 0) {
if (coord[begin] == 0) {
for (int j = begin; cond(j, end); j = iter(j)) {
//for (int j = Dim.rank - 1; j >= 0; j--) {
if (coord[j] == 0) {
printf("(");
}
else break;
}
}
//printf(" ");for (int j = 0; j < Dim.rank; j++) printf("[%d]", coord[j]); printf(" ");
//printf(" "); for (int j = beginInv; condInv(j, endInv); j = iterInv(j)) printf("[%d]", coord[j]); printf(" ");
//printf(" "); for (int k = beginInv; condInv(k, endInv); k = iterInv(k)) { printf("[%d]", coord[k]); } printf(" ");
printf(" %.6f ", elements[i]);
//if (coord[Dim.rank - 1] == Dim.dim[Dim.rank - 1] - 1) {
if (coord[begin] == Dim.dim[begin] - 1) {
for (int j = begin; cond(j, end); j = iter(j)) {
//for (int j = Dim.rank - 1; j >= 0; j--) {
if (coord[j] == Dim.dim[j] - 1) {
printf(")");
}
else break;
}
}
}
printf("\n");
}
template
void Tensor<float>::print();
template
void Tensor<double>::print();
template<typename T>
void tensorProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1) {
add(M.Dim, M0.Dim, M1.Dim);
M.initTensor();
int* coord = new int[M.Dim.rank];
int* coord0 = new int[M0.Dim.rank], lin0;
int* coord1 = new int[M1.Dim.rank], lin1;
for (int i = 0; i < M.Dim.size; i++) {
M.Dim.LinearToCoord(coord, i);
subArray(coord0, coord, 0, M0.Dim.rank, 0);
subArray(coord1, coord, 0, M1.Dim.rank, M0.Dim.rank);
lin0 = (M0.Dim).CoordToLinear(coord0);
lin1 = (M1.Dim).CoordToLinear(coord1);
M.elements[i] = M0.elements[lin0] * M1.elements[lin1];
}
}
template
void tensorProd<double>(Tensor<double>& M, const Tensor<double>& M1, const Tensor<double>& M0);
template
void tensorProd<float>(Tensor<float>& M, const Tensor<float>& M1, const Tensor<float>& M0);
bool checkMatchProdTensor(const dimension& d0, const dimension& d1, int nestingDepth) {
if (d0.rank <= nestingDepth || d1.rank <= nestingDepth) return false;
for (int i = 0; i < nestingDepth;i++) {
if (d1.dim[i] != d0.dim[d0.rank - nestingDepth + i]) return false;
}
return true;
}
bool checkMatchProdTensorReverse(const dimension& d0, const dimension& d1, int nestingDepth) {
if (d0.rank <= nestingDepth || d1.rank <= nestingDepth) return false;
for (int i = 0; i < nestingDepth;i++) {
if (d1.dim[i] != d0.dim[d0.rank - 1 - i]) return false;
}
return true;
}
void extractDimNestingDepth(dimension& dM, const dimension& d0, const dimension& d1, int nestingDepth) {
int len0 = d0.rank - nestingDepth;
int len1 = d1.rank - nestingDepth;
int* tsub0 = new int[len0];
int* tsub1 = new int[len1];
int* tDk1 = new int[nestingDepth];
int* tDk0 = new int[nestingDepth];
subArray(tsub0, d0.dim, 0, len0, 0);
subArray(tsub1, d1.dim, 0, len1, nestingDepth);
subArray(tDk1, d1.dim, 0, nestingDepth, 0);
subArray(tDk0, d0.dim, 0, nestingDepth, len0);
dimension dSub0(len0, tsub0);
dimension dSub1(len1, tsub1);
dimension dM1(nestingDepth, tDk1);
dimension dM0(nestingDepth, tDk0);
min(dM, dM0, dM1);
//max(dM, dM0, dM1);
}
// M[x0,x1,x3..xn] X M[y0,y1,y3..ym] = M[z0,z1...zp] (deep = l > 0) /exists 1<= l<...<l=n / xl = y0,x{l+1}=y1, x{n}=yl et zi=xi i<n-l et zj=y{j-(n-l)} j>=n-l alor p=n+m-2l
// M[x0,x1,x3..xl x{l+1}...xn] X M[xn,x{n-1},x{n-2}...xl y{l+1} ..ym] = M[x0,x1..xly{l+1}...y{n+m-2l}] (deep = l > 0)
//M[[i][j]]=sum_{[k]}M0[[i][k]]*M[[k][j]]
template<typename T>
void tensorContractnProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1, int nestingDepth) {
if (!checkMatchProdTensor(M0.Dim, M1.Dim, nestingDepth)) {
printf("Deep = %d\n", nestingDepth);
//throw std::check_ProdTensor(" Failed imbrication order in Multiplication matrix ");
//throw std::invalid_argument(" Failed imbrication order in Multiplication matrix ");
}
int len0 = M0.Dim.rank - nestingDepth;
int len1 = M1.Dim.rank - nestingDepth;
int* tsub0 = new int[len0];
int* tsub1 = new int[len1];
int* tDk1 = new int[nestingDepth];
int* tDk0 = new int[nestingDepth];
subArray(tsub0, M0.Dim.dim, 0, len0, 0);
subArray(tsub1, M1.Dim.dim, 0, len1, nestingDepth);
subArray(tDk1, M1.Dim.dim, 0, nestingDepth, 0);
subArray(tDk0, M0.Dim.dim, 0, nestingDepth, len0);
dimension dSub0(len0, tsub0);
dimension dSub1(len1, tsub1);
dimension dM1(nestingDepth, tDk1);
dimension dM0(nestingDepth, tDk0);
dimension dM;
min(dM, dM0, dM1);
//max(dM, dM0, dM1);
add(M.Dim, dSub0, dSub1);
M.initTensor();
int* coord = new int[M.Dim.rank];
int* coord0 = new int[len0], lin0;
int* coord1 = new int[len1], lin1;
int* coordM0 = new int[M0.Dim.rank];
int* coordM1 = new int[M1.Dim.rank];
int* Koord = new int[nestingDepth];
for (int i = 0; i < M.Dim.size; i++) {
M.Dim.LinearToCoord(coord, i);
subArray(coord0, coord, 0, len0, 0);
subArray(coord1, coord, 0, len1, len0);
M.elements[i] = 0;
for (int k = 0; k < dM.size; k++) {
dM.LinearToCoord(Koord, k);
concatArray(coordM0, coord0, Koord, 0, 0, len0, 0, nestingDepth);
concatArray(coordM1, Koord, coord1, 0, 0, nestingDepth, 0, len1);
lin0 = (M0.Dim).CoordToLinear(coordM0);
lin1 = (M1.Dim).CoordToLinear(coordM1);
M.elements[i] += M0.elements[lin0] * M1.elements[lin1];
}
}
}
template
void tensorContractnProd<float>(Tensor<float>& M, const Tensor<float>& M0, const Tensor<float>& M1, int nestingDepth);
template
void tensorContractnProd<double>(Tensor<double>& M, const Tensor<double>& M0, const Tensor<double>& M1, int nestingDepth);
void reverseDim(dimension& d, const dimension& d0) {
d.rank = d0.rank;
d.size = d0.size;
if (d.dim != NULL) free(d.dim);
d.dim = (int*)malloc(d.rank * sizeof(int));
for (int i = 0; i < d.rank; i++) d.dim[i] = d0.dim[d.rank - i - 1];
}
template<typename T>
void reverseTensor(Tensor<T>& M, const Tensor<T>& M0) {
reverseDim(M.Dim, M0.Dim);
size_t id;
int coor[M0.Dim.rank];
for (size_t i = 0; i < M.Dim.size; i++) {
M0.Dim.LinearToCoord(coor, i);
reverseArray(coor, M0.Dim.rank);
id = M.Dim.CoordToLinear(coor);
M.elements[id] = M0.elements[i];
}
}
// M[x0,x1,x3..xn] X M[y0,y1,y3..ym] = M[z0,z1...zp] (deep = l > 0) /exists 1<= l<...<l=n / xn = y0,x{n-1}=y1, x{n-l}=yl et zi=xi i<n-l et zj=y{j-(n-l)} j>=n-l alor p=n+m-2l
// M[x0,x1,x3..xl x{l+1}..xn] X M[xn,x{n-1},..x{l+1}xl y{l+1}..ym] = M[x0,x1..xly{l+1}...y{n+m-2l}] (deep = l > 0)
//M[[i][j]]=sum_{[k]}M0[[i][k]]*M[[k][j]]
template<typename T>
void tensorContractnReverseProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1, int nestingDepth) {
if (!checkMatchProdTensorReverse(M0.Dim, M1.Dim, nestingDepth)) {
printf("Failed in Deep = %d\n", nestingDepth);
//throw std::check_ProdTensor(" Failed imbrication order in Multiplication matrix ");
//throw std::invalid_argument(" Failed imbrication order in Multiplication matrix ");
}
int len0 = M0.Dim.rank - nestingDepth;
int len1 = M1.Dim.rank - nestingDepth;
int* tsub0 = new int[len0];
int* tsub1 = new int[len1];
int* tDk1 = new int[nestingDepth];
int* tDk0 = new int[nestingDepth];
subArray(tsub0, M0.Dim.dim, 0, len0, 0);
subArray(tsub1, M1.Dim.dim, 0, len1, nestingDepth);
subArray(tDk1, M1.Dim.dim, 0, nestingDepth, 0);
subArray(tDk0, M0.Dim.dim, 0, nestingDepth, len0);
dimension dSub0(len0, tsub0);
dimension dSub1(len1, tsub1);
dimension dM1(nestingDepth, tDk1);
dimension dM0(nestingDepth, tDk0);
dimension dM;
bool rev;
minReverse(dM, dM0, dM1, rev);
if (rev) reverseArray(dM.dim, dM.rank);
//max(dM, dM0, dM1);
add(M.Dim, dSub0, dSub1);
M.initTensor();
int* coord = new int[M.Dim.rank];
int* coord0 = new int[len0], lin0;
int* coord1 = new int[len1], lin1;
int* coordM0 = new int[M0.Dim.rank];
int* coordM1 = new int[M1.Dim.rank];
int* Koord = new int[nestingDepth];
for (int i = 0; i < M.Dim.size; i++) {
M.Dim.LinearToCoord(coord, i);
subArray(coord0, coord, 0, len0, 0);
subArray(coord1, coord, 0, len1, len0);
M.elements[i] = 0;
for (int k = 0; k < dM.size; k++) {
dM.LinearToCoord(Koord, k);
concatArray(coordM0, coord0, Koord, 0, 0, len0, 0, nestingDepth);
reverseArray(Koord, nestingDepth);
concatArray(coordM1, Koord, coord1, 0, 0, nestingDepth, 0, len1);
lin0 = (M0.Dim).CoordToLinear(coordM0);
lin1 = (M1.Dim).CoordToLinear(coordM1);
M.elements[i] += M0.elements[lin0] * M1.elements[lin1];
}
}
}
template
void tensorContractnReverseProd<float>(Tensor<float>& M, const Tensor<float>& M0, const Tensor<float>& M1, int nestingDepth);
template
void tensorContractnReverseProd<double>(Tensor<double>& M, const Tensor<double>& M0, const Tensor<double>& M1, int nestingDepth);
template<typename T>
void permuteTensorDef(Tensor<T>& M, const Tensor<T>& M0, permutation p) {
if (p.size == M0.Dim.rank) {
M.Dim.rank = M0.Dim.rank;
M.Dim.size = M0.Dim.size;
M.Dim.initDim();
M.initTensor();
//permuteArray(M.Dim.dim, M0.Dim.dim, p);
//for (int i = 0; i < p.size; i++) { M.Dim.dim[i] = M0.Dim.dim[p.perm[i]]; }
p.permute(M.Dim.dim, M0.Dim.dim);
size_t img;
int coor[p.size];
int rooc[p.size];
for (size_t i = 0; i < M.Dim.size;i++) {
M0.Dim.LinearToCoord(coor, i);
p.permute(rooc, coor);
img = M.Dim.CoordToLinear(rooc);
if (img >= M.Dim.size) printf(" i: %ld vs img:%ld size: %ld\n", i, img, M.Dim.size);
M.elements[img] = M0.elements[i];
}
}
}
template
void permuteTensorDef(Tensor<float>& M, const Tensor<float>& M0, permutation p);
template<typename T>
bool scanPermuteMatchContractTensorfromSrcToDst(int* perm, const Tensor<T>& Msecond, const Tensor<T>& Mfirst, int contractNest) {
if (contractNest < Msecond.Dim.rank && contractNest < Mfirst.Dim.rank) {
std::vector<int> founded;
int begin = Mfirst.Dim.rank - contractNest, tmp;
for (int i = 0; i < Msecond.Dim.rank;i++) perm[i] = i;
for (int i = begin; i < Mfirst.Dim.rank; i++) {
for (int j = 0; j < Msecond.Dim.rank;j++) {
if (std::find(founded.begin(), founded.end(), perm[j]) == founded.end()) {// not found
if (Msecond.Dim.dim[perm[j]] == Mfirst.Dim.dim[i]) {
founded.push_back(perm[j]);
tmp = perm[i - begin];
perm[i - begin] = perm[j];
perm[j] = tmp;
}
}
}
}
return (founded.size() == contractNest);
}
return false;
}
template
bool scanPermuteMatchContractTensorfromSrcToDst(int* perm, const Tensor<float>& Msecond, const Tensor<float>& Mfirst, int contractNest);
template<typename T>
bool scanInvPermuteMatchContractTensorfromSrcToDst(int* perm, const Tensor<T>& Msecond, const Tensor<T>& Mfirst, int contractNest) {
if (contractNest < Msecond.Dim.rank && contractNest < Mfirst.Dim.rank) {
std::vector<int> founded;
int begin = Mfirst.Dim.rank - contractNest, tmp;
for (int i = 0; i < Msecond.Dim.rank;i++) perm[i] = i;
for (int i = begin; i < Mfirst.Dim.rank; i++) {
for (int j = 0; j < Msecond.Dim.rank;j++) {
if (std::find(founded.begin(), founded.end(), j) == founded.end()) {// not found
if (Msecond.Dim.dim[j] == Mfirst.Dim.dim[perm[i - begin]]) {
founded.push_back(j);
tmp = perm[i - begin];
perm[i - begin] = j;
perm[j] = tmp;
}
}
}
}
return (founded.size() == contractNest);
}
return false;
}
template
bool scanInvPermuteMatchContractTensorfromSrcToDst(int* perm, const Tensor<float>& Msecond, const Tensor<float>& Mfirst, int contractNest);
void LinearTransformCoord(size_t& dst, size_t src, int* inversePerm, size_t Msize, dimension dDst, dimension dSrc) {
size_t sm = src;
size_t pp = Msize;
size_t s = 0;
size_t p = 1;
int ret;// = new int[rank];
int i;
for (i = 0; i < dSrc.rank; ++i) {
pp /= dSrc.dim[i];
ret = sm / pp;
p = 1;
for (int j = inversePerm[i] + 1; j < dDst.rank;j++) {
p *= dDst.dim[j];
}
s += ret * p;
sm %= pp;
}
dst = s;
if (s > Msize) printf("I have a problem in LinearTransformCoord: s:%ld siez:%ld \n", s, Msize);
}
template<typename T>
void permuteTensor(Tensor<T>& M, const Tensor<T>& M0, permutation p) {
if (p.size == M0.Dim.rank) {
M.Dim.rank = M0.Dim.rank;
M.Dim.size = M0.Dim.size;
M.Dim.initDim();
M.initTensor();
if (p.size == M0.Dim.rank) p.permute(M.Dim.dim, M0.Dim.dim);
else {
printf("something wrong perm, not the same size as M0.Dim.rank\n");
exit(1);
}
size_t img = 0;
printf("in permuteTensor:\n");
M0.Dim.print();
M.Dim.print();
setInit se(M.Dim.rank, 0);
int invP[M.Dim.rank];
inverseArray(invP, p.perm, M.Dim.rank);
for (size_t i = 0; i < M.Dim.size;i++) {
//LinearTransformCoord(img, i, p.perm, M.Dim.size, M.Dim, M0.Dim);
LinearTransformCoord(img, i, invP, M.Dim.size, M.Dim, M0.Dim);
M.elements[img] = M0.elements[i];
}
}
}
template
void permuteTensor(Tensor<float>& M, const Tensor<float>& M0, permutation p);
src/tensor/tens0neD/tens0neD.h
+114
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@@ -0,0 +1,114 @@
#ifndef __TENS_0NE_D_H__
#define __TENS_0NE_D_H__
#include <cstdio>
#include <cstdlib>
#include <stdexcept>
//#include "tensor.h"
//#include "cudatensor.h"
//#include "/home/fanasina/progr_/ptens0neD/src/dimension/dimension.h"
//#include "/home/fanasina/progr_/ptens0neD/src/permutation/permutation.h"
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tensCuda/tensCuda.h"
#include "src/dimension/dimension.h"
#include "src/permutation/permutation.h"
#include "src/tensor/tensCuda/tensCuda.h"
template<typename T>
struct Tensor {
struct dimension Dim;
T* elements;
Tensor(struct dimension dm = dimension(1)) {
Dim = dm;
//elements = new T[Dim.size];
elements = (T*)malloc(Dim.size * sizeof(T));
}
void initTensor() {
//delete[]elements;
//elements = new T[Dim.size];
if (elements != NULL)
free(elements);
elements = (T*)malloc(Dim.size * sizeof(T));
}
void initVal(T val); // { for (int i = 0; i < Dim.size; i++) elements[i] = val + 0.001f * i; }
void print();
Tensor& operator=(const Tensor& M);
Tensor& operator*=(const T& val);
template<typename Ty>
friend Tensor<Ty>& operator*(const Tensor<Ty>& M0, const Tensor<Ty>& M1);
// M[x0,x1,x3..xn] X M[y0,y1,y3..ym] = M[z0,z1...zp] (deep = l > 0) /exists 1<= l<...<l=n / xl = y0,x{l+1}=y1, x{n}=yl et zi=xi i<n-l et zj=y{j-(n-l)} j>=n-l alor p=n+m-2l
// M[x0,x1,x3..xl x{l+1}...xn] X M[xn,x{n-1},x{n-2}...xl y{l+1} ..ym] = M[x0,x1..xly{l+1}...y{n+m-2l}] (deep = l > 0)
template<typename Ty>
friend void tensorContractnProd(Tensor<Ty>& M, const Tensor<Ty>& M0, const Tensor<Ty>& M1, int nestingDepth);
// M[x0,x1,x3..xn] X M[y0,y1,y3..ym] = M[z0,z1...zp] (deep = l > 0) /exists 1<= l<...<l=n / xn = y0,x{n-1}=y1, x{n-l}=yl et zi=xi i<n-l et zj=y{j-(n-l)} j>=n-l alor p=n+m-2l
// M[x0,x1,x3..xl x{l+1}..xn] X M[xn,x{n-1},..x{l+1}xl y{l+1}..ym] = M[x0,x1..xly{l+1}...y{n+m-2l}] (deep = l > 0)
template<typename Ty>
friend void tensorContractnReverseProd(Tensor<Ty>& M, const Tensor<Ty>& M0, const Tensor<Ty>& M1, int nestingDepth);
template<typename Ty>
friend void cudaTensorContractNestProd(Tensor<Ty>& M, const Tensor<Ty>& M0, const Tensor<Ty>& M1, int nestingDepth, bool strict);
/*template<typename Ty>
friend void cudaTensorContractnProd(Tensor<Ty>& M, const Tensor<Ty>& M0, const Tensor<Ty>& M1, int nestingDepth);
*/
template<typename Ty>
friend void tensorProd(Tensor<Ty>& M, const Tensor<Ty>& M0, const Tensor<Ty>& M1);
template<typename Ty>
friend void cudaTensorProd(Tensor<Ty>& M, const Tensor<Ty>& M0, const Tensor<Ty>& M1);
template<typename Ty>
friend void cudaTensorProdEnd(Tensor<Ty>& M, const Tensor<Ty>& M0, const Tensor<Ty>& M1);
template<typename Ty>
friend void permuteTensor(Tensor<Ty>& M, const Tensor<Ty>& M0, permutation p);
template<typename Ty>
friend void permuteTensorDef(Tensor<Ty>& M, const Tensor<Ty>& M0, permutation p);
template<typename Tp>
friend bool scanPermuteMatchContractTensorfromSrcToDst(int* perm, const Tensor<Tp>& Msecond, const Tensor<Tp>& Mfirst, int contractNest);
//template<typename Ty>
//friend void cudapermuteTensor(Tensor<Ty>& M, const Tensor<Ty>& M0, permutation p);
};
template<typename T>
void transform(Tensor<T>& Dst, const Tensor<T>& Src, int* perm, int sz);
template<typename T>
Tensor<T>& operator*(const Tensor<T>& M0, const Tensor<T>& M1);
void subArray(int* dst, int* src, int debDst, int finDst, int debSrc);
void concatArray(int* dst, int* src0, int* src1, int debDst, int debSrc0, int finSrc0, int debSrc1, int finSrc1);
void reverseArray(int* arr, int sz);
template<typename T>
void tensorProd(Tensor<T>& M, const Tensor<T>& M1, const Tensor<T>& M0);
bool checkMatchProdTensor(const dimension& d0, const dimension& d1, int nestingDepth);
void extractDimNestingDepth(dimension& dM, const dimension& d0, const dimension& d1, int nestingDepth);
// M[x0,x1,x3..xn] X M[y0,y1,y3..ym] = M[z0,z1...zp] (deep = l > 0) /exists 1<= l<...<l=n / xn = y0,x{n-1}=y1, x{n-l}=yl et zi=xi i<n-l et zj=y{j-(n-l)} j>=n-l alor p=n+m-2l
//M[[i][j]]=sum_{[k]}M0[[i][k]]*M[[k][j]]
template<typename T>
void tensorContractnProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1, int nestingDepth);
// M[x0,x1,x3..xn] X M[y0,y1,y3..ym] = M[z0,z1...zp] (deep = l > 0) /exists 1<= l<...<l=n / xn = y0,x{n-1}=y1, x{n-l}=yl et zi=xi i<n-l et zj=y{j-(n-l)} j>=n-l alor p=n+m-2l
//M[[i][j]]=sum_{[k]}M0[[i][k]]*M[[k][j]]
template<typename T>
void tensorContractnReverseProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1, int nestingDepth);
#endif
src/tensor/tensCuda/d_tensCuda.cu
+493
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@@ -0,0 +1,493 @@
/*#include <cuda.h>
#include <cuda_runtime.h>
#include "cuda.h"
#include "cuda_runtime.h"
*/
#include "d_tensCuda.h"
//#include "index.h"
#include <stdio.h>
////////////////////////////////////////////////////////
//1D grid of 1D blocks
__device__
int d_getGlobalIdx_1D_1D() {
return blockIdx.x * blockDim.x + threadIdx.x;
}
//1D grid of 2D blocks
__device__
int d_getGlobalIdx_1D_2D() {
return blockIdx.x * blockDim.x * blockDim.y
+ threadIdx.y * blockDim.x + threadIdx.x;
}
//1D grid of 3D blocks
__device__
int d_getGlobalIdx_1D_3D() {
return blockIdx.x * blockDim.x * blockDim.y * blockDim.z
+ threadIdx.z * blockDim.y * blockDim.x
+ threadIdx.y * blockDim.x + threadIdx.x;
}
//2D grid of 1D blocks
__device__ int d_getGlobalIdx_2D_1D() {
int blockId
= blockIdx.y * gridDim.x + blockIdx.x;
int threadId = blockId * blockDim.x + threadIdx.x;
return threadId;
}
//2D grid of 2D blocks
__device__
int d_getGlobalIdx_2D_2D() {
int blockId = blockIdx.x + blockIdx.y * gridDim.x;
int threadId = blockId * (blockDim.x * blockDim.y)
+ (threadIdx.y * blockDim.x) + threadIdx.x;
return threadId;
}
//2D grid of 3D blocks
__device__
int d_getGlobalIdx_2D_3D() {
int blockId = blockIdx.x + blockIdx.y * gridDim.x;
int threadId = blockId * (blockDim.x * blockDim.y * blockDim.z)
+ (threadIdx.z * (blockDim.x * blockDim.y))
+ (threadIdx.y * blockDim.x) + threadIdx.x;
return threadId;
}
//3D grid of 1D blocks
__device__
int d_getGlobalIdx_3D_1D() {
int blockId = blockIdx.x + blockIdx.y * gridDim.x
+ gridDim.x * gridDim.y * blockIdx.z;
int threadId = blockId * blockDim.x + threadIdx.x;
return threadId;
}
//3D grid of 2D blocks
__device__
int d_getGlobalIdx_3D_2D() {
int blockId = blockIdx.x + blockIdx.y * gridDim.x
+ gridDim.x * gridDim.y * blockIdx.z;
int threadId = blockId * (blockDim.x * blockDim.y)
+ (threadIdx.y * blockDim.x) + threadIdx.x;
return threadId;
}
//3D grid of 3D blocks
__device__
int d_getGlobalIdx_3D_3D() {
int blockId = blockIdx.x + blockIdx.y * gridDim.x
+ gridDim.x * gridDim.y * blockIdx.z;
int threadId = blockId * (blockDim.x * blockDim.y * blockDim.z)
+ (threadIdx.z * (blockDim.x * blockDim.y))
+ (threadIdx.y * blockDim.x) + threadIdx.x;
return threadId;
}
///////////////////////////////////////////////////////////////////////////
__device__ void d_LinearToCoordEnd(int* ret, size_t lin, int* dim, int rank, size_t size) {
size_t sm = lin;
size_t pp = size;
for (int i = rank - 1;i > 0; --i) {
pp /= dim[i];
ret[i] = sm / pp;
sm %= pp;
}
ret[0] = sm;
}
__device__ size_t d_CoordToLinearEnd(int* coo, int* dim, int rank) {
size_t pp = 1;
size_t sm = 0;
for (int i = 0; i < rank; ++i) {
sm += (coo[i] * pp);
pp *= dim[i];
}
return sm;
}
__device__ size_t d_CoordToLinear(int* coo, int* dim, int rank) {
size_t pp = 1;
size_t sm = 0;
for (int i = rank - 1; i >= 0; --i) {
sm += (coo[i] * pp);
pp *= dim[i];
}
return sm;
}
__device__ void d_LinearToCoord(int* ret, size_t lin, int* dim, int rank, size_t size) {
size_t sm = lin;
size_t pp = size;
for (int i = 0; i < rank - 1; ++i) {
pp /= dim[i];
ret[i] = sm / pp;
sm %= pp;
}
ret[rank - 1] = sm;
}
/*__device__ void d_LinearToSplitSubrankLimSz(size_t& part0, size_t& part1, size_t lin, int* dim, int rank, int rankA, size_t size, size_t sizeA) {
size_t sm = lin;
size_t pp = size;
size_t s = 0;
size_t p = sizeA;
int ret;// = new int[rank];
for (int i = 0; i < rank; ++i) {
pp /= dim[i];
ret = sm / pp;
p /= dim[i];
s += ret * p;
sm %= pp;
if (i == rankA - 1) {
part0 = s;
s = 0;
p = size / sizeA;
}
}
part1 = s;
}*/
__device__ void d_LinearToSplitSubrankLimSz(size_t& part0, size_t& part1, size_t lin, int* dim, int rank, int rankA, size_t size, size_t sizeA) {
size_t sm = lin;
size_t pp = size;
size_t s = 0;
size_t p = sizeA;
int ret;// = new int[rank];
int i;
for (i = 0; i < rankA; ++i) {
pp /= dim[i];
ret = sm / pp;
p /= dim[i];
s += ret * p;
sm %= pp;
}
part0 = s;
s = 0;
p = size / sizeA;//sizeB
for (; i < rank; ++i) {
pp /= dim[i];
ret = sm / pp;
p /= dim[i];
s += ret * p;
sm %= pp;
}
part1 = s;
}
__device__ void d_LinearToSplitSubrankLimSzEnd(size_t& part0, size_t& part1, size_t lin, int* dim, int rank, int rankA, size_t size, size_t sizeA) {
size_t sm = lin;
size_t pp = size;
size_t s = 0;
size_t p = sizeA;
int ret;// = new int[rank];
for (int i = rank - 1; i >= 0; --i) {
pp /= dim[i];
ret = sm / pp;
p /= dim[i];
s += ret * p;
sm %= pp;
if (i == rankA) {
part1 = s;
s = 0;
p = size / sizeA;
}
}
part0 = s;
}
__device__ void d_subArray(int* dst, int* src, int debDst, int finDst, int debSrc) {
for (int i = debDst; i < finDst; i++) {
dst[i] = src[i + debSrc];
}
}
template<typename T>
__global__ void d_prodTensor(T* C, int* dimC, int rankC, size_t size, T* A, int* dimA, int rankA, size_t sizeA, T* B, int* dimB, int rankB) {
size_t lin0, lin1;
size_t i = threadIdx.x + blockIdx.x * blockDim.x;
if (i < size) {
d_LinearToSplitSubrankLimSz(lin0, lin1, i, dimC, rankC, rankA, size, sizeA);
C[i] = A[lin0] * B[lin1];
}
}
template __global__ void d_prodTensor<float>(float* C, int* dimC, int rankC, size_t size, float* A, int* dimA, int rankA, size_t sizeA, float* B, int* dimB, int rankB);
template<typename T>
__global__ void d_prodTensorEnd(T* C, int* dimC, int rankC, size_t size, T* A, int* dimA, int rankA, size_t sizeA, T* B, int* dimB, int rankB) {
size_t lin0, lin1;
size_t i = threadIdx.x + blockIdx.x * blockDim.x;
if (i < size) {
d_LinearToSplitSubrankLimSzEnd(lin0, lin1, i, dimC, rankC, rankA, size, sizeA);
C[i] = A[lin0] * B[lin1];
}
}
template __global__ void d_prodTensorEnd<float>(float* C, int* dimC, int rankC, size_t size, float* A, int* dimA, int rankA, size_t sizeA, float* B, int* dimB, int rankB);
__device__ void d_minReverse(int* dim, int& rank, const int* dim0, int rank0, const int* dim1, int rank1, bool& rev) {
if (rank0 > rank1) {
rank = rank1;
for (int i = 0; i < rank1; ++i) dim[i] = dim1[i];
rev = true;
}
else if (rank0 < rank1) {
rank = rank0;
for (int i = 0; i < rank1; ++i) dim[i] = dim0[i];
rev = false;
}
else {// rank0 == rank1
rank = rank0;
for (int i = 0; i < rank0; i++) {
if (dim[i] > dim1[rank1 - 1 - i]) dim[i] = dim1[rank1 - 1 - i];
else dim[i] = dim0[i];
}
rev = false;
}
}
__device__ void d_reverseArray(int* arr, int sz) {
int* tmp;
//tmp = (int*)malloc(sz * sizeof(int));
tmp = new int[sz];
if (tmp == NULL) {
size_t limit = 0;
cudaDeviceGetLimit(&limit, cudaLimitStackSize);
printf("cudaLimitStackSize: %u | %d (%d) %d | \n", (unsigned)limit, blockIdx.x, blockDim.x, threadIdx.x);
cudaDeviceGetLimit(&limit, cudaLimitPrintfFifoSize);
printf("cudaLimitPrintfFifoSize: %u | %d (%d) %d | \n", (unsigned)limit, blockIdx.x, blockDim.x, threadIdx.x);
cudaDeviceGetLimit(&limit, cudaLimitMallocHeapSize);
printf("cudaLimitMallocHeapSize: %u | %d (%d) %d | \n", (unsigned)limit, blockIdx.x, blockDim.x, threadIdx.x);
printf("error Allocation in tmp = (int*)malloc(sz * sizeof(int)); | | ");
}int i = 0;
for (; i < sz / 2; i++) {
tmp[i] = arr[i];
arr[i] = arr[sz - 1 - i];
}
for (; i < sz; i++) {
arr[i] = tmp[sz - 1 - i];
}
//free(tmp);
delete[]tmp;
}
__device__ int d_min(int a, int b) {
if (a < b) return a;
return b;
}
__device__ void d_concatArray(int* dst, int* src0, int* src1, int debDst, int debSrc0, int finSrc0, int debSrc1, int finSrc1) {
int i = debDst;
for (int j = debSrc0; j < finSrc0; j++) {
dst[i++] = src0[j];
}
for (int j = debSrc1; j < finSrc1; j++) {
dst[i++] = src1[j];
}
}
__device__ void d_ConcatLinearToSplitSubrankLimSz(size_t& part0, size_t& part1, size_t lin, int* dim, int rank, int rankA, int rankB, size_t size, size_t sizeA, size_t sizeB, int* dM, int dMrank, size_t dMsize, int ind) {
size_t sm = lin;
size_t pp = size;
size_t s = 0;
size_t p = sizeA;
//size_t sz_dA = sizeA / dMsize;
int rankdA = rankA - dMrank;
int ret;
int i;
for (i = 0; i < rankdA; ++i) {
pp /= dim[i];
ret = sm / pp;
p /= dim[i];
s += ret * p;
sm %= pp;
}
size_t s1 = 0;
size_t pb = sizeB / dMsize;
for (; i < rank; ++i) {
pp /= dim[i];
ret = sm / pp;
pb /= dim[i];
s1 += ret * pb;
sm %= pp;
}
size_t smd = ind;
size_t ppb = dMsize;
//size_t pb = size / sz_dA;
pb = sizeB;
p = dMsize;
for (int j = 0;j < dMrank;j++) {
ppb /= dM[j];
ret = smd / ppb;
p /= dM[j];
s += ret * p;
pb /= dM[j];
s1 += ret * pb;
smd %= ppb;
}
//pp = size / sz_dA;
part0 = s;
part1 = s1;
}
__device__ void d_SplitLineardToSubrank(size_t& part0, size_t& part1, size_t lin, int* dim, int rank, int rankA, int rankB, size_t size, size_t sizeA, size_t sizeB, int* dM, int dMrank, size_t dMsize) {
size_t sm = lin;
size_t pp = size;
size_t s = 0;
size_t p = sizeA;
//size_t sz_dA = sizeA / dMsize;
int rankdA = rankA - dMrank;
int ret;
int i;
for (i = 0; i < rankdA; ++i) {
pp /= dim[i];
ret = sm / pp;
p /= dim[i];
s += ret * p;
sm %= pp;
}
size_t s1 = 0;
size_t pb = sizeB / dMsize;
for (; i < rank; ++i) {
pp /= dim[i];
ret = sm / pp;
pb /= dim[i];
s1 += ret * pb;
sm %= pp;
}
part0 = s;
part1 = s1;
}
__device__ void d_UnionConcatLinearSplitedSubrank(size_t& part0, size_t& part1, size_t p0, size_t p1, size_t size, size_t sizeB, int* dM, int dMrank, size_t dMsize, int ind) {
size_t s = p0;
size_t s1 = p1;
int ret;
size_t smd = ind;
size_t ppb = dMsize;
//size_t pb = size / sz_dA;
size_t pb = sizeB;
size_t p = dMsize;
for (int j = 0;j < dMrank;j++) {
ppb /= dM[j];
ret = smd / ppb;
p /= dM[j];
s += ret * p;
pb /= dM[j];
s1 += ret * pb;
smd %= ppb;
}
//pp = size / sz_dA;
part0 = s;
part1 = s1;
}
template<typename T>
__global__ void d_TensorContractnReverseProd(T* C, int* dimC, int rankC, size_t sizeC, T* A, int rankA, size_t sizeA, T* B, int rankB, size_t sizeB, int* dM, int dMrank, size_t dMsize) {
size_t p0, p1;
size_t lin0, lin1;
//size_t i = threadIdx.x + blockIdx.x * blockDim.x;
size_t i = d_getGlobalIdx_1D_1D();
if (i < sizeC) {
d_SplitLineardToSubrank(p0, p1, i, dimC, rankC, rankA, rankB, sizeC, sizeA, sizeB, dM, dMrank, dMsize);
C[i] = 0;
for (size_t k = 0; k < dMsize; k++) {
d_UnionConcatLinearSplitedSubrank(lin0, lin1, p0, p1, sizeC, sizeB, dM, dMrank, dMsize, k);
//d_ConcatLinearToSplitSubrankLimSz(lin0, lin1, i, dimC, rankC, rankA, rankB, sizeC, sizeA, sizeB, dM, dMrank, dMsize, k);
C[i] += A[lin0] * B[lin1];
}
}
}
template
__global__ void d_TensorContractnReverseProd<float>(float* C, int* dimC, int rankC, size_t size, float* A, int rankA, size_t sizeA, float* B, int rankB, size_t sizeB, int* dM, int dMrank, size_t dMsize);
__device__ void d_LinearTransformCoord(size_t& dst, size_t src, int* inversePerm, size_t sizeA, int rankDst, int rankSrc, int* dDst, int* dSrc) {
size_t sm = src;
size_t pp = sizeA;
size_t s = 0;
size_t p = 1;
int ret;// = new int[rank];
int i, j;
for (i = 0; i < rankSrc; ++i) {
pp /= dSrc[i];
ret = sm / pp;
p = 1;
for (j = inversePerm[i] + 1; j < rankDst;j++) {
p *= dDst[j];
}
s += ret * p;
sm %= pp;
}
dst = s;
if (s > sizeA) printf("I have a problem in LinearTransformCoord: s:%ld siez:%ld \n", s, sizeA);
}
template<typename T>
__global__ void d_PermLinearTransformCoord(T* C, int* dimC, int rankC, size_t sizeC, T* A, int* dimA, int rankA, size_t sizeA, int* invPerm) {
//size_t i = threadIdx.x + blockIdx.x * blockDim.x;
size_t i = d_getGlobalIdx_1D_1D();
if (i < sizeC) {
//printf("<i:%*ld ", 3, i);
size_t img = 0;
//printf("<i:%*ld, img:%*ld\n", 3, i, 3, img);
d_LinearTransformCoord(img, i, invPerm, sizeA, rankC, rankA, dimC, dimA);
//img = d_LinearTransformCoord(i, invPerm, sizeC, dimC, dimA, rankC);
if (img < sizeC)
C[img] = A[i];
else {
printf("something wrong in device: i:%ld , s:%ld\n", i, img);
}
}
}
template
__global__ void d_PermLinearTransformCoord<float>(float* C, int* dimC, int rankC, size_t size, float* A, int* dimA, int rankA, size_t sizeA, int* invPerm);
src/tensor/tensCuda/d_tensCuda.h
+69
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@@ -0,0 +1,69 @@
#ifndef __D_CUDA_TENSOR_H__
#define __D_CUDA_TENSOR_H__
#include "cuda.h"
#include "cuda_runtime.h"
//#include "cuda_device_runtime_api.h"
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tensCuda/d_tensCuda.h"
#include "src/tensor/tensCuda/d_tensCuda.h"
//#1D grid of 1D blocks
__device__ int d_getGlobalIdx_1D_1D();
//#1D grid of 2D blocks
__device__ int d_getGlobalIdx_1D_2D();
//#1D grid of 3D blocks
__device__ int d_getGlobalIdx_1D_3D();
//#1D grid of 1D blocks
__device__ int d_getGlobalIdx_2D_1D();
//#1D grid of 2D blocks
__device__ int d_getGlobalIdx_2D_2D();
//2D grid of 3D blocks
__device__ int d_getGlobalIdx_2D_3D();
//#1D grid of 1D blocks
__device__ int d_getGlobalIdx_3D_1D();
//#1D grid of 2D blocks
__device__ int d_getGlobalIdx_3D_2D();
//#1D grid of 3D blocks
__device__ int d_getGlobalIdx_3D_3D();
extern cudaError_t cudaDeviceGetLimit(size_t* pValue, enum cudaLimit limit);
__device__ void d_LinearToCoordEnd(int* ret, size_t lin, int* dim, int rank, size_t size);
__device__ size_t d_CoordToLinearEnd(int* coo, int* dim, int rank);
__device__ size_t d_CoordToLinear(int* coo, int* dim, int rank);
__device__ void d_LinearToCoord(int* ret, size_t lin, int* dim, int rank, size_t size);
__device__ void d_subArray(int* dst, int* src, int debDst, int finDst, int debSrc);
__device__ void d_minReverse(int* dim, int& rank, const int* dim0, int rank0, const int* dim1, int rank1, bool& rev);
__device__ void d_reverseArray(int* arr, int sz);
__device__ int d_min(int a, int b);
__device__ void d_concatArray(int* dst, int* src0, int* src1, int debDst, int debSrc0, int finSrc0, int debSrc1, int finSrc1);
template<typename T>
__global__ void d_prodTensor(T* C, int* dimC, int rankC, size_t size, T* A, int* dimA, int rankA, size_t sizeA, T* B, int* dimB, int rankB);
template<typename T>
__global__ void d_prodTensorEnd(T* C, int* dimC, int rankC, size_t size, T* A, int* dimA, int rankA, size_t sizeA, T* B, int* dimB, int rankB);
template<typename T>
__global__ void d_TensorContractnReverseProd(T* C, int* dimC, int rankC, size_t size, T* A, int rankA, size_t sizeA, T* B, int rankB, size_t sizeB, int* dM, int dMrank, size_t dMsize);
template<typename T>
__global__ void d_PermLinearTransformCoord(T* C, int* dimC, int rankC, size_t sizeC, T* A, int* dimA, int rankA, size_t sizeA, int* invPerm);
#endif
src/tensor/tensCuda/tensCuda.cu
+574
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@@ -0,0 +1,574 @@
#include <cstdio>
#include <cstdlib>
#include <stdexcept>
#include <vector>
#include <algorithm>
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tens0neD/tens0neD.h"
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tensCuda/tensCuda.h"
#include "src/tensor/tensCuda/tensCuda.h"
template<typename T>
void cudaTensorProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1) {
add(M.Dim, M0.Dim, M1.Dim);
M.initTensor();
int* d_imM, * d_imM0, * d_imM1;
cudaError_t errCu = cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imM1, M1.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM1, M1.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM1, M1.Dim.dim, M1.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM1, M1.Dim.dim, M1.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
T* e, * e0, * e1;
errCu = cudaMalloc((void**)&e, M.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e, M.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&e1, M1.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e1, M1.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(e1, M1.elements, M1.Dim.size * sizeof(T), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(e1, M1.elements, M1.Dim.size * sizeof(T), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
int BLOCKSIZE = 256;//1024;
int DIMBLOCKS = (M.Dim.size + BLOCKSIZE - 1) / BLOCKSIZE;
//int DIMBLOCKS = (M.Dim.size) / BLOCKSIZE;
d_prodTensor<T> << < DIMBLOCKS, BLOCKSIZE >> > (e, d_imM, M.Dim.rank, M.Dim.size, e0, d_imM0, M0.Dim.rank, M0.Dim.size, e1, d_imM1, M1.Dim.rank);
errCu = cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e1);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e1) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM1);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM1) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
}
//template void cudaTensorProd<double>(Tensor<double>& M, const Tensor<double>& M1, const Tensor<double>& M0);
template void cudaTensorProd<float>(Tensor<float>& M, const Tensor<float>& M1, const Tensor<float>& M0);
template<typename T>
void cudaTensorProdEnd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1) {
add(M.Dim, M0.Dim, M1.Dim);
M.initTensor();
int* d_imM, * d_imM0, * d_imM1;
cudaError_t errCu = cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imM1, M1.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM1, M1.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM1, M1.Dim.dim, M1.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM1, M1.Dim.dim, M1.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
T* e, * e0, * e1;
errCu = cudaMalloc((void**)&e, M.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e, M.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&e1, M1.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e1, M1.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(e1, M1.elements, M1.Dim.size * sizeof(T), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(e1, M1.elements, M1.Dim.size * sizeof(T), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
size_t BLOCKSIZE = 1024;
size_t DIMBLOCKS = (M.Dim.size + BLOCKSIZE - 1) / BLOCKSIZE;
d_prodTensorEnd<T> << < DIMBLOCKS, BLOCKSIZE >> > (e, d_imM, M.Dim.rank, M.Dim.size, e0, d_imM0, M0.Dim.rank, M0.Dim.size, e1, d_imM1, M1.Dim.rank);
cudaDeviceSynchronize();
errCu = cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e1);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e1) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM1);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM1) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
}
//template void cudaTensorProd<double>(Tensor<double>& M, const Tensor<double>& M1, const Tensor<double>& M0);
template void cudaTensorProdEnd<float>(Tensor<float>& M, const Tensor<float>& M1, const Tensor<float>& M0);
template<typename T>
void cudapermuteTensor(Tensor<T>& M, const Tensor<T>& M0, permutation p) {
if (p.size == M0.Dim.rank) {
M.Dim.rank = M0.Dim.rank;
M.Dim.size = M0.Dim.size;
M.Dim.initDim();
M.initTensor();
p.permute(M.Dim.dim, M0.Dim.dim);
cudaEvent_t start, stop;
cudaEventCreate(&start);
cudaEventCreate(&stop);
cudaEventRecord(start);
int* d_imM, * d_imM0;
cudaError_t errCu = cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
T* e, * e0;
errCu = cudaMalloc((void**)&e, M.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e, M.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
size_t BLOCKSIZE = 256; //1024;//512;
size_t DIMBLOCKS = (M.Dim.size + BLOCKSIZE - 1) / BLOCKSIZE;
dim3 blckSZ, gridSZ;
blckSZ.x = BLOCKSIZE;
gridSZ.x = DIMBLOCKS;
int* invP, * d_invP;
invP = (int*)malloc(M.Dim.rank * sizeof(int));
inverseArray(invP, p.perm, M.Dim.rank);
errCu = cudaMalloc((void**)&d_invP, M.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_invP, M.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_invP, invP, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_invP, invP, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
//printf("size: %ld\n", M.Dim.size);
//d_prodTensorEnd<T> << < DIMBLOCKS, BLOCKSIZE >> > (e, d_imM, M.Dim.rank, M.Dim.size, e0, d_imM0, M0.Dim.rank, e1, d_imM1, M1.Dim.rank);
//d_TensorContractnReverseProd<T> << < DIMBLOCKS, BLOCKSIZE >> > (e, d_imM, M.Dim.rank, M.Dim.size, d_imdM, dM.rank, dM.size, e0, d_imM0, M0.Dim.rank, e1, d_imM1, M1.Dim.rank, nestingDepth);
//d_TensorContractnReverseProd<T> << < gridSZ, blckSZ, 0, 0 >> > (e, d_imM, M.Dim.rank, M.Dim.size, d_imdM, dM.rank, dM.size, e0, d_imM0, M0.Dim.rank, e1, d_imM1, M1.Dim.rank, nestingDepth);
d_PermLinearTransformCoord<T> << < gridSZ, blckSZ, 0, 0 >> > (e, d_imM, M.Dim.rank, M.Dim.size, e0, d_imM0, M0.Dim.rank, M0.Dim.size, d_invP);
//d_PermLinearTransformCoord<T> << < gridSZ, blckSZ, 0, 0 >> > (e, d_imM, M.Dim.rank, M.Dim.size, e0, d_imM0, M0.Dim.rank, M0.Dim.size, p.perm);
//cudaDeviceSynchronize();
errCu = cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
cudaEventRecord(stop);
cudaEventSynchronize(stop);
float milliseconds = 0;
cudaEventElapsedTime(&milliseconds, start, stop);
printf("ellaps time cuda permute tensor: %f ms\n", milliseconds);
}
}
template
void cudapermuteTensor(Tensor<float>& M, const Tensor<float>& M0, permutation p);
// strict match contract ! if no strict, we take the minimum
template<typename T>
void cudaTensorContractNestProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M11, int nestingDepth, bool strict) {
int perm[M11.Dim.rank];
struct Tensor<T> M1;
if (scanPermuteMatchContractTensorfromSrcToDst(perm, M11, M0, nestingDepth)) {
for (int i = 0; i < M11.Dim.rank; i++) printf(" %d[%d] ", i, perm[i]); printf(": last perm \n");
struct permutation p(M11.Dim.rank, perm);
permuteTensor(M1, M11, p);
M1.Dim.print();
}
else {
printf("Failed in Deep = %d\n", nestingDepth);
//throw std::check_ProdTensor(" Failed imbrication order in Multiplication matrix ");
throw std::invalid_argument(" Failed imbrication order in Multiplication matrix ");
exit(1);
}
cudaEvent_t start, stop;
cudaEventCreate(&start);
cudaEventCreate(&stop);
cudaEventRecord(start);
int len0 = M0.Dim.rank - nestingDepth;
int len1 = M1.Dim.rank - nestingDepth;
int* tsub0 = new int[len0];
int* tsub1 = new int[len1];
int* tDk1 = new int[nestingDepth];
int* tDk0 = new int[nestingDepth];
subArray(tsub0, M0.Dim.dim, 0, len0, 0);
subArray(tsub1, M1.Dim.dim, 0, len1, nestingDepth);
subArray(tDk1, M1.Dim.dim, 0, nestingDepth, 0);
subArray(tDk0, M0.Dim.dim, 0, nestingDepth, len0);
dimension dSub0(len0, tsub0);
dimension dSub1(len1, tsub1);
dimension dM1(nestingDepth, tDk1);
dimension dM0(nestingDepth, tDk0);
dimension dM(dM0);
//bool rev;
//minReverse(dM, dM0, dM1, rev);
//if (rev) reverseArray(dM.dim, dM.rank);
//max(dM, dM0, dM1);
add(M.Dim, dSub0, dSub1);
M.initTensor();
int* d_imM, * d_imM0, * d_imM1, * d_imdM;
cudaError_t errCu = cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM, M.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imdM, dM.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imdM, dM.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM0, M0.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&d_imM1, M1.Dim.rank * sizeof(int));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&d_imM1, M1.Dim.rank * sizeof(int)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM, M.Dim.dim, M.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imdM, dM.dim, dM.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imdM, dM.dim, dM.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM0, M0.Dim.dim, M0.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(d_imM1, M1.Dim.dim, M1.Dim.rank * sizeof(int), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(d_imM1, M1.Dim.dim, M1.Dim.rank * sizeof(int), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
T* e, * e0, * e1;
errCu = cudaMalloc((void**)&e, M.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e, M.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e0, M0.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMalloc((void**)&e1, M1.Dim.size * sizeof(T));
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMalloc((void**)&e1, M1.Dim.size * sizeof(T)) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(e0, M0.elements, M0.Dim.size * sizeof(T), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaMemcpy(e1, M1.elements, M1.Dim.size * sizeof(T), cudaMemcpyHostToDevice);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(e1, M1.elements, M1.Dim.size * sizeof(T), cudaMemcpyHostToDevice) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
size_t BLOCKSIZE = 256; //1024;//512;
size_t DIMBLOCKS = (M.Dim.size + BLOCKSIZE - 1) / BLOCKSIZE;
dim3 blckSZ, gridSZ;
blckSZ.x = BLOCKSIZE;
gridSZ.x = DIMBLOCKS;
//d_prodTensorEnd<T> << < DIMBLOCKS, BLOCKSIZE >> > (e, d_imM, M.Dim.rank, M.Dim.size, e0, d_imM0, M0.Dim.rank, e1, d_imM1, M1.Dim.rank);
//d_TensorContractnReverseProd<T> << < DIMBLOCKS, BLOCKSIZE >> > (e, d_imM, M.Dim.rank, M.Dim.size, d_imdM, dM.rank, dM.size, e0, d_imM0, M0.Dim.rank, e1, d_imM1, M1.Dim.rank, nestingDepth);
//d_TensorContractnReverseProd<T> << < gridSZ, blckSZ, 0, 0 >> > (e, d_imM, M.Dim.rank, M.Dim.size, d_imdM, dM.rank, dM.size, e0, d_imM0, M0.Dim.rank, e1, d_imM1, M1.Dim.rank, nestingDepth);
d_TensorContractnReverseProd<T> << < gridSZ, blckSZ, 0, 0 >> > (e, d_imM, M.Dim.rank, M.Dim.size, e0, M0.Dim.rank, M0.Dim.size, e1, M1.Dim.rank, M1.Dim.size, d_imdM, dM.rank, dM.size);
//cudaDeviceSynchronize();
errCu = cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaMemcpy(M.elements, e, M.Dim.size * sizeof(T), cudaMemcpyDeviceToHost) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(e1);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(e1) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM0);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM0) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
errCu = cudaFree(d_imM1);
if (cudaSuccess != errCu) {
printf("device fnc failed cudaFree(d_imM1) \n ErrorCuda: %d : %s\n", errCu, cudaGetErrorString(errCu));
exit(errCu);
}
cudaEventRecord(stop);
cudaEventSynchronize(stop);
float milliseconds = 0;
cudaEventElapsedTime(&milliseconds, start, stop);
printf("ellaps time cuda prod contract prod: %f ms\n", milliseconds);
}
template
void cudaTensorContractNestProd<float>(Tensor<float>& M, const Tensor<float>& M0, const Tensor<float>& M1, int nestingDepth, bool strict);
//template void cudaTensorContractnReverseProd<double>(Tensor<double>& M, const Tensor<double>& M0, const Tensor<double>& M1, int nestingDepth);
src/tensor/tensCuda/tensCuda.h
+31
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@@ -0,0 +1,31 @@
#ifndef __TENS_CUDA_H__
#define __TENS_CUDA_H__
#include <cstdio>
#include <cstdlib>
#include <stdexcept>
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tens0neD/tens0neD.h"
#include "src/tensor/tens0neD/tens0neD.h"
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tensCuda/d_tensCuda.h"
#include "src/tensor/tensCuda/d_tensCuda.h"
//#include "src/dimension/dimension.h"
template<typename T>
struct Tensor;
template<typename T>
void cudaTensorContractNestProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1, int nestingDepth, bool strict = true);
template<typename T>
void cudaTensorProd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1);
template<typename T>
void cudaTensorProdEnd(Tensor<T>& M, const Tensor<T>& M0, const Tensor<T>& M1);
template<typename T>
void cudapermuteTensor(Tensor<T>& M, const Tensor<T>& M0, permutation p);
#endif
src/tools/tools.c
+144
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@@ -0,0 +1,144 @@
#include "src/tools/tools.h"
int
compare_int(void* a, void* b)
{
return (*(int*)a - *(int*)b);
}
int
compare_unsigned_int(void* a, void* b)
{
return ((unsigned int*)a-*(unsigned int*)b);
}
int
compare_float(void *a, void *b)
{
if (*(float*)a == *(float*)b) return 0;
if (*(float*)a > *(float*)b) return 1;
return -1;
}
int
compare_double(void *a, void *b)
{
if (*(double*)a == *(double*)b) return 0;
if (*(double*)a > *(double*)b) return 1;
return -1;
}
int
compare_string(void *a, void *b)
{
return strcmp((char*)a, (char*)b);
}
int
max_array_int(int * arr, size_t sz)
{
if(sz == 0) return 0;
int mx = arr[0];
for(size_t i = 1; i < sz; ++i)
if(mx < arr[i]) mx = arr[i];
return mx;
}
unsigned int
max_array_unsigned_int(unsigned int *arr, size_t sz)
{
if(sz == 0) return 0;
unsigned int mx = arr[0];
for(size_t i = 1; i < sz; ++i)
if(mx < arr[i]) mx = arr[i];
return mx;
}
int
min_array_int(int * arr, size_t sz)
{
if(sz == 0) return 0;
int mn = arr[0];
for(size_t i = 1; i < sz; ++i)
if(mn > arr[i]) mn = arr[i];
return mn;
}
unsigned int
min_array_unsigned_int(unsigned int *arr, size_t sz)
{
if(sz == 0) return 0;
unsigned int mn = arr[0];
for(size_t i = 1; i < sz; ++i)
if(mn > arr[i]) mn = arr[i];
return mn;
}
size_t
arg_max_array_int(int * arr, size_t sz)
{
if(sz == 0) return 0;
size_t i_mx = 0;
for(size_t i = 1; i < sz; ++i)
if(arr[i_mx] < arr[i]) i_mx = i;
return i_mx;
}
size_t
arg_max_array_unsigned_int(unsigned int *arr, size_t sz)
{
if(sz == 0) return 0;
size_t i_mx = 0;
for(size_t i = 1; i < sz; ++i)
if(arr[i_mx] < arr[i]) i_mx = i;
return i_mx;
}
size_t
arg_min_array_int(int * arr, size_t sz)
{
if(sz == 0) return 0;
size_t i_mn = 0;
for(size_t i = 1; i < sz; ++i)
if(arr[i_mn] > arr[i]) i_mn = i;
return i_mn;
}
size_t
arg_min_array_unsigned_int(unsigned int *arr, size_t sz)
{
if(sz == 0) return 0;
size_t i_mn = 0;
for(size_t i = 1; i < sz; ++i)
if(arr[i_mn] > arr[i]) i_mn = i;
return i_mn;
}
void
copy_array_unsigned_int(unsigned int *dst, const unsigned int *src, size_t size)
{
for(size_t i=0; i< size; ++i)
dst[i]=src[i];
}
/*
bool is_less_eq_than_i(int a, int b) { return a <= b; }
bool is_less_than_i(int a, int b) { return a < b; }
bool is_great_eq_than_i(int a, int b) { return a >= b; }
bool is_great_than_i(int a, int b) { return a > b; }
*/
int incr_i(int i) { return i + 1; }
int decr_i(int i) { return i - 1; }
/*
bool is_less_eq_than_u(unsigned int a, unsigned int b) { return a <= b; }
bool is_less_than_u(unsigned int a, unsigned int b) { return a < b; }
bool is_great_eq_than_u(unsigned int a, unsigned int b) { return a >= b; }
bool is_great_than_u(unsigned int a, unsigned int b) { return a > b; }
*/
unsigned int incr_u(unsigned int i) { return i + 1; }
unsigned int decr_u(unsigned int i) { return i - 1; }
src/tools/tools.h
+48
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@@ -0,0 +1,48 @@
#ifndef __TOOLS_C_H__
#define __TOOLS_C_H__
#include <stdlib.h>
#include <string.h>
#define FREE(x) { free((x)); (x) = NULL;}
int compare_int(void* a, void* b);
int compare_unsigned_int(void* a, void* b);
int compare_float(void *a, void *b);
int compare_double(void *a, void *b);
int compare_string(void *a, void *b);
int max_array_int(int *arr, size_t sz);
unsigned int max_array_unsigned_int(unsigned int *arr, size_t sz);
int min_array_int(int *arr, size_t sz);
unsigned int min_array_unsigned_int(unsigned int *arr, size_t sz);
size_t arg_max_array_int(int *arr, size_t sz);
size_t arg_max_array_unsigned_int(unsigned int *arr, size_t sz);
size_t arg_min_array_int(int *arr, size_t sz);
size_t arg_min_array_unsigned_int(unsigned int *arr, size_t sz);
void copy_array_unsigned_int(unsigned int *dst, const unsigned int *src, size_t size);
/*
bool is_less_eq_than_i(int a, int b); // { return a <= b; }
bool is_less_than_i(int a, int b); // { return a < b; }
bool is_great_eq_than_i(int a, int b); // { return a >= b; }
bool is_great_than_i(int a, int b); // { return a > b; }
*/
int incr_i(int i); // { return i + 1; }
int decr_i(int i); // { return i - 1; }
/*
bool is_less_eq_than_u(unsigned int a, unsigned int b); // { return a <= b; }
bool is_less_than_u(unsigned int a, unsigned int b); // { return a < b; }
bool is_great_eq_than_u(unsigned int a, unsigned int b); // { return a >= b; }
bool is_great_than_u(unsigned int a, unsigned int b); // { return a > b; }
*/
unsigned int incr_u(unsigned int i); // { return i + 1; }
unsigned int decr_u(unsigned int i); // { return i - 1; }
#endif /*__TOOLS_C_H__*/
src/tools_t/tools_t.c
+137
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#include "src/tools_t/tools_t.h"
#define COMPARE_N(type,a,b)\
int COMPARE_N_##type(const void *a, const void *b){ \
if (*(type*)a == *(type*)b) return 0; \
if (*(type*)a > *(type*)b) return 1; \
return -1; }
COMPARE_N(TYPE_CHAR,a,b)
COMPARE_N(TYPE_U_CHAR,a,b)
COMPARE_N(TYPE_INT,a,b)
COMPARE_N(TYPE_U_INT,a,b)
COMPARE_N(TYPE_L_INT,a,b)
COMPARE_N(TYPE_U_L_INT,a,b)
COMPARE_N(TYPE_FLOAT,a,b)
COMPARE_N(TYPE_DOUBLE,a,b)
COMPARE_N(TYPE_L_DOUBLE,a,b)
int
COMPARE_N_TYPE_STRING(const void *a,const void* b)
{
return strcmp(( char*)a,( char*)b);
}
#define COPY_ARRAY(type, dst, src, size)\
void COPY_ARRAY_##type(type *dst, const type *src, size_t size){\
for(size_t i = 0; i < size; ++i) dst[i]=src[i]; }
COPY_ARRAY(TYPE_CHAR,dst,src,size);
COPY_ARRAY(TYPE_U_CHAR,dst,src,size);
COPY_ARRAY(TYPE_INT,dst,src,size);
COPY_ARRAY(TYPE_U_INT,dst,src,size);
COPY_ARRAY(TYPE_L_INT,dst,src,size);
COPY_ARRAY(TYPE_U_L_INT,dst,src,size);
COPY_ARRAY(TYPE_FLOAT,dst,src,size);
COPY_ARRAY(TYPE_DOUBLE,dst,src,size);
COPY_ARRAY(TYPE_L_DOUBLE,dst,src,size);
void COPY_ARRAY_TYPE_STRING(char** dst, const char** src, size_t size)
{
for(size_t i = 0; i < size; ++i) strcpy(dst[i],src[i]);
}
#define MAX_ARRAY(type, array, size, compare)\
type MAX_ARRAY_##type(const type *array, size_t size){\
if(array == NULL) return 0;\
type mx =(type)array[0];\
for(size_t i = 0; i < size; ++i)\
if(compare(&mx,&array[i]) < 0) mx =(type)array[i];\
return mx;}
MAX_ARRAY(TYPE_CHAR,array,size,COMPARE_N_TYPE_CHAR);
MAX_ARRAY(TYPE_U_CHAR,array,size,COMPARE_N_TYPE_U_CHAR);
MAX_ARRAY(TYPE_INT,array,size,COMPARE_N_TYPE_INT);
MAX_ARRAY(TYPE_U_INT,array,size,COMPARE_N_TYPE_U_INT);
MAX_ARRAY(TYPE_L_INT,array,size,COMPARE_N_TYPE_L_INT);
MAX_ARRAY(TYPE_U_L_INT,array,size,COMPARE_N_TYPE_U_L_INT);
MAX_ARRAY(TYPE_FLOAT,array,size,COMPARE_N_TYPE_FLOAT);
MAX_ARRAY(TYPE_DOUBLE,array,size,COMPARE_N_TYPE_DOUBLE);
MAX_ARRAY(TYPE_L_DOUBLE,array,size,COMPARE_N_TYPE_L_DOUBLE);
MAX_ARRAY(TYPE_STRING,array,size,COMPARE_N_TYPE_STRING);
#define ARG_MAX_ARRAY(type, array, size, compare)\
size_t ARG_MAX_ARRAY_##type(const type *array, size_t size){\
if(array == NULL) return 0;\
size_t i_mx = 0;\
for(size_t i = 0; i < size; ++i)\
if(compare(&array[i_mx],&array[i]) < 0) i_mx = i;\
return i_mx;}
ARG_MAX_ARRAY(TYPE_CHAR,array,size,COMPARE_N_TYPE_CHAR);
ARG_MAX_ARRAY(TYPE_U_CHAR,array,size,COMPARE_N_TYPE_U_CHAR);
ARG_MAX_ARRAY(TYPE_INT,array,size,COMPARE_N_TYPE_INT);
ARG_MAX_ARRAY(TYPE_U_INT,array,size,COMPARE_N_TYPE_U_INT);
ARG_MAX_ARRAY(TYPE_L_INT,array,size,COMPARE_N_TYPE_L_INT);
ARG_MAX_ARRAY(TYPE_U_L_INT,array,size,COMPARE_N_TYPE_U_L_INT);
ARG_MAX_ARRAY(TYPE_FLOAT,array,size,COMPARE_N_TYPE_FLOAT);
ARG_MAX_ARRAY(TYPE_DOUBLE,array,size,COMPARE_N_TYPE_DOUBLE);
ARG_MAX_ARRAY(TYPE_L_DOUBLE,array,size,COMPARE_N_TYPE_L_DOUBLE);
ARG_MAX_ARRAY(TYPE_STRING,array,size,COMPARE_N_TYPE_STRING);
#define MIN_ARRAY(type, array, size, compare)\
type MIN_ARRAY_##type(const type *array, size_t size){\
if(array == NULL) return 0;\
type mn =(type)array[0];\
for(size_t i = 0; i < size; ++i)\
if(compare(&mn,&array[i]) > 0) mn =(type)array[i];\
return mn;}
MIN_ARRAY(TYPE_CHAR,array,size,COMPARE_N_TYPE_CHAR);
MIN_ARRAY(TYPE_U_CHAR,array,size,COMPARE_N_TYPE_U_CHAR);
MIN_ARRAY(TYPE_INT,array,size,COMPARE_N_TYPE_INT);
MIN_ARRAY(TYPE_U_INT,array,size,COMPARE_N_TYPE_U_INT);
MIN_ARRAY(TYPE_L_INT,array,size,COMPARE_N_TYPE_L_INT);
MIN_ARRAY(TYPE_U_L_INT,array,size,COMPARE_N_TYPE_U_L_INT);
MIN_ARRAY(TYPE_FLOAT,array,size,COMPARE_N_TYPE_FLOAT);
MIN_ARRAY(TYPE_DOUBLE,array,size,COMPARE_N_TYPE_DOUBLE);
MIN_ARRAY(TYPE_L_DOUBLE,array,size,COMPARE_N_TYPE_L_DOUBLE);
MIN_ARRAY(TYPE_STRING,array,size,COMPARE_N_TYPE_STRING);
#define ARG_MIN_ARRAY(type, array, size, compare)\
size_t ARG_MIN_ARRAY_##type(const type *array, size_t size){\
if(array == NULL) return 0;\
size_t i_mn = 0;\
for(size_t i = 0; i < size; ++i)\
if(compare(&array[i_mn],&array[i]) > 0) i_mn = i;\
return i_mn;}
ARG_MIN_ARRAY(TYPE_CHAR,array,size,COMPARE_N_TYPE_CHAR);
ARG_MIN_ARRAY(TYPE_U_CHAR,array,size,COMPARE_N_TYPE_U_CHAR);
ARG_MIN_ARRAY(TYPE_INT,array,size,COMPARE_N_TYPE_INT);
ARG_MIN_ARRAY(TYPE_U_INT,array,size,COMPARE_N_TYPE_U_INT);
ARG_MIN_ARRAY(TYPE_L_INT,array,size,COMPARE_N_TYPE_L_INT);
ARG_MIN_ARRAY(TYPE_U_L_INT,array,size,COMPARE_N_TYPE_U_L_INT);
ARG_MIN_ARRAY(TYPE_FLOAT,array,size,COMPARE_N_TYPE_FLOAT);
ARG_MIN_ARRAY(TYPE_DOUBLE,array,size,COMPARE_N_TYPE_DOUBLE);
ARG_MIN_ARRAY(TYPE_L_DOUBLE,array,size,COMPARE_N_TYPE_L_DOUBLE);
ARG_MIN_ARRAY(TYPE_STRING,array,size,COMPARE_N_TYPE_STRING);
int main()
{
unsigned int ui1 = 2545466;
unsigned int ui2 = 2544566;
printf(" %u >? %u = %d \n",ui1,ui2,COMPARE_N_TYPE_U_INT(&ui1,&ui2));
printf(" %u >? %u = %d \n",ui1,ui1,COMPARE_N_TYPE_U_INT(&ui1,&ui1));
printf(" %u >? %u = %d \n",ui2,ui1,COMPARE_N_TYPE_U_INT(&ui2,&ui1));
int i1 = 2545466;
int i2 = 2544566;
printf(" %d >? %d = %d \n",i1,i2,COMPARE_N_TYPE_U_INT(&i1,&i2));
printf(" %d >? %d = %d \n",i1,i1,COMPARE_N_TYPE_U_INT(&i1,&i1));
printf(" %d >? %d = %d \n",i2,i1,COMPARE_N_TYPE_U_INT(&i2,&i1));
int tabi[]={5,2,6,4,3,1};
int tabr[6]={0};
COPY_ARRAY_TYPE_INT(tabr,tabi,6);
for(size_t i=0; i<6; ++i) printf(" %d \n", tabr[i]);
printf("MIN = %d \n",MIN_ARRAY_TYPE_INT(tabr,6));
return 0;
}
src/tools_t/tools_t.h
+92
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#ifndef __TOOLS_T_C_H__
#define __TOOLS_T_C_H__
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#define TYPE_CHAR char
#define TYPE_U_CHAR unsigned char
#define TYPE_INT int
#define TYPE_U_INT unsigned int
#define TYPE_L_INT long int
#define TYPE_U_L_INT unsigned long int
#define TYPE_FLOAT float
#define TYPE_DOUBLE double
#define TYPE_L_DOUBLE long double
#define TYPE_STRING char*
#define FREE(x) { free((x)); (x) = NULL;}
#define FOREACH(array, size, function)\
for(size_t _ind = 0; _ind < size; ++_ind) function(array[_ind]);
int COMPARE_N_TYPE_CHAR(const void *,const void*);
int COMPARE_N_TYPE_U_CHAR(const void *,const void*);
int COMPARE_N_TYPE_INT(const void *,const void*);
int COMPARE_N_TYPE_U_INT(const void *,const void*);
int COMPARE_N_TYPE_L_INT(const void *,const void*);
int COMPARE_N_TYPE_U_L_INT(const void *,const void*);
int COMPARE_N_TYPE_FLOAT(const void *,const void*);
int COMPARE_N_TYPE_DOUBLE(const void *,const void*);
int COMPARE_N_TYPE_L_DOUBLE(const void *,const void*);
int COMPARE_N_TYPE_STRING(const void *,const void*);
void COPY_ARRAY_TYPE_CHAR(TYPE_CHAR* dst, const TYPE_CHAR* src, size_t size);
void COPY_ARRAY_TYPE_U_CHAR(TYPE_U_CHAR* dst, const TYPE_U_CHAR* src, size_t size);
void COPY_ARRAY_TYPE_INT(TYPE_INT* dst, const TYPE_INT* src, size_t size);
void COPY_ARRAY_TYPE_U_INT(TYPE_U_INT* dst, const TYPE_U_INT* src, size_t size);
void COPY_ARRAY_TYPE_L_INT(TYPE_L_INT* dst, const TYPE_L_INT* src, size_t size);
void COPY_ARRAY_TYPE_U_L_INT(TYPE_U_L_INT* dst, const TYPE_U_L_INT* src, size_t size);
void COPY_ARRAY_TYPE_FLOAT(TYPE_FLOAT* dst, const TYPE_FLOAT* src, size_t size);
void COPY_ARRAY_TYPE_DOUBLE(TYPE_DOUBLE* dst, const TYPE_DOUBLE* src, size_t size);
void COPY_ARRAY_TYPE_L_DOUBLE(TYPE_L_DOUBLE* dst, const TYPE_L_DOUBLE* src, size_t size);
void COPY_ARRAY_TYPE_STRING(TYPE_STRING* dst, const TYPE_STRING* src, size_t size);
TYPE_CHAR MAX_ARRAY_TYPE_CHAR(const TYPE_CHAR *array, size_t size);
TYPE_U_CHAR MAX_ARRAY_TYPE_U_CHAR(const TYPE_U_CHAR *array, size_t size);
TYPE_INT MAX_ARRAY_TYPE_INT(const TYPE_INT *array, size_t size);
TYPE_U_INT MAX_ARRAY_TYPE_U_INT(const TYPE_U_INT *array, size_t size);
TYPE_L_INT MAX_ARRAY_TYPE_L_INT(const TYPE_L_INT *array, size_t size);
TYPE_U_L_INT MAX_ARRAY_TYPE_U_L_INT(const TYPE_U_L_INT *array, size_t size);
TYPE_FLOAT MAX_ARRAY_TYPE_FLOAT(const TYPE_FLOAT *array, size_t size);
TYPE_DOUBLE MAX_ARRAY_TYPE_DOUBLE(const TYPE_DOUBLE *array, size_t size);
TYPE_L_DOUBLE MAX_ARRAY_TYPE_L_DOUBLE(const TYPE_L_DOUBLE *array, size_t size);
TYPE_STRING MAX_ARRAY_TYPE_STRING(const TYPE_STRING *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_CHAR(const TYPE_CHAR *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_U_CHAR(const TYPE_U_CHAR *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_INT(const TYPE_INT *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_U_INT(const TYPE_U_INT *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_L_INT(const TYPE_L_INT *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_U_L_INT(const TYPE_U_L_INT *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_FLOAT(const TYPE_FLOAT *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_DOUBLE(const TYPE_DOUBLE *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_L_DOUBLE(const TYPE_L_DOUBLE *array, size_t size);
size_t ARG_MAX_ARRAY_TYPE_STRING(const TYPE_STRING *array, size_t size);
TYPE_CHAR MIN_ARRAY_TYPE_CHAR(const TYPE_CHAR *array, size_t size);
TYPE_U_CHAR MIN_ARRAY_TYPE_U_CHAR(const TYPE_U_CHAR *array, size_t size);
TYPE_INT MIN_ARRAY_TYPE_INT(const TYPE_INT *array, size_t size);
TYPE_U_INT MIN_ARRAY_TYPE_U_INT(const TYPE_U_INT *array, size_t size);
TYPE_L_INT MIN_ARRAY_TYPE_L_INT(const TYPE_L_INT *array, size_t size);
TYPE_U_L_INT MIN_ARRAY_TYPE_U_L_INT(const TYPE_U_L_INT *array, size_t size);
TYPE_FLOAT MIN_ARRAY_TYPE_FLOAT(const TYPE_FLOAT *array, size_t size);
TYPE_DOUBLE MIN_ARRAY_TYPE_DOUBLE(const TYPE_DOUBLE *array, size_t size);
TYPE_L_DOUBLE MIN_ARRAY_TYPE_L_DOUBLE(const TYPE_L_DOUBLE *array, size_t size);
TYPE_STRING MIN_ARRAY_TYPE_STRING(const TYPE_STRING *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_CHAR(const TYPE_CHAR *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_U_CHAR(const TYPE_U_CHAR *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_INT(const TYPE_INT *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_U_INT(const TYPE_U_INT *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_L_INT(const TYPE_L_INT *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_U_L_INT(const TYPE_U_L_INT *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_FLOAT(const TYPE_FLOAT *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_DOUBLE(const TYPE_DOUBLE *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_L_DOUBLE(const TYPE_L_DOUBLE *array, size_t size);
size_t ARG_MIN_ARRAY_TYPE_STRING(const TYPE_STRING *array, size_t size);
#endif /*__TOOLS_T_C_H__*/
test/isgood.cu
+652
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#include <gtest/gtest.h>
#include <stdlib.h>
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tens0neD/tens0neD.h"
#include "src/tensor/tens0neD/tens0neD.h"
//#include "cudatensor.h"
//#include "/home/fanasina/progr_/ptens0neD/src/tensor/tensCuda/tensCuda.h"
#include "src/tensor/tensCuda/tensCuda.h"
/*TEST(LineraCoodTransform, check_print) {
int t3[] = { [0] = 2,[1] = 4,[2] = 3 };
struct dimension D0(3, t3);
int coor0[3] = { 1,3,2 };
int* coor1 = new int[3];
int l0 = D0.CoordToLinear(coor0);
D0.print();
D0.LinearToCoord(coor1, l0);
for (int i = 0; i < D0.rank; i++) {
EXPECT_EQ(coor0[i], coor1[i]) << " coor0: " << coor0[i] << " coor1: " << coor1[i] << " i: " << i;
}
}*/
TEST(subArray, concatArray) {
int t[] = { 1,5,6,2,3 };
int t0[] = { 1,5,6 };
int t1[] = { 2,3 };
int n = 5;
int s0[3];
int s1[2];
int s[n];
subArray(s0, t, 0, 3, 0);
subArray(s1, t, 0, 2, 3);
ASSERT_EQ(0, memcmp(t0, s0, sizeof(int) * 3));
ASSERT_EQ(0, memcmp(t1, s1, sizeof(int) * 2));
concatArray(s, s0, s1, 0, 0, 3, 0, 2);
ASSERT_EQ(0, memcmp(t, s, sizeof(int) * 5));
}
TEST(tensorProdpetit, floatTemp) {
/*int t3[] = { 2, 4, 3 };
int t4[] = { 2, 4, 3, 2 };*/
int t3[] = { 3, 6, 5 };
int t4[] = { 3, 5, 8, 4 };
struct dimension d3(3, t3), d4(4, t4), d;
struct Tensor<float> M3(d3), M4(d4), M;
M3.initVal(3.0f); // M3.print();
M4.initVal(2.0f); // M4.print();
tensorProd<float>(M, M3, M4);
//tensorProd(M, M4, M3);
int coord[M.Dim.rank];
int coord3[M3.Dim.rank];
int coord4[M4.Dim.rank];
int idx3[M3.Dim.rank];
int idx4[M4.Dim.rank];
int lin3, lin4, lin;
d = M.Dim;
for (idx3[0] = 0; idx3[0] < d3.dim[0];idx3[0]++)
for (idx3[1] = 0; idx3[1] < d3.dim[1];idx3[1]++)
for (idx3[2] = 0; idx3[2] < d3.dim[2]; idx3[2]++)
for (idx4[0] = 0; idx4[0] < d4.dim[0];idx4[0]++)
for (idx4[1] = 0; idx4[1] < d4.dim[1];idx4[1]++)
for (idx4[2] = 0; idx4[2] < d4.dim[2];idx4[2]++)
for (idx4[3] = 0; idx4[3] < d4.dim[3];idx4[3]++) {
for (int i = 0; i < d3.rank; i++) coord3[i] = idx3[i];
for (int i = 0; i < d4.rank; i++) coord4[i] = idx4[i];
concatArray(coord, coord3, coord4, 0, 0, d3.rank, 0, d4.rank);
lin3 = d3.CoordToLinear(coord3);
lin4 = d4.CoordToLinear(coord4);
lin = d.CoordToLinear(coord);
//ASSERT_FLOAT_EQ(M.elements[lin], M3.elements[lin3] * M4.elements[lin4]) << " lin: " << lin << " lin3: " << lin3 << " lin4: " << lin4;
ASSERT_FLOAT_EQ(M.elements[lin], M3.elements[lin3] * M4.elements[lin4]) << " lin: " << lin << " lin3: " << lin3 << " lin4: " << lin4;
//ASSERT_NEAR(M.elements[lin], M3.elements[lin3] * M4.elements[lin4], 0.0001) << " lin: " << lin << " lin3: " << lin3 << " lin4: " << lin4;
}
}
TEST(tensorProd, doubleTemp) {
int t3[] = { 2, 4, 3 };
int t4[] = { 4, 3, 2,3 };
struct dimension d3(3, t3), d4(4, t4), d;
struct Tensor<double> M3(d3), M4(d4), M;
M3.initVal(3.0f); // M3.print();
M4.initVal(2.0f); // M4.print();
tensorProd(M, M3, M4);
//tensorProd(M, M4, M3);
d = M.Dim;
int coord[M.Dim.rank];
int coord3[M3.Dim.rank];
int coord4[M4.Dim.rank];
int idx3[M3.Dim.rank];
int idx4[M4.Dim.rank];
int lin3, lin4, lin;
for (idx3[0] = 0; idx3[0] < d3.dim[0];idx3[0]++)
for (idx3[1] = 0; idx3[1] < d3.dim[1];idx3[1]++)
for (idx3[2] = 0; idx3[2] < d3.dim[2]; idx3[2]++)
for (idx4[0] = 0; idx4[0] < d4.dim[0];idx4[0]++)
for (idx4[1] = 0; idx4[1] < d4.dim[1];idx4[1]++)
for (idx4[2] = 0; idx4[2] < d4.dim[2];idx4[2]++)
for (idx4[3] = 0; idx4[3] < d4.dim[3];idx4[3]++) {
for (int i = 0; i < d3.rank; i++) coord3[i] = idx3[i];
for (int i = 0; i < d4.rank; i++) coord4[i] = idx4[i];
concatArray(coord, coord3, coord4, 0, 0, d3.rank, 0, d4.rank);
lin3 = d3.CoordToLinear(coord3);
lin4 = d4.CoordToLinear(coord4);
lin = d.CoordToLinear(coord);
//ASSERT_FLOAT_EQ(M.elements[lin], M3.elements[lin3] * M4.elements[lin4]);
ASSERT_DOUBLE_EQ(M.elements[lin], M3.elements[lin3] * M4.elements[lin4]);
//ASSERT_NEAR(M.elements[lin], M3.elements[lin3] * M4.elements[lin4], 0.001) << " lin: " << lin << " lin3: " << lin3 << " lin4: " << lin4;
}
}
void printArray(int* t, int sz) {
for (int i = 0; i < sz;i++) printf(" %d ", t[i]);
}
TEST(tensorContractnProd, floatTemp) {
int t3[] = { 2, 4, 3 };
int t4[] = { 4, 3, 2, 3 };
struct dimension d3(3, t3), d4(4, t4), d;
struct Tensor<float> M3(d3), M4(d4), M;
M3.initVal(3.0f); // M3.print();
M4.initVal(2.0f); // M4.print();
int dee = 2;
try {
//tensorContractnProd(M, M3, M4, dee);
tensorContractnProd(M, M3, M4, dee);
}
catch (const std::invalid_argument& e) {
printf("bye from test tensorContractnProd floatTemp invalid arg! deep:\n");
dimension dM;
extractDimNestingDepth(dM, d3, d4, dee);
dM.print();
ASSERT_TRUE(false);
}
int coord[M.Dim.rank];
int coord3[M3.Dim.rank];
int coord4[M4.Dim.rank];
int idx3[M3.Dim.rank];
int idx4[M4.Dim.rank];
int l0, l1;
l0 = M3.Dim.rank - dee;
l1 = M4.Dim.rank - dee;
int pcoord3[l0];
int pcoord4[l1];
int r[dee];
int lin3, lin4, lin;
d = M.Dim;
d.print();
Tensor<float> Msum(d);
//for (size_t idx = 0; idx < d.size; idx++) Msum.elements[idx] = 0.0f;
//Msum.print();
for (idx3[0] = 0; idx3[0] < d3.dim[0];idx3[0]++)
for (idx4[2] = 0; idx4[2] < d4.dim[2];idx4[2]++)
for (idx4[3] = 0; idx4[3] < d4.dim[3];idx4[3]++) {
for (int i = 0; i < l0; i++) pcoord3[i] = idx3[i];
for (int i = 0; i < l1; i++) pcoord4[i] = idx4[i + dee];
concatArray(coord, pcoord3, pcoord4, 0, 0, l0, 0, l1);
lin = d.CoordToLinear(coord);
Msum.elements[lin] = 0.0f;
//for (idx3[1] = 0; idx3[1] < d3.dim[1];idx3[1]++)
//for (idx3[2] = 0; idx3[2] < d3.dim[2]; idx3[2]++)
for (idx4[0] = 0; idx4[0] < d4.dim[0];idx4[0]++)
for (idx4[1] = 0; idx4[1] < d4.dim[1];idx4[1]++)
{
for (int i = 0; i < dee; i++) r[i] = idx4[i];
concatArray(coord3, pcoord3, r, 0, 0, l0, 0, dee);
concatArray(coord4, r, pcoord4, 0, 0, dee, 0, l1);
//printf("[");printArray(coord3, M3.Dim.rank); printf("]["); printArray(coord4, M4.Dim.rank);printf("] =*= ("); printArray(coord, Msum.Dim.rank); printf(") |||");
lin3 = d3.CoordToLinear(coord3);
lin4 = d4.CoordToLinear(coord4);
Msum.elements[lin] += (M3.elements[lin3] * M4.elements[lin4]);
//printf("lin:%d lin3:%d lin4:%d el+:%f\n", lin, lin3, lin4, Msum.elements[lin]);
}
ASSERT_FLOAT_EQ(Msum.elements[lin], M.elements[lin]);
}
}
TEST(tensorContractnProdD, doubleTemp) {
int t3[] = { 2, 3, 4 };
int t4[] = { 3, 4, 2, 3 };
struct dimension d3(3, t3), d4(4, t4), d;
struct Tensor<double> M3(d3), M4(d4), M;
M3.initVal(3.0f); // M3.print();
M4.initVal(2.0f); // M4.print();
int dee = 2;
try {
//tensorContractnProd(M, M3, M4, dee);
tensorContractnProd(M, M3, M4, dee);
}
catch (const std::invalid_argument& e) {
printf("bye from test tensorContractnProd floatTemp invalid arg! deep:\n");
dimension dM;
extractDimNestingDepth(dM, d3, d4, dee);
dM.print();
ASSERT_TRUE(false);
}
int coord[M.Dim.rank];
int coord3[M3.Dim.rank];
int coord4[M4.Dim.rank];
int idx3[M3.Dim.rank];
int idx4[M4.Dim.rank];
int l0, l1;
l0 = M3.Dim.rank - dee;
l1 = M4.Dim.rank - dee;
int pcoord3[l0];
int pcoord4[l1];
int r[dee];
int lin3, lin4, lin;
d = M.Dim;
d.print();
Tensor<double> Msum(d);
//for (size_t idx = 0; idx < d.size; idx++) Msum.elements[idx] = 0.0f;
//Msum.print();
for (idx3[0] = 0; idx3[0] < d3.dim[0];idx3[0]++)
for (idx4[2] = 0; idx4[2] < d4.dim[2];idx4[2]++)
for (idx4[3] = 0; idx4[3] < d4.dim[3];idx4[3]++) {
for (int i = 0; i < l0; i++) pcoord3[i] = idx3[i];
for (int i = 0; i < l1; i++) pcoord4[i] = idx4[i + dee];
concatArray(coord, pcoord3, pcoord4, 0, 0, l0, 0, l1);
lin = d.CoordToLinear(coord);
Msum.elements[lin] = 0.0f;
//for (idx3[1] = 0; idx3[1] < d3.dim[1];idx3[1]++)
//for (idx3[2] = 0; idx3[2] < d3.dim[2]; idx3[2]++)
for (idx4[0] = 0; idx4[0] < d4.dim[0];idx4[0]++)
for (idx4[1] = 0; idx4[1] < d4.dim[1];idx4[1]++)
{
for (int i = 0; i < dee; i++) r[i] = idx4[i];
concatArray(coord3, pcoord3, r, 0, 0, l0, 0, dee);
concatArray(coord4, r, pcoord4, 0, 0, dee, 0, l1);
//printf("[");printArray(coord3, M3.Dim.rank); printf("]["); printArray(coord4, M4.Dim.rank);printf("] =*= ("); printArray(coord, Msum.Dim.rank); printf(") |||");
lin3 = d3.CoordToLinear(coord3);
lin4 = d4.CoordToLinear(coord4);
Msum.elements[lin] += (M3.elements[lin3] * M4.elements[lin4]);
//printf("lin:%d lin3:%d lin4:%d el+:%f\n", lin, lin3, lin4, Msum.elements[lin]);
}
ASSERT_DOUBLE_EQ(Msum.elements[lin], M.elements[lin]);
}
}
TEST(reverseArray, innt) {
int n = 6;
int t4[6] = { 3, 4, 2, 3 ,5, 1 };
int revt4[6] = { 1,5,3,2, 4, 3 };
reverseArray(t4, n);
for (int i = 0; i < n; i++) {
ASSERT_EQ(t4[i], revt4[i]);
}
}
TEST(tensorContractnReverseProd, floatTemp) {
int t3[] = { 4, 4, 3 };
int t4[] = { 3, 4, 7, 2 };
struct dimension d3(3, t3), d4(4, t4), d;
struct Tensor<float> M3(d3), M4(d4), M;
M3.initVal(3.0f); // M3.print();
M4.initVal(2.0f); // M4.print();
int dee = 2;
try {
//tensorContractnProd(M, M3, M4, dee);
tensorContractnReverseProd(M, M3, M4, dee);
}
catch (const std::invalid_argument& e) {
printf("bye from test tensorContractnProd floatTemp invalid arg! deep:\n");
dimension dM;
extractDimNestingDepth(dM, d3, d4, dee);
dM.print();
ASSERT_TRUE(false);
}
int coord[M.Dim.rank];
int coord3[M3.Dim.rank];
int coord4[M4.Dim.rank];
int idx3[M3.Dim.rank];
int idx4[M4.Dim.rank];
int l0, l1;
l0 = M3.Dim.rank - dee;
l1 = M4.Dim.rank - dee;
int pcoord3[l0];
int pcoord4[l1];
int r[dee];
int rev[dee];
int lin3, lin4, lin;
d = M.Dim;
d.print();
Tensor<float> Msum(d);
for (idx3[0] = 0; idx3[0] < d3.dim[0];idx3[0]++)
for (idx4[2] = 0; idx4[2] < d4.dim[2];idx4[2]++)
for (idx4[3] = 0; idx4[3] < d4.dim[3];idx4[3]++) {
for (int i = 0; i < l0; i++) pcoord3[i] = idx3[i];
for (int i = 0; i < l1; i++) pcoord4[i] = idx4[i + dee];
concatArray(coord, pcoord3, pcoord4, 0, 0, l0, 0, l1);
lin = d.CoordToLinear(coord);
Msum.elements[lin] = 0.0f;
//for (idx3[1] = 0; idx3[1] < d3.dim[1];idx3[1]++)
//for (idx3[2] = 0; idx3[2] < d3.dim[2]; idx3[2]++)
for (idx4[0] = 0; idx4[0] < d4.dim[0];idx4[0]++)
for (idx4[1] = 0; idx4[1] < d4.dim[1];idx4[1]++)
{
for (int i = 0; i < dee; i++) {
r[i] = idx4[i];
rev[i] = idx4[dee - 1 - i];
}
concatArray(coord3, pcoord3, rev, 0, 0, l0, 0, dee);
concatArray(coord4, r, pcoord4, 0, 0, dee, 0, l1);
//printf("[");printArray(coord3, M3.Dim.rank); printf("]["); printArray(coord4, M4.Dim.rank);printf("] =*= ("); printArray(coord, Msum.Dim.rank); printf(") |||");
lin3 = d3.CoordToLinear(coord3);
lin4 = d4.CoordToLinear(coord4);
Msum.elements[lin] += (M3.elements[lin3] * M4.elements[lin4]);
//printf("lin:%d lin3:%d lin4:%d el+:%f\n", lin, lin3, lin4, Msum.elements[lin]);
}
ASSERT_FLOAT_EQ(Msum.elements[lin], M.elements[lin]);
}
}
TEST(cudaTensorProd, floatTemp) {
int t3[] = { 15, 6, 24 };
int t4[] = { 23, 15, 6, 10 };
struct dimension d3(3, t3), d4(4, t4), d;
struct Tensor<float> M3(d3), M4(d4), M;
M3.initVal(1.0f); // M3.print();
M4.initVal(0.5f); // M4.print();
cudaTensorProd(M, M3, M4);
//tensorProd(M, M4, M3);
int coord[M.Dim.rank];
int coord3[M3.Dim.rank];
int coord4[M4.Dim.rank];
int idx3[M3.Dim.rank];
int idx4[M4.Dim.rank];
int lin3, lin4, lin;
d = M.Dim;
d.print();
for (idx3[0] = 0; idx3[0] < d3.dim[0];idx3[0]++)
for (idx3[1] = 0; idx3[1] < d3.dim[1];idx3[1]++)
for (idx3[2] = 0; idx3[2] < d3.dim[2]; idx3[2]++)
for (idx4[0] = 0; idx4[0] < d4.dim[0];idx4[0]++)
for (idx4[1] = 0; idx4[1] < d4.dim[1];idx4[1]++)
for (idx4[2] = 0; idx4[2] < d4.dim[2];idx4[2]++)
for (idx4[3] = 0; idx4[3] < d4.dim[3];idx4[3]++) {
for (int i = 0; i < d3.rank; i++) coord3[i] = idx3[i];
for (int i = 0; i < d4.rank; i++) coord4[i] = idx4[i];
concatArray(coord, coord3, coord4, 0, 0, d3.rank, 0, d4.rank);
lin3 = d3.CoordToLinear(coord3);
lin4 = d4.CoordToLinear(coord4);
lin = d.CoordToLinear(coord);
//ASSERT_FLOAT_EQ(M.elements[lin], M3.elements[lin3] * M4.elements[lin4]) << " lin: " << lin << " lin3: " << lin3 << " lin4: " << lin4;
//ASSERT_FLOAT_EQ(M.elements[lin], M3.elements[lin3] * M4.elements[lin4]) << " lin: " << lin << " lin3: " << lin3 << " lin4: " << lin4;
ASSERT_FLOAT_EQ(M.elements[lin], M3.elements[lin3] * M4.elements[lin4]) << " M " << M.elements[lin] << " lin: " << lin << " M3: " << M3.elements[lin3] << " lin3:" << lin3 << " lin4: " << lin4 << " M4 " << M4.elements[lin4] << std::endl;
//std::cout << " M " << M.elements[lin] << " lin: " << lin << " M3: " << M3.elements[lin3] << " lin3:" << lin3 << " lin4: " << lin4 << " M4 " << M4.elements[lin4] << std::endl;
//ASSERT_NEAR(M.elements[lin], M3.elements[lin3] * M4.elements[lin4], 0.0001) << " lin: " << lin << " lin3: " << lin3 << " lin4: " << lin4;
}
}
TEST(permuteTensor, float) {
int t4[] = { 3, 8, 2, 4 };
struct dimension d4(4, t4);
struct Tensor<float> M4(d4), M;
M4.initVal(1.0f);
permutation p(4, true);
int n = 5;
//for (int n = 0; n < 24;n++) {
PlaceToTab(p.perm, n, p.size);
printf(" %*d : ", 2, n);
for (int i = 0; i < p.size; i++)printf("(%d)%d ", i, p.perm[i]);printf("\n");
permuteTensor(M, M4, p);
//permuteTensorDef(M, M4, p);
int ind[4];
int coor[4];
size_t cM, cM4;
for (ind[0] = 0; ind[0] < M4.Dim.dim[0]; ind[0]++)
for (ind[1] = 0; ind[1] < M4.Dim.dim[1]; ind[1]++)
for (ind[2] = 0; ind[2] < M4.Dim.dim[2]; ind[2]++)
for (ind[3] = 0; ind[3] < M4.Dim.dim[3]; ind[3]++) {
p.permute(coor, ind);
cM = M.Dim.CoordToLinear(coor);
cM4 = M4.Dim.CoordToLinear(ind);
//printf("M[%ld]=%f M4[%ld]=%f \n", cM, M.elements[cM], cM4, M4.elements[cM4]);
ASSERT_FLOAT_EQ(M.elements[cM], M4.elements[cM4]);
}
}
TEST(cudapermuteTensor, float) {
int t4[] = { 3, 8, 2, 4 };
struct dimension d4(4, t4);
struct Tensor<float> M4(d4), M;
M4.initVal(1.0f);
permutation p(4, true);
int n = 5;
//for (int n = 0; n < 24;n++) {
PlaceToTab(p.perm, n, p.size);
printf(" %*d : ", 2, n);
for (int i = 0; i < p.size; i++)printf("{%d}%d ", i, p.perm[i]);printf("\n");
cudapermuteTensor(M, M4, p);
//permuteTensor(M, M4, p);
//permuteTensorDef(M, M4, p);
int ind[4];
int coor[4];
size_t cM, cM4;
for (ind[0] = 0; ind[0] < M4.Dim.dim[0]; ind[0]++)
for (ind[1] = 0; ind[1] < M4.Dim.dim[1]; ind[1]++)
for (ind[2] = 0; ind[2] < M4.Dim.dim[2]; ind[2]++)
for (ind[3] = 0; ind[3] < M4.Dim.dim[3]; ind[3]++) {
p.permute(coor, ind);
cM = M.Dim.CoordToLinear(coor);
cM4 = M4.Dim.CoordToLinear(ind);
//printf("M[%ld]=%f M4[%ld]=%f \n", cM, M.elements[cM], cM4, M4.elements[cM4]);
ASSERT_FLOAT_EQ(M.elements[cM], M4.elements[cM4]);
}
}
TEST(scanPermuteMatchContractTensorfromSrcToDst1, permId) {
int t[] = { 3, 8, 2, 3, 4 };
//int tm[] = { 4, 2, 7, 3 };
int tm[] = { 2, 3,4,7 };
struct dimension d(5, t);
struct dimension dm(4, tm);
struct Tensor<float> M4(d), M(dm);
M4.initVal(1.0f);
M.initVal(1.0f);
int dee = 3;
//int result[4] = { 1,3,0,2 };
int result[4] = { 0,1,2,3 };
int perm[M.Dim.rank];
ASSERT_TRUE(scanPermuteMatchContractTensorfromSrcToDst(perm, M, M4, dee));
for (int i = 0; i < M.Dim.rank; i++) printf(" %d[%d] ", i, perm[i]); printf(" first perm \n");
ASSERT_EQ(0, memcmp(result, perm, sizeof(int) * M.Dim.rank));
Tensor<float> tM;
permutation p(M.Dim.rank, perm);
permuteTensor(tM, M, p);
ASSERT_FALSE(scanPermuteMatchContractTensorfromSrcToDst(perm, M, M4, 4));
for (int i = 0; i < M.Dim.rank; i++) printf(" %d[%d] ", i, perm[i]); printf(": last perm \n");
tM.Dim.print();
int resultDim[] = { 2,3,4,7 };
ASSERT_EQ(0, memcmp(resultDim, tM.Dim.dim, sizeof(int) * tM.Dim.rank));
}
TEST(scanPermuteMatchContractTensorfromSrcToDst2, floatest) {
int t[] = { 3, 8, 2, 3, 4 };
int tm[] = { 4, 2, 7, 3 };
//int tm[] = { 2, 3,4,7 };
struct dimension d(5, t);
struct dimension dm(4, tm);
struct Tensor<float> M4(d), M(dm);
M4.initVal(1.0f);
M.initVal(1.0f);
int dee = 3;
int result[4] = { 1,3,0,2 };
//int result[4] = { 0,1,2,3 };
int perm[M.Dim.rank];
ASSERT_TRUE(scanPermuteMatchContractTensorfromSrcToDst(perm, M, M4, dee));
for (int i = 0; i < M.Dim.rank; i++) printf(" %d[%d] ", i, perm[i]); printf(" first perm \n");
ASSERT_EQ(0, memcmp(result, perm, sizeof(int) * M.Dim.rank));
Tensor<float> tM;
permutation p(M.Dim.rank, perm);
permuteTensor(tM, M, p);
ASSERT_FALSE(scanPermuteMatchContractTensorfromSrcToDst(perm, M, M4, 4));
for (int i = 0; i < M.Dim.rank; i++) printf(" %d[%d] ", i, perm[i]); printf(": last perm \n");
tM.Dim.print();
int resultDim[] = { 2,3,4,7 };
ASSERT_EQ(0, memcmp(resultDim, tM.Dim.dim, sizeof(int) * tM.Dim.rank));
}
TEST(cudaTensorContractNestProd, floatTemp) {
int t3[] = { 77, 8, 25 };
int t4[] = { 8, 25, 52, 144 };
struct dimension d3(3, t3), d4(4, t4), d;
struct Tensor<float> M3(d3), M4(d4), M;
M3.initVal(1.0f); // M3.print();
M4.initVal(0.0f); // M4.print();
int dee = 2;
M4.Dim.print();
try {
//tensorContractnProd(M, M3, M4, dee);
cudaTensorContractNestProd(M, M3, M4, dee);
}
catch (const std::invalid_argument& e) {
printf("bye from test tensorContractnProd floatTemp invalid arg! deep: \n");
dimension dM;
extractDimNestingDepth(dM, d3, d4, dee);
dM.print();
ASSERT_TRUE(false);
}
int coord[M.Dim.rank];
int coord3[M3.Dim.rank];
int coord4[M4.Dim.rank];
int idx3[M3.Dim.rank];
int idx4[M4.Dim.rank];
int l0, l1;
l0 = M3.Dim.rank - dee;
l1 = M4.Dim.rank - dee;
int pcoord3[l0];
int pcoord4[l1];
int r[dee];
//int rev[dee];
int lin3, lin4, lin;
d = M.Dim;
d.print();
Tensor<float> Msum(d);
for (idx3[0] = 0; idx3[0] < d3.dim[0];idx3[0]++)
for (idx4[2] = 0; idx4[2] < d4.dim[2];idx4[2]++)
for (idx4[3] = 0; idx4[3] < d4.dim[3];idx4[3]++) {
for (int i = 0; i < l0; i++) pcoord3[i] = idx3[i];
for (int i = 0; i < l1; i++) pcoord4[i] = idx4[i + dee];
concatArray(coord, pcoord3, pcoord4, 0, 0, l0, 0, l1);
lin = d.CoordToLinear(coord);
Msum.elements[lin] = 0.0f;
//for (idx3[1] = 0; idx3[1] < d3.dim[1];idx3[1]++)
//for (idx3[2] = 0; idx3[2] < d3.dim[2]; idx3[2]++)
for (idx4[0] = 0; idx4[0] < d4.dim[0];idx4[0]++)
for (idx4[1] = 0; idx4[1] < d4.dim[1];idx4[1]++)
{
for (int i = 0; i < dee; i++) {
r[i] = idx4[i];
//rev[i] = idx4[dee - 1 - i];
}
//concatArray(coord3, pcoord3, rev, 0, 0, l0, 0, dee);
concatArray(coord3, pcoord3, r, 0, 0, l0, 0, dee);
concatArray(coord4, r, pcoord4, 0, 0, dee, 0, l1);
//printf("[");printArray(coord3, M3.Dim.rank); printf("]["); printArray(coord4, M4.Dim.rank);printf("] =*= ("); printArray(coord, Msum.Dim.rank); printf(") |||");
lin3 = d3.CoordToLinear(coord3);
lin4 = d4.CoordToLinear(coord4);
Msum.elements[lin] += (M3.elements[lin3] * M4.elements[lin4]);
//printf("lin:%d lin3:%d lin4:%d el+:%f\n", lin, lin3, lin4, Msum.elements[lin]);
}
ASSERT_FLOAT_EQ(Msum.elements[lin], M.elements[lin]) << " lin: " << lin << " Msumelem: " << Msum.elements[lin] << " Melem: " << M.elements[lin];
}
}
int main(int argc, char** argv) {
testing::InitGoogleTest(&argc, argv);
return RUN_ALL_TESTS();
}
testool
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try/CMakeLists.txt
+37
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#cmake_minimum_required(VERSION 3.2)
cmake_minimum_required(VERSION 3.18)
project(ptens0neD)
include(FetchContent)
FetchContent_Declare(googletest
GIT_REPOSITORY https://github.com/google/googletest
GIT_TAG release-1.12.1
)
FetchContent_GetProperties(googletest)
if(NOT googletest_POPULATED)
FetchContent_Populate(googletest)
add_subdirectory(${googletest_SOURCE_DIR} ${googletest_BUILD_DIR})
endif()
#add_library(add STATIC add.cu)
add_library(permutation STATIC src/permutation/permutation.cpp)
add_library(dimension STATIC src/dimension/dimension.cpp)
add_library(tens0ne STATIC src/tens0ne/tens0ne.cpp)
add_library(cutens0ne STATIC src/cutens0ne/cutens0ne.cu)
add_library(d_cutens0ne STATIC src/cutens0ne/d_cutens0ne.cu)
#find_package(CUDA REQUIRED)
enable_language(CUDA)
#cuda_add_library(add STATIC add.cu)
#add_library(permutation STATIC ../permutation/permutation.cu)
#cuda_add_executable( )
add_executable(isgood isgood.cu device.cuh ../tensor/tensor.cpp ../permutation/permutation.cpp)
#cuda_add_executable(isgood isgood.cpp add.cu )
#target_link_libraries(isgood add gtest_main gmock_main pthread)
target_link_libraries(isgood gtest_main gmock_main pthread)
enable_testing()
add_test(Tester isgood)
try/saved0work/CMakeLists.txt
+71
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@@ -0,0 +1,71 @@
#cmake_minimum_required(VERSION 3.20)
#cmake_minimum_required(VERSION 3.18)
cmake_minimum_required(VERSION 3.0.0)
set(F0_PROJECT_NAME projectF0)
set(F0_LIBRARIES
permutation
dimension
tens0neD
)
set(F0_CUDA_LIBRARIES
tensCuda
d_tensCuda
)
set(F0_SOURCE_DIR
src
)
project(${F0_PROJECT_NAME})
include(FetchContent)
FetchContent_Declare(googletest
GIT_REPOSITORY https://github.com/google/googletest
GIT_TAG release-1.12.1
)
FetchContent_GetProperties(googletest)
if(NOT googletest_POPULATED)
FetchContent_Populate(googletest)
add_subdirectory(${googletest_SOURCE_DIR} ${googletest_BUILD_DIR})
endif()
#add_library(add STATIC add.cu)
foreach(libvarcu ${F0_CUDA_LIBRARIES})
list(APPEND F0_SOURCES_CU ${F0_SOURCE_DIR}/tensor/tensCuda/${libvarcu}.cu)
endforeach()
foreach(libvar ${F0_LIBRARIES})
if( ${libvar} STREQUAL "tens0neD" )
list(APPEND F0_SOURCES_CPP ${F0_SOURCE_DIR}/tensor/${libvar}/${libvar}.cpp)
else()
list(APPEND F0_SOURCES_CPP ${F0_SOURCE_DIR}/${libvar}/${libvar}.cpp)
endif()
endforeach()
set(CMAKE_INCLUDE_CURRENT_DIR ON)
#find_package(CUDA REQUIRED) # no need
enable_language(CUDA)
#if version < 3.18
if(NOT DEFINED CMAKE_CUDA_ARCHITECTURES)
set(CMAKE_CUDA_ARCHITECTURES 75)
endif()
add_library(${F0_PROJECT_NAME} STATIC ${F0_SOURCES_CPP} ${F0_SOURCES_CU}) # no need if add sources in executable
add_executable(isgood test/isgood.cu) # if library set, no need of ${F0_SOURCES_CPP} ${F0_SOURCES_CU}) but if not you nedd to add theses files src
target_link_libraries(isgood gtest_main gmock_main pthread ${F0_PROJECT_NAME}) # no need if no local library set
enable_testing()
add_test(Tester isgood)
try/try_cmakelists0/CMakeLists.txt
+37
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@@ -0,0 +1,37 @@
cmake_minimum_required(VERSION 3.0.0)
set(FOO_PROJECT_NAME
Foo
)
set(FOO_SOURCE_DIR
src
)
set(FOO_SOURCE
${FOO_SOURCE_DIR}/main.cpp
)
set(FOO_LIBRARIES_DIR
libs
)
set(FOO_LIBRARIES
A
B
)
project(${FOO_PROJECT_NAME})
#########
# GTest #
#########
enable_testing()
add_subdirectory(libs/gtest-1.7.0)
include_directories(${gtest_SOURCE_DIR}/include ${gtest_SOURCE_DIR})
###########
# Project #
###########
add_executable(${FOO_PROJECT_NAME} ${FOO_SOURCE})
foreach(LIBRARY ${FOO_LIBRARIES})
add_subdirectory("${FOO_LIBRARIES_DIR}/${LIBRARY}")
endforeach(LIBRARY)
target_link_libraries(${FOO_PROJECT_NAME} ${FOO_LIBRARIES})
try/try_cmakelists1/CMakeLists.txt
+80
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@@ -0,0 +1,80 @@
cmake_minimum_required(VERSION 3.18)
project(ptens0neD VERSION 2023.0
LANGUAGES CXX
HOMEPAGE_URL "https://github.com/fanasina/ptens0neD")
#####################################################################
# DEPENDENCIES
#####################################################################
find_package(Threads REQUIRED)
find_package(Boost REQUIRED)
include(FetchContent)
FetchContent_Declare(
googletest
GIT_REPOSITORY https://github.com/google/googletest.git
GIT_TAG release-1.10.0)
FetchContent_GetProperties(googletest)
if(NOT googletest_POPULATED)
FetchContent_Populate(googletest)
add_subdirectory(${googletest_SOURCE_DIR} ${googletest_BINARY_DIR}
EXCLUDE_FROM_ALL)
endif()
#####################################################################
# LIBRARY
#####################################################################
add_library(${PROJECT_NAME}
src/ptens0neD/implementation.cpp
)
add_library(${PROJECT_NAME}::${PROJECT_NAME} ALIAS ${PROJECT_NAME})
set_target_properties(${PROJECT_NAME} PROPERTIES
VERSION ${PROJECT_VERSION})
target_include_directories(${PROJECT_NAME}
PUBLIC include
PRIVATE src)
target_link_libraries(${PROJECT_NAME}
PUBLIC Threads::Threads
PRIVATE Boost::boost)
target_compile_options(${PROJECT_NAME}
PRIVATE -Wall -Wextra -pedantic -Werror)
target_compile_features(${PROJECT_NAME}
PRIVATE cxx_std_17)
include(GNUInstallDirs)
install(TARGETS ${PROJECT_NAME}
EXPORT ptens0neDTargets
LIBRARY DESTINATION ${CMAKE_INSTALL_LIBDIR}
ARCHIVE DESTINATION ${CMAKE_INSTALL_LIBDIR}
RUNTIME DESTINATION ${CMAKE_INSTALL_BINDIR})
install(DIRECTORY include/ DESTINATION ${CMAKE_INSTALL_INCLUDEDIR})
#####################################################################
# UNIT TESTS
#####################################################################
add_executable(${PROJECT_NAME}-tests
test/test-myclass.cpp)
target_link_libraries(${PROJECT_NAME}-tests
PRIVATE gtest_main Threads::Threads ${PROJECT_NAME}::${PROJECT_NAME})
target_compile_options(${PROJECT_NAME}-tests
PRIVATE -Wall -Wextra -pedantic -Werror)
target_compile_features(${PROJECT_NAME}
PRIVATE cxx_std_17)
try/try_cmakelists2/CMakeLists.txt
+10
View File
@@ -0,0 +1,10 @@
cmake_minimum_required(VERSION 3.20)
project(geometries LANGUAGES CXX)
add_executable(app)
target_sources(app PRIVATE "app.cpp")
target_include_directories(app PRIVATE "${PROJECT_SOURCE_DIR}")
add_subdirectory("shape")
add_subdirectory("square")
install(TARGETS app)