// RUN: %libomp-compile-and-run
#include <stdio.h>
#include <math.h>
#include "omp_testsuite.h"
int test_omp_parallel_sections_reduction()
{
int sum;
int known_sum;
double dpt;
double dsum;
double dknown_sum;
double dt=0.5; /* base of geometric row for + and - test*/
double rounding_error= 1.E-5;
int diff;
double ddiff;
int product;
int known_product;
int logic_and;
int bit_and;
int logic_or;
int bit_or;
int exclusiv_bit_or;
int logics[1000];
int i;
int result;
sum = 7;
dsum=0;
product =1;
dpt = 1;
logic_and=1;
bit_and=1;
logic_or=0;
bit_or=0;
exclusiv_bit_or=0;
result =0;
/* int my_islarger;*/
/*int is_larger=1;*/
// Test summation of integers
known_sum = (999*1000)/2+7;
#pragma omp parallel sections private(i) reduction(+:sum)
{
#pragma omp section
{
for (i=1;i<300;i++) {
sum=sum+i;
}
}
#pragma omp section
{
for (i=300;i<700;i++) {
sum=sum+i;
}
}
#pragma omp section
{
for (i=700;i<1000;i++) {
sum=sum+i;
}
}
}
if(known_sum!=sum) {
result++;
fprintf(stderr,"Error in sum with integers: Result was %d"
" instead of %d.\n",sum, known_sum);
}
// Test differences of integers
diff = (999*1000)/2;
#pragma omp parallel sections private(i) reduction(-:diff)
{
#pragma omp section
{
for (i=1;i<300;i++) {
diff=diff-i;
}
}
#pragma omp section
{
for (i=300;i<700;i++) {
diff=diff-i;
}
}
#pragma omp section
{
for (i=700;i<1000;i++) {
diff=diff-i;
}
}
}
if(diff != 0) {
result++;
fprintf(stderr,"Error in Difference with integers: Result was %d"
" instead of 0.\n",diff);
}
// Test summation of doubles
for (i=0;i<20;++i) {
dpt*=dt;
}
dknown_sum = (1-dpt)/(1-dt);
#pragma omp parallel sections private(i) reduction(+:dsum)
{
#pragma omp section
{
for (i=0;i<6;++i) {
dsum += pow(dt,i);
}
}
#pragma omp section
{
for (i=6;i<12;++i) {
dsum += pow(dt,i);
}
}
#pragma omp section
{
for (i=12;i<20;++i) {
dsum += pow(dt,i);
}
}
}
if( fabs(dsum-dknown_sum) > rounding_error ) {
result++;
fprintf(stderr,"Error in sum with doubles: Result was %f"
" instead of %f (Difference: %E)\n",
dsum, dknown_sum, dsum-dknown_sum);
}
// Test differences of doubles
dpt=1;
for (i=0;i<20;++i) {
dpt*=dt;
}
fprintf(stderr,"\n");
ddiff = (1-dpt)/(1-dt);
#pragma omp parallel sections private(i) reduction(-:ddiff)
{
#pragma omp section
{
for (i=0;i<6;++i) {
ddiff -= pow(dt,i);
}
}
#pragma omp section
{
for (i=6;i<12;++i) {
ddiff -= pow(dt,i);
}
}
#pragma omp section
{
for (i=12;i<20;++i) {
ddiff -= pow(dt,i);
}
}
}
if( fabs(ddiff) > rounding_error) {
result++;
fprintf(stderr,"Error in Difference with doubles: Result was %E"
" instead of 0.0\n",ddiff);
}
// Test product of integers
known_product = 3628800;
#pragma omp parallel sections private(i) reduction(*:product)
{
#pragma omp section
{
for(i=1;i<3;i++) {
product *= i;
}
}
#pragma omp section
{
for(i=3;i<7;i++) {
product *= i;
}
}
#pragma omp section
{
for(i=7;i<11;i++) {
product *= i;
}
}
}
if(known_product != product) {
result++;
fprintf(stderr,"Error in Product with integers: Result was %d"
" instead of %d\n",product,known_product);
}
// Test logical AND
for(i=0;i<1000;i++) {
logics[i]=1;
}
#pragma omp parallel sections private(i) reduction(&&:logic_and)
{
#pragma omp section
{
for (i=1;i<300;i++) {
logic_and = (logic_and && logics[i]);
}
}
#pragma omp section
{
for (i=300;i<700;i++) {
logic_and = (logic_and && logics[i]);
}
}
#pragma omp section
{
for (i=700;i<1000;i++) {
logic_and = (logic_and && logics[i]);
}
}
}
if(!logic_and) {
result++;
fprintf(stderr,"Error in logic AND part 1\n");
}
logic_and = 1;
logics[501] = 0;
#pragma omp parallel sections private(i) reduction(&&:logic_and)
{
#pragma omp section
{
for (i=1;i<300;i++) {
logic_and = (logic_and && logics[i]);
}
}
#pragma omp section
{
for (i=300;i<700;i++) {
logic_and = (logic_and && logics[i]);
}
}
#pragma omp section
{
for (i=700;i<1000;i++) {
logic_and = (logic_and && logics[i]);
}
}
}
if(logic_and) {
result++;
fprintf(stderr,"Error in logic AND part 2");
}
// Test logical OR
for(i=0;i<1000;i++) {
logics[i]=0;
}
#pragma omp parallel sections private(i) reduction(||:logic_or)
{
#pragma omp section
{
for (i=1;i<300;i++) {
logic_or = (logic_or || logics[i]);
}
}
#pragma omp section
{
for (i=300;i<700;i++) {
logic_or = (logic_or || logics[i]);
}
}
#pragma omp section
{
for (i=700;i<1000;i++) {
logic_or = (logic_or || logics[i]);
}
}
}
if(logic_or) {
result++;
fprintf(stderr,"Error in logic OR part 1\n");
}
logic_or = 0;
logics[501]=1;
#pragma omp parallel sections private(i) reduction(||:logic_or)
{
#pragma omp section
{
for (i=1;i<300;i++) {
logic_or = (logic_or || logics[i]);
}
}
#pragma omp section
{
for (i=300;i<700;i++) {
logic_or = (logic_or || logics[i]);
}
}
#pragma omp section
{
for (i=700;i<1000;i++) {
logic_or = (logic_or || logics[i]);
}
}
}
if(!logic_or) {
result++;
fprintf(stderr,"Error in logic OR part 2\n");
}
// Test bitwise AND
for(i=0;i<1000;++i) {
logics[i]=1;
}
#pragma omp parallel sections private(i) reduction(&:bit_and)
{
#pragma omp section
{
for(i=0;i<300;++i) {
bit_and = (bit_and & logics[i]);
}
}
#pragma omp section
{
for(i=300;i<700;++i) {
bit_and = (bit_and & logics[i]);
}
}
#pragma omp section
{
for(i=700;i<1000;++i) {
bit_and = (bit_and & logics[i]);
}
}
}
if(!bit_and) {
result++;
fprintf(stderr,"Error in BIT AND part 1\n");
}
bit_and = 1;
logics[501]=0;
#pragma omp parallel sections private(i) reduction(&:bit_and)
{
#pragma omp section
{
for(i=0;i<300;++i) {
bit_and = bit_and & logics[i];
}
}
#pragma omp section
{
for(i=300;i<700;++i) {
bit_and = bit_and & logics[i];
}
}
#pragma omp section
{
for(i=700;i<1000;++i) {
bit_and = bit_and & logics[i];
}
}
}
if(bit_and) {
result++;
fprintf(stderr,"Error in BIT AND part 2");
}
// Test bitwise OR
for(i=0;i<1000;i++) {
logics[i]=0;
}
#pragma omp parallel sections private(i) reduction(|:bit_or)
{
#pragma omp section
{
for(i=0;i<300;++i) {
bit_or = bit_or | logics[i];
}
}
#pragma omp section
{
for(i=300;i<700;++i) {
bit_or = bit_or | logics[i];
}
}
#pragma omp section
{
for(i=700;i<1000;++i) {
bit_or = bit_or | logics[i];
}
}
}
if(bit_or) {
result++;
fprintf(stderr,"Error in BIT OR part 1\n");
}
bit_or = 0;
logics[501]=1;
#pragma omp parallel sections private(i) reduction(|:bit_or)
{
#pragma omp section
{
for(i=0;i<300;++i) {
bit_or = bit_or | logics[i];
}
}
#pragma omp section
{
for(i=300;i<700;++i) {
bit_or = bit_or | logics[i];
}
}
#pragma omp section
{
for(i=700;i<1000;++i) {
bit_or = bit_or | logics[i];
}
}
}
if(!bit_or) {
result++;
fprintf(stderr,"Error in BIT OR part 2\n");
}
// Test bitwise XOR
for(i=0;i<1000;i++) {
logics[i]=0;
}
#pragma omp parallel sections private(i) reduction(^:exclusiv_bit_or)
{
#pragma omp section
{
for(i=0;i<300;++i) {
exclusiv_bit_or = exclusiv_bit_or ^ logics[i];
}
}
#pragma omp section
{
for(i=300;i<700;++i) {
exclusiv_bit_or = exclusiv_bit_or ^ logics[i];
}
}
#pragma omp section
{
for(i=700;i<1000;++i) {
exclusiv_bit_or = exclusiv_bit_or ^ logics[i];
}
}
}
if(exclusiv_bit_or) {
result++;
fprintf(stderr,"Error in EXCLUSIV BIT OR part 1\n");
}
exclusiv_bit_or = 0;
logics[501]=1;
#pragma omp parallel sections private(i) reduction(^:exclusiv_bit_or)
{
#pragma omp section
{
for(i=0;i<300;++i) {
exclusiv_bit_or = exclusiv_bit_or ^ logics[i];
}
}
#pragma omp section
{
for(i=300;i<700;++i) {
exclusiv_bit_or = exclusiv_bit_or ^ logics[i];
}
}
#pragma omp section
{
for(i=700;i<1000;++i) {
exclusiv_bit_or = exclusiv_bit_or ^ logics[i];
}
}
}
if(!exclusiv_bit_or) {
result++;
fprintf(stderr,"Error in EXCLUSIV BIT OR part 2\n");
}
/*printf("\nResult:%d\n",result);*/
return (result==0);
}
int main()
{
int i;
int num_failed=0;
for(i = 0; i < REPETITIONS; i++) {
if(!test_omp_parallel_sections_reduction()) {
num_failed++;
}
}
return num_failed;
}