/* C / C++'s logical AND and OR operators take any scalar argument which compares (un)equal to 0 - the result 1 or 0 and of type int. In this testcase, the int result is again converted to a floating-poing or complex type. While having a floating-point/complex array element with || and && can make sense, having a non-integer/non-bool reduction variable is odd but valid. Test: FP reduction variable + integer array. */ #define N 1024 char rcf[N]; short rcd[N]; int rf[N]; long rd[N]; int reduction_or () { float orf = 0; double ord = 0; _Complex float orfc = 0; _Complex double ordc = 0; #pragma omp parallel reduction(||: orf) for (int i=0; i < N; ++i) orf = orf || rf[i]; #pragma omp parallel for reduction(||: ord) for (int i=0; i < N; ++i) ord = ord || rcd[i]; #pragma omp parallel for simd reduction(||: orfc) for (int i=0; i < N; ++i) orfc = orfc || rcf[i]; #pragma omp parallel loop reduction(||: ordc) for (int i=0; i < N; ++i) ordc = ordc || rcd[i]; return orf + ord + __real__ orfc + __real__ ordc; } int reduction_or_teams () { float orf = 0; double ord = 0; _Complex float orfc = 0; _Complex double ordc = 0; #pragma omp teams distribute parallel for reduction(||: orf) for (int i=0; i < N; ++i) orf = orf || rf[i]; #pragma omp teams distribute parallel for simd reduction(||: ord) for (int i=0; i < N; ++i) ord = ord || rcd[i]; #pragma omp teams distribute parallel for reduction(||: orfc) for (int i=0; i < N; ++i) orfc = orfc || rcf[i]; #pragma omp teams distribute parallel for simd reduction(||: ordc) for (int i=0; i < N; ++i) ordc = ordc || rcd[i]; return orf + ord + __real__ orfc + __real__ ordc; } int reduction_and () { float andf = 1; double andd = 1; _Complex float andfc = 1; _Complex double anddc = 1; #pragma omp parallel reduction(&&: andf) for (int i=0; i < N; ++i) andf = andf && rf[i]; #pragma omp parallel for reduction(&&: andd) for (int i=0; i < N; ++i) andd = andd && rcd[i]; #pragma omp parallel for simd reduction(&&: andfc) for (int i=0; i < N; ++i) andfc = andfc && rcf[i]; #pragma omp parallel loop reduction(&&: anddc) for (int i=0; i < N; ++i) anddc = anddc && rcd[i]; return andf + andd + __real__ andfc + __real__ anddc; } int reduction_and_teams () { float andf = 1; double andd = 1; _Complex float andfc = 1; _Complex double anddc = 1; #pragma omp teams distribute parallel for reduction(&&: andf) for (int i=0; i < N; ++i) andf = andf && rf[i]; #pragma omp teams distribute parallel for simd reduction(&&: andd) for (int i=0; i < N; ++i) andd = andd && rcd[i]; #pragma omp teams distribute parallel for reduction(&&: andfc) for (int i=0; i < N; ++i) andfc = andfc && rcf[i]; #pragma omp teams distribute parallel for simd reduction(&&: anddc) for (int i=0; i < N; ++i) anddc = anddc && rcd[i]; return andf + andd + __real__ andfc + __real__ anddc; } int main () { for (int i = 0; i < N; ++i) { rf[i] = 0; rd[i] = 0; rcf[i] = 0; rcd[i] = 0; } if (reduction_or () != 0) __builtin_abort (); if (reduction_or_teams () != 0) __builtin_abort (); if (reduction_and () != 0) __builtin_abort (); if (reduction_and_teams () != 0) __builtin_abort (); rf[10] = 1; rd[15] = 1; rcf[10] = 1; rcd[15] = 1; if (reduction_or () != 4) __builtin_abort (); if (reduction_or_teams () != 4) __builtin_abort (); if (reduction_and () != 0) __builtin_abort (); if (reduction_and_teams () != 0) __builtin_abort (); for (int i = 0; i < N; ++i) { rf[i] = 1; rd[i] = 1; rcf[i] = 1; rcd[i] = 1; } if (reduction_or () != 4) __builtin_abort (); if (reduction_or_teams () != 4) __builtin_abort (); if (reduction_and () != 4) __builtin_abort (); if (reduction_and_teams () != 4) __builtin_abort (); rf[10] = 0; rd[15] = 0; rcf[10] = 0; rcd[15] = 0; if (reduction_or () != 4) __builtin_abort (); if (reduction_or_teams () != 4) __builtin_abort (); if (reduction_and () != 0) __builtin_abort (); if (reduction_and_teams () != 0) __builtin_abort (); return 0; }