/* Test of worker-private variables declared on a loop directive, broadcasting to vector-partitioned mode. Addressable worker variable. */ /* { dg-additional-options "--param=openacc-kernels=decompose" } */ /* { dg-additional-options "-fopt-info-omp-all" } { dg-additional-options "-foffload=-fopt-info-omp-all" } */ /* { dg-additional-options "--param=openacc-privatization=noisy" } { dg-additional-options "-foffload=--param=openacc-privatization=noisy" } Prune a few: uninteresting: { dg-prune-output {note: variable 'D\.[0-9]+' declared in block isn't candidate for adjusting OpenACC privatization level: not addressable} } */ /* It's only with Tcl 8.5 (released in 2007) that "the variable 'varName' passed to 'incr' may be unset, and in that case, it will be set to [...]", so to maintain compatibility with earlier Tcl releases, we manually initialize counter variables: { dg-line l_dummy[variable c_compute 0 c_loop_i 0 c_loop_j 0 c_loop_k 0] } { dg-message "dummy" "" { target iN-VAl-Id } l_dummy } to avoid "WARNING: dg-line var l_dummy defined, but not used". */ #include int main (int argc, char* argv[]) { int x = 5, i, arr[32 * 32 * 32]; for (i = 0; i < 32 * 32 * 32; i++) arr[i] = i; #pragma acc kernels copy(arr) /* { dg-line l_compute[incr c_compute] } */ /* [PR104784] For some reason, for C++, the OpenACC 'kernels' decomposition decides that a data region is needed for 'j', and subsequently requests it to be made addressable. { dg-note {OpenACC 'kernels' decomposition: variable 'j' declared in block requested to be made addressable} {} { target c++ } l_compute$c_compute } { dg-note {variable 'j' made addressable} {} { target c++ } l_compute$c_compute } { dg-note {variable 'j' declared in block is candidate for adjusting OpenACC privatization level} {} { target c++ } l_compute$c_compute } */ /* { dg-note {variable 'x\.[0-9]+' declared in block isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target *-*-* } l_compute$c_compute } */ { int j; /* { dg-note {forwarded loop nest in OpenACC 'kernels' region to 'parloops' for analysis} {} { target *-*-* } .+1 } */ #pragma acc loop gang(num:32) /* { dg-line l_loop_i[incr c_loop_i] } */ /* { dg-note {variable 'j' declared in block isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target c } l_loop_i$c_loop_i } */ /* { dg-note {variable 'i' in 'private' clause isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target *-*-* } l_loop_i$c_loop_i } */ for (i = 0; i < 32; i++) { #pragma acc loop worker(num:32) private(x) /* { dg-line l_loop_j[incr c_loop_j] } */ /* { dg-note {variable 'x' in 'private' clause is candidate for adjusting OpenACC privatization level} {} { target *-*-* } l_loop_j$c_loop_j } */ /* { dg-note {variable 'j' in 'private' clause isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target *-*-* } l_loop_j$c_loop_j } */ /* { dg-note {variable 'k' declared in block isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target *-*-* } l_loop_j$c_loop_j } */ /* { dg-note {variable 'p' declared in block isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target *-*-* } l_loop_j$c_loop_j } */ for (j = 0; j < 32; j++) { int k; int *p = &x; x = i ^ j * 3; #pragma acc loop vector(length:32) /* { dg-line l_loop_k[incr c_loop_k] } */ /* { dg-note {variable 'k' in 'private' clause isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target *-*-* } l_loop_k$c_loop_k } */ for (k = 0; k < 32; k++) arr[i * 1024 + j * 32 + k] += x * k; *p = i | j * 5; #pragma acc loop vector(length:32) /* { dg-line l_loop_k[incr c_loop_k] } */ /* { dg-note {variable 'k' in 'private' clause isn't candidate for adjusting OpenACC privatization level: not addressable} {} { target *-*-* } l_loop_k$c_loop_k } */ for (k = 0; k < 32; k++) arr[i * 1024 + j * 32 + k] += x * k; } } /* { dg-optimized {assigned OpenACC seq loop parallelism} {} { target *-*-* } l_loop_i$c_loop_i } */ } for (i = 0; i < 32; i++) for (int j = 0; j < 32; j++) for (int k = 0; k < 32; k++) { int idx = i * 1024 + j * 32 + k; assert (arr[idx] == idx + (i ^ j * 3) * k + (i | j * 5) * k); } return 0; }