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IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER INN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR INN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include #include #include #include "printf_common.h" // NOLINT const char* msg_short = "Carpe diem."; const char* msg_long1 = "Lorem ipsum dolor sit amet, consectetur nullam. In mollis imperdiet nibh nec ullamcorper."; // NOLINT const char* msg_long2 = "Curabitur nec metus sit amet augue vehicula ultrices ut id leo. Lorem ipsum dolor sit amet, " "consectetur adipiscing elit amet."; // NOLINT __global__ void kernel_uniform0(int* retval) { uint tid = hipThreadIdx_x + hipBlockIdx_x * hipBlockDim_x; retval[tid] = printf("Hello World\n"); } static void test_uniform0(int* retval, uint num_blocks, uint threads_per_block) { CaptureStream captured(stdout); uint num_threads = num_blocks * threads_per_block; for (uint i = 0; i != num_threads; ++i) { retval[i] = 0x23232323; } hipLaunchKernelGGL(kernel_uniform0, dim3(num_blocks), dim3(threads_per_block), 0, 0, retval); HIP_CHECK(hipStreamSynchronize(0)); auto CapturedData = captured.getCapturedData(); for (uint ii = 0; ii != num_threads; ++ii) { REQUIRE(retval[ii] == strlen("Hello World\n")); } std::map linecount; for (std::string line; std::getline(CapturedData, line);) { linecount[line]++; } REQUIRE(linecount.size() == 1); REQUIRE(linecount["Hello World"] == num_threads); } __global__ void kernel_uniform1(int* retval) { uint tid = hipThreadIdx_x + hipBlockIdx_x * hipBlockDim_x; retval[tid] = printf("Six times Eight is %d\n", 42); } static void test_uniform1(int* retval, uint num_blocks, uint threads_per_block) { CaptureStream captured(stdout); uint num_threads = num_blocks * threads_per_block; for (uint i = 0; i != num_threads; ++i) { retval[i] = 0x23232323; } hipLaunchKernelGGL(kernel_uniform1, dim3(num_blocks), dim3(threads_per_block), 0, 0, retval); HIP_CHECK(hipStreamSynchronize(0)); auto CapturedData = captured.getCapturedData(); for (uint ii = 0; ii != num_threads; ++ii) { REQUIRE(retval[ii] == strlen("Six times Eight is 42") + 1); } std::map linecount; for (std::string line; std::getline(CapturedData, line);) { linecount[line]++; } REQUIRE(linecount.size() == 1); REQUIRE(linecount["Six times Eight is 42"] == num_threads); } __global__ void kernel_divergent0(int* retval) { uint tid = hipThreadIdx_x + hipBlockIdx_x * hipBlockDim_x; retval[tid] = printf("Thread ID: %d\n", tid); } static void test_divergent0(int* retval, uint num_blocks, uint threads_per_block) { CaptureStream captured(stdout); uint num_threads = num_blocks * threads_per_block; for (uint i = 0; i != num_threads; ++i) { retval[i] = 0x23232323; } hipLaunchKernelGGL(kernel_divergent0, dim3(num_blocks), dim3(threads_per_block), 0, 0, retval); HIP_CHECK(hipStreamSynchronize(0)); auto CapturedData = captured.getCapturedData(); for (uint ii = 0; ii != 10; ++ii) { REQUIRE(retval[ii] == 13); } for (uint ii = 10; ii != num_threads; ++ii) { REQUIRE(retval[ii] == 14); } std::vector threadIds; for (std::string line; std::getline(CapturedData, line);) { auto pos = line.find(':'); REQUIRE(line.substr(0, pos) == "Thread ID"); threadIds.push_back(std::stoul(line.substr(pos + 2))); } std::sort(threadIds.begin(), threadIds.end()); REQUIRE(threadIds.size() == num_threads); REQUIRE(threadIds.back() == num_threads - 1); } __global__ void kernel_divergent1(int* retval) { uint tid = hipThreadIdx_x + hipBlockIdx_x * hipBlockDim_x; if (tid % 2) { retval[tid] = printf("Hello World\n"); } else { retval[tid] = -1; } } static void test_divergent1(int* retval, uint num_blocks, uint threads_per_block) { CaptureStream captured(stdout); uint num_threads = num_blocks * threads_per_block; for (uint i = 0; i != num_threads; ++i) { retval[i] = 0x23232323; } hipLaunchKernelGGL(kernel_divergent1, dim3(num_blocks), dim3(threads_per_block), 0, 0, retval); HIP_CHECK(hipStreamSynchronize(0)); auto CapturedData = captured.getCapturedData(); for (uint ii = 0; ii != num_threads; ++ii) { if (ii % 2) { REQUIRE(retval[ii] == strlen("Hello World\n")); } else { REQUIRE(retval[ii] == -1); } } std::map linecount; for (std::string line; std::getline(CapturedData, line);) { linecount[line]++; } REQUIRE(linecount.size() == 1); REQUIRE(linecount["Hello World"] == num_threads / 2); } __global__ void kernel_series(int* retval) { const uint tid = hipThreadIdx_x + hipBlockIdx_x * hipBlockDim_x; int result = 0; result += printf("%s\n", msg_long1_dev); result += printf("%s\n", msg_short_dev); result += printf("%s\n", msg_long2_dev); retval[tid] = result; } static void test_series(int* retval, uint num_blocks, uint threads_per_block) { CaptureStream captured(stdout); uint num_threads = num_blocks * threads_per_block; for (uint i = 0; i != num_threads; ++i) { retval[i] = 0x23232323; } hipLaunchKernelGGL(kernel_series, dim3(num_blocks), dim3(threads_per_block), 0, 0, retval); HIP_CHECK(hipStreamSynchronize(0)); auto CapturedData = captured.getCapturedData(); for (uint ii = 0; ii != num_threads; ++ii) { REQUIRE(retval[ii] == strlen(msg_long1) + strlen(msg_short) + strlen(msg_long2) + 3); } std::map linecount; for (std::string line; std::getline(CapturedData, line);) { linecount[line]++; } REQUIRE(linecount.size() == 3); REQUIRE(linecount[msg_long1] == num_threads); REQUIRE(linecount[msg_long2] == num_threads); REQUIRE(linecount[msg_short] == num_threads); } /** * @addtogroup printf printf * @{ * @ingroup PrintfTest * `int printf()` - * Method to print the content on output device. */ /** * Test Description * ------------------------ * - Test case to verify basic functionality of printf API. * Test source * ------------------------ * - catch/unit/printf/hipPrintfBasic.cc * Test requirements * ------------------------ * - HIP_VERSION >= 6.2 */ TEST_CASE("Unit_Printf_PrintfBasicTsts") { int pcieAtomic = 0; HIP_CHECK(hipDeviceGetAttribute(&pcieAtomic, hipDeviceAttributeHostNativeAtomicSupported, 0)); if (!pcieAtomic) { HipTest::HIP_SKIP_TEST("Device doesn't support pcie atomic, Skipped"); return; } uint num_blocks = 1; uint threads_per_block = 64; uint num_threads = num_blocks * threads_per_block; void* retval_void; HIP_CHECK(hipHostMalloc(&retval_void, 4 * num_threads)); auto retval = reinterpret_cast(retval_void); test_uniform0(retval, num_blocks, threads_per_block); test_uniform1(retval, num_blocks, threads_per_block); test_divergent0(retval, num_blocks, threads_per_block); test_divergent1(retval, num_blocks, threads_per_block); test_series(retval, num_blocks, threads_per_block); HIP_CHECK(hipFree(retval_void)); } /** * End doxygen group PrintfTest. * @} */