// // Copyright (c) 2017 The Khronos Group Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // #include "common.h" #include "function_list.h" #include "test_functions.h" #include "utility.h" #include namespace { const float twoToMinus126 = MAKE_HEX_FLOAT(0x1p-126f, 1, -126); cl_int BuildKernelFn(cl_uint job_id, cl_uint thread_id UNUSED, void *p) { BuildKernelInfo &info = *(BuildKernelInfo *)p; auto generator = [](const std::string &kernel_name, const char *builtin, cl_uint vector_size_index) { return GetBinaryKernel(kernel_name, builtin, ParameterType::Float, ParameterType::Float, ParameterType::Float, vector_size_index); }; return BuildKernels(info, job_id, generator); } // Thread specific data for a worker thread struct ThreadInfo { // Input and output buffers for the thread clMemWrapper inBuf; clMemWrapper inBuf2; Buffers outBuf; float maxError; // max error value. Init to 0. double maxErrorValue; // position of the max error value (param 1). Init to 0. double maxErrorValue2; // position of the max error value (param 2). Init // to 0. MTdataHolder d; // Per thread command queue to improve performance clCommandQueueWrapper tQueue; }; struct TestInfo { size_t subBufferSize; // Size of the sub-buffer in elements const Func *f; // A pointer to the function info // Programs for various vector sizes. Programs programs; // Thread-specific kernels for each vector size: // k[vector_size][thread_id] KernelMatrix k; // Array of thread specific information std::vector tinfo; cl_uint threadCount; // Number of worker threads cl_uint jobCount; // Number of jobs cl_uint step; // step between each chunk and the next. cl_uint scale; // stride between individual test values float ulps; // max_allowed ulps int ftz; // non-zero if running in flush to zero mode int isFDim; int skipNanInf; int isNextafter; bool relaxedMode; // True if test is running in relaxed mode, false // otherwise. }; // A table of more difficult cases to get right const float specialValues[] = { -NAN, -INFINITY, -FLT_MAX, MAKE_HEX_FLOAT(-0x1.000002p64f, -0x1000002L, 40), MAKE_HEX_FLOAT(-0x1.0p64f, -0x1L, 64), MAKE_HEX_FLOAT(-0x1.fffffep63f, -0x1fffffeL, 39), MAKE_HEX_FLOAT(-0x1.000002p63f, -0x1000002L, 39), MAKE_HEX_FLOAT(-0x1.0p63f, -0x1L, 63), MAKE_HEX_FLOAT(-0x1.fffffep62f, -0x1fffffeL, 38), MAKE_HEX_FLOAT(-0x1.000002p32f, -0x1000002L, 8), MAKE_HEX_FLOAT(-0x1.0p32f, -0x1L, 32), MAKE_HEX_FLOAT(-0x1.fffffep31f, -0x1fffffeL, 7), MAKE_HEX_FLOAT(-0x1.000002p31f, -0x1000002L, 7), MAKE_HEX_FLOAT(-0x1.0p31f, -0x1L, 31), MAKE_HEX_FLOAT(-0x1.fffffep30f, -0x1fffffeL, 6), -1000.f, -100.f, -4.0f, -3.5f, -3.0f, MAKE_HEX_FLOAT(-0x1.800002p1f, -0x1800002L, -23), -2.5f, MAKE_HEX_FLOAT(-0x1.7ffffep1f, -0x17ffffeL, -23), -2.0f, MAKE_HEX_FLOAT(-0x1.800002p0f, -0x1800002L, -24), -1.5f, MAKE_HEX_FLOAT(-0x1.7ffffep0f, -0x17ffffeL, -24), MAKE_HEX_FLOAT(-0x1.000002p0f, -0x1000002L, -24), -1.0f, MAKE_HEX_FLOAT(-0x1.fffffep-1f, -0x1fffffeL, -25), MAKE_HEX_FLOAT(-0x1.000002p-1f, -0x1000002L, -25), -0.5f, MAKE_HEX_FLOAT(-0x1.fffffep-2f, -0x1fffffeL, -26), MAKE_HEX_FLOAT(-0x1.000002p-2f, -0x1000002L, -26), -0.25f, MAKE_HEX_FLOAT(-0x1.fffffep-3f, -0x1fffffeL, -27), MAKE_HEX_FLOAT(-0x1.000002p-126f, -0x1000002L, -150), -FLT_MIN, MAKE_HEX_FLOAT(-0x0.fffffep-126f, -0x0fffffeL, -150), MAKE_HEX_FLOAT(-0x0.000ffep-126f, -0x0000ffeL, -150), MAKE_HEX_FLOAT(-0x0.0000fep-126f, -0x00000feL, -150), MAKE_HEX_FLOAT(-0x0.00000ep-126f, -0x000000eL, -150), MAKE_HEX_FLOAT(-0x0.00000cp-126f, -0x000000cL, -150), MAKE_HEX_FLOAT(-0x0.00000ap-126f, -0x000000aL, -150), MAKE_HEX_FLOAT(-0x0.000008p-126f, -0x0000008L, -150), MAKE_HEX_FLOAT(-0x0.000006p-126f, -0x0000006L, -150), MAKE_HEX_FLOAT(-0x0.000004p-126f, -0x0000004L, -150), MAKE_HEX_FLOAT(-0x0.000002p-126f, -0x0000002L, -150), -0.0f, +NAN, +INFINITY, +FLT_MAX, MAKE_HEX_FLOAT(+0x1.000002p64f, +0x1000002L, 40), MAKE_HEX_FLOAT(+0x1.0p64f, +0x1L, 64), MAKE_HEX_FLOAT(+0x1.fffffep63f, +0x1fffffeL, 39), MAKE_HEX_FLOAT(+0x1.000002p63f, +0x1000002L, 39), MAKE_HEX_FLOAT(+0x1.0p63f, +0x1L, 63), MAKE_HEX_FLOAT(+0x1.fffffep62f, +0x1fffffeL, 38), MAKE_HEX_FLOAT(+0x1.000002p32f, +0x1000002L, 8), MAKE_HEX_FLOAT(+0x1.0p32f, +0x1L, 32), MAKE_HEX_FLOAT(+0x1.fffffep31f, +0x1fffffeL, 7), MAKE_HEX_FLOAT(+0x1.000002p31f, +0x1000002L, 7), MAKE_HEX_FLOAT(+0x1.0p31f, +0x1L, 31), MAKE_HEX_FLOAT(+0x1.fffffep30f, +0x1fffffeL, 6), +1000.f, +100.f, +4.0f, +3.5f, +3.0f, MAKE_HEX_FLOAT(+0x1.800002p1f, +0x1800002L, -23), 2.5f, MAKE_HEX_FLOAT(+0x1.7ffffep1f, +0x17ffffeL, -23), +2.0f, MAKE_HEX_FLOAT(+0x1.800002p0f, +0x1800002L, -24), 1.5f, MAKE_HEX_FLOAT(+0x1.7ffffep0f, +0x17ffffeL, -24), MAKE_HEX_FLOAT(+0x1.000002p0f, +0x1000002L, -24), +1.0f, MAKE_HEX_FLOAT(+0x1.fffffep-1f, +0x1fffffeL, -25), MAKE_HEX_FLOAT(+0x1.000002p-1f, +0x1000002L, -25), +0.5f, MAKE_HEX_FLOAT(+0x1.fffffep-2f, +0x1fffffeL, -26), MAKE_HEX_FLOAT(+0x1.000002p-2f, +0x1000002L, -26), +0.25f, MAKE_HEX_FLOAT(+0x1.fffffep-3f, +0x1fffffeL, -27), MAKE_HEX_FLOAT(0x1.000002p-126f, 0x1000002L, -150), +FLT_MIN, MAKE_HEX_FLOAT(+0x0.fffffep-126f, +0x0fffffeL, -150), MAKE_HEX_FLOAT(+0x0.000ffep-126f, +0x0000ffeL, -150), MAKE_HEX_FLOAT(+0x0.0000fep-126f, +0x00000feL, -150), MAKE_HEX_FLOAT(+0x0.00000ep-126f, +0x000000eL, -150), MAKE_HEX_FLOAT(+0x0.00000cp-126f, +0x000000cL, -150), MAKE_HEX_FLOAT(+0x0.00000ap-126f, +0x000000aL, -150), MAKE_HEX_FLOAT(+0x0.000008p-126f, +0x0000008L, -150), MAKE_HEX_FLOAT(+0x0.000006p-126f, +0x0000006L, -150), MAKE_HEX_FLOAT(+0x0.000004p-126f, +0x0000004L, -150), MAKE_HEX_FLOAT(+0x0.000002p-126f, +0x0000002L, -150), +0.0f, }; constexpr size_t specialValuesCount = sizeof(specialValues) / sizeof(specialValues[0]); cl_int Test(cl_uint job_id, cl_uint thread_id, void *data) { TestInfo *job = (TestInfo *)data; size_t buffer_elements = job->subBufferSize; size_t buffer_size = buffer_elements * sizeof(cl_float); cl_uint base = job_id * (cl_uint)job->step; ThreadInfo *tinfo = &(job->tinfo[thread_id]); fptr func = job->f->func; int ftz = job->ftz; bool relaxedMode = job->relaxedMode; float ulps = getAllowedUlpError(job->f, relaxedMode); MTdata d = tinfo->d; cl_int error; std::vector overflow(buffer_elements, false); const char *name = job->f->name; int isFDim = job->isFDim; int skipNanInf = job->skipNanInf; int isNextafter = job->isNextafter; cl_uint *t = 0; cl_float *r = 0; cl_float *s = 0; cl_float *s2 = 0; cl_int copysign_test = 0; RoundingMode oldRoundMode; int skipVerification = 0; if (relaxedMode) { func = job->f->rfunc; if (strcmp(name, "pow") == 0 && gFastRelaxedDerived) { ulps = INFINITY; skipVerification = 1; } } cl_event e[VECTOR_SIZE_COUNT]; cl_uint *out[VECTOR_SIZE_COUNT]; if (gHostFill) { // start the map of the output arrays for (auto j = gMinVectorSizeIndex; j < gMaxVectorSizeIndex; j++) { out[j] = (cl_uint *)clEnqueueMapBuffer( tinfo->tQueue, tinfo->outBuf[j], CL_FALSE, CL_MAP_WRITE, 0, buffer_size, 0, NULL, e + j, &error); if (error || NULL == out[j]) { vlog_error("Error: clEnqueueMapBuffer %d failed! err: %d\n", j, error); return error; } } // Get that moving if ((error = clFlush(tinfo->tQueue))) vlog("clFlush failed\n"); } // Init input array cl_uint *p = (cl_uint *)gIn + thread_id * buffer_elements; cl_uint *p2 = (cl_uint *)gIn2 + thread_id * buffer_elements; cl_uint idx = 0; int totalSpecialValueCount = specialValuesCount * specialValuesCount; int lastSpecialJobIndex = (totalSpecialValueCount - 1) / buffer_elements; // Test edge cases if (job_id <= (cl_uint)lastSpecialJobIndex) { float *fp = (float *)p; float *fp2 = (float *)p2; uint32_t x, y; x = (job_id * buffer_elements) % specialValuesCount; y = (job_id * buffer_elements) / specialValuesCount; for (; idx < buffer_elements; idx++) { fp[idx] = specialValues[x]; fp2[idx] = specialValues[y]; ++x; if (x >= specialValuesCount) { x = 0; y++; if (y >= specialValuesCount) break; } } } // Init any remaining values for (; idx < buffer_elements; idx++) { p[idx] = genrand_int32(d); p2[idx] = genrand_int32(d); } if ((error = clEnqueueWriteBuffer(tinfo->tQueue, tinfo->inBuf, CL_FALSE, 0, buffer_size, p, 0, NULL, NULL))) { vlog_error("Error: clEnqueueWriteBuffer failed! err: %d\n", error); return error; } if ((error = clEnqueueWriteBuffer(tinfo->tQueue, tinfo->inBuf2, CL_FALSE, 0, buffer_size, p2, 0, NULL, NULL))) { vlog_error("Error: clEnqueueWriteBuffer failed! err: %d\n", error); return error; } for (auto j = gMinVectorSizeIndex; j < gMaxVectorSizeIndex; j++) { if (gHostFill) { // Wait for the map to finish if ((error = clWaitForEvents(1, e + j))) { vlog_error("Error: clWaitForEvents failed! err: %d\n", error); return error; } if ((error = clReleaseEvent(e[j]))) { vlog_error("Error: clReleaseEvent failed! err: %d\n", error); return error; } } // Fill the result buffer with garbage, so that old results don't carry // over uint32_t pattern = 0xffffdead; if (gHostFill) { memset_pattern4(out[j], &pattern, buffer_size); if ((error = clEnqueueUnmapMemObject( tinfo->tQueue, tinfo->outBuf[j], out[j], 0, NULL, NULL))) { vlog_error("Error: clEnqueueUnmapMemObject failed! err: %d\n", error); return error; } } else { if ((error = clEnqueueFillBuffer(tinfo->tQueue, tinfo->outBuf[j], &pattern, sizeof(pattern), 0, buffer_size, 0, NULL, NULL))) { vlog_error("Error: clEnqueueFillBuffer failed! err: %d\n", error); return error; } } // Run the kernel size_t vectorCount = (buffer_elements + sizeValues[j] - 1) / sizeValues[j]; cl_kernel kernel = job->k[j][thread_id]; // each worker thread has its // own copy of the cl_kernel cl_program program = job->programs[j]; if ((error = clSetKernelArg(kernel, 0, sizeof(tinfo->outBuf[j]), &tinfo->outBuf[j]))) { LogBuildError(program); return error; } if ((error = clSetKernelArg(kernel, 1, sizeof(tinfo->inBuf), &tinfo->inBuf))) { LogBuildError(program); return error; } if ((error = clSetKernelArg(kernel, 2, sizeof(tinfo->inBuf2), &tinfo->inBuf2))) { LogBuildError(program); return error; } if ((error = clEnqueueNDRangeKernel(tinfo->tQueue, kernel, 1, NULL, &vectorCount, NULL, 0, NULL, NULL))) { vlog_error("FAILED -- could not execute kernel\n"); return error; } } // Get that moving if ((error = clFlush(tinfo->tQueue))) vlog("clFlush 2 failed\n"); if (gSkipCorrectnessTesting) { if ((error = clFinish(tinfo->tQueue))) { vlog_error("Error: clFinish failed! err: %d\n", error); return error; } return CL_SUCCESS; } FPU_mode_type oldMode; oldRoundMode = kRoundToNearestEven; if (isFDim) { // Calculate the correctly rounded reference result memset(&oldMode, 0, sizeof(oldMode)); if (ftz || relaxedMode) ForceFTZ(&oldMode); // Set the rounding mode to match the device if (gIsInRTZMode) oldRoundMode = set_round(kRoundTowardZero, kfloat); } if (!strcmp(name, "copysign")) copysign_test = 1; #define ref_func(s, s2) (copysign_test ? func.f_ff_f(s, s2) : func.f_ff(s, s2)) // Calculate the correctly rounded reference result r = (float *)gOut_Ref + thread_id * buffer_elements; s = (float *)gIn + thread_id * buffer_elements; s2 = (float *)gIn2 + thread_id * buffer_elements; if (skipNanInf) { for (size_t j = 0; j < buffer_elements; j++) { feclearexcept(FE_OVERFLOW); r[j] = (float)ref_func(s[j], s2[j]); overflow[j] = FE_OVERFLOW == (FE_OVERFLOW & fetestexcept(FE_OVERFLOW)); } } else { for (size_t j = 0; j < buffer_elements; j++) r[j] = (float)ref_func(s[j], s2[j]); } if (isFDim && ftz) RestoreFPState(&oldMode); // Read the data back -- no need to wait for the first N-1 buffers but wait // for the last buffer. This is an in order queue. for (auto j = gMinVectorSizeIndex; j < gMaxVectorSizeIndex; j++) { cl_bool blocking = (j + 1 < gMaxVectorSizeIndex) ? CL_FALSE : CL_TRUE; out[j] = (cl_uint *)clEnqueueMapBuffer( tinfo->tQueue, tinfo->outBuf[j], blocking, CL_MAP_READ, 0, buffer_size, 0, NULL, NULL, &error); if (error || NULL == out[j]) { vlog_error("Error: clEnqueueMapBuffer %d failed! err: %d\n", j, error); return error; } } if (!skipVerification) { // Verify data t = (cl_uint *)r; for (size_t j = 0; j < buffer_elements; j++) { for (auto k = gMinVectorSizeIndex; k < gMaxVectorSizeIndex; k++) { cl_uint *q = out[k]; // If we aren't getting the correctly rounded result if (t[j] != q[j]) { float test = ((float *)q)[j]; double correct = ref_func(s[j], s2[j]); // Per section 10 paragraph 6, accept any result if an input // or output is a infinity or NaN or overflow As per // OpenCL 2.0 spec, section 5.8.4.3, enabling // fast-relaxed-math mode also enables -cl-finite-math-only // optimization. This optimization allows to assume that // arguments and results are not NaNs or +/-INFs. Hence, // accept any result if inputs or results are NaNs or INFs. if (relaxedMode || skipNanInf) { if (skipNanInf && overflow[j]) continue; // Note: no double rounding here. Reference functions // calculate in single precision. if (IsFloatInfinity(correct) || IsFloatNaN(correct) || IsFloatInfinity(s2[j]) || IsFloatNaN(s2[j]) || IsFloatInfinity(s[j]) || IsFloatNaN(s[j])) continue; } float err = Ulp_Error(test, correct); int fail = !(fabsf(err) <= ulps); if (fail && (ftz || relaxedMode)) { // retry per section 6.5.3.2 if (IsFloatResultSubnormal(correct, ulps)) { fail = fail && (test != 0.0f); if (!fail) err = 0.0f; } // nextafter on FTZ platforms may return the smallest // normal float (2^-126) given a denormal or a zero // as the first argument. The rationale here is that // nextafter flushes the argument to zero and then // returns the next representable number in the // direction of the second argument, and since // denorms are considered as zero, the smallest // normal number is the next representable number. // In which case, it should have the same sign as the // second argument. if (isNextafter) { if (IsFloatSubnormal(s[j]) || s[j] == 0.0f) { float value = copysignf(twoToMinus126, s2[j]); fail = fail && (test != value); if (!fail) err = 0.0f; } } else { // retry per section 6.5.3.3 if (IsFloatSubnormal(s[j])) { double correct2, correct3; float err2, err3; if (skipNanInf) feclearexcept(FE_OVERFLOW); correct2 = ref_func(0.0, s2[j]); correct3 = ref_func(-0.0, s2[j]); // Per section 10 paragraph 6, accept any result // if an input or output is a infinity or NaN or // overflow As per OpenCL 2.0 spec, // section 5.8.4.3, enabling fast-relaxed-math // mode also enables -cl-finite-math-only // optimization. This optimization allows to // assume that arguments and results are not // NaNs or +/-INFs. Hence, accept any result if // inputs or results are NaNs or INFs. if (relaxedMode || skipNanInf) { if (fetestexcept(FE_OVERFLOW) && skipNanInf) continue; // Note: no double rounding here. Reference // functions calculate in single precision. if (IsFloatInfinity(correct2) || IsFloatNaN(correct2) || IsFloatInfinity(correct3) || IsFloatNaN(correct3)) continue; } err2 = Ulp_Error(test, correct2); err3 = Ulp_Error(test, correct3); fail = fail && ((!(fabsf(err2) <= ulps)) && (!(fabsf(err3) <= ulps))); if (fabsf(err2) < fabsf(err)) err = err2; if (fabsf(err3) < fabsf(err)) err = err3; // retry per section 6.5.3.4 if (IsFloatResultSubnormal(correct2, ulps) || IsFloatResultSubnormal(correct3, ulps)) { fail = fail && (test != 0.0f); if (!fail) err = 0.0f; } // try with both args as zero if (IsFloatSubnormal(s2[j])) { double correct4, correct5; float err4, err5; if (skipNanInf) feclearexcept(FE_OVERFLOW); correct2 = ref_func(0.0, 0.0); correct3 = ref_func(-0.0, 0.0); correct4 = ref_func(0.0, -0.0); correct5 = ref_func(-0.0, -0.0); // Per section 10 paragraph 6, accept any // result if an input or output is a // infinity or NaN or overflow As per // OpenCL 2.0 spec, section 5.8.4.3, // enabling fast-relaxed-math mode also // enables -cl-finite-math-only // optimization. This optimization allows to // assume that arguments and results are not // NaNs or +/-INFs. Hence, accept any result // if inputs or results are NaNs or INFs. if (relaxedMode || skipNanInf) { if (fetestexcept(FE_OVERFLOW) && skipNanInf) continue; // Note: no double rounding here. // Reference functions calculate in // single precision. if (IsFloatInfinity(correct2) || IsFloatNaN(correct2) || IsFloatInfinity(correct3) || IsFloatNaN(correct3) || IsFloatInfinity(correct4) || IsFloatNaN(correct4) || IsFloatInfinity(correct5) || IsFloatNaN(correct5)) continue; } err2 = Ulp_Error(test, correct2); err3 = Ulp_Error(test, correct3); err4 = Ulp_Error(test, correct4); err5 = Ulp_Error(test, correct5); fail = fail && ((!(fabsf(err2) <= ulps)) && (!(fabsf(err3) <= ulps)) && (!(fabsf(err4) <= ulps)) && (!(fabsf(err5) <= ulps))); if (fabsf(err2) < fabsf(err)) err = err2; if (fabsf(err3) < fabsf(err)) err = err3; if (fabsf(err4) < fabsf(err)) err = err4; if (fabsf(err5) < fabsf(err)) err = err5; // retry per section 6.5.3.4 if (IsFloatResultSubnormal(correct2, ulps) || IsFloatResultSubnormal(correct3, ulps) || IsFloatResultSubnormal(correct4, ulps) || IsFloatResultSubnormal(correct5, ulps)) { fail = fail && (test != 0.0f); if (!fail) err = 0.0f; } } } else if (IsFloatSubnormal(s2[j])) { double correct2, correct3; float err2, err3; if (skipNanInf) feclearexcept(FE_OVERFLOW); correct2 = ref_func(s[j], 0.0); correct3 = ref_func(s[j], -0.0); // Per section 10 paragraph 6, accept any result // if an input or output is a infinity or NaN or // overflow As per OpenCL 2.0 spec, // section 5.8.4.3, enabling fast-relaxed-math // mode also enables -cl-finite-math-only // optimization. This optimization allows to // assume that arguments and results are not // NaNs or +/-INFs. Hence, accept any result if // inputs or results are NaNs or INFs. if (relaxedMode || skipNanInf) { // Note: no double rounding here. Reference // functions calculate in single precision. if (overflow[j] && skipNanInf) continue; if (IsFloatInfinity(correct2) || IsFloatNaN(correct2) || IsFloatInfinity(correct3) || IsFloatNaN(correct3)) continue; } err2 = Ulp_Error(test, correct2); err3 = Ulp_Error(test, correct3); fail = fail && ((!(fabsf(err2) <= ulps)) && (!(fabsf(err3) <= ulps))); if (fabsf(err2) < fabsf(err)) err = err2; if (fabsf(err3) < fabsf(err)) err = err3; // retry per section 6.5.3.4 if (IsFloatResultSubnormal(correct2, ulps) || IsFloatResultSubnormal(correct3, ulps)) { fail = fail && (test != 0.0f); if (!fail) err = 0.0f; } } } } if (fabsf(err) > tinfo->maxError) { tinfo->maxError = fabsf(err); tinfo->maxErrorValue = s[j]; tinfo->maxErrorValue2 = s2[j]; } if (fail) { vlog_error( "\nERROR: %s%s: %f ulp error at {%a (0x%x), %a " "(0x%x)}: *%a vs. %a (0x%8.8x) at index: %zu\n", name, sizeNames[k], err, s[j], ((cl_uint *)s)[j], s2[j], ((cl_uint *)s2)[j], r[j], test, ((cl_uint *)&test)[0], j); return -1; } } } } } if (isFDim && gIsInRTZMode) (void)set_round(oldRoundMode, kfloat); for (auto j = gMinVectorSizeIndex; j < gMaxVectorSizeIndex; j++) { if ((error = clEnqueueUnmapMemObject(tinfo->tQueue, tinfo->outBuf[j], out[j], 0, NULL, NULL))) { vlog_error("Error: clEnqueueUnmapMemObject %d failed 2! err: %d\n", j, error); return error; } } if ((error = clFlush(tinfo->tQueue))) vlog("clFlush 3 failed\n"); if (0 == (base & 0x0fffffff)) { if (gVerboseBruteForce) { vlog("base:%14u step:%10u scale:%10u buf_elements:%10zu ulps:%5.3f " "ThreadCount:%2u\n", base, job->step, job->scale, buffer_elements, job->ulps, job->threadCount); } else { vlog("."); } fflush(stdout); } return CL_SUCCESS; } } // anonymous namespace int TestFunc_Float_Float_Float(const Func *f, MTdata d, bool relaxedMode) { TestInfo test_info{}; cl_int error; float maxError = 0.0f; double maxErrorVal = 0.0; double maxErrorVal2 = 0.0; logFunctionInfo(f->name, sizeof(cl_float), relaxedMode); // Init test_info test_info.threadCount = GetThreadCount(); test_info.subBufferSize = BUFFER_SIZE / (sizeof(cl_float) * RoundUpToNextPowerOfTwo(test_info.threadCount)); test_info.scale = getTestScale(sizeof(cl_float)); test_info.step = (cl_uint)test_info.subBufferSize * test_info.scale; if (test_info.step / test_info.subBufferSize != test_info.scale) { // there was overflow test_info.jobCount = 1; } else { test_info.jobCount = (cl_uint)((1ULL << 32) / test_info.step); } test_info.f = f; test_info.ulps = gIsEmbedded ? f->float_embedded_ulps : f->float_ulps; test_info.ftz = f->ftz || gForceFTZ || 0 == (CL_FP_DENORM & gFloatCapabilities); test_info.relaxedMode = relaxedMode; test_info.isFDim = 0 == strcmp("fdim", f->nameInCode); test_info.skipNanInf = test_info.isFDim && !gInfNanSupport; test_info.isNextafter = 0 == strcmp("nextafter", f->nameInCode); test_info.tinfo.resize(test_info.threadCount); for (cl_uint i = 0; i < test_info.threadCount; i++) { cl_buffer_region region = { i * test_info.subBufferSize * sizeof(cl_float), test_info.subBufferSize * sizeof(cl_float) }; test_info.tinfo[i].inBuf = clCreateSubBuffer(gInBuffer, CL_MEM_READ_ONLY, CL_BUFFER_CREATE_TYPE_REGION, ®ion, &error); if (error || NULL == test_info.tinfo[i].inBuf) { vlog_error("Error: Unable to create sub-buffer of gInBuffer for " "region {%zd, %zd}\n", region.origin, region.size); return error; } test_info.tinfo[i].inBuf2 = clCreateSubBuffer(gInBuffer2, CL_MEM_READ_ONLY, CL_BUFFER_CREATE_TYPE_REGION, ®ion, &error); if (error || NULL == test_info.tinfo[i].inBuf2) { vlog_error("Error: Unable to create sub-buffer of gInBuffer2 for " "region {%zd, %zd}\n", region.origin, region.size); return error; } for (auto j = gMinVectorSizeIndex; j < gMaxVectorSizeIndex; j++) { test_info.tinfo[i].outBuf[j] = clCreateSubBuffer( gOutBuffer[j], CL_MEM_WRITE_ONLY, CL_BUFFER_CREATE_TYPE_REGION, ®ion, &error); if (error || NULL == test_info.tinfo[i].outBuf[j]) { vlog_error("Error: Unable to create sub-buffer of " "gOutBuffer[%d] for region {%zd, %zd}\n", (int)j, region.origin, region.size); return error; } } test_info.tinfo[i].tQueue = clCreateCommandQueue(gContext, gDevice, 0, &error); if (NULL == test_info.tinfo[i].tQueue || error) { vlog_error("clCreateCommandQueue failed. (%d)\n", error); return error; } test_info.tinfo[i].d = MTdataHolder(genrand_int32(d)); } // Init the kernels BuildKernelInfo build_info{ test_info.threadCount, test_info.k, test_info.programs, f->nameInCode, relaxedMode }; if ((error = ThreadPool_Do(BuildKernelFn, gMaxVectorSizeIndex - gMinVectorSizeIndex, &build_info))) return error; // Run the kernels if (!gSkipCorrectnessTesting) { error = ThreadPool_Do(Test, test_info.jobCount, &test_info); if (error) return error; // Accumulate the arithmetic errors for (cl_uint i = 0; i < test_info.threadCount; i++) { if (test_info.tinfo[i].maxError > maxError) { maxError = test_info.tinfo[i].maxError; maxErrorVal = test_info.tinfo[i].maxErrorValue; maxErrorVal2 = test_info.tinfo[i].maxErrorValue2; } } if (gWimpyMode) vlog("Wimp pass"); else vlog("passed"); vlog("\t%8.2f @ {%a, %a}", maxError, maxErrorVal, maxErrorVal2); } vlog("\n"); return CL_SUCCESS; }