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// =================================================================================================
// This file is part of the CLBlast project. The project is licensed under Apache Version 2.0. This
// project loosely follows the Google C++ styleguide and uses a tab-size of two spaces and a max-
// width of 100 characters per line.
//
// Author(s):
// Cedric Nugteren <www.cedricnugteren.nl>
//
// This file implements an auto-tuner to tune the Xgemm OpenCL kernel. It uses the CLTune library.
// Note that this tuner uses random-search: running it multiple times or with a larger fraction
// argument might be neccessary to obtain good results.
//
// =================================================================================================
#include <string>
#include <vector>
#include <stdexcept>
#include "internal/utilities.h"
#include "internal/tuning.h"
namespace clblast {
// =================================================================================================
// The Xgemm auto-tuner
template <typename T>
void XgemmTune(const Arguments<T> &args,
const std::vector<T> &a_mat, const std::vector<T> &b_mat, std::vector<T> &c_mat,
cltune::Tuner &tuner) {
// This points to the Xgemm kernel as found in the CLBlast library and its golden reference
std::string sources =
#include "../src/kernels/common.opencl"
#include "../src/kernels/xgemm.opencl"
;
auto id = tuner.AddKernelFromString(sources, "Xgemm", {args.m, args.n}, {1, 1});
tuner.SetReferenceFromString(sources, "Xgemm", {args.m, args.n}, {8, 8});
// Sets the tunable parameters and their possible values
tuner.AddParameter(id, "MWG", {16, 32, 64, 128});
tuner.AddParameter(id, "NWG", {16, 32, 64, 128});
tuner.AddParameter(id, "KWG", {16, 32});
tuner.AddParameter(id, "MDIMC", {8, 16, 32});
tuner.AddParameter(id, "NDIMC", {8, 16, 32});
tuner.AddParameter(id, "MDIMA", {8, 16, 32});
tuner.AddParameter(id, "NDIMB", {8, 16, 32});
tuner.AddParameter(id, "KWI", {2, 8});
tuner.AddParameter(id, "VWM", {1, 2, 4, 8});
tuner.AddParameter(id, "VWN", {1, 2, 4, 8});
tuner.AddParameter(id, "STRM", {0, 1});
tuner.AddParameter(id, "STRN", {0, 1});
tuner.AddParameter(id, "SA", {0, 1});
tuner.AddParameter(id, "SB", {0, 1});
// Tests for a specific precision
tuner.AddParameter(id, "PRECISION", {static_cast<size_t>(args.precision)});
tuner.AddParameterReference("PRECISION", static_cast<size_t>(args.precision));
// Sets the helper functions to implement the constraints below
auto MultipleOfX = [] (std::vector<size_t> v) { return IsMultiple(v[0], v[1]); };
auto MultipleOfXMulY = [] (std::vector<size_t> v) { return IsMultiple(v[0], v[1]*v[2]); };
auto MultipleOfXMulYDivZ = [] (std::vector<size_t> v) { return IsMultiple(v[0], (v[1]*v[2])/v[3]); };
// Sets constraints: Requirement for unrolling the KWG loop
tuner.AddConstraint(id, MultipleOfX, {"KWG", "KWI"});
// Sets constraints: Required for integer MWI and NWI
tuner.AddConstraint(id, MultipleOfXMulY, {"MWG", "MDIMC", "VWM"});
tuner.AddConstraint(id, MultipleOfXMulY, {"NWG", "NDIMC", "VWN"});
// Sets constraints: Required for integer MWIA and NWIB
tuner.AddConstraint(id, MultipleOfXMulY, {"MWG", "MDIMA", "VWM"});
tuner.AddConstraint(id, MultipleOfXMulY, {"NWG", "NDIMB", "VWN"});
// Sets constraints: KWG has to be a multiple of KDIMA = ((MDIMC*NDIMC)/(MDIMA)) and KDIMB = (...)
tuner.AddConstraint(id, MultipleOfXMulYDivZ, {"KWG", "MDIMC", "NDIMC", "MDIMA"});
tuner.AddConstraint(id, MultipleOfXMulYDivZ, {"KWG", "MDIMC", "NDIMC", "NDIMB"});
// Sets the constraints for local memory size limitations
auto LocalMemorySize = [args] (std::vector<size_t> v) {
return (((v[0]*v[1]*v[2]/v[3]) + (v[4]*v[5]*v[6]/v[7]))*GetBytes(args.precision));
};
tuner.SetLocalMemoryUsage(id, LocalMemorySize, {"SA", "KWG", "MWG", "VWM",
"SB", "KWG", "NWG", "VWN"});
// Modifies the thread-sizes (both global and local) based on the parameters
tuner.MulLocalSize(id, {"MDIMC", "NDIMC"});
tuner.MulGlobalSize(id, {"MDIMC", "NDIMC"});
tuner.DivGlobalSize(id, {"MWG", "NWG"});
// Sets the function's arguments
tuner.AddArgumentScalar(static_cast<int>(args.m));
tuner.AddArgumentScalar(static_cast<int>(args.n));
tuner.AddArgumentScalar(static_cast<int>(args.k));
tuner.AddArgumentScalar(args.alpha);
tuner.AddArgumentScalar(args.beta);
tuner.AddArgumentInput(a_mat);
tuner.AddArgumentInput(b_mat);
tuner.AddArgumentOutput(c_mat);
}
// =================================================================================================
// Main function which calls the common client code with the routine-specific function as argument.
void TunerXgemm(int argc, char *argv[]) {
switch(GetPrecision(argc, argv)) {
case Precision::kHalf: throw std::runtime_error("Unsupported precision mode");
case Precision::kSingle: TunerABC<float>(argc, argv, XgemmTune<float>); break;
case Precision::kDouble: TunerABC<double>(argc, argv, XgemmTune<double>); break;
case Precision::kComplexSingle: TunerABC<float2>(argc, argv, XgemmTune<float2>); break;
case Precision::kComplexDouble: TunerABC<double2>(argc, argv, XgemmTune<double2>); break;
}
}
// =================================================================================================
} // namespace clblast
// Main function (not within the clblast namespace)
int main(int argc, char *argv[]) {
clblast::TunerXgemm(argc, argv);
return 0;
}
// =================================================================================================
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