diff options
Diffstat (limited to 'src')
-rw-r--r-- | src/clblast.cc | 59 | ||||
-rw-r--r-- | src/routines/xher2k.cc | 178 |
2 files changed, 232 insertions, 5 deletions
diff --git a/src/clblast.cc b/src/clblast.cc index 638bc944..00a90707 100644 --- a/src/clblast.cc +++ b/src/clblast.cc @@ -29,6 +29,7 @@ #include "internal/routines/xsyrk.h" #include "internal/routines/xherk.h" #include "internal/routines/xsyr2k.h" +#include "internal/routines/xher2k.h" #include "internal/routines/xtrmm.h" namespace clblast { @@ -350,11 +351,11 @@ template StatusCode Herk<double>(const Layout, const Triangle, const Transpose, // SYR2K template <typename T> StatusCode Syr2k(const Layout layout, const Triangle triangle, const Transpose ab_transpose, - const size_t n, const size_t k, const T alpha, - const cl_mem a_buffer, const size_t a_offset, const size_t a_ld, - const cl_mem b_buffer, const size_t b_offset, const size_t b_ld, const T beta, - cl_mem c_buffer, const size_t c_offset, const size_t c_ld, - cl_command_queue* queue, cl_event* event) { + const size_t n, const size_t k, const T alpha, + const cl_mem a_buffer, const size_t a_offset, const size_t a_ld, + const cl_mem b_buffer, const size_t b_offset, const size_t b_ld, const T beta, + cl_mem c_buffer, const size_t c_offset, const size_t c_ld, + cl_command_queue* queue, cl_event* event) { auto queue_cpp = CommandQueue(*queue); auto event_cpp = Event(*event); auto routine = Xsyr2k<T>(queue_cpp, event_cpp); @@ -407,6 +408,54 @@ template StatusCode Syr2k<double2>(const Layout, const Triangle, const Transpose // ================================================================================================= +// SYR2K +template <typename T, typename U> +StatusCode Her2k(const Layout layout, const Triangle triangle, const Transpose ab_transpose, + const size_t n, const size_t k, const T alpha, + const cl_mem a_buffer, const size_t a_offset, const size_t a_ld, + const cl_mem b_buffer, const size_t b_offset, const size_t b_ld, const U beta, + cl_mem c_buffer, const size_t c_offset, const size_t c_ld, + cl_command_queue* queue, cl_event* event) { + auto queue_cpp = CommandQueue(*queue); + auto event_cpp = Event(*event); + auto routine = Xher2k<T,U>(queue_cpp, event_cpp); + + // Loads the kernel source-code as an include (C++11 raw string literal) + std::string common_source1 = + #include "kernels/copy.opencl" + std::string common_source2 = + #include "kernels/pad.opencl" + std::string common_source3 = + #include "kernels/transpose.opencl" + std::string common_source4 = + #include "kernels/padtranspose.opencl" + std::string kernel_source = + #include "kernels/xgemm.opencl" + auto status = routine.SetUp(common_source1 + common_source2 + common_source3 + common_source4 + + kernel_source); + if (status != StatusCode::kSuccess) { return status; } + + // Runs the routine + return routine.DoHer2k(layout, triangle, ab_transpose, n, k, alpha, + Buffer(a_buffer), a_offset, a_ld, + Buffer(b_buffer), b_offset, b_ld, beta, + Buffer(c_buffer), c_offset, c_ld); +} +template StatusCode Her2k<float2,float>(const Layout, const Triangle, const Transpose, + const size_t, const size_t, const float2, + const cl_mem, const size_t, const size_t, + const cl_mem, const size_t, const size_t, const float, + cl_mem, const size_t, const size_t, + cl_command_queue*, cl_event*); +template StatusCode Her2k<double2,double>(const Layout, const Triangle, const Transpose, + const size_t, const size_t, const double2, + const cl_mem, const size_t, const size_t, + const cl_mem, const size_t, const size_t, const double, + cl_mem, const size_t, const size_t, + cl_command_queue*, cl_event*); + +// ================================================================================================= + // TRMM template <typename T> StatusCode Trmm(const Layout layout, const Side side, const Triangle triangle, diff --git a/src/routines/xher2k.cc b/src/routines/xher2k.cc new file mode 100644 index 00000000..b19b743b --- /dev/null +++ b/src/routines/xher2k.cc @@ -0,0 +1,178 @@ + +// ================================================================================================= +// 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 the Xher2k class (see the header for information about the class). +// +// ================================================================================================= + +#include "internal/routines/xher2k.h" + +#include <string> +#include <vector> + +namespace clblast { +// ================================================================================================= + +// Specific implementations to get the memory-type based on a template argument +template <> const Precision Xher2k<float2,float>::precision_ = Precision::kComplexSingle; +template <> const Precision Xher2k<double2,double>::precision_ = Precision::kComplexDouble; + +// ================================================================================================= + +// Constructor: forwards to base class constructor +template <typename T, typename U> +Xher2k<T,U>::Xher2k(CommandQueue &queue, Event &event): + Routine(queue, event, {"Copy", "Pad", "Transpose", "PadTranspose", "Xgemm"}, precision_) { +} + +// ================================================================================================= + +// The main routine +template <typename T, typename U> +StatusCode Xher2k<T,U>::DoHer2k(const Layout layout, const Triangle triangle, const Transpose ab_transpose, + const size_t n, const size_t k, + const T alpha, + const Buffer &a_buffer, const size_t a_offset, const size_t a_ld, + const Buffer &b_buffer, const size_t b_offset, const size_t b_ld, + const U beta, + const Buffer &c_buffer, const size_t c_offset, const size_t c_ld) { + + // Makes sure all dimensions are larger than zero + if ((n == 0) || (k == 0) ) { return StatusCode::kInvalidDimension; } + + // Determines whether to apply the conjugate transpose to matrix B (argument: no transpose) or + // to matrix A (argument: conjugate transpose) + auto ab_conjugate = (ab_transpose != Transpose::kNo); + + // Computes whether or not the matrices are transposed in memory. This is based on their layout + // (row or column-major) and whether or not they are requested to be pre-transposed. + auto ab_rotated = (layout == Layout::kColMajor && ab_conjugate) || + (layout == Layout::kRowMajor && !ab_conjugate); + auto c_rotated = (layout == Layout::kRowMajor); + + // Computes the first and second dimensions of the A and B matrices taking the layout into account + auto ab_one = (ab_rotated) ? k : n; + auto ab_two = (ab_rotated) ? n : k; + + // Tests the matrices (A, B, C) for validity, first from a perspective of the OpenCL buffers and + // their sizes, and then from a perspective of parameter values (e.g. n, k). Tests whether the + // OpenCL buffers are valid and non-zero and whether the OpenCL buffers have sufficient storage + // space. Also tests that the leading dimensions of: + // matrix A cannot be less than N when rotated, or less than K when not-rotated + // matrix B cannot be less than N when rotated, or less than K when not-rotated + // matrix C cannot be less than N + auto status = TestMatrixA(ab_one, ab_two, a_buffer, a_offset, a_ld, sizeof(T)); + if (ErrorIn(status)) { return status; } + status = TestMatrixB(ab_one, ab_two, b_buffer, b_offset, b_ld, sizeof(T)); + if (ErrorIn(status)) { return status; } + status = TestMatrixC(n, n, c_buffer, c_offset, c_ld, sizeof(T)); + if (ErrorIn(status)) { return status; } + + // Calculates the ceiled versions of n and k + auto n_ceiled = Ceil(n, db_["NWG"]); + auto k_ceiled = Ceil(k, db_["KWG"]); + + // Decides which kernel to run: the upper-triangular or lower-triangular version + auto kernel_name = (triangle == Triangle::kUpper) ? "XgemmUpper" : "XgemmLower"; + + // Allocates space on the device for padded and/or transposed input and output matrices. + try { + auto temp_a1 = Buffer(context_, CL_MEM_READ_WRITE, k_ceiled*n_ceiled*sizeof(T)); + auto temp_b1 = Buffer(context_, CL_MEM_READ_WRITE, k_ceiled*n_ceiled*sizeof(T)); + auto temp_a2 = Buffer(context_, CL_MEM_READ_WRITE, k_ceiled*n_ceiled*sizeof(T)); + auto temp_b2 = Buffer(context_, CL_MEM_READ_WRITE, k_ceiled*n_ceiled*sizeof(T)); + auto temp_c = Buffer(context_, CL_MEM_READ_WRITE, n_ceiled*n_ceiled*sizeof(T)); + + // Loads the program from the database + auto& program = GetProgramFromCache(); + + // Runs the pre-processing kernels. This transposes the matrices A and B, but also pads zeros to + // fill them up until they reach a certain multiple of size (kernel parameter dependent). + status = PadCopyTransposeMatrix(ab_one, ab_two, a_ld, a_offset, a_buffer, + n_ceiled, k_ceiled, n_ceiled, 0, temp_a1, + ab_rotated, ab_conjugate, true, false, false, false, program); + if (ErrorIn(status)) { return status; } + status = PadCopyTransposeMatrix(ab_one, ab_two, a_ld, a_offset, a_buffer, + n_ceiled, k_ceiled, n_ceiled, 0, temp_a2, + ab_rotated, !ab_conjugate, true, false, false, false, program); + if (ErrorIn(status)) { return status; } + status = PadCopyTransposeMatrix(ab_one, ab_two, b_ld, b_offset, b_buffer, + n_ceiled, k_ceiled, n_ceiled, 0, temp_b1, + ab_rotated, ab_conjugate, true, false, false, false, program); + status = PadCopyTransposeMatrix(ab_one, ab_two, b_ld, b_offset, b_buffer, + n_ceiled, k_ceiled, n_ceiled, 0, temp_b2, + ab_rotated, !ab_conjugate, true, false, false, false, program); + if (ErrorIn(status)) { return status; } + + // Furthermore, also creates a (possibly padded) copy of matrix C, since it is not allowed to + // modify the other triangle. + status = PadCopyTransposeMatrix(n, n, c_ld, c_offset, c_buffer, + n_ceiled, n_ceiled, n_ceiled, 0, temp_c, + c_rotated, false, true, false, false, false, program); + if (ErrorIn(status)) { return status; } + + // Retrieves the XgemmUpper or XgemmLower kernel from the compiled binary + try { + auto kernel = Kernel(program, kernel_name); + + // Sets the kernel arguments + auto complex_beta = T{beta, static_cast<U>(0.0)}; + kernel.SetArgument(0, static_cast<int>(n_ceiled)); + kernel.SetArgument(1, static_cast<int>(k_ceiled)); + kernel.SetArgument(2, alpha); + kernel.SetArgument(3, complex_beta); + kernel.SetArgument(4, temp_a1()); + kernel.SetArgument(5, temp_b2()); + kernel.SetArgument(6, temp_c()); + + // Computes the global and local thread sizes + auto global = std::vector<size_t>{ + (n_ceiled * db_["MDIMC"]) / db_["MWG"], + (n_ceiled * db_["NDIMC"]) / db_["NWG"] + }; + auto local = std::vector<size_t>{db_["MDIMC"], db_["NDIMC"]}; + + // Launches the kernel + status = RunKernel(kernel, global, local); + if (ErrorIn(status)) { return status; } + + // Swaps the arguments for matrices A and B, sets 'beta' to 1, and conjugate alpha + auto conjugate_alpha = T{alpha.real(), -alpha.imag()}; + auto complex_one = T{static_cast<U>(1.0), static_cast<U>(0.0)}; + kernel.SetArgument(2, conjugate_alpha); + kernel.SetArgument(3, complex_one); + kernel.SetArgument(4, temp_b1()); + kernel.SetArgument(5, temp_a2()); + + // Runs the kernel again + status = RunKernel(kernel, global, local); + if (ErrorIn(status)) { return status; } + + // Runs the post-processing kernel + auto upper = (triangle == Triangle::kUpper); + auto lower = (triangle == Triangle::kLower); + status = PadCopyTransposeMatrix(n_ceiled, n_ceiled, n_ceiled, 0, temp_c, + n, n, c_ld, c_offset, c_buffer, + c_rotated, false, false, upper, lower, true, program); + if (ErrorIn(status)) { return status; } + + // Successfully finished the computation + return StatusCode::kSuccess; + } catch (...) { return StatusCode::kInvalidKernel; } + } catch (...) { return StatusCode::kTempBufferAllocFailure; } +} + +// ================================================================================================= + +// Compiles the templated class +template class Xher2k<float2,float>; +template class Xher2k<double2,double>; + +// ================================================================================================= +} // namespace clblast |