diff options
Diffstat (limited to 'src/cpu/operators/CpuGemm.cpp')
-rw-r--r-- | src/cpu/operators/CpuGemm.cpp | 567 |
1 files changed, 567 insertions, 0 deletions
diff --git a/src/cpu/operators/CpuGemm.cpp b/src/cpu/operators/CpuGemm.cpp new file mode 100644 index 0000000000..905e86c185 --- /dev/null +++ b/src/cpu/operators/CpuGemm.cpp @@ -0,0 +1,567 @@ +/* + * Copyright (c) 2021-2024 Arm Limited. + * + * SPDX-License-Identifier: MIT + * + * Permission is hereby granted, free of charge, to any person obtaining a copy + * of this software and associated documentation files (the "Software"), to + * deal in the Software without restriction, including without limitation the + * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or + * sell copies of the Software, and to permit persons to whom the Software is + * furnished to do so, subject to the following conditions: + * + * The above copyright notice and this permission notice shall be included in all + * copies or substantial portions of the Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE + * SOFTWARE. + */ +#include "src/cpu/operators/CpuGemm.h" + +#include "arm_compute/core/TensorInfo.h" +#include "arm_compute/core/utils/misc/ShapeCalculator.h" +#include "arm_compute/core/Validate.h" +#include "arm_compute/runtime/NEON/NEScheduler.h" + +#include "src/common/utils/Log.h" +#include "src/core/CPP/Validate.h" +#include "src/core/helpers/AutoConfiguration.h" +#include "src/core/helpers/MemoryHelpers.h" +#include "src/cpu/utils/CpuAuxTensorHandler.h" + +using namespace arm_compute::experimental; +using namespace arm_compute::misc::shape_calculator; + +namespace arm_compute +{ +namespace cpu +{ +namespace +{ +cpu::AsmGemmInfo init_assembly_metadata(const GEMMInfo &info) +{ + cpu::AsmGemmInfo asm_info; + asm_info.method = cpu::AsmConvMethod::Im2Col; + asm_info.reinterpret_input_as_3d = info.reinterpret_input_as_3d(); + asm_info.depth_output_gemm3d = info.depth_output_gemm3d(); + asm_info.activation_info = info.activation_info(); + asm_info.fast_mode = info.fast_math(); + asm_info.fixed_format = info.fixed_format(); + asm_info.weight_format = info.weight_format(); + asm_info.accumulate = info.accumulate(); + asm_info.transpose_b = + info.pretranspose_B(); // The "pretranspose_B" flag here is not the same as the pretranspose_B_array method. The flag here signals to pretranspose_B_array method if we want to perform additional transpose on B before the pretranspose_B_array method + + return asm_info; +} +} // namespace + +void CpuGemm::configure(const ITensorInfo *a, + const ITensorInfo *b, + const ITensorInfo *c, + ITensorInfo *d, + float alpha, + float beta, + const GEMMInfo &gemm_info) +{ + ARM_COMPUTE_ERROR_ON_NULLPTR(a, b, d); + ARM_COMPUTE_ERROR_THROW_ON(CpuGemm::validate(a, b, c, d, alpha, beta, gemm_info)); + ARM_COMPUTE_LOG_PARAMS(a, b, c, d, alpha, beta, gemm_info); + + const cpu::AsmGemmInfo asm_info = init_assembly_metadata(gemm_info); + const bool is_c_bias = beta == 1 && c != nullptr; + const bool run_optimised = + bool(cpu::CpuGemmAssemblyDispatch::validate(a, b, (is_c_bias) ? c : nullptr, d, asm_info)) && + (c == nullptr || beta == 0.f || beta == 1.f) && // Optimized GeMM doesn't support beta coefficient. + !(!b->are_values_constant() && + b->tensor_shape().z() > 1); // Disable batch matmul as optimized GeMM handles batching differently. + + // Check if we need to reshape the matrix B only on the first run + _is_prepared = false; + _reshape_b_only_on_first_run = b->are_values_constant(); + _run_vector_matrix_multiplication = a->dimension(1) < 2; + _run_alpha_scale = alpha != 1.f; + _run_bias_addition = is_c_bias; + _run_addition = beta != 0 && beta != 1 && c != nullptr; + _run_activation = + gemm_info.activation_info().enabled() && + (!run_optimised || + (run_optimised && !cpu::CpuGemmAssemblyDispatch::is_activation_supported(gemm_info.activation_info()))); + + if (run_optimised) + { + _run_interleave_transpose = false; + const ITensorInfo *c_to_use = is_c_bias ? c : nullptr; + _asm_glue = std::make_unique<cpu::CpuGemmAssemblyDispatch>(); + _asm_glue->configure(a, b, c_to_use, d, asm_info); + ARM_COMPUTE_ERROR_ON(!_asm_glue->is_configured()); + + const auto asm_mem_req = _asm_glue->workspace(); + for (unsigned int slot = 0; slot < asm_mem_req.size(); ++slot) + { + _aux_mem[slot] = asm_mem_req[slot]; + } + + // Scale product by alpha + if (_run_alpha_scale) + { + _alpha_scale_func = std::make_unique<cpu::CpuActivation>(); + _alpha_scale_func->configure( + d, nullptr, ActivationLayerInfo(ActivationLayerInfo::ActivationFunction::LINEAR, alpha, 0.f)); + } + } + else + { + _run_interleave_transpose = !_run_vector_matrix_multiplication; + // Pick output tensor in case bias addition should be performed + ITensorInfo *gemm_output_to_use = (_run_bias_addition) ? &_tmp_d : d; + // Pick b tensor in case pretranspose should be performed + const ITensorInfo *b_to_use = b; + + _mm_kernel = std::make_unique<cpu::kernels::CpuGemmMatrixMultiplyKernel>(); + + // Configure rhs pretranspose + if (gemm_info.pretranspose_B()) + { + _pretranspose_b_func = std::make_unique<CpuTranspose>(); + _pretranspose_b_func->configure(b_to_use, &_pretransposed_b); + MemoryLifetime lifetime; + if (_reshape_b_only_on_first_run) + { + if (_run_interleave_transpose) + { + // PreTransposedRHS tensor is only used in prepare(), but is then succeeded by Transposed1xWRHS + // So PreTransposedRHS can be freed inside prepare() + lifetime = MemoryLifetime::Prepare; + } + else + { + // PreTransposedRHS tensor is only used in prepare(), but is the final transformation of rhs + // So PreTransposedRHS needs to persist beyond prepare() + lifetime = MemoryLifetime::Persistent; + } + } + else + { + // PreTransposedRHS tensor is always used in run() and doesn't need to persist + lifetime = MemoryLifetime::Temporary; + } + _aux_mem[PreTransposedRHS] = + MemoryInfo(offset_int_vec(PreTransposedRHS), lifetime, _pretransposed_b.total_size()); + b_to_use = &_pretransposed_b; + } + + // Select between GEMV and GEMM + if (_run_vector_matrix_multiplication) + { + // Configure the matrix multiply kernel + _mm_kernel->configure(a, b_to_use, gemm_output_to_use, alpha, false); + } + else + { + ARM_COMPUTE_ERROR_ON(!_run_interleave_transpose); + // Configure interleave kernel + _interleave_kernel = std::make_unique<cpu::kernels::CpuGemmInterleave4x4Kernel>(); + _interleave_kernel->configure(a, &_tmp_a); + _aux_mem[InterleavedLHS] = + MemoryInfo(offset_int_vec(InterleavedLHS), MemoryLifetime::Temporary, _tmp_a.total_size()); + + // Configure rhs transpose1xw kernel + _transpose1xW_b_kernel = std::make_unique<cpu::kernels::CpuGemmTranspose1xWKernel>(); + _transpose1xW_b_kernel->configure(b_to_use, &_tmp_b); + _aux_mem[Transposed1xWRHS] = + MemoryInfo(offset_int_vec(Transposed1xWRHS), MemoryLifetime::Persistent, _tmp_b.total_size()); + + // Use a and b here instead of _tmp_a and _tmp_b because CpuGemmMatrixMultiplyKernel requires the original m,n,k in case of interleaved a and transposed1xw b + const int m = a->dimension(1); + const int n = b_to_use->dimension(0); + const int k = a->dimension(0); + + // Configure matrix multiplication kernel + _mm_kernel->configure(&_tmp_a, &_tmp_b, gemm_output_to_use, alpha, _run_interleave_transpose, + GEMMReshapeInfo(m, n, k)); + } + + if (_run_bias_addition) + { + _add_bias = std::make_unique<cpu::CpuAdd>(); + _add_bias->configure(gemm_output_to_use, c, d, ConvertPolicy::SATURATE); + _aux_mem[TempResult] = + MemoryInfo(offset_int_vec(TempResult), MemoryLifetime::Temporary, _tmp_d.total_size()); + } + } + + // Configure matrix addition kernel + if (_run_addition) + { + _ma_kernel = std::make_unique<cpu::kernels::CpuGemmMatrixAdditionKernel>(); + _ma_kernel->configure(c, d, beta); + } + + // Configure activation + if (_run_activation) + { + _activation_func = std::make_unique<cpu::CpuActivation>(); + _activation_func->configure(d, nullptr, gemm_info.activation_info()); + } +} + +Status CpuGemm::validate(const ITensorInfo *a, + const ITensorInfo *b, + const ITensorInfo *c, + const ITensorInfo *d, + float alpha, + float beta, + const GEMMInfo &gemm_info) +{ + ARM_COMPUTE_UNUSED(alpha); + // When using accumulation(in place summation), for now, the only supported values for alpha and beta are 1 respectively 0. + // Do the appropriate checks before proceeding. + if (gemm_info.accumulate()) + { + ARM_COMPUTE_RETURN_ERROR_ON_MSG(alpha != 1, "Accumulation is not supported when alpha is different from 1"); + ARM_COMPUTE_RETURN_ERROR_ON_MSG( + (beta != 0 && c != nullptr), + "Accumulation is not supported when beta is different from 0 with a non-null bias matrix c"); + } + + const bool is_c_bias = beta == 1 && c != nullptr; + const bool run_addition = c != nullptr && beta != 0 && beta != 1; + // Check if we should use the pretransposed_b or original b + // TODO: COMPMID-6597 + // Note that this check should only apply to the non-optimized path. The reason we brought this at the beginning + // instead of only for the fallback path is because of the checks performed below, between here and the run_optimised decision + // We should simplify this by + // 1. Moving the checks between "fix-start" and "fix-end" into their corresponding ops / kernels (e.g. the weights format checks can and should be moved into CpuGemmAssemblyDispatch) + // 2. Moving this b_to_use check back into the non-optimized path + TensorInfo pretransposed_b = b->clone()->set_tensor_shape(misc::shape_calculator::compute_transposed_shape(*b)); + const ITensorInfo *b_to_use = gemm_info.pretranspose_B() ? &pretransposed_b : b; + // TODO: COMPMID-6597 fix-start + + ARM_COMPUTE_RETURN_ERROR_ON_CPU_F16_UNSUPPORTED(a); + ARM_COMPUTE_RETURN_ERROR_ON_CPU_BF16_UNSUPPORTED(a); + ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_CHANNEL_NOT_IN(a, 1, DataType::BFLOAT16, DataType::F16, DataType::F32); + + if (is_fixed_format_fast_math(gemm_info.weight_format())) + { + ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_NOT_IN(a, DataType::F32); + ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_NOT_IN(b_to_use, DataType::BFLOAT16); + } + else + { + ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(a, b_to_use); + } + + const int block_by = arm_compute::block_by(gemm_info.weight_format()); + // test if im2col has changed the dimensions that are needed for padding + if (a->dimension(0) != b_to_use->dimension(1) && block_by > 1) + { + // have to verify bias + const size_t dim0_sz = a->dimension(0); + ARM_COMPUTE_RETURN_ERROR_ON_MSG( + (dim0_sz % block_by) != 0, + ("The matrix A number of columns must be a multiple of block_by=" + std::to_string(block_by)).c_str()); + // a->dimension(0) = kernel_area * input_channel + kernel_area * input_pad_right + // b_to_use->dimension(1) = kernel_area * input_channel + // a->dimension(0) = b_to_use->dimension(1) + kernel_area * input_pad_right + const size_t input_pad_right = (dim0_sz - b_to_use->dimension(1)) % block_by; + const size_t kernel_area = (dim0_sz - b_to_use->dimension(1)) / input_pad_right; + ARM_COMPUTE_RETURN_ERROR_ON_MSG( + (dim0_sz - kernel_area * input_pad_right) != b_to_use->dimension(1), + "The product AB is defined only if A number of columns and B number of rows are related"); + } + else + { + ARM_COMPUTE_RETURN_ERROR_ON_MSG( + a->dimension(0) != b_to_use->dimension(1), + "The product AB is defined only if the number of columns in A is equal to the number of rows in B"); + } + + ARM_COMPUTE_RETURN_ERROR_ON_MSG(gemm_info.is_a_reshaped(), "Matrix A already reshaped is not supported"); + ARM_COMPUTE_RETURN_ERROR_ON_MSG(gemm_info.is_b_reshaped(), "Matrix B already reshaped is not supported"); + if (a->data_type() != DataType::BFLOAT16) + { + ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(a, d); + } + + if (run_addition) + { + ARM_COMPUTE_RETURN_ERROR_ON(gemm_info.depth_output_gemm3d() != 0); + ARM_COMPUTE_RETURN_ERROR_ON(gemm_info.reinterpret_input_as_3d()); + ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(c, d); + ARM_COMPUTE_RETURN_ERROR_ON_MSG(a->dimension(1) != c->dimension(1), + "The C matrix must have the same number of rows as the matrix A"); + ARM_COMPUTE_RETURN_ERROR_ON_MSG(b_to_use->dimension(0) != c->dimension(0), + "The C matrix must have the same number of columns as the matrix B"); + } + + if (d->total_size() != 0) + { + // For fixed format we are expecting some kind of blocked format for B/RHS so the dimension won't necessarily match the result matrix any more. + ARM_COMPUTE_RETURN_ERROR_ON(!gemm_info.fixed_format() && b_to_use->dimension(0) != d->dimension(0)); + if (gemm_info.depth_output_gemm3d() != 0) + { + if (gemm_info.reinterpret_input_as_3d()) + { + ARM_COMPUTE_RETURN_ERROR_ON(a->dimension(1) != d->dimension(1)); + ARM_COMPUTE_RETURN_ERROR_ON(a->dimension(2) != d->dimension(2)); + } + else + { + ARM_COMPUTE_RETURN_ERROR_ON(a->dimension(1) != d->dimension(1) * d->dimension(2)); + } + } + else + { + ARM_COMPUTE_RETURN_ERROR_ON(a->dimension(1) != d->dimension(1)); + } + } + // TODO: COMPMID-6597 fix-end + + // Check if we need to run the optimized assembly kernel + cpu::AsmGemmInfo asm_info = init_assembly_metadata(gemm_info); + + // Note we use b instead of b_to_use here because asm_info also captures the pretranspose_b() flag + // so we pass the original b to CpuGemmAssemblyDispatch + const bool run_optimised = + bool(cpu::CpuGemmAssemblyDispatch::validate(a, b, is_c_bias ? c : nullptr, d, asm_info)) && + (c == nullptr || beta == 0.f || beta == 1.f) && // Optimized GeMM doesn't support beta coefficient. + !(!b->are_values_constant() && + b->tensor_shape().z() > 1); // Disable batch matmul as optimized GeMM handles batching differently. + + if (!run_optimised) + { + ARM_COMPUTE_RETURN_ERROR_ON_MSG(gemm_info.reinterpret_input_as_3d(), + "CpuGemm cannot reinterpret the input tensor as 3D"); + ARM_COMPUTE_RETURN_ERROR_ON_MSG(gemm_info.depth_output_gemm3d() != 0, + "CpuGemm cannot reinterpret the output tensor as 3D"); + + // Check if the first input tensor is a vector. + const bool run_vector_matrix_multiplication = a->dimension(1) < 2; + // Check if we need to reshape the matrix A and matrix B + const bool run_interleave_transpose = !run_vector_matrix_multiplication; + + // Arguments used by GEMMReshapeInfo + // If we pass the matrix A and matrix B reshaped to CpuGemmMatrixMultiplyKernel, we need to pass m, n, k, mult_transpose1xW_width and mult_interleave4x4_height to GEMMReshapeInfo + // in order to know how the matrices have been reshaped + const int m = a->dimension(1); + const int n = b_to_use->dimension(0); + const int k = a->dimension(0); + int mult_transpose1xW_width = 1; + int mult_interleave4x4_height = 1; + + const GEMMReshapeInfo reshape_info = GEMMReshapeInfo( + m, n, k, mult_transpose1xW_width, mult_interleave4x4_height, gemm_info.depth_output_gemm3d()); + + const ITensorInfo *matrix_a_info = a; + const ITensorInfo *matrix_b_info = b_to_use; + + TensorInfo tmp_a_info{}; + TensorInfo tmp_b_info{}; + TensorInfo tmp_output_info = *d->clone(); + + if (run_interleave_transpose) + { + matrix_a_info = &tmp_a_info; + matrix_b_info = &tmp_b_info; + + // Validate interleave kernel + auto_init_if_empty(tmp_a_info, a->clone()->set_tensor_shape(compute_interleaved_shape( + *a, mult_interleave4x4_height, gemm_info.reinterpret_input_as_3d()))); + ARM_COMPUTE_RETURN_ON_ERROR(cpu::kernels::CpuGemmInterleave4x4Kernel::validate(a, &tmp_a_info)); + + // Validate transpose kernel + auto_init_if_empty(tmp_b_info, + b_to_use->clone()->set_tensor_shape( + compute_transpose1xW_with_element_size_shape(*b_to_use, mult_transpose1xW_width))); + ARM_COMPUTE_RETURN_ON_ERROR(cpu::kernels::CpuGemmTranspose1xWKernel::validate(b_to_use, &tmp_b_info)); + } + + // Validate matrix multiply + auto_init_if_empty(tmp_output_info, + matrix_a_info->clone()->set_tensor_shape(compute_mm_shape( + *matrix_a_info, *matrix_b_info, run_interleave_transpose, reshape_info))); + ARM_COMPUTE_RETURN_ON_ERROR(cpu::kernels::CpuGemmMatrixMultiplyKernel::validate( + matrix_a_info, matrix_b_info, &tmp_output_info, alpha, run_interleave_transpose, reshape_info)); + + if (is_c_bias) + { + ARM_COMPUTE_RETURN_ON_ERROR(cpu::CpuAdd::validate(&tmp_output_info, c, d, ConvertPolicy::SATURATE)); + } + } + + // Validate matrix addition kernel + if (run_addition) + { + ARM_COMPUTE_RETURN_ON_ERROR(cpu::kernels::CpuGemmMatrixAdditionKernel::validate(c, d, beta)); + } + + // Validate activation + const ActivationLayerInfo &activation = gemm_info.activation_info(); + if (activation.enabled()) + { + ARM_COMPUTE_RETURN_ON_ERROR(cpu::CpuActivation::validate(d, nullptr, activation)); + } + + return Status{}; +} + +void CpuGemm::run(ITensorPack &tensors) +{ + prepare(tensors); + + auto a = tensors.get_const_tensor(ACL_SRC_0); + auto b = tensors.get_const_tensor(ACL_SRC_1); + auto c = tensors.get_const_tensor(ACL_SRC_2); + auto d = tensors.get_tensor(ACL_DST); + + if (_asm_glue && _asm_glue->is_configured()) + { + // Pass c to asm dispatch only if it's the bias tensor + ITensorPack asm_pack = tensors; + asm_pack.add_const_tensor(ACL_SRC_2, _run_bias_addition ? c : nullptr); + _asm_glue->run(asm_pack); + if (_run_alpha_scale) + { + ITensorPack pack{{ACL_SRC, d}, {ACL_DST, d}}; + _alpha_scale_func->run(pack); + } + } + else + { + CpuAuxTensorHandler interleaved_a(offset_int_vec(InterleavedLHS), _tmp_a, tensors, true); + CpuAuxTensorHandler pretransposed_b(offset_int_vec(PreTransposedRHS), _pretransposed_b, tensors); + CpuAuxTensorHandler transposed1xw_b(offset_int_vec(Transposed1xWRHS), _tmp_b, tensors, true); + CpuAuxTensorHandler temp_d(offset_int_vec(TempResult), _tmp_d, tensors, true); + + ITensorPack mm_pack{{ACL_SRC_0, a}, {ACL_SRC_1, b}, {ACL_DST, (_run_bias_addition) ? temp_d.get() : d}}; + + if (_run_interleave_transpose) + { + // Run interleave kernel + ITensorPack interleave_pack{{ACL_SRC, a}, {ACL_DST, interleaved_a.get()}}; + NEScheduler::get().schedule_op(_interleave_kernel.get(), Window::DimY, _interleave_kernel->window(), + interleave_pack); + // Use reshaped matrices + mm_pack.add_const_tensor(ACL_SRC_0, interleaved_a.get()); + } + + const ITensor *b_to_use = b; + if (_pretranspose_b_func) + { + if (!_reshape_b_only_on_first_run) + { + // Run pretranspose kernel + ITensorPack pretranspose_pack{{ACL_SRC, b_to_use}, {ACL_DST, pretransposed_b.get()}}; + _pretranspose_b_func->run(pretranspose_pack); + } + b_to_use = pretransposed_b.get(); + } + if (_run_interleave_transpose) + { + if (!_reshape_b_only_on_first_run) + { + // Run transpose1xw kernel + ITensorPack transpose_pack{{ACL_SRC, b_to_use}, {ACL_DST, transposed1xw_b.get()}}; + NEScheduler::get().schedule_op(_transpose1xW_b_kernel.get(), Window::DimY, + _transpose1xW_b_kernel->window(), transpose_pack); + } + b_to_use = transposed1xw_b.get(); + } + // Use reshaped matrices + mm_pack.add_const_tensor(ACL_SRC_1, b_to_use); + + NEScheduler::get().schedule_op(_mm_kernel.get(), + _run_vector_matrix_multiplication ? Window::DimX : Window::DimY, + _mm_kernel->window(), mm_pack); + + // Run bias addition kernel + if (_run_bias_addition) + { + ITensorPack pack{{ACL_SRC_0, temp_d.get()}, {ACL_SRC_1, c}, {ACL_DST, d}}; + _add_bias->run(pack); + } + } + + // Run matrix addition kernel + if (_run_addition) + { + ITensorPack c_add_pack{{ACL_SRC, c}, {ACL_DST, d}}; + NEScheduler::get().schedule_op(_ma_kernel.get(), Window::DimY, _ma_kernel->window(), c_add_pack); + } + + // Run activation function + if (_run_activation) + { + ITensorPack pack{{ACL_SRC, d}, {ACL_DST, d}}; + _activation_func->run(pack); + } +} + +void CpuGemm::prepare(ITensorPack &tensors) +{ + if (!_is_prepared) + { + if (_asm_glue && _asm_glue->is_configured()) + { + _asm_glue->prepare(tensors); + } + else if (_reshape_b_only_on_first_run) + { + const ITensor *b = tensors.get_const_tensor(ACL_SRC_1); + const ITensor *b_to_use = b; + CpuAuxTensorHandler pretransposed_b( + offset_int_vec(PreTransposedRHS), _pretransposed_b, tensors, + false /*pack_inject: no need to inject into tensors*/, + _pretranspose_b_func == + nullptr /*bypass_alloc: no need to allocate if _pretranspose_b_func is not run*/); + CpuAuxTensorHandler transposed1xw_b(offset_int_vec(Transposed1xWRHS), _tmp_b, tensors, + false /*pack_inject*/, !_run_interleave_transpose /*bypass_alloc*/); + + if (_pretranspose_b_func) + { + // Run pretranspose kernel + ITensorPack pretranspose_pack{{ACL_SRC, b_to_use}, {ACL_DST, pretransposed_b.get()}}; + _pretranspose_b_func->run(pretranspose_pack); + b_to_use = pretransposed_b.get(); + } + if (_run_interleave_transpose) + { + // Run transpose kernel + ITensorPack transpose_pack{{ACL_SRC, b_to_use}, {ACL_DST, transposed1xw_b.get()}}; + NEScheduler::get().schedule_op(_transpose1xW_b_kernel.get(), Window::DimY, + _transpose1xW_b_kernel->window(), transpose_pack); + } + } + _is_prepared = true; + } +} + +experimental::MemoryRequirements CpuGemm::workspace() const +{ + return _aux_mem; +} + +Status CpuGemm::has_opt_impl(arm_compute::WeightFormat &expected_weight_format, + const ITensorInfo *a, + const ITensorInfo *b, + const ITensorInfo *c, + const ITensorInfo *d, + const GEMMInfo &gemm_info) +{ + const cpu::AsmGemmInfo asm_info = init_assembly_metadata(gemm_info); + + return CpuGemmAssemblyDispatch::has_opt_impl(expected_weight_format, a, b, c, d, asm_info); +} + +bool CpuGemm::isVarWeightsKernel() const +{ + return _asm_glue && _asm_glue->isVarWeightsKernel(); +} +} // namespace cpu +} // namespace arm_compute |