This patch adds the logic necessary to target the sparse-tensor dialect integration tests for SVE. As the LLVM backend for AArch64 does not currently support product reductions, the corresponding tests are disabled for SVE. Not all tests have been updated yet. The remaining tests will be refactored in a separate patch shortly. Differential Revision: https://reviews.llvm.org/D121304 Co-authored-by: Andrzej Warzynski <andrzej.warzynski@arm.com>
145 lines
5.2 KiB
MLIR
145 lines
5.2 KiB
MLIR
// DEFINE: %{option} = enable-runtime-library=true
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// DEFINE: %{compile} = mlir-opt %s --sparse-compiler=%{option}
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// DEFINE: %{run} = TENSOR0="%mlir_src_dir/test/Integration/data/mttkrp_b.tns" \
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// DEFINE: mlir-cpu-runner \
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// DEFINE: -e entry -entry-point-result=void \
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// DEFINE: -shared-libs=%mlir_lib_dir/libmlir_c_runner_utils%shlibext,%mlir_lib_dir/libmlir_runner_utils%shlibext | \
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// DEFINE: FileCheck %s
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//
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// RUN: %{compile} | %{run}
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//
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// Do the same run, but now with direct IR generation.
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// REDEFINE: %{option} = enable-runtime-library=false
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// RUN: %{compile} | %{run}
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//
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// Do the same run, but now with direct IR generation and vectorization.
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// REDEFINE: %{option} = "enable-runtime-library=false vl=2 reassociate-fp-reductions=true enable-index-optimizations=true"
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// RUN: %{compile} | %{run}
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// If SVE is available, do the same run, but now with direct IR generation and VLA
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// vectorization.
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// REDEFINE: %{option} = "enable-runtime-library=false vl=4 enable-arm-sve=%ENABLE_VLA"
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// REDEFINE: %{run} = TENSOR0="%mlir_src_dir/test/Integration/data/mttkrp_b.tns" \
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// REDEFINE: %lli \
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// REDEFINE: --entry-function=entry_lli \
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// REDEFINE: --extra-module=%S/Inputs/main_for_lli.ll \
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// REDEFINE: %VLA_ARCH_ATTR_OPTIONS \
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// REDEFINE: --dlopen=%mlir_native_utils_lib_dir/libmlir_c_runner_utils%shlibext -dlopen=%mlir_lib_dir/libmlir_runner_utils%shlibext| \
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// REDEFINE: FileCheck %s
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// RUN: %{compile} | mlir-translate -mlir-to-llvmir | %{run}
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!Filename = !llvm.ptr<i8>
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#SparseTensor = #sparse_tensor.encoding<{
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dimLevelType = [ "compressed", "compressed", "compressed" ]
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}>
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#mttkrp = {
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indexing_maps = [
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affine_map<(i,j,k,l) -> (i,k,l)>, // B
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affine_map<(i,j,k,l) -> (k,j)>, // C
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affine_map<(i,j,k,l) -> (l,j)>, // D
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affine_map<(i,j,k,l) -> (i,j)> // A (out)
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],
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iterator_types = ["parallel", "parallel", "reduction", "reduction"],
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doc = "A(i,j) += B(i,k,l) * D(l,j) * C(k,j)"
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}
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//
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// Integration test that lowers a kernel annotated as sparse to
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// actual sparse code, initializes a matching sparse storage scheme
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// from file, and runs the resulting code with the JIT compiler.
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//
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module {
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func.func private @printMemrefF64(%ptr : tensor<*xf64>)
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//
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// Computes Matricized Tensor Times Khatri-Rao Product (MTTKRP) kernel. See
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// http://tensor-compiler.org/docs/data_analytics/index.html.
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//
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func.func @kernel_mttkrp(%argb: tensor<?x?x?xf64, #SparseTensor>,
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%argc: tensor<?x?xf64>,
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%argd: tensor<?x?xf64>,
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%arga: tensor<?x?xf64>)
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-> tensor<?x?xf64> {
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%0 = linalg.generic #mttkrp
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ins(%argb, %argc, %argd:
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tensor<?x?x?xf64, #SparseTensor>, tensor<?x?xf64>, tensor<?x?xf64>)
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outs(%arga: tensor<?x?xf64>) {
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^bb(%b: f64, %c: f64, %d: f64, %a: f64):
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%0 = arith.mulf %b, %c : f64
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%1 = arith.mulf %d, %0 : f64
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%2 = arith.addf %a, %1 : f64
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linalg.yield %2 : f64
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} -> tensor<?x?xf64>
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return %0 : tensor<?x?xf64>
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}
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func.func private @getTensorFilename(index) -> (!Filename)
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//
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// Main driver that reads matrix from file and calls the sparse kernel.
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//
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func.func @entry() {
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%f0 = arith.constant 0.0 : f64
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%cst0 = arith.constant 0 : index
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%cst1 = arith.constant 1 : index
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%cst2 = arith.constant 2 : index
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// Read the sparse input tensor B from a file.
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%fileName = call @getTensorFilename(%cst0) : (index) -> (!Filename)
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%b = sparse_tensor.new %fileName
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: !Filename to tensor<?x?x?xf64, #SparseTensor>
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// Get sizes from B, pick a fixed size for dim-2 of A.
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%isz = tensor.dim %b, %cst0 : tensor<?x?x?xf64, #SparseTensor>
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%jsz = arith.constant 5 : index
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%ksz = tensor.dim %b, %cst1 : tensor<?x?x?xf64, #SparseTensor>
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%lsz = tensor.dim %b, %cst2 : tensor<?x?x?xf64, #SparseTensor>
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// Initialize dense input matrix C.
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%c = tensor.generate %ksz, %jsz {
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^bb0(%k : index, %j : index):
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%k0 = arith.muli %k, %jsz : index
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%k1 = arith.addi %k0, %j : index
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%k2 = arith.index_cast %k1 : index to i32
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%kf = arith.sitofp %k2 : i32 to f64
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tensor.yield %kf : f64
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} : tensor<?x?xf64>
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// Initialize dense input matrix D.
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%d = tensor.generate %lsz, %jsz {
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^bb0(%l : index, %j : index):
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%k0 = arith.muli %l, %jsz : index
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%k1 = arith.addi %k0, %j : index
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%k2 = arith.index_cast %k1 : index to i32
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%kf = arith.sitofp %k2 : i32 to f64
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tensor.yield %kf : f64
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} : tensor<?x?xf64>
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// Initialize dense output matrix A.
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%a = tensor.generate %isz, %jsz {
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^bb0(%i : index, %j: index):
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tensor.yield %f0 : f64
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} : tensor<?x?xf64>
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// Call kernel.
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%0 = call @kernel_mttkrp(%b, %c, %d, %a)
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: (tensor<?x?x?xf64, #SparseTensor>,
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tensor<?x?xf64>, tensor<?x?xf64>, tensor<?x?xf64>) -> tensor<?x?xf64>
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// Print the result for verification.
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//
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// CHECK: {{\[}}[16075, 21930, 28505, 35800, 43815],
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// CHECK-NEXT: [10000, 14225, 19180, 24865, 31280]]
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//
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%u = tensor.cast %0: tensor<?x?xf64> to tensor<*xf64>
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call @printMemrefF64(%u) : (tensor<*xf64>) -> ()
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// Release the resources.
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bufferization.dealloc_tensor %b : tensor<?x?x?xf64, #SparseTensor>
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return
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}
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}
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