mlir/test/Integration/Dialect/SparseTensor/CPU/sparse_block3d.mlir - llvm-project - Git at Google

 //--------------------------------------------------------------------------------------------------
 // WHEN CREATING A NEW TEST, PLEASE JUST COPY & PASTE WITHOUT EDITS.
 //
 // Set-up that's shared across all tests in this directory. In principle, this
 // config could be moved to lit.local.cfg. However, there are downstream users that
 //  do not use these LIT config files. Hence why this is kept inline.
 //
 // DEFINE: %{sparsifier_opts} = enable-runtime-library=true
 // DEFINE: %{sparsifier_opts_sve} = enable-arm-sve=true %{sparsifier_opts}
 // DEFINE: %{compile} = mlir-opt %s --sparsifier="%{sparsifier_opts}"
 // DEFINE: %{compile_sve} = mlir-opt %s --sparsifier="%{sparsifier_opts_sve}"
 // DEFINE: %{run_libs} = -shared-libs=%mlir_c_runner_utils,%mlir_runner_utils
 // DEFINE: %{run_libs_sve} = -shared-libs=%native_mlir_runner_utils,%native_mlir_c_runner_utils
 // DEFINE: %{run_opts} = -e main -entry-point-result=void
 // DEFINE: %{run} = mlir-runner %{run_opts} %{run_libs}
 // DEFINE: %{run_sve} = %mcr_aarch64_cmd --march=aarch64 --mattr="+sve" %{run_opts} %{run_libs_sve}
 //
 // DEFINE: %{env} =
 //--------------------------------------------------------------------------------------------------

 // RUN: %{compile} | %{run} | FileCheck %s
 //
 // Do the same run, but now with direct IR generation.
 // REDEFINE: %{sparsifier_opts} = enable-runtime-library=false enable-buffer-initialization=true
 // RUN: %{compile} | %{run} | FileCheck %s
 //
 // Do the same run, but now with direct IR generation and vectorization.
 // REDEFINE: %{sparsifier_opts} = enable-runtime-library=false enable-buffer-initialization=true vl=2 reassociate-fp-reductions=true enable-index-optimizations=true
 // RUN: %{compile} | %{run} | FileCheck %s
 //
 // Do the same run, but now with direct IR generation and VLA vectorization.
 // RUN: %if mlir_arm_sve_tests %{ %{compile_sve} | %{run_sve} | FileCheck %s %}

 // Test that test-bufferization-analysis-only works. This option is useful
 // for understanding why buffer copies were inserted.
 // RUN: mlir-opt %s --sparsifier="test-bufferization-analysis-only" -o /dev/null

 #Sparse1 = #sparse_tensor.encoding<{
   map = (i, j, k) -> (
     j : compressed,
     k : compressed,
     i : dense
   )
 }>

 #Sparse2 = #sparse_tensor.encoding<{
   map = (i, j, k) -> (
     i floordiv 2 : compressed,
     j floordiv 2 : compressed,
     k floordiv 2 : compressed,
     i mod 2 : dense,
     j mod 2 : dense,
     k mod 2 : dense)
 }>

 module {

   //
   // Main driver that tests sparse tensor storage.
   //
   func.func @main() {
     %c0 = arith.constant 0 : index
     %i0 = arith.constant 0 : i32

     // Setup input dense tensor and convert to two sparse tensors.
     %d = arith.constant dense <[
        [ // i=0
          [ 1, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 5, 0 ] ],
        [ // i=1
          [ 2, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 6, 0 ] ],
        [ //i=2
          [ 3, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 7, 0 ] ],
 	 //i=3
        [ [ 4, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 0, 0 ],
          [ 0, 0, 8, 0 ] ]
     ]> : tensor<4x4x4xi32>

     %a = sparse_tensor.convert %d : tensor<4x4x4xi32> to tensor<4x4x4xi32, #Sparse1>
     %b = sparse_tensor.convert %d : tensor<4x4x4xi32> to tensor<4x4x4xi32, #Sparse2>

     //
     // If we store the two "fibers" [1,2,3,4] starting at index (0,0,0) and
     // ending at index (3,0,0) and [5,6,7,8] starting at index (0,3,2) and
     // ending at index (3,3,2)) with a “DCSR-flavored” along (j,k) with
     // dense “fibers” in the i-dim, we end up with 8 stored entries.
     //
     // CHECK:      ---- Sparse Tensor ----
     // CHECK-NEXT: nse = 8
     // CHECK-NEXT: dim = ( 4, 4, 4 )
     // CHECK-NEXT: lvl = ( 4, 4, 4 )
     // CHECK-NEXT: pos[0] : ( 0, 2 )
     // CHECK-NEXT: crd[0] : ( 0, 3 )
     // CHECK-NEXT: pos[1] : ( 0, 1, 2 )
     // CHECK-NEXT: crd[1] : ( 0, 2 )
     // CHECK-NEXT: values : ( 1, 2, 3, 4, 5, 6, 7, 8 )
     // CHECK-NEXT: ----
     //
     sparse_tensor.print %a : tensor<4x4x4xi32, #Sparse1>

     //
     // If we store full 2x2x2 3-D blocks in the original index order
     // in a compressed fashion, we end up with 4 blocks to incorporate
     // all the nonzeros, and thus 32 stored entries.
     //
     // CHECK:      ---- Sparse Tensor ----
     // CHECK-NEXT: nse = 32
     // CHECK-NEXT: dim = ( 4, 4, 4 )
     // CHECK-NEXT: lvl = ( 2, 2, 2, 2, 2, 2 )
     // CHECK-NEXT: pos[0] : ( 0, 2 )
     // CHECK-NEXT: crd[0] : ( 0, 1 )
     // CHECK-NEXT: pos[1] : ( 0, 2, 4 )
     // CHECK-NEXT: crd[1] : ( 0, 1, 0, 1 )
     // CHECK-NEXT: pos[2] : ( 0, 1, 2, 3, 4 )
     // CHECK-NEXT: crd[2] : ( 0, 1, 0, 1 )
     // CHECK-NEXT: values : ( 1, 0, 0, 0, 2, 0, 0, 0, 0, 0, 5, 0, 0, 0, 6, 0, 3, 0, 0, 0, 4, 0, 0, 0, 0, 0, 7, 0, 0, 0, 8, 0 )
     // CHECK-NEXT: ----
     //
     sparse_tensor.print %b : tensor<4x4x4xi32, #Sparse2>

     // Release the resources.
     bufferization.dealloc_tensor %a : tensor<4x4x4xi32, #Sparse1>
     bufferization.dealloc_tensor %b : tensor<4x4x4xi32, #Sparse2>

     return
   }
 }
	//--------------------------------------------------------------------------------------------------
	// WHEN CREATING A NEW TEST, PLEASE JUST COPY & PASTE WITHOUT EDITS.
	//
	// Set-up that's shared across all tests in this directory. In principle, this
	// config could be moved to lit.local.cfg. However, there are downstream users that
	// do not use these LIT config files. Hence why this is kept inline.
	//
	// DEFINE: %{sparsifier_opts} = enable-runtime-library=true
	// DEFINE: %{sparsifier_opts_sve} = enable-arm-sve=true %{sparsifier_opts}
	// DEFINE: %{compile} = mlir-opt %s --sparsifier="%{sparsifier_opts}"
	// DEFINE: %{compile_sve} = mlir-opt %s --sparsifier="%{sparsifier_opts_sve}"
	// DEFINE: %{run_libs} = -shared-libs=%mlir_c_runner_utils,%mlir_runner_utils
	// DEFINE: %{run_libs_sve} = -shared-libs=%native_mlir_runner_utils,%native_mlir_c_runner_utils
	// DEFINE: %{run_opts} = -e main -entry-point-result=void
	// DEFINE: %{run} = mlir-runner %{run_opts} %{run_libs}
	// DEFINE: %{run_sve} = %mcr_aarch64_cmd --march=aarch64 --mattr="+sve" %{run_opts} %{run_libs_sve}
	//
	// DEFINE: %{env} =
	//--------------------------------------------------------------------------------------------------

	// RUN: %{compile} \| %{run} \| FileCheck %s
	//
	// Do the same run, but now with direct IR generation.
	// REDEFINE: %{sparsifier_opts} = enable-runtime-library=false enable-buffer-initialization=true
	// RUN: %{compile} \| %{run} \| FileCheck %s
	//
	// Do the same run, but now with direct IR generation and vectorization.
	// REDEFINE: %{sparsifier_opts} = enable-runtime-library=false enable-buffer-initialization=true vl=2 reassociate-fp-reductions=true enable-index-optimizations=true
	// RUN: %{compile} \| %{run} \| FileCheck %s
	//
	// Do the same run, but now with direct IR generation and VLA vectorization.
	// RUN: %if mlir_arm_sve_tests %{ %{compile_sve} \| %{run_sve} \| FileCheck %s %}

	// Test that test-bufferization-analysis-only works. This option is useful
	// for understanding why buffer copies were inserted.
	// RUN: mlir-opt %s --sparsifier="test-bufferization-analysis-only" -o /dev/null

	#Sparse1 = #sparse_tensor.encoding<{
	map = (i, j, k) -> (
	j : compressed,
	k : compressed,
	i : dense
	)
	}>

	#Sparse2 = #sparse_tensor.encoding<{
	map = (i, j, k) -> (
	i floordiv 2 : compressed,
	j floordiv 2 : compressed,
	k floordiv 2 : compressed,
	i mod 2 : dense,
	j mod 2 : dense,
	k mod 2 : dense)
	}>

	module {

	//
	// Main driver that tests sparse tensor storage.
	//
	func.func @main() {
	%c0 = arith.constant 0 : index
	%i0 = arith.constant 0 : i32

	// Setup input dense tensor and convert to two sparse tensors.
	%d = arith.constant dense <[
	[ // i=0
	[ 1, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 5, 0 ] ],
	[ // i=1
	[ 2, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 6, 0 ] ],
	[ //i=2
	[ 3, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 7, 0 ] ],
	//i=3
	[ [ 4, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 0, 0 ],
	[ 0, 0, 8, 0 ] ]
	]> : tensor<4x4x4xi32>

	%a = sparse_tensor.convert %d : tensor<4x4x4xi32> to tensor<4x4x4xi32, #Sparse1>
	%b = sparse_tensor.convert %d : tensor<4x4x4xi32> to tensor<4x4x4xi32, #Sparse2>

	//
	// If we store the two "fibers" [1,2,3,4] starting at index (0,0,0) and
	// ending at index (3,0,0) and [5,6,7,8] starting at index (0,3,2) and
	// ending at index (3,3,2)) with a “DCSR-flavored” along (j,k) with
	// dense “fibers” in the i-dim, we end up with 8 stored entries.
	//
	// CHECK: ---- Sparse Tensor ----
	// CHECK-NEXT: nse = 8
	// CHECK-NEXT: dim = ( 4, 4, 4 )
	// CHECK-NEXT: lvl = ( 4, 4, 4 )
	// CHECK-NEXT: pos[0] : ( 0, 2 )
	// CHECK-NEXT: crd[0] : ( 0, 3 )
	// CHECK-NEXT: pos[1] : ( 0, 1, 2 )
	// CHECK-NEXT: crd[1] : ( 0, 2 )
	// CHECK-NEXT: values : ( 1, 2, 3, 4, 5, 6, 7, 8 )
	// CHECK-NEXT: ----
	//
	sparse_tensor.print %a : tensor<4x4x4xi32, #Sparse1>

	//
	// If we store full 2x2x2 3-D blocks in the original index order
	// in a compressed fashion, we end up with 4 blocks to incorporate
	// all the nonzeros, and thus 32 stored entries.
	//
	// CHECK: ---- Sparse Tensor ----
	// CHECK-NEXT: nse = 32
	// CHECK-NEXT: dim = ( 4, 4, 4 )
	// CHECK-NEXT: lvl = ( 2, 2, 2, 2, 2, 2 )
	// CHECK-NEXT: pos[0] : ( 0, 2 )
	// CHECK-NEXT: crd[0] : ( 0, 1 )
	// CHECK-NEXT: pos[1] : ( 0, 2, 4 )
	// CHECK-NEXT: crd[1] : ( 0, 1, 0, 1 )
	// CHECK-NEXT: pos[2] : ( 0, 1, 2, 3, 4 )
	// CHECK-NEXT: crd[2] : ( 0, 1, 0, 1 )
	// CHECK-NEXT: values : ( 1, 0, 0, 0, 2, 0, 0, 0, 0, 0, 5, 0, 0, 0, 6, 0, 3, 0, 0, 0, 4, 0, 0, 0, 0, 0, 7, 0, 0, 0, 8, 0 )
	// CHECK-NEXT: ----
	//
	sparse_tensor.print %b : tensor<4x4x4xi32, #Sparse2>

	// Release the resources.
	bufferization.dealloc_tensor %a : tensor<4x4x4xi32, #Sparse1>
	bufferization.dealloc_tensor %b : tensor<4x4x4xi32, #Sparse2>

	return
	}
	}