mlir/test/Transforms/parametric-tiling.mlir - llvm-project - Git at Google

 // RUN: mlir-opt -test-extract-fixed-outer-loops='test-outer-loop-sizes=7' %s | FileCheck %s --check-prefixes=COMMON,TILE_7
 // RUN: mlir-opt -test-extract-fixed-outer-loops='test-outer-loop-sizes=7,4' %s | FileCheck %s --check-prefixes=COMMON,TILE_74

 // COMMON-LABEL: @rectangular
 func @rectangular(%arg0: memref<?x?xf32>) {
   %c2 = arith.constant 2 : index
   %c44 = arith.constant 44 : index
   %c1 = arith.constant 1 : index
   // Range of the original loop:
   //   (upper - lower + step - 1) / step
   // where step is known to be %c1.
   // COMMON:      %[[diff:.*]] = arith.subi %c44, %c2
   // COMMON:      %[[adjustment:.*]] = arith.subi %c1, %c1_{{.*}}
   // COMMON-NEXT: %[[diff_adj:.*]] = arith.addi %[[diff]], %[[adjustment]]
   // COMMON-NEXT: %[[range:.*]] = arith.divsi %[[diff_adj]], %c1

   // Ceildiv to get the parametric tile size.
   // COMMON:       %[[sum:.*]] = arith.addi %[[range]], %c6
   // COMMON-NEXT:  %[[size:.*]] = arith.divsi %[[sum]], %c7
   // New outer step (original is %c1).
   // COMMON-NEXT:      %[[step:.*]] = arith.muli %c1, %[[size]]

   // Range of the second original loop
   //   (upper - lower + step - 1) / step
   // where step is known to be %c2.
   // TILE_74:      %[[diff2:.*]] = arith.subi %c44, %c1
   // TILE_74:      %[[adjustment2:.*]] = arith.subi %c2, %c1_{{.*}}
   // TILE_74-NEXT: %[[diff2_adj:.*]] = arith.addi %[[diff2]], %[[adjustment2]]
   // TILE_74-NEXT: %[[range2:.*]] = arith.divsi %[[diff2_adj]], %c2

   // Ceildiv to get the parametric tile size for the second original scf.
   // TILE_74:      %[[sum2:.*]] = arith.addi %[[range2]], %c3
   // TILE_74-NEXT: %[[size2:.*]] = arith.divsi %[[sum2]], %c4
   // New inner step (original is %c2).
   // TILE_74-NEXT:     %[[step2:.*]] = arith.muli %c2, %[[size2]]

   // Updated outer loop(s) use new steps.
   // COMMON: scf.for %[[i:.*]] = %c2 to %c44 step %[[step]]
   // TILE_74:scf.for %[[j:.*]] = %c1 to %c44 step %[[step2]]
  scf.for %i = %c2 to %c44 step %c1 {
     // Upper bound for the inner loop min(%i + %step, %c44).
     // COMMON:      %[[stepped:.*]] = arith.addi %[[i]], %[[step]]
     // COMMON-NEXT: arith.cmpi slt, %c44, %[[stepped]]
     // COMMON-NEXT: %[[ub:.*]] = select {{.*}}, %c44, %[[stepped]]
     //
     // TILE_74:      %[[stepped2:.*]] = arith.addi %[[j]], %[[step2]]
     // TILE_74-NEXT: arith.cmpi slt, %c44, %[[stepped2]]
     // TILE_74-NEXT: %[[ub2:.*]] = select {{.*}}, %c44, %[[stepped2]]

     // Created inner scf.
     // COMMON:scf.for %[[ii:.*]] = %[[i]] to %[[ub:.*]] step %c1

     // This loop is not modified in TILE_7 case.
     // TILE_7: scf.for %[[j:.*]] = %c1 to %c44 step %c2
     //
     // But is modified in TILE_74 case.
     // TILE_74:scf.for %[[jj:.*]] = %[[j]] to %[[ub2]] step %c2
    scf.for %j = %c1 to %c44 step %c2 {
       // The right iterator are used.
       // TILE_7:  memref.load %arg0[%[[ii]], %[[j]]]
       // TILE_74: memref.load %arg0[%[[ii]], %[[jj]]]
       memref.load %arg0[%i, %j]: memref<?x?xf32>
     }
   }
   return
 }

 // COMMON-LABEL: @triangular
 func @triangular(%arg0: memref<?x?xf32>) {
   %c2 = arith.constant 2 : index
   %c44 = arith.constant 44 : index
   %c1 = arith.constant 1 : index
   // Range of the original outer loop:
   //   (upper - lower + step - 1) / step
   // where step is known to be %c1.
   // COMMON:      %[[diff:.*]] = arith.subi %c44, %c2
   // COMMON:      %[[adjustment:.*]] = arith.subi %c1, %c1_{{.*}}
   // COMMON-NEXT: %[[diff_adj:.*]] = arith.addi %[[diff]], %[[adjustment]]
   // COMMON-NEXT: %[[range:.*]] = arith.divsi %[[diff_adj]], %c1

   // Ceildiv to get the parametric tile size.
   // COMMON:       %[[sum:.*]] = arith.addi %[[range]], %c6
   // COMMON-NEXT:  %[[size:.*]] = arith.divsi %[[sum]], %c7
   // New outer step (original is %c1).
   // COMMON-NEXT:  %[[step:.*]] = arith.muli %c1, %[[size]]

   // Constant adjustment for inner loop has been hoisted out.
   // TILE_74:      %[[adjustment2:.*]] = arith.subi %c2, %c1_{{.*}}

   // New outer scf.
   // COMMON: scf.for %[[i:.*]] = %c2 to %c44 step %[[step]]

   // Range of the original inner loop
   //   (upper - lower + step - 1) / step
   // where step is known to be %c2.
   // TILE_74:      %[[diff2:.*]] = arith.subi %[[i]], %c1
   // TILE_74-NEXT: %[[diff2_adj:.*]] = arith.addi %[[diff2]], %[[adjustment2]]
   // TILE_74-NEXT: %[[range2:.*]] = arith.divsi %[[diff2_adj]], %c2

   // Ceildiv to get the parametric tile size for the second original scf.
   // TILE_74:      %[[sum2:.*]] = arith.addi %[[range2]], %c3
   // TILE_74-NEXT: %[[size2:.*]] = arith.divsi %[[sum2]], %c4
   // New inner step (original is %c2).
   // TILE_74-NEXT:     %[[step2:.*]] = arith.muli %c2, %[[size2]]

   // New inner scf.
   // TILE_74:scf.for %[[j:.*]] = %c1 to %[[i]] step %[[step2]]
  scf.for %i = %c2 to %c44 step %c1 {
     // Upper bound for the inner loop min(%i + %step, %c44).
     // COMMON:      %[[stepped:.*]] = arith.addi %[[i]], %[[step]]
     // COMMON-NEXT: arith.cmpi slt, %c44, %[[stepped]]
     // COMMON-NEXT: %[[ub:.*]] = select {{.*}}, %c44, %[[stepped]]
     // TILE_74:      %[[stepped2:.*]] = arith.addi %[[j]], %[[step2]]
     // TILE_74-NEXT: arith.cmpi slt, %[[i]], %[[stepped2]]
     // TILE_74-NEXT: %[[ub2:.*]] = select {{.*}}, %[[i]], %[[stepped2]]
     //
     // Created inner scf.
     // COMMON:scf.for %[[ii:.*]] = %[[i]] to %[[ub:.*]] step %c1

     // This loop is not modified in TILE_7 case.
     // TILE_7: scf.for %[[j:.*]] = %c1 to %[[ii]] step %c2
     //
     // But is modified in TILE_74 case.
     // TILE_74:scf.for %[[jj:.*]] = %[[j]] to %[[ub2]] step %c2
    scf.for %j = %c1 to %i step %c2 {
       // The right iterator are used.
       // TILE_7:  memref.load %arg0[%[[ii]], %[[j]]]
       // TILE_74: memref.load %arg0[%[[ii]], %[[jj]]]
       memref.load %arg0[%i, %j]: memref<?x?xf32>
     }
   }
   return
 }
	// RUN: mlir-opt -test-extract-fixed-outer-loops='test-outer-loop-sizes=7' %s \| FileCheck %s --check-prefixes=COMMON,TILE_7
	// RUN: mlir-opt -test-extract-fixed-outer-loops='test-outer-loop-sizes=7,4' %s \| FileCheck %s --check-prefixes=COMMON,TILE_74

	// COMMON-LABEL: @rectangular
	func @rectangular(%arg0: memref<?x?xf32>) {
	%c2 = arith.constant 2 : index
	%c44 = arith.constant 44 : index
	%c1 = arith.constant 1 : index
	// Range of the original loop:
	// (upper - lower + step - 1) / step
	// where step is known to be %c1.
	// COMMON: %[[diff:.*]] = arith.subi %c44, %c2
	// COMMON: %[[adjustment:.]] = arith.subi %c1, %c1_{{.}}
	// COMMON-NEXT: %[[diff_adj:.*]] = arith.addi %[[diff]], %[[adjustment]]
	// COMMON-NEXT: %[[range:.*]] = arith.divsi %[[diff_adj]], %c1

	// Ceildiv to get the parametric tile size.
	// COMMON: %[[sum:.*]] = arith.addi %[[range]], %c6
	// COMMON-NEXT: %[[size:.*]] = arith.divsi %[[sum]], %c7
	// New outer step (original is %c1).
	// COMMON-NEXT: %[[step:.*]] = arith.muli %c1, %[[size]]

	// Range of the second original loop
	// (upper - lower + step - 1) / step
	// where step is known to be %c2.
	// TILE_74: %[[diff2:.*]] = arith.subi %c44, %c1
	// TILE_74: %[[adjustment2:.]] = arith.subi %c2, %c1_{{.}}
	// TILE_74-NEXT: %[[diff2_adj:.*]] = arith.addi %[[diff2]], %[[adjustment2]]
	// TILE_74-NEXT: %[[range2:.*]] = arith.divsi %[[diff2_adj]], %c2

	// Ceildiv to get the parametric tile size for the second original scf.
	// TILE_74: %[[sum2:.*]] = arith.addi %[[range2]], %c3
	// TILE_74-NEXT: %[[size2:.*]] = arith.divsi %[[sum2]], %c4
	// New inner step (original is %c2).
	// TILE_74-NEXT: %[[step2:.*]] = arith.muli %c2, %[[size2]]

	// Updated outer loop(s) use new steps.
	// COMMON: scf.for %[[i:.*]] = %c2 to %c44 step %[[step]]
	// TILE_74:scf.for %[[j:.*]] = %c1 to %c44 step %[[step2]]
	scf.for %i = %c2 to %c44 step %c1 {
	// Upper bound for the inner loop min(%i + %step, %c44).
	// COMMON: %[[stepped:.*]] = arith.addi %[[i]], %[[step]]
	// COMMON-NEXT: arith.cmpi slt, %c44, %[[stepped]]
	// COMMON-NEXT: %[[ub:.]] = select {{.}}, %c44, %[[stepped]]
	//
	// TILE_74: %[[stepped2:.*]] = arith.addi %[[j]], %[[step2]]
	// TILE_74-NEXT: arith.cmpi slt, %c44, %[[stepped2]]
	// TILE_74-NEXT: %[[ub2:.]] = select {{.}}, %c44, %[[stepped2]]

	// Created inner scf.
	// COMMON:scf.for %[[ii:.]] = %[[i]] to %[[ub:.]] step %c1

	// This loop is not modified in TILE_7 case.
	// TILE_7: scf.for %[[j:.*]] = %c1 to %c44 step %c2
	//
	// But is modified in TILE_74 case.
	// TILE_74:scf.for %[[jj:.*]] = %[[j]] to %[[ub2]] step %c2
	scf.for %j = %c1 to %c44 step %c2 {
	// The right iterator are used.
	// TILE_7: memref.load %arg0[%[[ii]], %[[j]]]
	// TILE_74: memref.load %arg0[%[[ii]], %[[jj]]]
	memref.load %arg0[%i, %j]: memref<?x?xf32>
	}
	}
	return
	}

	// COMMON-LABEL: @triangular
	func @triangular(%arg0: memref<?x?xf32>) {
	%c2 = arith.constant 2 : index
	%c44 = arith.constant 44 : index
	%c1 = arith.constant 1 : index
	// Range of the original outer loop:
	// (upper - lower + step - 1) / step
	// where step is known to be %c1.
	// COMMON: %[[diff:.*]] = arith.subi %c44, %c2
	// COMMON: %[[adjustment:.]] = arith.subi %c1, %c1_{{.}}
	// COMMON-NEXT: %[[diff_adj:.*]] = arith.addi %[[diff]], %[[adjustment]]
	// COMMON-NEXT: %[[range:.*]] = arith.divsi %[[diff_adj]], %c1

	// Ceildiv to get the parametric tile size.
	// COMMON: %[[sum:.*]] = arith.addi %[[range]], %c6
	// COMMON-NEXT: %[[size:.*]] = arith.divsi %[[sum]], %c7
	// New outer step (original is %c1).
	// COMMON-NEXT: %[[step:.*]] = arith.muli %c1, %[[size]]

	// Constant adjustment for inner loop has been hoisted out.
	// TILE_74: %[[adjustment2:.]] = arith.subi %c2, %c1_{{.}}

	// New outer scf.
	// COMMON: scf.for %[[i:.*]] = %c2 to %c44 step %[[step]]

	// Range of the original inner loop
	// (upper - lower + step - 1) / step
	// where step is known to be %c2.
	// TILE_74: %[[diff2:.*]] = arith.subi %[[i]], %c1
	// TILE_74-NEXT: %[[diff2_adj:.*]] = arith.addi %[[diff2]], %[[adjustment2]]
	// TILE_74-NEXT: %[[range2:.*]] = arith.divsi %[[diff2_adj]], %c2

	// Ceildiv to get the parametric tile size for the second original scf.
	// TILE_74: %[[sum2:.*]] = arith.addi %[[range2]], %c3
	// TILE_74-NEXT: %[[size2:.*]] = arith.divsi %[[sum2]], %c4
	// New inner step (original is %c2).
	// TILE_74-NEXT: %[[step2:.*]] = arith.muli %c2, %[[size2]]

	// New inner scf.
	// TILE_74:scf.for %[[j:.*]] = %c1 to %[[i]] step %[[step2]]
	scf.for %i = %c2 to %c44 step %c1 {
	// Upper bound for the inner loop min(%i + %step, %c44).
	// COMMON: %[[stepped:.*]] = arith.addi %[[i]], %[[step]]
	// COMMON-NEXT: arith.cmpi slt, %c44, %[[stepped]]
	// COMMON-NEXT: %[[ub:.]] = select {{.}}, %c44, %[[stepped]]
	// TILE_74: %[[stepped2:.*]] = arith.addi %[[j]], %[[step2]]
	// TILE_74-NEXT: arith.cmpi slt, %[[i]], %[[stepped2]]
	// TILE_74-NEXT: %[[ub2:.]] = select {{.}}, %[[i]], %[[stepped2]]
	//
	// Created inner scf.
	// COMMON:scf.for %[[ii:.]] = %[[i]] to %[[ub:.]] step %c1

	// This loop is not modified in TILE_7 case.
	// TILE_7: scf.for %[[j:.*]] = %c1 to %[[ii]] step %c2
	//
	// But is modified in TILE_74 case.
	// TILE_74:scf.for %[[jj:.*]] = %[[j]] to %[[ub2]] step %c2
	scf.for %j = %c1 to %i step %c2 {
	// The right iterator are used.
	// TILE_7: memref.load %arg0[%[[ii]], %[[j]]]
	// TILE_74: memref.load %arg0[%[[ii]], %[[jj]]]
	memref.load %arg0[%i, %j]: memref<?x?xf32>
	}
	}
	return
	}