mlir/test/Transforms/loop-fusion-4.mlir - llvm-project - Git at Google

 // RUN: mlir-opt -allow-unregistered-dialect %s -affine-loop-fusion="mode=producer" -split-input-file | FileCheck %s --check-prefix=PRODUCER-CONSUMER
 // RUN: mlir-opt -allow-unregistered-dialect %s -affine-loop-fusion="fusion-maximal mode=sibling" -split-input-file | FileCheck %s --check-prefix=SIBLING-MAXIMAL

 // Part I of fusion tests in  mlir/test/Transforms/loop-fusion.mlir.
 // Part II of fusion tests in mlir/test/Transforms/loop-fusion-2.mlir
 // Part III of fusion tests in mlir/test/Transforms/loop-fusion-3.mlir

 // Expects fusion of producer into consumer at depth 4 and subsequent removal of
 // source loop.
 // PRODUCER-CONSUMER-LABEL: func @unflatten4d
 func @unflatten4d(%arg1: memref<7x8x9x10xf32>) {
   %m = memref.alloc() : memref<5040xf32>
   %cf7 = arith.constant 7.0 : f32

   affine.for %i0 = 0 to 7 {
     affine.for %i1 = 0 to 8 {
       affine.for %i2 = 0 to 9 {
         affine.for %i3 = 0 to 10 {
           affine.store %cf7, %m[720 * %i0 + 90 * %i1 + 10 * %i2 + %i3] : memref<5040xf32>
         }
       }
     }
   }
   affine.for %i0 = 0 to 7 {
     affine.for %i1 = 0 to 8 {
       affine.for %i2 = 0 to 9 {
         affine.for %i3 = 0 to 10 {
           %v0 = affine.load %m[720 * %i0 + 90 * %i1 + 10 * %i2 + %i3] : memref<5040xf32>
           affine.store %v0, %arg1[%i0, %i1, %i2, %i3] : memref<7x8x9x10xf32>
         }
       }
     }
   }
   return
 }

 // PRODUCER-CONSUMER:        affine.for
 // PRODUCER-CONSUMER-NEXT:     affine.for
 // PRODUCER-CONSUMER-NEXT:       affine.for
 // PRODUCER-CONSUMER-NEXT:         affine.for
 // PRODUCER-CONSUMER-NOT:    affine.for
 // PRODUCER-CONSUMER: return

 // -----

 // Expects fusion of producer into consumer at depth 2 and subsequent removal of
 // source loop.
 // PRODUCER-CONSUMER-LABEL: func @unflatten2d_with_transpose
 func @unflatten2d_with_transpose(%arg1: memref<8x7xf32>) {
   %m = memref.alloc() : memref<56xf32>
   %cf7 = arith.constant 7.0 : f32

   affine.for %i0 = 0 to 7 {
     affine.for %i1 = 0 to 8 {
       affine.store %cf7, %m[8 * %i0 + %i1] : memref<56xf32>
     }
   }
   affine.for %i0 = 0 to 8 {
     affine.for %i1 = 0 to 7 {
       %v0 = affine.load %m[%i0 + 8 * %i1] : memref<56xf32>
       affine.store %v0, %arg1[%i0, %i1] : memref<8x7xf32>
     }
   }
   return
 }

 // PRODUCER-CONSUMER:        affine.for
 // PRODUCER-CONSUMER-NEXT:     affine.for
 // PRODUCER-CONSUMER-NOT:    affine.for
 // PRODUCER-CONSUMER: return

 // -----

 // Expects fusion of producer into consumer at depth 1 and source loop to not
 // be removed due to difference in loop steps.
 // PRODUCER-CONSUMER-LABEL: func @check_src_dst_step
 func @check_src_dst_step(%m : memref<100xf32>,
                          %src: memref<100xf32>,
                          %out: memref<100xf32>) {
   affine.for %i0 = 0 to 100 {
     %r1 = affine.load %src[%i0]: memref<100xf32>
     affine.store %r1, %m[%i0] : memref<100xf32>
   }
   affine.for %i2 = 0 to 100 step 2 {
     %r2 = affine.load %m[%i2] : memref<100xf32>
     affine.store %r2, %out[%i2] : memref<100xf32>
   }
   return
 }

 // Check if the fusion did take place as well as that the source loop was
 // not removed. To check if fusion took place, the read instruction from the
 // original source loop is checked to be in the fused loop.
 //
 // PRODUCER-CONSUMER:        affine.for %[[idx_0:.*]] = 0 to 100 {
 // PRODUCER-CONSUMER-NEXT:     %[[result_0:.*]] = affine.load %[[arr1:.*]][%[[idx_0]]] : memref<100xf32>
 // PRODUCER-CONSUMER-NEXT:     affine.store %[[result_0]], %{{.*}}[%[[idx_0]]] : memref<100xf32>
 // PRODUCER-CONSUMER-NEXT:   }
 // PRODUCER-CONSUMER:        affine.for %[[idx_1:.*]] = 0 to 100 step 2 {
 // PRODUCER-CONSUMER:          affine.load %[[arr1]][%[[idx_1]]] : memref<100xf32>
 // PRODUCER-CONSUMER:        }
 // PRODUCER-CONSUMER:        return

 // -----

 // SIBLING-MAXIMAL-LABEL:   func @reduce_add_non_maximal_f32_f32(
 func @reduce_add_non_maximal_f32_f32(%arg0: memref<64x64xf32, 1>, %arg1 : memref<1x64xf32, 1>, %arg2 : memref<1x64xf32, 1>) {
     %cst_0 = arith.constant 0.000000e+00 : f32
     %cst_1 = arith.constant 1.000000e+00 : f32
     affine.for %arg3 = 0 to 1 {
       affine.for %arg4 = 0 to 64 {
         %accum = affine.for %arg5 = 0 to 64 iter_args (%prevAccum = %cst_0) -> f32 {
           %4 = affine.load %arg0[%arg5, %arg4] : memref<64x64xf32, 1>
           %5 = arith.addf %prevAccum, %4 : f32
           affine.yield %5 : f32
         }
         %accum_dbl = arith.addf %accum, %accum : f32
         affine.store %accum_dbl, %arg1[%arg3, %arg4] : memref<1x64xf32, 1>
       }
     }
     affine.for %arg3 = 0 to 1 {
       affine.for %arg4 = 0 to 64 {
         // Following loop  trip count does not match the corresponding source trip count.
         %accum = affine.for %arg5 = 0 to 32 iter_args (%prevAccum = %cst_1) -> f32 {
           %4 = affine.load %arg0[%arg5, %arg4] : memref<64x64xf32, 1>
           %5 = arith.mulf %prevAccum, %4 : f32
           affine.yield %5 : f32
         }
         %accum_sqr = arith.mulf %accum, %accum : f32
         affine.store %accum_sqr, %arg2[%arg3, %arg4] : memref<1x64xf32, 1>
       }
     }
     return
 }
 // Test checks the loop structure is preserved after sibling fusion
 // since the destination loop and source loop trip counts do not
 // match.
 // SIBLING-MAXIMAL:        %[[cst_0:.*]] = arith.constant 0.000000e+00 : f32
 // SIBLING-MAXIMAL-NEXT:        %[[cst_1:.*]] = arith.constant 1.000000e+00 : f32
 // SIBLING-MAXIMAL-NEXT:           affine.for %[[idx_0:.*]]= 0 to 1 {
 // SIBLING-MAXIMAL-NEXT:             affine.for %[[idx_1:.*]] = 0 to 64 {
 // SIBLING-MAXIMAL-NEXT:               %[[result_1:.*]] = affine.for %[[idx_2:.*]] = 0 to 32 iter_args(%[[iter_0:.*]] = %[[cst_1]]) -> (f32) {
 // SIBLING-MAXIMAL-NEXT:                 %[[result_0:.*]] = affine.for %[[idx_3:.*]] = 0 to 64 iter_args(%[[iter_1:.*]] = %[[cst_0]]) -> (f32) {
	// RUN: mlir-opt -allow-unregistered-dialect %s -affine-loop-fusion="mode=producer" -split-input-file \| FileCheck %s --check-prefix=PRODUCER-CONSUMER
	// RUN: mlir-opt -allow-unregistered-dialect %s -affine-loop-fusion="fusion-maximal mode=sibling" -split-input-file \| FileCheck %s --check-prefix=SIBLING-MAXIMAL

	// Part I of fusion tests in mlir/test/Transforms/loop-fusion.mlir.
	// Part II of fusion tests in mlir/test/Transforms/loop-fusion-2.mlir
	// Part III of fusion tests in mlir/test/Transforms/loop-fusion-3.mlir

	// Expects fusion of producer into consumer at depth 4 and subsequent removal of
	// source loop.
	// PRODUCER-CONSUMER-LABEL: func @unflatten4d
	func @unflatten4d(%arg1: memref<7x8x9x10xf32>) {
	%m = memref.alloc() : memref<5040xf32>
	%cf7 = arith.constant 7.0 : f32

	affine.for %i0 = 0 to 7 {
	affine.for %i1 = 0 to 8 {
	affine.for %i2 = 0 to 9 {
	affine.for %i3 = 0 to 10 {
	affine.store %cf7, %m[720 * %i0 + 90 * %i1 + 10 * %i2 + %i3] : memref<5040xf32>
	}
	}
	}
	}
	affine.for %i0 = 0 to 7 {
	affine.for %i1 = 0 to 8 {
	affine.for %i2 = 0 to 9 {
	affine.for %i3 = 0 to 10 {
	%v0 = affine.load %m[720 * %i0 + 90 * %i1 + 10 * %i2 + %i3] : memref<5040xf32>
	affine.store %v0, %arg1[%i0, %i1, %i2, %i3] : memref<7x8x9x10xf32>
	}
	}
	}
	}
	return
	}

	// PRODUCER-CONSUMER: affine.for
	// PRODUCER-CONSUMER-NEXT: affine.for
	// PRODUCER-CONSUMER-NEXT: affine.for
	// PRODUCER-CONSUMER-NEXT: affine.for
	// PRODUCER-CONSUMER-NOT: affine.for
	// PRODUCER-CONSUMER: return

	// -----

	// Expects fusion of producer into consumer at depth 2 and subsequent removal of
	// source loop.
	// PRODUCER-CONSUMER-LABEL: func @unflatten2d_with_transpose
	func @unflatten2d_with_transpose(%arg1: memref<8x7xf32>) {
	%m = memref.alloc() : memref<56xf32>
	%cf7 = arith.constant 7.0 : f32

	affine.for %i0 = 0 to 7 {
	affine.for %i1 = 0 to 8 {
	affine.store %cf7, %m[8 * %i0 + %i1] : memref<56xf32>
	}
	}
	affine.for %i0 = 0 to 8 {
	affine.for %i1 = 0 to 7 {
	%v0 = affine.load %m[%i0 + 8 * %i1] : memref<56xf32>
	affine.store %v0, %arg1[%i0, %i1] : memref<8x7xf32>
	}
	}
	return
	}

	// PRODUCER-CONSUMER: affine.for
	// PRODUCER-CONSUMER-NEXT: affine.for
	// PRODUCER-CONSUMER-NOT: affine.for
	// PRODUCER-CONSUMER: return

	// -----

	// Expects fusion of producer into consumer at depth 1 and source loop to not
	// be removed due to difference in loop steps.
	// PRODUCER-CONSUMER-LABEL: func @check_src_dst_step
	func @check_src_dst_step(%m : memref<100xf32>,
	%src: memref<100xf32>,
	%out: memref<100xf32>) {
	affine.for %i0 = 0 to 100 {
	%r1 = affine.load %src[%i0]: memref<100xf32>
	affine.store %r1, %m[%i0] : memref<100xf32>
	}
	affine.for %i2 = 0 to 100 step 2 {
	%r2 = affine.load %m[%i2] : memref<100xf32>
	affine.store %r2, %out[%i2] : memref<100xf32>
	}
	return
	}

	// Check if the fusion did take place as well as that the source loop was
	// not removed. To check if fusion took place, the read instruction from the
	// original source loop is checked to be in the fused loop.
	//
	// PRODUCER-CONSUMER: affine.for %[[idx_0:.*]] = 0 to 100 {
	// PRODUCER-CONSUMER-NEXT: %[[result_0:.]] = affine.load %[[arr1:.]][%[[idx_0]]] : memref<100xf32>
	// PRODUCER-CONSUMER-NEXT: affine.store %[[result_0]], %{{.*}}[%[[idx_0]]] : memref<100xf32>
	// PRODUCER-CONSUMER-NEXT: }
	// PRODUCER-CONSUMER: affine.for %[[idx_1:.*]] = 0 to 100 step 2 {
	// PRODUCER-CONSUMER: affine.load %[[arr1]][%[[idx_1]]] : memref<100xf32>
	// PRODUCER-CONSUMER: }
	// PRODUCER-CONSUMER: return

	// -----

	// SIBLING-MAXIMAL-LABEL: func @reduce_add_non_maximal_f32_f32(
	func @reduce_add_non_maximal_f32_f32(%arg0: memref<64x64xf32, 1>, %arg1 : memref<1x64xf32, 1>, %arg2 : memref<1x64xf32, 1>) {
	%cst_0 = arith.constant 0.000000e+00 : f32
	%cst_1 = arith.constant 1.000000e+00 : f32
	affine.for %arg3 = 0 to 1 {
	affine.for %arg4 = 0 to 64 {
	%accum = affine.for %arg5 = 0 to 64 iter_args (%prevAccum = %cst_0) -> f32 {
	%4 = affine.load %arg0[%arg5, %arg4] : memref<64x64xf32, 1>
	%5 = arith.addf %prevAccum, %4 : f32
	affine.yield %5 : f32
	}
	%accum_dbl = arith.addf %accum, %accum : f32
	affine.store %accum_dbl, %arg1[%arg3, %arg4] : memref<1x64xf32, 1>
	}
	}
	affine.for %arg3 = 0 to 1 {
	affine.for %arg4 = 0 to 64 {
	// Following loop trip count does not match the corresponding source trip count.
	%accum = affine.for %arg5 = 0 to 32 iter_args (%prevAccum = %cst_1) -> f32 {
	%4 = affine.load %arg0[%arg5, %arg4] : memref<64x64xf32, 1>
	%5 = arith.mulf %prevAccum, %4 : f32
	affine.yield %5 : f32
	}
	%accum_sqr = arith.mulf %accum, %accum : f32
	affine.store %accum_sqr, %arg2[%arg3, %arg4] : memref<1x64xf32, 1>
	}
	}
	return
	}
	// Test checks the loop structure is preserved after sibling fusion
	// since the destination loop and source loop trip counts do not
	// match.
	// SIBLING-MAXIMAL: %[[cst_0:.*]] = arith.constant 0.000000e+00 : f32
	// SIBLING-MAXIMAL-NEXT: %[[cst_1:.*]] = arith.constant 1.000000e+00 : f32
	// SIBLING-MAXIMAL-NEXT: affine.for %[[idx_0:.*]]= 0 to 1 {
	// SIBLING-MAXIMAL-NEXT: affine.for %[[idx_1:.*]] = 0 to 64 {
	// SIBLING-MAXIMAL-NEXT: %[[result_1:.]] = affine.for %[[idx_2:.]] = 0 to 32 iter_args(%[[iter_0:.*]] = %[[cst_1]]) -> (f32) {
	// SIBLING-MAXIMAL-NEXT: %[[result_0:.]] = affine.for %[[idx_3:.]] = 0 to 64 iter_args(%[[iter_1:.*]] = %[[cst_0]]) -> (f32) {