test/python/dialects/linalg/opdsl/emit_convolution.py - llvm-project/mlir - Git at Google

 # RUN: %PYTHON %s | FileCheck %s

 from mlir.ir import *
 from mlir.dialects import builtin
 from mlir.dialects import linalg
 from mlir.dialects import std

 from mlir.dialects.linalg.opdsl.lang import *

 T1 = TV.T1
 T2 = TV.T2


 @linalg_structured_op
 def conv_poly(
     I=TensorDef(T1, S.N, S.IH, S.IW, S.C),
     K=TensorDef(T2, S.KH, S.KW, S.C),
     O=TensorDef(U, S.N, S.OH, S.OW, S.C, output=True),
     strides=AttributeDef(S.SH, S.SW),
     dilations=AttributeDef(S.DH, S.DW)):
   domain(D.n, D.oh, D.ow, D.kh, D.kw, D.c)
   O[D.n, D.oh, D.ow, D.c] += cast(
       U, I[D.n, D.oh * S.SH + D.kh * S.DH, D.ow * S.SW + D.kw * S.DW,
            D.c]) * cast(U, K[D.kh, D.kw, D.c])


 with Context() as ctx, Location.unknown():
   module = Module.create()
   f32 = F32Type.get()
   i32 = IntegerType.get_signless(32)
   with InsertionPoint(module.body):

     # Convolution indexing maps.
     # CHECK: #[[$CONV_MAP_I:.+]] = affine_map<(d0, d1, d2, d3, d4, d5) -> (d0, d1 * 2 + d3, d2 * 4 + d4 * 2, d5)>
     # CHECK: #[[$CONV_MAP_K:.+]] = affine_map<(d0, d1, d2, d3, d4, d5) -> (d3, d4, d5)>
     # CHECK: #[[$CONV_MAP_O:.+]] = affine_map<(d0, d1, d2, d3, d4, d5) -> (d0, d1, d2, d5)>

     # CHECK-LABEL: @test_f32i32_conv
     # CHECK: linalg.generic
     # CHECK-SAME: indexing_maps = [#[[$CONV_MAP_I]], #[[$CONV_MAP_K]], #[[$CONV_MAP_O]]]
     # CHECK-SAME: iterator_types = ["parallel", "parallel", "parallel", "reduction", "reduction", "parallel"]
     # CHECK:      ^{{.*}}(%[[IN:.+]]: f32, %[[FILTER:.+]]: f32, %[[OUT:.+]]: i32)
     # CHECK-NEXT:   %[[IN_CAST:.+]] = arith.fptosi %[[IN:.+]] : f32 to i32
     # CHECK-NEXT:   %[[FILTER_CAST:.+]] = arith.fptosi %[[FILTER:.+]] : f32 to i32
     # CHECK-NEXT:   %[[PROD:.+]] = arith.muli %[[IN_CAST]], %[[FILTER_CAST]] : i32
     # CHECK-NEXT:   %[[SUM:.+]] = arith.addi %[[OUT]], %[[PROD]] : i32
     # CHECK-NEXT:   linalg.yield %[[SUM]] : i32
     # CHECK-NEXT: -> tensor<1x2x4x1xi32>
     @builtin.FuncOp.from_py_func(
         RankedTensorType.get((1, 4, 16, 1), f32),
         RankedTensorType.get((2, 2, 1), f32),
         RankedTensorType.get((1, 2, 4, 1), i32))
     def test_f32i32_conv(input, filter, init_result):
       return conv_poly(
           input, filter, outs=[init_result], strides=[2, 4], dilations=[1, 2])


 print(module)
	# RUN: %PYTHON %s \| FileCheck %s

	from mlir.ir import *
	from mlir.dialects import builtin
	from mlir.dialects import linalg
	from mlir.dialects import std

	from mlir.dialects.linalg.opdsl.lang import *

	T1 = TV.T1
	T2 = TV.T2


	@linalg_structured_op
	def conv_poly(
	I=TensorDef(T1, S.N, S.IH, S.IW, S.C),
	K=TensorDef(T2, S.KH, S.KW, S.C),
	O=TensorDef(U, S.N, S.OH, S.OW, S.C, output=True),
	strides=AttributeDef(S.SH, S.SW),
	dilations=AttributeDef(S.DH, S.DW)):
	domain(D.n, D.oh, D.ow, D.kh, D.kw, D.c)
	O[D.n, D.oh, D.ow, D.c] += cast(
	U, I[D.n, D.oh * S.SH + D.kh * S.DH, D.ow * S.SW + D.kw * S.DW,
	D.c]) * cast(U, K[D.kh, D.kw, D.c])


	with Context() as ctx, Location.unknown():
	module = Module.create()
	f32 = F32Type.get()
	i32 = IntegerType.get_signless(32)
	with InsertionPoint(module.body):

	# Convolution indexing maps.
	# CHECK: #[[$CONV_MAP_I:.+]] = affine_map<(d0, d1, d2, d3, d4, d5) -> (d0, d1 * 2 + d3, d2 * 4 + d4 * 2, d5)>
	# CHECK: #[[$CONV_MAP_K:.+]] = affine_map<(d0, d1, d2, d3, d4, d5) -> (d3, d4, d5)>
	# CHECK: #[[$CONV_MAP_O:.+]] = affine_map<(d0, d1, d2, d3, d4, d5) -> (d0, d1, d2, d5)>

	# CHECK-LABEL: @test_f32i32_conv
	# CHECK: linalg.generic
	# CHECK-SAME: indexing_maps = [#[[$CONV_MAP_I]], #[[$CONV_MAP_K]], #[[$CONV_MAP_O]]]
	# CHECK-SAME: iterator_types = ["parallel", "parallel", "parallel", "reduction", "reduction", "parallel"]
	# CHECK: ^{{.*}}(%[[IN:.+]]: f32, %[[FILTER:.+]]: f32, %[[OUT:.+]]: i32)
	# CHECK-NEXT: %[[IN_CAST:.+]] = arith.fptosi %[[IN:.+]] : f32 to i32
	# CHECK-NEXT: %[[FILTER_CAST:.+]] = arith.fptosi %[[FILTER:.+]] : f32 to i32
	# CHECK-NEXT: %[[PROD:.+]] = arith.muli %[[IN_CAST]], %[[FILTER_CAST]] : i32
	# CHECK-NEXT: %[[SUM:.+]] = arith.addi %[[OUT]], %[[PROD]] : i32
	# CHECK-NEXT: linalg.yield %[[SUM]] : i32
	# CHECK-NEXT: -> tensor<1x2x4x1xi32>
	@builtin.FuncOp.from_py_func(
	RankedTensorType.get((1, 4, 16, 1), f32),
	RankedTensorType.get((2, 2, 1), f32),
	RankedTensorType.get((1, 2, 4, 1), i32))
	def test_f32i32_conv(input, filter, init_result):
	return conv_poly(
	input, filter, outs=[init_result], strides=[2, 4], dilations=[1, 2])


	print(module)