test/python/dialects/linalg/opdsl/emit_misc.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 *

 # This tests miscellaneous features of the emitter that are not tested by the
 # matmul, convolution, or, pooling tests. The features include:
 # - constant defined in the body
 # - fix/predefined types
 # - exponential functions
 # - custom op names.

 @linalg_structured_op
 def fill_rng_poly(
     min=ScalarDef(F64),
     max=ScalarDef(F64),
     seed=ScalarDef(I32),
     O=TensorDef(T, S.M, S.N, output=True)):
   multiplier = cast(I32, const(1103515245))
   increment = cast(I32, const(12345))
   rand1 = (cast(I32, index(D.m)) + seed) * multiplier + increment
   rand2 = (cast(I32, index(D.n)) + rand1) * multiplier + increment
   inv_range = cast(F64, const(2.3283064e-10))
   offset = cast(F64, const(2147483647))
   scaling = (max - min) * inv_range
   O[D.m, D.n] = cast(T, (offset + cast(F64, rand2)) * scaling + min)


 @linalg_structured_op
 def soft_plus_poly(
     I=TensorDef(T, S.M, S.N), O=TensorDef(U, S.M, S.N, output=True)):
   O[D.m, D.n] = \
       PrimFn.log(cast(U, const(1.0)) + cast(U, PrimFn.exp(I[D.m, D.n])))


 @linalg_structured_op(op_name="custom_op_name")
 def non_default_op_name(I=TensorDef(T, S.N), O=TensorDef(T, S.N, output=True)):
   O[D.n] = I[D.n]


 with Context() as ctx, Location.unknown():
   module = Module.create()
   f32 = F32Type.get()
   f64 = F64Type.get()
   i32 = IntegerType.get_signless(32)
   with InsertionPoint(module.body):

     # CHECK-LABEL: @test_i32_fill_rng
     # CHECK:      ^{{.*}}(%[[MIN:.+]]: f64, %[[MAX:.+]]: f64, %[[SEED:.+]]: i32, %{{.*}}
     # CHECK-DAG:    %[[IDX0:.+]] = linalg.index 0 : index
     # CHECK-DAG:    %[[IDX0_CAST:.+]] = arith.index_cast %[[IDX0]] : index to i32
     # CHECK-DAG:    %[[RND0:.+]] = arith.addi %[[IDX0_CAST]], %[[SEED]] : i32
     # CHECK-DAG:    %[[CST0:.+]] = arith.constant 1103515245 : i64
     # CHECK-DAG:    %[[CST0_CAST:.+]] = arith.trunci %[[CST0]] : i64 to i32
     # Skip the remaining random number computation and match the scaling logic.
     # CHECK-DAG:    %[[DIFF:.+]] = arith.subf %[[MAX]], %[[MIN]] : f64
     # CHECK-DAG:    %[[CST3:.+]] = arith.constant 2.3283063999999999E-10 : f64
     # CHECK-DAG:    %[[FACT:.+]] = arith.mulf %[[DIFF]], %[[CST3]] : f64
     # CHECK-DAG:    %[[RND4:.+]] = arith.mulf %{{.+}}, %[[FACT]] : f64
     # CHECK-DAG:    %[[RND5:.+]] = arith.addf %[[RND4]], %[[MIN]] : f64
     # CHECK-DAG:    %{{.*}} = arith.fptosi %[[RND5]] : f64 to i32
     @builtin.FuncOp.from_py_func(f64, f64, i32,
                                  RankedTensorType.get((4, 16), i32))
     def test_i32_fill_rng(min, max, seed, init_result):
       return fill_rng_poly(min, max, seed, outs=[init_result])

     # CHECK-LABEL: @test_f32_soft_plus
     # CHECK:      ^{{.*}}(%[[IN:.+]]: f32, %[[OUT:.+]]: f32)
     # CHECK-NEXT:   %[[C1:.+]] = arith.constant 1.000000e+00 : f64
     # CHECK-NEXT:   %[[C1_CAST:.+]] = arith.truncf %[[C1]] : f64 to f32
     # CHECK-NEXT:   %[[EXP:.+]] = math.exp %[[IN]] : f32
     # CHECK-NEXT:   %[[SUM:.+]] = arith.addf %[[C1_CAST]], %[[EXP]] : f32
     # CHECK-NEXT:   %[[LOG:.+]] = math.log %[[SUM]] : f32
     # CHECK-NEXT:   linalg.yield %[[LOG]] : f32
     # CHECK-NEXT: -> tensor<4x16xf32>
     @builtin.FuncOp.from_py_func(
         RankedTensorType.get((4, 16), f32), RankedTensorType.get((4, 16), f32))
     def test_f32_soft_plus(input, init_result):
       return soft_plus_poly(input, outs=[init_result])

     # Just check that we don't assert out on name mismatch.
     # CHECK-LABEL: @test_non_default_op_name
     @builtin.FuncOp.from_py_func(
         RankedTensorType.get((42,), f32), RankedTensorType.get((42,), f32))
     def test_non_default_op_name(input, init_result):
       return non_default_op_name(input, outs=[init_result])


 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 *

	# This tests miscellaneous features of the emitter that are not tested by the
	# matmul, convolution, or, pooling tests. The features include:
	# - constant defined in the body
	# - fix/predefined types
	# - exponential functions
	# - custom op names.

	@linalg_structured_op
	def fill_rng_poly(
	min=ScalarDef(F64),
	max=ScalarDef(F64),
	seed=ScalarDef(I32),
	O=TensorDef(T, S.M, S.N, output=True)):
	multiplier = cast(I32, const(1103515245))
	increment = cast(I32, const(12345))
	rand1 = (cast(I32, index(D.m)) + seed) * multiplier + increment
	rand2 = (cast(I32, index(D.n)) + rand1) * multiplier + increment
	inv_range = cast(F64, const(2.3283064e-10))
	offset = cast(F64, const(2147483647))
	scaling = (max - min) * inv_range
	O[D.m, D.n] = cast(T, (offset + cast(F64, rand2)) * scaling + min)


	@linalg_structured_op
	def soft_plus_poly(
	I=TensorDef(T, S.M, S.N), O=TensorDef(U, S.M, S.N, output=True)):
	O[D.m, D.n] = \
	PrimFn.log(cast(U, const(1.0)) + cast(U, PrimFn.exp(I[D.m, D.n])))


	@linalg_structured_op(op_name="custom_op_name")
	def non_default_op_name(I=TensorDef(T, S.N), O=TensorDef(T, S.N, output=True)):
	O[D.n] = I[D.n]


	with Context() as ctx, Location.unknown():
	module = Module.create()
	f32 = F32Type.get()
	f64 = F64Type.get()
	i32 = IntegerType.get_signless(32)
	with InsertionPoint(module.body):

	# CHECK-LABEL: @test_i32_fill_rng
	# CHECK: ^{{.}}(%[[MIN:.+]]: f64, %[[MAX:.+]]: f64, %[[SEED:.+]]: i32, %{{.}}
	# CHECK-DAG: %[[IDX0:.+]] = linalg.index 0 : index
	# CHECK-DAG: %[[IDX0_CAST:.+]] = arith.index_cast %[[IDX0]] : index to i32
	# CHECK-DAG: %[[RND0:.+]] = arith.addi %[[IDX0_CAST]], %[[SEED]] : i32
	# CHECK-DAG: %[[CST0:.+]] = arith.constant 1103515245 : i64
	# CHECK-DAG: %[[CST0_CAST:.+]] = arith.trunci %[[CST0]] : i64 to i32
	# Skip the remaining random number computation and match the scaling logic.
	# CHECK-DAG: %[[DIFF:.+]] = arith.subf %[[MAX]], %[[MIN]] : f64
	# CHECK-DAG: %[[CST3:.+]] = arith.constant 2.3283063999999999E-10 : f64
	# CHECK-DAG: %[[FACT:.+]] = arith.mulf %[[DIFF]], %[[CST3]] : f64
	# CHECK-DAG: %[[RND4:.+]] = arith.mulf %{{.+}}, %[[FACT]] : f64
	# CHECK-DAG: %[[RND5:.+]] = arith.addf %[[RND4]], %[[MIN]] : f64
	# CHECK-DAG: %{{.*}} = arith.fptosi %[[RND5]] : f64 to i32
	@builtin.FuncOp.from_py_func(f64, f64, i32,
	RankedTensorType.get((4, 16), i32))
	def test_i32_fill_rng(min, max, seed, init_result):
	return fill_rng_poly(min, max, seed, outs=[init_result])

	# CHECK-LABEL: @test_f32_soft_plus
	# CHECK: ^{{.*}}(%[[IN:.+]]: f32, %[[OUT:.+]]: f32)
	# CHECK-NEXT: %[[C1:.+]] = arith.constant 1.000000e+00 : f64
	# CHECK-NEXT: %[[C1_CAST:.+]] = arith.truncf %[[C1]] : f64 to f32
	# CHECK-NEXT: %[[EXP:.+]] = math.exp %[[IN]] : f32
	# CHECK-NEXT: %[[SUM:.+]] = arith.addf %[[C1_CAST]], %[[EXP]] : f32
	# CHECK-NEXT: %[[LOG:.+]] = math.log %[[SUM]] : f32
	# CHECK-NEXT: linalg.yield %[[LOG]] : f32
	# CHECK-NEXT: -> tensor<4x16xf32>
	@builtin.FuncOp.from_py_func(
	RankedTensorType.get((4, 16), f32), RankedTensorType.get((4, 16), f32))
	def test_f32_soft_plus(input, init_result):
	return soft_plus_poly(input, outs=[init_result])

	# Just check that we don't assert out on name mismatch.
	# CHECK-LABEL: @test_non_default_op_name
	@builtin.FuncOp.from_py_func(
	RankedTensorType.get((42,), f32), RankedTensorType.get((42,), f32))
	def test_non_default_op_name(input, init_result):
	return non_default_op_name(input, outs=[init_result])


	print(module)