mlir/test/mlir-linalg-ods-gen/test-linalg-ods-gen.tc - llvm-project - Git at Google

 // RUN: mlir-linalg-ods-gen %s -gen-ods-decl=1 | FileCheck %s --check-prefix=ODS
 // RUN: mlir-linalg-ods-gen %s -gen-impl=1 | FileCheck %s --check-prefix=IMPL

 // ODS-LABEL: def Test1Op : LinalgStructuredBase_Op<"test1", [
 //  ODS-NEXT:   AttrSizedOperandSegments
 //  ODS-NEXT:   DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
 //  ODS-NEXT:   SingleBlockImplicitTerminator<"YieldOp">
 //
 // IMPL-LABEL:  ArrayAttr Test1Op::iterator_types() {
 //       IMPL:  { {{.*}}Parallel{{.*}}, {{.*}}Reduction{{.*}} }
 //
 //       IMPL:  ArrayAttr Test1Op::indexing_maps() {
 //       IMPL: auto s0 = getAffineSymbolExpr(0, context); (void)s0;
 //  IMPL-NEXT: auto s1 = getAffineSymbolExpr(1, context); (void)s1;
 //  IMPL-NEXT: auto map0 = AffineMap::get(2, 2, {d0, d1}, context);
 //  IMPL-NEXT: map0 = map0.replaceDimsAndSymbols({}, { s0, s1 }, 2, 0);
 //  IMPL-NEXT: map0 = simplifyAffineMap(map0);
 //  IMPL-NEXT: auto map1 = AffineMap::get(2, 2, {d1}, context);
 //  IMPL-NEXT: map1 = map1.replaceDimsAndSymbols({}, { s0, s1 }, 2, 0);
 //  IMPL-NEXT: map1 = simplifyAffineMap(map1);
 //  IMPL-NEXT: auto map2 = AffineMap::get(2, 2, {d0}, context);
 //  IMPL-NEXT: map2 = map2.replaceDimsAndSymbols({}, { s0, s1 }, 2, 0);
 //  IMPL-NEXT: map2 = simplifyAffineMap(map2);
 //  IMPL-NEXT: return {{.+}}.getAffineMapArrayAttr({ map0, map1, map2 });
 //
 //       IMPL:  void Test1Op::regionBuilder(Block &block) {
 //       IMPL:  Value [[a:.*]](args[0]), [[b:.*]](args[1]), [[c:.*]](args[2]);
 //       IMPL:  Value [[d:.*]] = std_mulf([[a]], [[b]]);
 //       IMPL:  Value [[e:.*]] = std_addf([[c]], [[d]]);
 //       IMPL:  (linalg_yield(ValueRange{ [[e]] }));
 //
 ods_def<Test1Op> :
 def test1(A: f32(M, K), B: f32(K)) -> (C: f32(M)) {
   C(m) = std_addf<k>(std_mulf(A(m, k), B(k)));
 }

 // ODS-LABEL: def Test2Op : LinalgStructuredBase_Op<"test2", [
 //  ODS-NEXT:   AttrSizedOperandSegments
 //  ODS-NEXT:   DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
 //  ODS-NEXT:   SingleBlockImplicitTerminator<"YieldOp">
 //
 // IMPL-LABEL:  ArrayAttr Test2Op::iterator_types() {
 //       IMPL:  { {{.*}}Parallel{{.*}}, {{.*}}Parallel{{.*}}, {{.*}}Reduction{{.*}} }
 //
 //       IMPL:  ArrayAttr Test2Op::indexing_maps() {
 //       IMPL:  AffineMap::get(3, 3, {d0, d2}, context)
 //       IMPL:  AffineMap::get(3, 3, {d2, d1}, context)
 //       IMPL:  AffineMap::get(3, 3, {d0, d1}, context)
 //
 //       IMPL:  Test2Op::regionBuilder(Block &block) {
 //       IMPL:  Value [[a:.*]](args[0]), [[b:.*]](args[1]), [[c:.*]](args[2]);
 //       IMPL:  Value [[d:.*]] = std_mulf([[a]], [[b]]);
 //       IMPL:  Value [[e:.*]] = std_addf([[c]], [[d]]);
 //       IMPL:  (linalg_yield(ValueRange{ [[e]] }));
 //
 ods_def<Test2Op> :
 def test2(A: f32(M, K), B: f32(K, N)) -> (C: f32(M, N)) {
   C(m, n) = std_addf<k>(std_mulf(A(m, k), B(k, n)));
 }

 // ODS-LABEL: def Test3Op : LinalgStructuredBase_Op<"test3", [
 //  ODS-NEXT:   AttrSizedOperandSegments
 //  ODS-NEXT:   DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
 //  ODS-NEXT:   SingleBlockImplicitTerminator<"YieldOp">
 //
 // IMPL-LABEL:  ArrayAttr Test3Op::iterator_types() {
 //       IMPL:  { {{.*}}Parallel{{.*}}, {{.*}}Parallel{{.*}}, {{.*}}Reduction{{.*}} }
 //
 //       IMPL:  ArrayAttr Test3Op::indexing_maps() {
 //       IMPL:  AffineMap::get(4, 4, {d0, d1, d3}, context)
 //       IMPL:  AffineMap::get(4, 4, {d3, d2}, context)
 //       IMPL:  AffineMap::get(4, 4, {d0, d1, d2}, context)
 //
 //       IMPL:  Test3Op::regionBuilder(Block &block) {
 //       IMPL:  Value [[a:.*]](args[0]), [[b:.*]](args[1]), [[c:.*]](args[2]);
 //       IMPL:  Value [[d:.*]] = std_mulf([[a]], [[b]]);
 //       IMPL:  Value [[e:.*]] = std_addf([[c]], [[d]]);
 //       IMPL:  (linalg_yield(ValueRange{ [[e]] }));
 //
 ods_def<Test3Op> :
 def test3(A: f32(Batch, M, K), B: f32(K, N)) -> (C: f32(Batch, M, N)) {
   C(b, m, n) = std_addf<k>(std_mulf(A(b, m, k), B(k, n)));
 }

 // Test attribute definitions
 // ODS-LABEL: def Test4Op
 // ODS: F32ArrayAttr:$array_attr,
 // ODS: F32:$f32_attr,
 // ODS: RankedF32ElementsAttr<[4]>:$fvec_attr,
 // ODS: I32:$i32_attr,
 // ODS: I64:$i64_attr,
 // ODS: RankedI32ElementsAttr<[5, 6]>:$ivec_attr,
 // ODS: OptionalAttr<F32>:$optional_attr
 //
 ods_def<Test4Op> :
 def test4(A: f32(Batch, M, K), B: f32(K, N)) -> (C: f32(Batch, M, N))
 attr(
   f32_attr: f32,
   i32_attr: i32,
   i64_attr: i64,
   fvec_attr: 4xf32,
   ivec_attr: 5x6xi32,
   array_attr : f32[],
   optional_attr? : f32
 ) {
   C(b, m, n) = std_addf<k>(std_mulf(A(b, m, k), B(k, n)));
 }

 // Test attribute usage in affine expressions
 // IMPL-LABEL: ArrayAttr Test5Op::indexing_maps() {
 // IMPL: auto cst0 = getAffineConstantExpr(strides().getValue<int>({ 0 }), context);
 // IMPL: auto cst1 = getAffineConstantExpr(strides().getValue<int>({ 1 }), context);
 // IMPL: auto map0 = AffineMap::get(7, 9, {d0, d1 * s7 + d4, d2 * s8 + d5, d6}, context);
 // IMPL: map0 = map0.replaceDimsAndSymbols({}, { s0, s1, s2, s3, s4, s5, s6, cst0, cst1 }, 7, 0);
 // IMPL: map0 = simplifyAffineMap(map0);
 // IMPL: auto map1 = AffineMap::get(7, 9, {d3, d4, d5, d6}, context);
 // IMPL: map1 = map1.replaceDimsAndSymbols({}, { s0, s1, s2, s3, s4, s5, s6, cst0, cst1 }, 7, 0);
 // IMPL: map1 = simplifyAffineMap(map1);
 // IMPL: auto map2 = AffineMap::get(7, 7, {d0, d1, d2, d3}, context);
 // IMPL: map2 = map2.replaceDimsAndSymbols({}, { s0, s1, s2, s3, s4, s5, s6, cst0, cst1 }, 7, 0);
 // IMPL: map2 = simplifyAffineMap(map2);
 // IMPL: return {{.+}}.getAffineMapArrayAttr({ map0, map1, map2 });
 //
 ods_def<Test5Op>:
 def test5(I: f32(N, H, W, C), K: f32(F, KH, KW, C)) -> (O: f32(N, H, W, F))
      attr(strides: 2xi32) {
   O(n, h, w, f) = std_addf<kh, kw>(std_mulf(
     I(n, h * strides[0] + kh, w * strides[1] + kw, c), K(f, kh, kw, c)));
 }

 // Test documentation
 // ODS-LABEL: def Test6Op
 // ODS:       let summary = [{ My magic op. }];
 // ODS-NEXT:  let description = [{
 // ODS-NEXT:    It has two inputs.
 // ODS-NEXT:    It has one output.
 // ODS-NEXT:  }];
 //
 ods_def<Test6Op>:
 def test6(A: f32(M, K), B: f32(K)) -> (C: f32(M))
 """
 My magic op.

 It has two inputs.
 It has one output.
 """
 {
   C(m) = std_addf<k>(std_mulf(A(m, k), B(k)));
 }

 // Test attribute builder
 // ODS-LABEL: def Test7Op
 // ODS:         OpBuilderDAG<
 // ODS:           (ins "TypeRange":$resultTensorTypes, "ValueRange":$inputs,
 // ODS:            "ValueRange":$outputs, "Attribute":$attr_a, "Attribute":$attr_b)
 // ODS:           $_state.addAttribute("attr_a", attr_a);
 // ODS:           $_state.addAttribute("attr_b", attr_b);
 //
 ods_def<Test7Op>:
 def test7(A: f32(M, K), B: f32(K)) -> (C: f32(M))
      attr(attr_a: f32, attr_b: 4xi32)
 {
   C(m) = std_addf<k>(std_mulf(A(m, k), B(k)));
 }
	// RUN: mlir-linalg-ods-gen %s -gen-ods-decl=1 \| FileCheck %s --check-prefix=ODS
	// RUN: mlir-linalg-ods-gen %s -gen-impl=1 \| FileCheck %s --check-prefix=IMPL

	// ODS-LABEL: def Test1Op : LinalgStructuredBase_Op<"test1", [
	// ODS-NEXT: AttrSizedOperandSegments
	// ODS-NEXT: DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
	// ODS-NEXT: SingleBlockImplicitTerminator<"YieldOp">
	//
	// IMPL-LABEL: ArrayAttr Test1Op::iterator_types() {
	// IMPL: { {{.}}Parallel{{.}}, {{.}}Reduction{{.}} }
	//
	// IMPL: ArrayAttr Test1Op::indexing_maps() {
	// IMPL: auto s0 = getAffineSymbolExpr(0, context); (void)s0;
	// IMPL-NEXT: auto s1 = getAffineSymbolExpr(1, context); (void)s1;
	// IMPL-NEXT: auto map0 = AffineMap::get(2, 2, {d0, d1}, context);
	// IMPL-NEXT: map0 = map0.replaceDimsAndSymbols({}, { s0, s1 }, 2, 0);
	// IMPL-NEXT: map0 = simplifyAffineMap(map0);
	// IMPL-NEXT: auto map1 = AffineMap::get(2, 2, {d1}, context);
	// IMPL-NEXT: map1 = map1.replaceDimsAndSymbols({}, { s0, s1 }, 2, 0);
	// IMPL-NEXT: map1 = simplifyAffineMap(map1);
	// IMPL-NEXT: auto map2 = AffineMap::get(2, 2, {d0}, context);
	// IMPL-NEXT: map2 = map2.replaceDimsAndSymbols({}, { s0, s1 }, 2, 0);
	// IMPL-NEXT: map2 = simplifyAffineMap(map2);
	// IMPL-NEXT: return {{.+}}.getAffineMapArrayAttr({ map0, map1, map2 });
	//
	// IMPL: void Test1Op::regionBuilder(Block &block) {
	// IMPL: Value [[a:.]](args[0]), [[b:.]](args[1]), [[c:.*]](args[2]);
	// IMPL: Value [[d:.*]] = std_mulf([[a]], [[b]]);
	// IMPL: Value [[e:.*]] = std_addf([[c]], [[d]]);
	// IMPL: (linalg_yield(ValueRange{ [[e]] }));
	//
	ods_def<Test1Op> :
	def test1(A: f32(M, K), B: f32(K)) -> (C: f32(M)) {
	C(m) = std_addf<k>(std_mulf(A(m, k), B(k)));
	}

	// ODS-LABEL: def Test2Op : LinalgStructuredBase_Op<"test2", [
	// ODS-NEXT: AttrSizedOperandSegments
	// ODS-NEXT: DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
	// ODS-NEXT: SingleBlockImplicitTerminator<"YieldOp">
	//
	// IMPL-LABEL: ArrayAttr Test2Op::iterator_types() {
	// IMPL: { {{.}}Parallel{{.}}, {{.}}Parallel{{.}}, {{.}}Reduction{{.}} }
	//
	// IMPL: ArrayAttr Test2Op::indexing_maps() {
	// IMPL: AffineMap::get(3, 3, {d0, d2}, context)
	// IMPL: AffineMap::get(3, 3, {d2, d1}, context)
	// IMPL: AffineMap::get(3, 3, {d0, d1}, context)
	//
	// IMPL: Test2Op::regionBuilder(Block &block) {
	// IMPL: Value [[a:.]](args[0]), [[b:.]](args[1]), [[c:.*]](args[2]);
	// IMPL: Value [[d:.*]] = std_mulf([[a]], [[b]]);
	// IMPL: Value [[e:.*]] = std_addf([[c]], [[d]]);
	// IMPL: (linalg_yield(ValueRange{ [[e]] }));
	//
	ods_def<Test2Op> :
	def test2(A: f32(M, K), B: f32(K, N)) -> (C: f32(M, N)) {
	C(m, n) = std_addf<k>(std_mulf(A(m, k), B(k, n)));
	}

	// ODS-LABEL: def Test3Op : LinalgStructuredBase_Op<"test3", [
	// ODS-NEXT: AttrSizedOperandSegments
	// ODS-NEXT: DeclareOpInterfaceMethods<MemoryEffectsOpInterface>,
	// ODS-NEXT: SingleBlockImplicitTerminator<"YieldOp">
	//
	// IMPL-LABEL: ArrayAttr Test3Op::iterator_types() {
	// IMPL: { {{.}}Parallel{{.}}, {{.}}Parallel{{.}}, {{.}}Reduction{{.}} }
	//
	// IMPL: ArrayAttr Test3Op::indexing_maps() {
	// IMPL: AffineMap::get(4, 4, {d0, d1, d3}, context)
	// IMPL: AffineMap::get(4, 4, {d3, d2}, context)
	// IMPL: AffineMap::get(4, 4, {d0, d1, d2}, context)
	//
	// IMPL: Test3Op::regionBuilder(Block &block) {
	// IMPL: Value [[a:.]](args[0]), [[b:.]](args[1]), [[c:.*]](args[2]);
	// IMPL: Value [[d:.*]] = std_mulf([[a]], [[b]]);
	// IMPL: Value [[e:.*]] = std_addf([[c]], [[d]]);
	// IMPL: (linalg_yield(ValueRange{ [[e]] }));
	//
	ods_def<Test3Op> :
	def test3(A: f32(Batch, M, K), B: f32(K, N)) -> (C: f32(Batch, M, N)) {
	C(b, m, n) = std_addf<k>(std_mulf(A(b, m, k), B(k, n)));
	}

	// Test attribute definitions
	// ODS-LABEL: def Test4Op
	// ODS: F32ArrayAttr:$array_attr,
	// ODS: F32:$f32_attr,
	// ODS: RankedF32ElementsAttr<[4]>:$fvec_attr,
	// ODS: I32:$i32_attr,
	// ODS: I64:$i64_attr,
	// ODS: RankedI32ElementsAttr<[5, 6]>:$ivec_attr,
	// ODS: OptionalAttr<F32>:$optional_attr
	//
	ods_def<Test4Op> :
	def test4(A: f32(Batch, M, K), B: f32(K, N)) -> (C: f32(Batch, M, N))
	attr(
	f32_attr: f32,
	i32_attr: i32,
	i64_attr: i64,
	fvec_attr: 4xf32,
	ivec_attr: 5x6xi32,
	array_attr : f32[],
	optional_attr? : f32
	) {
	C(b, m, n) = std_addf<k>(std_mulf(A(b, m, k), B(k, n)));
	}

	// Test attribute usage in affine expressions
	// IMPL-LABEL: ArrayAttr Test5Op::indexing_maps() {
	// IMPL: auto cst0 = getAffineConstantExpr(strides().getValue<int>({ 0 }), context);
	// IMPL: auto cst1 = getAffineConstantExpr(strides().getValue<int>({ 1 }), context);
	// IMPL: auto map0 = AffineMap::get(7, 9, {d0, d1 * s7 + d4, d2 * s8 + d5, d6}, context);
	// IMPL: map0 = map0.replaceDimsAndSymbols({}, { s0, s1, s2, s3, s4, s5, s6, cst0, cst1 }, 7, 0);
	// IMPL: map0 = simplifyAffineMap(map0);
	// IMPL: auto map1 = AffineMap::get(7, 9, {d3, d4, d5, d6}, context);
	// IMPL: map1 = map1.replaceDimsAndSymbols({}, { s0, s1, s2, s3, s4, s5, s6, cst0, cst1 }, 7, 0);
	// IMPL: map1 = simplifyAffineMap(map1);
	// IMPL: auto map2 = AffineMap::get(7, 7, {d0, d1, d2, d3}, context);
	// IMPL: map2 = map2.replaceDimsAndSymbols({}, { s0, s1, s2, s3, s4, s5, s6, cst0, cst1 }, 7, 0);
	// IMPL: map2 = simplifyAffineMap(map2);
	// IMPL: return {{.+}}.getAffineMapArrayAttr({ map0, map1, map2 });
	//
	ods_def<Test5Op>:
	def test5(I: f32(N, H, W, C), K: f32(F, KH, KW, C)) -> (O: f32(N, H, W, F))
	attr(strides: 2xi32) {
	O(n, h, w, f) = std_addf<kh, kw>(std_mulf(
	I(n, h * strides[0] + kh, w * strides[1] + kw, c), K(f, kh, kw, c)));
	}

	// Test documentation
	// ODS-LABEL: def Test6Op
	// ODS: let summary = [{ My magic op. }];
	// ODS-NEXT: let description = [{
	// ODS-NEXT: It has two inputs.
	// ODS-NEXT: It has one output.
	// ODS-NEXT: }];
	//
	ods_def<Test6Op>:
	def test6(A: f32(M, K), B: f32(K)) -> (C: f32(M))
	"""
	My magic op.

	It has two inputs.
	It has one output.
	"""
	{
	C(m) = std_addf<k>(std_mulf(A(m, k), B(k)));
	}

	// Test attribute builder
	// ODS-LABEL: def Test7Op
	// ODS: OpBuilderDAG<
	// ODS: (ins "TypeRange":$resultTensorTypes, "ValueRange":$inputs,
	// ODS: "ValueRange":$outputs, "Attribute":$attr_a, "Attribute":$attr_b)
	// ODS: $_state.addAttribute("attr_a", attr_a);
	// ODS: $_state.addAttribute("attr_b", attr_b);
	//
	ods_def<Test7Op>:
	def test7(A: f32(M, K), B: f32(K)) -> (C: f32(M))
	attr(attr_a: f32, attr_b: 4xi32)
	{
	C(m) = std_addf<k>(std_mulf(A(m, k), B(k)));
	}