mlir/test/mlir-tblgen/typedefs.td - llvm-project - Git at Google

 // RUN: mlir-tblgen -gen-typedef-decls -I %S/../../include %s | FileCheck %s --check-prefix=DECL
 // RUN: mlir-tblgen -gen-typedef-defs -I %S/../../include %s | FileCheck %s --check-prefix=DEF

 include "mlir/IR/OpBase.td"

 // DECL: #ifdef GET_TYPEDEF_CLASSES
 // DECL: #undef GET_TYPEDEF_CLASSES

 // DECL: namespace mlir {
 // DECL: class AsmParser;
 // DECL: class AsmPrinter;
 // DECL: } // namespace mlir

 // DEF: #ifdef GET_TYPEDEF_LIST
 // DEF: #undef GET_TYPEDEF_LIST
 // DEF: ::test::SimpleAType,
 // DEF: ::test::CompoundAType,
 // DEF: ::test::IndexType,
 // DEF: ::test::SingleParameterType,
 // DEF: ::test::IntegerType

 // DEF-LABEL: ::mlir::OptionalParseResult generatedTypeParser(
 // DEF-NEXT: ::mlir::AsmParser &parser,
 // DEF-NEXT: ::llvm::StringRef mnemonic,
 // DEF-NEXT: ::mlir::Type &value) {
 // DEF: if (mnemonic == ::test::CompoundAType::getMnemonic()) {
 // DEF-NEXT:   value = ::test::CompoundAType::parse(parser);
 // DEF-NEXT:   return ::mlir::success(!!value);
 // DEF-NEXT: }
 // DEF-NEXT: if (mnemonic == ::test::IndexType::getMnemonic()) {
 // DEF-NEXT:   value = ::test::IndexType::parse(parser);
 // DEF-NEXT:   return ::mlir::success(!!value);
 // DEF: return {};

 def Test_Dialect: Dialect {
 // DECL-NOT: TestDialect
 // DEF-NOT: TestDialect
     let name = "TestDialect";
     let cppNamespace = "::test";
 }

 class TestType<string name> : TypeDef<Test_Dialect, name> { }

 def A_SimpleTypeA : TestType<"SimpleA"> {
 // DECL: class SimpleAType : public ::mlir::Type
 }

 def RTLValueType : Type<CPred<"isRTLValueType($_self)">, "Type"> {
   string cppType = "::mlir::Type";
 }

 // A more complex parameterized type
 def B_CompoundTypeA : TestType<"CompoundA"> {
   let summary = "A more complex parameterized type";
   let description = "This type is to test a reasonably complex type";
   let mnemonic = "cmpnd_a";
   let parameters = (
       ins
       "int":$widthOfSomething,
       "::test::SimpleTypeA": $exampleTdType,
       "SomeCppStruct": $exampleCppType,
       ArrayRefParameter<"int", "Matrix dimensions">:$dims,
       RTLValueType:$inner
   );

   let genVerifyDecl = 1;

 // DECL-LABEL: class CompoundAType : public ::mlir::Type
 // DECL: static CompoundAType getChecked(llvm::function_ref<::mlir::InFlightDiagnostic()> emitError, ::mlir::MLIRContext *context, int widthOfSomething, ::test::SimpleTypeA exampleTdType, SomeCppStruct exampleCppType, ::llvm::ArrayRef<int> dims, ::mlir::Type inner);
 // DECL: static ::mlir::LogicalResult verify(::llvm::function_ref<::mlir::InFlightDiagnostic()> emitError, int widthOfSomething, ::test::SimpleTypeA exampleTdType, SomeCppStruct exampleCppType, ::llvm::ArrayRef<int> dims, ::mlir::Type inner);
 // DECL: static constexpr ::llvm::StringLiteral getMnemonic() {
 // DECL:   return ::llvm::StringLiteral("cmpnd_a");
 // DECL: }
 // DECL: static ::mlir::Type parse(::mlir::AsmParser &parser);
 // DECL: void print(::mlir::AsmPrinter &printer) const;
 // DECL: int getWidthOfSomething() const;
 // DECL: ::test::SimpleTypeA getExampleTdType() const;
 // DECL: SomeCppStruct getExampleCppType() const;
 }

 def C_IndexType : TestType<"Index"> {
     let mnemonic = "index";

     let parameters = (
       ins
       StringRefParameter<"Label for index">:$label
     );

 // DECL-LABEL: class IndexType : public ::mlir::Type
 // DECL: static constexpr ::llvm::StringLiteral getMnemonic() {
 // DECL:   return ::llvm::StringLiteral("index");
 // DECL: }
 // DECL: static ::mlir::Type parse(::mlir::AsmParser &parser);
 // DECL: void print(::mlir::AsmPrinter &printer) const;
 }

 def D_SingleParameterType : TestType<"SingleParameter"> {
   let parameters = (
     ins
     "int": $num
   );
 // DECL-LABEL: struct SingleParameterTypeStorage;
 // DECL-LABEL: class SingleParameterType
 // DECL-NEXT:                   detail::SingleParameterTypeStorage
 }

 def E_IntegerType : TestType<"Integer"> {
     let mnemonic = "int";
     let genVerifyDecl = 1;
     let parameters = (
         ins
         "SignednessSemantics":$signedness,
         TypeParameter<"unsigned", "Bitwidth of integer">:$width
     );

 // DECL-LABEL: IntegerType : public ::mlir::Type

     let extraClassDeclaration = [{
   /// Signedness semantics.
   enum SignednessSemantics {
     Signless, /// No signedness semantics
     Signed,   /// Signed integer
     Unsigned, /// Unsigned integer
   };

   /// This extra function is necessary since it doesn't include signedness
   static IntegerType getChecked(unsigned width, Location location);

   /// Return true if this is a signless integer type.
   bool isSignless() const { return getSignedness() == Signless; }
   /// Return true if this is a signed integer type.
   bool isSigned() const { return getSignedness() == Signed; }
   /// Return true if this is an unsigned integer type.
   bool isUnsigned() const { return getSignedness() == Unsigned; }
     }];

 // DECL: /// Signedness semantics.
 // DECL-NEXT: enum SignednessSemantics {
 // DECL-NEXT:   Signless, /// No signedness semantics
 // DECL-NEXT:   Signed,   /// Signed integer
 // DECL-NEXT:   Unsigned, /// Unsigned integer
 // DECL-NEXT: };
 // DECL: /// This extra function is necessary since it doesn't include signedness
 // DECL-NEXT: static IntegerType getChecked(unsigned width, Location location);

 // DECL: /// Return true if this is a signless integer type.
 // DECL-NEXT: bool isSignless() const { return getSignedness() == Signless; }
 // DECL-NEXT: /// Return true if this is a signed integer type.
 // DECL-NEXT: bool isSigned() const { return getSignedness() == Signed; }
 // DECL-NEXT: /// Return true if this is an unsigned integer type.
 // DECL-NEXT: bool isUnsigned() const { return getSignedness() == Unsigned; }
 }
	// RUN: mlir-tblgen -gen-typedef-decls -I %S/../../include %s \| FileCheck %s --check-prefix=DECL
	// RUN: mlir-tblgen -gen-typedef-defs -I %S/../../include %s \| FileCheck %s --check-prefix=DEF

	include "mlir/IR/OpBase.td"

	// DECL: #ifdef GET_TYPEDEF_CLASSES
	// DECL: #undef GET_TYPEDEF_CLASSES

	// DECL: namespace mlir {
	// DECL: class AsmParser;
	// DECL: class AsmPrinter;
	// DECL: } // namespace mlir

	// DEF: #ifdef GET_TYPEDEF_LIST
	// DEF: #undef GET_TYPEDEF_LIST
	// DEF: ::test::SimpleAType,
	// DEF: ::test::CompoundAType,
	// DEF: ::test::IndexType,
	// DEF: ::test::SingleParameterType,
	// DEF: ::test::IntegerType

	// DEF-LABEL: ::mlir::OptionalParseResult generatedTypeParser(
	// DEF-NEXT: ::mlir::AsmParser &parser,
	// DEF-NEXT: ::llvm::StringRef mnemonic,
	// DEF-NEXT: ::mlir::Type &value) {
	// DEF: if (mnemonic == ::test::CompoundAType::getMnemonic()) {
	// DEF-NEXT: value = ::test::CompoundAType::parse(parser);
	// DEF-NEXT: return ::mlir::success(!!value);
	// DEF-NEXT: }
	// DEF-NEXT: if (mnemonic == ::test::IndexType::getMnemonic()) {
	// DEF-NEXT: value = ::test::IndexType::parse(parser);
	// DEF-NEXT: return ::mlir::success(!!value);
	// DEF: return {};

	def Test_Dialect: Dialect {
	// DECL-NOT: TestDialect
	// DEF-NOT: TestDialect
	let name = "TestDialect";
	let cppNamespace = "::test";
	}

	class TestType<string name> : TypeDef<Test_Dialect, name> { }

	def A_SimpleTypeA : TestType<"SimpleA"> {
	// DECL: class SimpleAType : public ::mlir::Type
	}

	def RTLValueType : Type<CPred<"isRTLValueType($_self)">, "Type"> {
	string cppType = "::mlir::Type";
	}

	// A more complex parameterized type
	def B_CompoundTypeA : TestType<"CompoundA"> {
	let summary = "A more complex parameterized type";
	let description = "This type is to test a reasonably complex type";
	let mnemonic = "cmpnd_a";
	let parameters = (
	ins
	"int":$widthOfSomething,
	"::test::SimpleTypeA": $exampleTdType,
	"SomeCppStruct": $exampleCppType,
	ArrayRefParameter<"int", "Matrix dimensions">:$dims,
	RTLValueType:$inner
	);

	let genVerifyDecl = 1;

	// DECL-LABEL: class CompoundAType : public ::mlir::Type
	// DECL: static CompoundAType getChecked(llvm::function_ref<::mlir::InFlightDiagnostic()> emitError, ::mlir::MLIRContext *context, int widthOfSomething, ::test::SimpleTypeA exampleTdType, SomeCppStruct exampleCppType, ::llvm::ArrayRef<int> dims, ::mlir::Type inner);
	// DECL: static ::mlir::LogicalResult verify(::llvm::function_ref<::mlir::InFlightDiagnostic()> emitError, int widthOfSomething, ::test::SimpleTypeA exampleTdType, SomeCppStruct exampleCppType, ::llvm::ArrayRef<int> dims, ::mlir::Type inner);
	// DECL: static constexpr ::llvm::StringLiteral getMnemonic() {
	// DECL: return ::llvm::StringLiteral("cmpnd_a");
	// DECL: }
	// DECL: static ::mlir::Type parse(::mlir::AsmParser &parser);
	// DECL: void print(::mlir::AsmPrinter &printer) const;
	// DECL: int getWidthOfSomething() const;
	// DECL: ::test::SimpleTypeA getExampleTdType() const;
	// DECL: SomeCppStruct getExampleCppType() const;
	}

	def C_IndexType : TestType<"Index"> {
	let mnemonic = "index";

	let parameters = (
	ins
	StringRefParameter<"Label for index">:$label
	);

	// DECL-LABEL: class IndexType : public ::mlir::Type
	// DECL: static constexpr ::llvm::StringLiteral getMnemonic() {
	// DECL: return ::llvm::StringLiteral("index");
	// DECL: }
	// DECL: static ::mlir::Type parse(::mlir::AsmParser &parser);
	// DECL: void print(::mlir::AsmPrinter &printer) const;
	}

	def D_SingleParameterType : TestType<"SingleParameter"> {
	let parameters = (
	ins
	"int": $num
	);
	// DECL-LABEL: struct SingleParameterTypeStorage;
	// DECL-LABEL: class SingleParameterType
	// DECL-NEXT: detail::SingleParameterTypeStorage
	}

	def E_IntegerType : TestType<"Integer"> {
	let mnemonic = "int";
	let genVerifyDecl = 1;
	let parameters = (
	ins
	"SignednessSemantics":$signedness,
	TypeParameter<"unsigned", "Bitwidth of integer">:$width
	);

	// DECL-LABEL: IntegerType : public ::mlir::Type

	let extraClassDeclaration = [{
	/// Signedness semantics.
	enum SignednessSemantics {
	Signless, /// No signedness semantics
	Signed, /// Signed integer
	Unsigned, /// Unsigned integer
	};

	/// This extra function is necessary since it doesn't include signedness
	static IntegerType getChecked(unsigned width, Location location);

	/// Return true if this is a signless integer type.
	bool isSignless() const { return getSignedness() == Signless; }
	/// Return true if this is a signed integer type.
	bool isSigned() const { return getSignedness() == Signed; }
	/// Return true if this is an unsigned integer type.
	bool isUnsigned() const { return getSignedness() == Unsigned; }
	}];

	// DECL: /// Signedness semantics.
	// DECL-NEXT: enum SignednessSemantics {
	// DECL-NEXT: Signless, /// No signedness semantics
	// DECL-NEXT: Signed, /// Signed integer
	// DECL-NEXT: Unsigned, /// Unsigned integer
	// DECL-NEXT: };
	// DECL: /// This extra function is necessary since it doesn't include signedness
	// DECL-NEXT: static IntegerType getChecked(unsigned width, Location location);

	// DECL: /// Return true if this is a signless integer type.
	// DECL-NEXT: bool isSignless() const { return getSignedness() == Signless; }
	// DECL-NEXT: /// Return true if this is a signed integer type.
	// DECL-NEXT: bool isSigned() const { return getSignedness() == Signed; }
	// DECL-NEXT: /// Return true if this is an unsigned integer type.
	// DECL-NEXT: bool isUnsigned() const { return getSignedness() == Unsigned; }
	}