mlir/lib/Parser/Parser.h - llvm-project - Git at Google

 //===- Parser.h - MLIR Base Parser Class ------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef MLIR_LIB_PARSER_PARSER_H
 #define MLIR_LIB_PARSER_PARSER_H

 #include "ParserState.h"
 #include "mlir/IR/Builders.h"
 #include "mlir/IR/OpImplementation.h"

 namespace mlir {
 namespace detail {
 //===----------------------------------------------------------------------===//
 // Parser
 //===----------------------------------------------------------------------===//

 /// This class implement support for parsing global entities like attributes and
 /// types. It is intended to be subclassed by specialized subparsers that
 /// include state.
 class Parser {
 public:
   using Delimiter = OpAsmParser::Delimiter;

   Builder builder;

   Parser(ParserState &state) : builder(state.context), state(state) {}

   // Helper methods to get stuff from the parser-global state.
   ParserState &getState() const { return state; }
   MLIRContext *getContext() const { return state.context; }
   const llvm::SourceMgr &getSourceMgr() { return state.lex.getSourceMgr(); }

   /// Parse a comma-separated list of elements up until the specified end token.
   ParseResult
   parseCommaSeparatedListUntil(Token::Kind rightToken,
                                function_ref<ParseResult()> parseElement,
                                bool allowEmptyList = true);

   /// Parse a list of comma-separated items with an optional delimiter.  If a
   /// delimiter is provided, then an empty list is allowed.  If not, then at
   /// least one element will be parsed.
   ParseResult
   parseCommaSeparatedList(Delimiter delimiter,
                           function_ref<ParseResult()> parseElementFn,
                           StringRef contextMessage = StringRef());

   /// Parse a comma separated list of elements that must have at least one entry
   /// in it.
   ParseResult
   parseCommaSeparatedList(function_ref<ParseResult()> parseElementFn) {
     return parseCommaSeparatedList(Delimiter::None, parseElementFn);
   }

   ParseResult parsePrettyDialectSymbolName(StringRef &prettyName);

   // We have two forms of parsing methods - those that return a non-null
   // pointer on success, and those that return a ParseResult to indicate whether
   // they returned a failure.  The second class fills in by-reference arguments
   // as the results of their action.

   //===--------------------------------------------------------------------===//
   // Error Handling
   //===--------------------------------------------------------------------===//

   /// Emit an error and return failure.
   InFlightDiagnostic emitError(const Twine &message = {}) {
     return emitError(state.curToken.getLoc(), message);
   }
   InFlightDiagnostic emitError(llvm::SMLoc loc, const Twine &message = {});

   /// Encode the specified source location information into an attribute for
   /// attachment to the IR.
   Location getEncodedSourceLocation(llvm::SMLoc loc) {
     // If there are no active nested parsers, we can get the encoded source
     // location directly.
     if (state.parserDepth == 0)
       return state.lex.getEncodedSourceLocation(loc);
     // Otherwise, we need to re-encode it to point to the top level buffer.
     return state.symbols.topLevelLexer->getEncodedSourceLocation(
         remapLocationToTopLevelBuffer(loc));
   }

   /// Remaps the given SMLoc to the top level lexer of the parser. This is used
   /// to adjust locations of potentially nested parsers to ensure that they can
   /// be emitted properly as diagnostics.
   llvm::SMLoc remapLocationToTopLevelBuffer(llvm::SMLoc loc) {
     // If there are no active nested parsers, we can return location directly.
     SymbolState &symbols = state.symbols;
     if (state.parserDepth == 0)
       return loc;
     assert(symbols.topLevelLexer && "expected valid top-level lexer");

     // Otherwise, we need to remap the location to the main parser. This is
     // simply offseting the location onto the location of the last nested
     // parser.
     size_t offset = loc.getPointer() - state.lex.getBufferBegin();
     auto *rawLoc =
         symbols.nestedParserLocs[state.parserDepth - 1].getPointer() + offset;
     return llvm::SMLoc::getFromPointer(rawLoc);
   }

   //===--------------------------------------------------------------------===//
   // Token Parsing
   //===--------------------------------------------------------------------===//

   /// Return the current token the parser is inspecting.
   const Token &getToken() const { return state.curToken; }
   StringRef getTokenSpelling() const { return state.curToken.getSpelling(); }

   /// If the current token has the specified kind, consume it and return true.
   /// If not, return false.
   bool consumeIf(Token::Kind kind) {
     if (state.curToken.isNot(kind))
       return false;
     consumeToken(kind);
     return true;
   }

   /// Advance the current lexer onto the next token.
   void consumeToken() {
     assert(state.curToken.isNot(Token::eof, Token::error) &&
            "shouldn't advance past EOF or errors");
     state.curToken = state.lex.lexToken();
   }

   /// Advance the current lexer onto the next token, asserting what the expected
   /// current token is.  This is preferred to the above method because it leads
   /// to more self-documenting code with better checking.
   void consumeToken(Token::Kind kind) {
     assert(state.curToken.is(kind) && "consumed an unexpected token");
     consumeToken();
   }

   /// Consume the specified token if present and return success.  On failure,
   /// output a diagnostic and return failure.
   ParseResult parseToken(Token::Kind expectedToken, const Twine &message);

   /// Parse an optional integer value from the stream.
   OptionalParseResult parseOptionalInteger(APInt &result);

   /// Parse a floating point value from an integer literal token.
   ParseResult parseFloatFromIntegerLiteral(Optional<APFloat> &result,
                                            const Token &tok, bool isNegative,
                                            const llvm::fltSemantics &semantics,
                                            size_t typeSizeInBits);

   //===--------------------------------------------------------------------===//
   // Type Parsing
   //===--------------------------------------------------------------------===//

   /// Invoke the `getChecked` method of the given Attribute or Type class, using
   /// the provided location to emit errors in the case of failure. Note that
   /// unlike `OpBuilder::getType`, this method does not implicitly insert a
   /// context parameter.
   template <typename T, typename... ParamsT>
   T getChecked(llvm::SMLoc loc, ParamsT &&...params) {
     return T::getChecked([&] { return emitError(loc); },
                          std::forward<ParamsT>(params)...);
   }

   ParseResult parseFunctionResultTypes(SmallVectorImpl<Type> &elements);
   ParseResult parseTypeListNoParens(SmallVectorImpl<Type> &elements);
   ParseResult parseTypeListParens(SmallVectorImpl<Type> &elements);

   /// Optionally parse a type.
   OptionalParseResult parseOptionalType(Type &type);

   /// Parse an arbitrary type.
   Type parseType();

   /// Parse a complex type.
   Type parseComplexType();

   /// Parse an extended type.
   Type parseExtendedType();

   /// Parse a function type.
   Type parseFunctionType();

   /// Parse a memref type.
   Type parseMemRefType();

   /// Parse a non function type.
   Type parseNonFunctionType();

   /// Parse a tensor type.
   Type parseTensorType();

   /// Parse a tuple type.
   Type parseTupleType();

   /// Parse a vector type.
   VectorType parseVectorType();
   ParseResult parseDimensionListRanked(SmallVectorImpl<int64_t> &dimensions,
                                        bool allowDynamic = true);
   ParseResult parseXInDimensionList();

   /// Parse strided layout specification.
   ParseResult parseStridedLayout(int64_t &offset,
                                  SmallVectorImpl<int64_t> &strides);

   // Parse a brace-delimiter list of comma-separated integers with `?` as an
   // unknown marker.
   ParseResult parseStrideList(SmallVectorImpl<int64_t> &dimensions);

   //===--------------------------------------------------------------------===//
   // Attribute Parsing
   //===--------------------------------------------------------------------===//

   /// Parse an arbitrary attribute with an optional type.
   Attribute parseAttribute(Type type = {});

   /// Parse an optional attribute with the provided type.
   OptionalParseResult parseOptionalAttribute(Attribute &attribute,
                                              Type type = {});
   OptionalParseResult parseOptionalAttribute(ArrayAttr &attribute, Type type);
   OptionalParseResult parseOptionalAttribute(StringAttr &attribute, Type type);

   /// Parse an optional attribute that is demarcated by a specific token.
   template <typename AttributeT>
   OptionalParseResult parseOptionalAttributeWithToken(Token::Kind kind,
                                                       AttributeT &attr,
                                                       Type type = {}) {
     if (getToken().isNot(kind))
       return llvm::None;

     if (Attribute parsedAttr = parseAttribute(type)) {
       attr = parsedAttr.cast<AttributeT>();
       return success();
     }
     return failure();
   }

   /// Parse an attribute dictionary.
   ParseResult parseAttributeDict(NamedAttrList &attributes);

   /// Parse an extended attribute.
   Attribute parseExtendedAttr(Type type);

   /// Parse a float attribute.
   Attribute parseFloatAttr(Type type, bool isNegative);

   /// Parse a decimal or a hexadecimal literal, which can be either an integer
   /// or a float attribute.
   Attribute parseDecOrHexAttr(Type type, bool isNegative);

   /// Parse an opaque elements attribute.
   Attribute parseOpaqueElementsAttr(Type attrType);

   /// Parse a dense elements attribute.
   Attribute parseDenseElementsAttr(Type attrType);
   ShapedType parseElementsLiteralType(Type type);

   /// Parse a sparse elements attribute.
   Attribute parseSparseElementsAttr(Type attrType);

   //===--------------------------------------------------------------------===//
   // Location Parsing
   //===--------------------------------------------------------------------===//

   /// Parse a raw location instance.
   ParseResult parseLocationInstance(LocationAttr &loc);

   /// Parse a callsite location instance.
   ParseResult parseCallSiteLocation(LocationAttr &loc);

   /// Parse a fused location instance.
   ParseResult parseFusedLocation(LocationAttr &loc);

   /// Parse a name or FileLineCol location instance.
   ParseResult parseNameOrFileLineColLocation(LocationAttr &loc);

   //===--------------------------------------------------------------------===//
   // Affine Parsing
   //===--------------------------------------------------------------------===//

   /// Parse a reference to either an affine map, or an integer set.
   ParseResult parseAffineMapOrIntegerSetReference(AffineMap &map,
                                                   IntegerSet &set);
   ParseResult parseAffineMapReference(AffineMap &map);
   ParseResult parseIntegerSetReference(IntegerSet &set);

   /// Parse an AffineMap where the dim and symbol identifiers are SSA ids.
   ParseResult
   parseAffineMapOfSSAIds(AffineMap &map,
                          function_ref<ParseResult(bool)> parseElement,
                          Delimiter delimiter);

   /// Parse an AffineExpr where dim and symbol identifiers are SSA ids.
   ParseResult
   parseAffineExprOfSSAIds(AffineExpr &expr,
                           function_ref<ParseResult(bool)> parseElement);

 protected:
   /// The Parser is subclassed and reinstantiated.  Do not add additional
   /// non-trivial state here, add it to the ParserState class.
   ParserState &state;
 };
 } // end namespace detail
 } // end namespace mlir

 #endif // MLIR_LIB_PARSER_PARSER_H
	//===- Parser.h - MLIR Base Parser Class ------------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef MLIR_LIB_PARSER_PARSER_H
	#define MLIR_LIB_PARSER_PARSER_H

	#include "ParserState.h"
	#include "mlir/IR/Builders.h"
	#include "mlir/IR/OpImplementation.h"

	namespace mlir {
	namespace detail {
	//===----------------------------------------------------------------------===//
	// Parser
	//===----------------------------------------------------------------------===//

	/// This class implement support for parsing global entities like attributes and
	/// types. It is intended to be subclassed by specialized subparsers that
	/// include state.
	class Parser {
	public:
	using Delimiter = OpAsmParser::Delimiter;

	Builder builder;

	Parser(ParserState &state) : builder(state.context), state(state) {}

	// Helper methods to get stuff from the parser-global state.
	ParserState &getState() const { return state; }
	MLIRContext *getContext() const { return state.context; }
	const llvm::SourceMgr &getSourceMgr() { return state.lex.getSourceMgr(); }

	/// Parse a comma-separated list of elements up until the specified end token.
	ParseResult
	parseCommaSeparatedListUntil(Token::Kind rightToken,
	function_ref<ParseResult()> parseElement,
	bool allowEmptyList = true);

	/// Parse a list of comma-separated items with an optional delimiter. If a
	/// delimiter is provided, then an empty list is allowed. If not, then at
	/// least one element will be parsed.
	ParseResult
	parseCommaSeparatedList(Delimiter delimiter,
	function_ref<ParseResult()> parseElementFn,
	StringRef contextMessage = StringRef());

	/// Parse a comma separated list of elements that must have at least one entry
	/// in it.
	ParseResult
	parseCommaSeparatedList(function_ref<ParseResult()> parseElementFn) {
	return parseCommaSeparatedList(Delimiter::None, parseElementFn);
	}

	ParseResult parsePrettyDialectSymbolName(StringRef &prettyName);

	// We have two forms of parsing methods - those that return a non-null
	// pointer on success, and those that return a ParseResult to indicate whether
	// they returned a failure. The second class fills in by-reference arguments
	// as the results of their action.

	//===--------------------------------------------------------------------===//
	// Error Handling
	//===--------------------------------------------------------------------===//

	/// Emit an error and return failure.
	InFlightDiagnostic emitError(const Twine &message = {}) {
	return emitError(state.curToken.getLoc(), message);
	}
	InFlightDiagnostic emitError(llvm::SMLoc loc, const Twine &message = {});

	/// Encode the specified source location information into an attribute for
	/// attachment to the IR.
	Location getEncodedSourceLocation(llvm::SMLoc loc) {
	// If there are no active nested parsers, we can get the encoded source
	// location directly.
	if (state.parserDepth == 0)
	return state.lex.getEncodedSourceLocation(loc);
	// Otherwise, we need to re-encode it to point to the top level buffer.
	return state.symbols.topLevelLexer->getEncodedSourceLocation(
	remapLocationToTopLevelBuffer(loc));
	}

	/// Remaps the given SMLoc to the top level lexer of the parser. This is used
	/// to adjust locations of potentially nested parsers to ensure that they can
	/// be emitted properly as diagnostics.
	llvm::SMLoc remapLocationToTopLevelBuffer(llvm::SMLoc loc) {
	// If there are no active nested parsers, we can return location directly.
	SymbolState &symbols = state.symbols;
	if (state.parserDepth == 0)
	return loc;
	assert(symbols.topLevelLexer && "expected valid top-level lexer");

	// Otherwise, we need to remap the location to the main parser. This is
	// simply offseting the location onto the location of the last nested
	// parser.
	size_t offset = loc.getPointer() - state.lex.getBufferBegin();
	auto *rawLoc =
	symbols.nestedParserLocs[state.parserDepth - 1].getPointer() + offset;
	return llvm::SMLoc::getFromPointer(rawLoc);
	}

	//===--------------------------------------------------------------------===//
	// Token Parsing
	//===--------------------------------------------------------------------===//

	/// Return the current token the parser is inspecting.
	const Token &getToken() const { return state.curToken; }
	StringRef getTokenSpelling() const { return state.curToken.getSpelling(); }

	/// If the current token has the specified kind, consume it and return true.
	/// If not, return false.
	bool consumeIf(Token::Kind kind) {
	if (state.curToken.isNot(kind))
	return false;
	consumeToken(kind);
	return true;
	}

	/// Advance the current lexer onto the next token.
	void consumeToken() {
	assert(state.curToken.isNot(Token::eof, Token::error) &&
	"shouldn't advance past EOF or errors");
	state.curToken = state.lex.lexToken();
	}

	/// Advance the current lexer onto the next token, asserting what the expected
	/// current token is. This is preferred to the above method because it leads
	/// to more self-documenting code with better checking.
	void consumeToken(Token::Kind kind) {
	assert(state.curToken.is(kind) && "consumed an unexpected token");
	consumeToken();
	}

	/// Consume the specified token if present and return success. On failure,
	/// output a diagnostic and return failure.
	ParseResult parseToken(Token::Kind expectedToken, const Twine &message);

	/// Parse an optional integer value from the stream.
	OptionalParseResult parseOptionalInteger(APInt &result);

	/// Parse a floating point value from an integer literal token.
	ParseResult parseFloatFromIntegerLiteral(Optional<APFloat> &result,
	const Token &tok, bool isNegative,
	const llvm::fltSemantics &semantics,
	size_t typeSizeInBits);

	//===--------------------------------------------------------------------===//
	// Type Parsing
	//===--------------------------------------------------------------------===//

	/// Invoke the `getChecked` method of the given Attribute or Type class, using
	/// the provided location to emit errors in the case of failure. Note that
	/// unlike `OpBuilder::getType`, this method does not implicitly insert a
	/// context parameter.
	template <typename T, typename... ParamsT>
	T getChecked(llvm::SMLoc loc, ParamsT &&...params) {
	return T::getChecked([&] { return emitError(loc); },
	std::forward<ParamsT>(params)...);
	}

	ParseResult parseFunctionResultTypes(SmallVectorImpl<Type> &elements);
	ParseResult parseTypeListNoParens(SmallVectorImpl<Type> &elements);
	ParseResult parseTypeListParens(SmallVectorImpl<Type> &elements);

	/// Optionally parse a type.
	OptionalParseResult parseOptionalType(Type &type);

	/// Parse an arbitrary type.
	Type parseType();

	/// Parse a complex type.
	Type parseComplexType();

	/// Parse an extended type.
	Type parseExtendedType();

	/// Parse a function type.
	Type parseFunctionType();

	/// Parse a memref type.
	Type parseMemRefType();

	/// Parse a non function type.
	Type parseNonFunctionType();

	/// Parse a tensor type.
	Type parseTensorType();

	/// Parse a tuple type.
	Type parseTupleType();

	/// Parse a vector type.
	VectorType parseVectorType();
	ParseResult parseDimensionListRanked(SmallVectorImpl<int64_t> &dimensions,
	bool allowDynamic = true);
	ParseResult parseXInDimensionList();

	/// Parse strided layout specification.
	ParseResult parseStridedLayout(int64_t &offset,
	SmallVectorImpl<int64_t> &strides);

	// Parse a brace-delimiter list of comma-separated integers with `?` as an
	// unknown marker.
	ParseResult parseStrideList(SmallVectorImpl<int64_t> &dimensions);

	//===--------------------------------------------------------------------===//
	// Attribute Parsing
	//===--------------------------------------------------------------------===//

	/// Parse an arbitrary attribute with an optional type.
	Attribute parseAttribute(Type type = {});

	/// Parse an optional attribute with the provided type.
	OptionalParseResult parseOptionalAttribute(Attribute &attribute,
	Type type = {});
	OptionalParseResult parseOptionalAttribute(ArrayAttr &attribute, Type type);
	OptionalParseResult parseOptionalAttribute(StringAttr &attribute, Type type);

	/// Parse an optional attribute that is demarcated by a specific token.
	template <typename AttributeT>
	OptionalParseResult parseOptionalAttributeWithToken(Token::Kind kind,
	AttributeT &attr,
	Type type = {}) {
	if (getToken().isNot(kind))
	return llvm::None;

	if (Attribute parsedAttr = parseAttribute(type)) {
	attr = parsedAttr.cast<AttributeT>();
	return success();
	}
	return failure();
	}

	/// Parse an attribute dictionary.
	ParseResult parseAttributeDict(NamedAttrList &attributes);

	/// Parse an extended attribute.
	Attribute parseExtendedAttr(Type type);

	/// Parse a float attribute.
	Attribute parseFloatAttr(Type type, bool isNegative);

	/// Parse a decimal or a hexadecimal literal, which can be either an integer
	/// or a float attribute.
	Attribute parseDecOrHexAttr(Type type, bool isNegative);

	/// Parse an opaque elements attribute.
	Attribute parseOpaqueElementsAttr(Type attrType);

	/// Parse a dense elements attribute.
	Attribute parseDenseElementsAttr(Type attrType);
	ShapedType parseElementsLiteralType(Type type);

	/// Parse a sparse elements attribute.
	Attribute parseSparseElementsAttr(Type attrType);

	//===--------------------------------------------------------------------===//
	// Location Parsing
	//===--------------------------------------------------------------------===//

	/// Parse a raw location instance.
	ParseResult parseLocationInstance(LocationAttr &loc);

	/// Parse a callsite location instance.
	ParseResult parseCallSiteLocation(LocationAttr &loc);

	/// Parse a fused location instance.
	ParseResult parseFusedLocation(LocationAttr &loc);

	/// Parse a name or FileLineCol location instance.
	ParseResult parseNameOrFileLineColLocation(LocationAttr &loc);

	//===--------------------------------------------------------------------===//
	// Affine Parsing
	//===--------------------------------------------------------------------===//

	/// Parse a reference to either an affine map, or an integer set.
	ParseResult parseAffineMapOrIntegerSetReference(AffineMap &map,
	IntegerSet &set);
	ParseResult parseAffineMapReference(AffineMap &map);
	ParseResult parseIntegerSetReference(IntegerSet &set);

	/// Parse an AffineMap where the dim and symbol identifiers are SSA ids.
	ParseResult
	parseAffineMapOfSSAIds(AffineMap &map,
	function_ref<ParseResult(bool)> parseElement,
	Delimiter delimiter);

	/// Parse an AffineExpr where dim and symbol identifiers are SSA ids.
	ParseResult
	parseAffineExprOfSSAIds(AffineExpr &expr,
	function_ref<ParseResult(bool)> parseElement);

	protected:
	/// The Parser is subclassed and reinstantiated. Do not add additional
	/// non-trivial state here, add it to the ParserState class.
	ParserState &state;
	};
	} // end namespace detail
	} // end namespace mlir

	#endif // MLIR_LIB_PARSER_PARSER_H