//===- 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: 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 parseElement, bool allowEmptyList = true); /// Parse a comma separated list of elements that must have at least one entry /// in it. ParseResult parseCommaSeparatedList(function_ref parseElement); 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); //===--------------------------------------------------------------------===// // Type Parsing //===--------------------------------------------------------------------===// ParseResult parseFunctionResultTypes(SmallVectorImpl &elements); ParseResult parseTypeListNoParens(SmallVectorImpl &elements); ParseResult parseTypeListParens(SmallVectorImpl &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 &dimensions, bool allowDynamic = true); ParseResult parseXInDimensionList(); /// Parse strided layout specification. ParseResult parseStridedLayout(int64_t &offset, SmallVectorImpl &strides); // Parse a brace-delimiter list of comma-separated integers with `?` as an // unknown marker. ParseResult parseStrideList(SmallVectorImpl &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 OptionalParseResult parseOptionalAttributeWithToken(Token::Kind kind, AttributeT &attr, Type type = {}) { if (getToken().isNot(kind)) return llvm::None; if (Attribute parsedAttr = parseAttribute(type)) { attr = parsedAttr.cast(); 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 parseElement, OpAsmParser::Delimiter delimiter); private: /// 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