mlir/lib/Parser/DialectSymbolParser.cpp - llvm-project - Git at Google

 //===- DialectSymbolParser.cpp - MLIR Dialect Symbol Parser  --------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements the parser for the dialect symbols, such as extended
 // attributes and types.
 //
 //===----------------------------------------------------------------------===//

 #include "Parser.h"
 #include "mlir/IR/BuiltinTypes.h"
 #include "mlir/IR/Dialect.h"
 #include "mlir/IR/DialectImplementation.h"
 #include "llvm/Support/SourceMgr.h"

 using namespace mlir;
 using namespace mlir::detail;
 using llvm::MemoryBuffer;
 using llvm::SMLoc;
 using llvm::SourceMgr;

 namespace {
 /// This class provides the main implementation of the DialectAsmParser that
 /// allows for dialects to parse attributes and types. This allows for dialect
 /// hooking into the main MLIR parsing logic.
 class CustomDialectAsmParser : public DialectAsmParser {
 public:
   CustomDialectAsmParser(StringRef fullSpec, Parser &parser)
       : fullSpec(fullSpec), nameLoc(parser.getToken().getLoc()),
         parser(parser) {}
   ~CustomDialectAsmParser() override {}

   /// Emit a diagnostic at the specified location and return failure.
   InFlightDiagnostic emitError(llvm::SMLoc loc, const Twine &message) override {
     return parser.emitError(loc, message);
   }

   /// Return a builder which provides useful access to MLIRContext, global
   /// objects like types and attributes.
   Builder &getBuilder() const override { return parser.builder; }

   /// Get the location of the next token and store it into the argument.  This
   /// always succeeds.
   llvm::SMLoc getCurrentLocation() override {
     return parser.getToken().getLoc();
   }

   /// Return the location of the original name token.
   llvm::SMLoc getNameLoc() const override { return nameLoc; }

   /// Re-encode the given source location as an MLIR location and return it.
   Location getEncodedSourceLoc(llvm::SMLoc loc) override {
     return parser.getEncodedSourceLocation(loc);
   }

   /// Returns the full specification of the symbol being parsed. This allows
   /// for using a separate parser if necessary.
   StringRef getFullSymbolSpec() const override { return fullSpec; }

   /// Parse a floating point value from the stream.
   ParseResult parseFloat(double &result) override {
     bool negative = parser.consumeIf(Token::minus);
     Token curTok = parser.getToken();

     // Check for a floating point value.
     if (curTok.is(Token::floatliteral)) {
       auto val = curTok.getFloatingPointValue();
       if (!val.hasValue())
         return emitError(curTok.getLoc(), "floating point value too large");
       parser.consumeToken(Token::floatliteral);
       result = negative ? -*val : *val;
       return success();
     }

     // TODO: support hex floating point values.
     return emitError(getCurrentLocation(), "expected floating point literal");
   }

   /// Parse an optional integer value from the stream.
   OptionalParseResult parseOptionalInteger(uint64_t &result) override {
     return parser.parseOptionalInteger(result);
   }

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

   /// Parse a `->` token.
   ParseResult parseArrow() override {
     return parser.parseToken(Token::arrow, "expected '->'");
   }

   /// Parses a `->` if present.
   ParseResult parseOptionalArrow() override {
     return success(parser.consumeIf(Token::arrow));
   }

   /// Parse a '{' token.
   ParseResult parseLBrace() override {
     return parser.parseToken(Token::l_brace, "expected '{'");
   }

   /// Parse a '{' token if present
   ParseResult parseOptionalLBrace() override {
     return success(parser.consumeIf(Token::l_brace));
   }

   /// Parse a `}` token.
   ParseResult parseRBrace() override {
     return parser.parseToken(Token::r_brace, "expected '}'");
   }

   /// Parse a `}` token if present
   ParseResult parseOptionalRBrace() override {
     return success(parser.consumeIf(Token::r_brace));
   }

   /// Parse a `:` token.
   ParseResult parseColon() override {
     return parser.parseToken(Token::colon, "expected ':'");
   }

   /// Parse a `:` token if present.
   ParseResult parseOptionalColon() override {
     return success(parser.consumeIf(Token::colon));
   }

   /// Parse a `,` token.
   ParseResult parseComma() override {
     return parser.parseToken(Token::comma, "expected ','");
   }

   /// Parse a `,` token if present.
   ParseResult parseOptionalComma() override {
     return success(parser.consumeIf(Token::comma));
   }

   /// Parses a `...` if present.
   ParseResult parseOptionalEllipsis() override {
     return success(parser.consumeIf(Token::ellipsis));
   }

   /// Parse a `=` token.
   ParseResult parseEqual() override {
     return parser.parseToken(Token::equal, "expected '='");
   }

   /// Parse a `=` token if present.
   ParseResult parseOptionalEqual() override {
     return success(parser.consumeIf(Token::equal));
   }

   /// Parse a '<' token.
   ParseResult parseLess() override {
     return parser.parseToken(Token::less, "expected '<'");
   }

   /// Parse a `<` token if present.
   ParseResult parseOptionalLess() override {
     return success(parser.consumeIf(Token::less));
   }

   /// Parse a '>' token.
   ParseResult parseGreater() override {
     return parser.parseToken(Token::greater, "expected '>'");
   }

   /// Parse a `>` token if present.
   ParseResult parseOptionalGreater() override {
     return success(parser.consumeIf(Token::greater));
   }

   /// Parse a `(` token.
   ParseResult parseLParen() override {
     return parser.parseToken(Token::l_paren, "expected '('");
   }

   /// Parses a '(' if present.
   ParseResult parseOptionalLParen() override {
     return success(parser.consumeIf(Token::l_paren));
   }

   /// Parse a `)` token.
   ParseResult parseRParen() override {
     return parser.parseToken(Token::r_paren, "expected ')'");
   }

   /// Parses a ')' if present.
   ParseResult parseOptionalRParen() override {
     return success(parser.consumeIf(Token::r_paren));
   }

   /// Parse a `[` token.
   ParseResult parseLSquare() override {
     return parser.parseToken(Token::l_square, "expected '['");
   }

   /// Parses a '[' if present.
   ParseResult parseOptionalLSquare() override {
     return success(parser.consumeIf(Token::l_square));
   }

   /// Parse a `]` token.
   ParseResult parseRSquare() override {
     return parser.parseToken(Token::r_square, "expected ']'");
   }

   /// Parses a ']' if present.
   ParseResult parseOptionalRSquare() override {
     return success(parser.consumeIf(Token::r_square));
   }

   /// Parses a '?' if present.
   ParseResult parseOptionalQuestion() override {
     return success(parser.consumeIf(Token::question));
   }

   /// Parses a '*' if present.
   ParseResult parseOptionalStar() override {
     return success(parser.consumeIf(Token::star));
   }

   /// Parses a quoted string token if present.
   ParseResult parseOptionalString(StringRef *string) override {
     if (!parser.getToken().is(Token::string))
       return failure();

     if (string)
       *string = parser.getTokenSpelling().drop_front().drop_back();
     parser.consumeToken();
     return success();
   }

   /// Returns true if the current token corresponds to a keyword.
   bool isCurrentTokenAKeyword() const {
     return parser.getToken().is(Token::bare_identifier) ||
            parser.getToken().isKeyword();
   }

   /// Parse the given keyword if present.
   ParseResult parseOptionalKeyword(StringRef keyword) override {
     // Check that the current token has the same spelling.
     if (!isCurrentTokenAKeyword() || parser.getTokenSpelling() != keyword)
       return failure();
     parser.consumeToken();
     return success();
   }

   /// Parse a keyword, if present, into 'keyword'.
   ParseResult parseOptionalKeyword(StringRef *keyword) override {
     // Check that the current token is a keyword.
     if (!isCurrentTokenAKeyword())
       return failure();

     *keyword = parser.getTokenSpelling();
     parser.consumeToken();
     return success();
   }

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

   /// Parse an arbitrary attribute and return it in result.
   ParseResult parseAttribute(Attribute &result, Type type) override {
     result = parser.parseAttribute(type);
     return success(static_cast<bool>(result));
   }

   /// Parse an affine map instance into 'map'.
   ParseResult parseAffineMap(AffineMap &map) override {
     return parser.parseAffineMapReference(map);
   }

   /// Parse an integer set instance into 'set'.
   ParseResult printIntegerSet(IntegerSet &set) override {
     return parser.parseIntegerSetReference(set);
   }

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

   ParseResult parseType(Type &result) override {
     result = parser.parseType();
     return success(static_cast<bool>(result));
   }

   ParseResult parseDimensionList(SmallVectorImpl<int64_t> &dimensions,
                                  bool allowDynamic) override {
     return parser.parseDimensionListRanked(dimensions, allowDynamic);
   }

   OptionalParseResult parseOptionalType(Type &result) override {
     return parser.parseOptionalType(result);
   }

 private:
   /// The full symbol specification.
   StringRef fullSpec;

   /// The source location of the dialect symbol.
   SMLoc nameLoc;

   /// The main parser.
   Parser &parser;
 };
 } // namespace

 /// Parse the body of a pretty dialect symbol, which starts and ends with <>'s,
 /// and may be recursive.  Return with the 'prettyName' StringRef encompassing
 /// the entire pretty name.
 ///
 ///   pretty-dialect-sym-body ::= '<' pretty-dialect-sym-contents+ '>'
 ///   pretty-dialect-sym-contents ::= pretty-dialect-sym-body
 ///                                  | '(' pretty-dialect-sym-contents+ ')'
 ///                                  | '[' pretty-dialect-sym-contents+ ']'
 ///                                  | '{' pretty-dialect-sym-contents+ '}'
 ///                                  | '[^[<({>\])}\0]+'
 ///
 ParseResult Parser::parsePrettyDialectSymbolName(StringRef &prettyName) {
   // Pretty symbol names are a relatively unstructured format that contains a
   // series of properly nested punctuation, with anything else in the middle.
   // Scan ahead to find it and consume it if successful, otherwise emit an
   // error.
   auto *curPtr = getTokenSpelling().data();

   SmallVector<char, 8> nestedPunctuation;

   // Scan over the nested punctuation, bailing out on error and consuming until
   // we find the end.  We know that we're currently looking at the '<', so we
   // can go until we find the matching '>' character.
   assert(*curPtr == '<');
   do {
     char c = *curPtr++;
     switch (c) {
     case '\0':
       // This also handles the EOF case.
       return emitError("unexpected nul or EOF in pretty dialect name");
     case '<':
     case '[':
     case '(':
     case '{':
       nestedPunctuation.push_back(c);
       continue;

     case '-':
       // The sequence `->` is treated as special token.
       if (*curPtr == '>')
         ++curPtr;
       continue;

     case '>':
       if (nestedPunctuation.pop_back_val() != '<')
         return emitError("unbalanced '>' character in pretty dialect name");
       break;
     case ']':
       if (nestedPunctuation.pop_back_val() != '[')
         return emitError("unbalanced ']' character in pretty dialect name");
       break;
     case ')':
       if (nestedPunctuation.pop_back_val() != '(')
         return emitError("unbalanced ')' character in pretty dialect name");
       break;
     case '}':
       if (nestedPunctuation.pop_back_val() != '{')
         return emitError("unbalanced '}' character in pretty dialect name");
       break;

     default:
       continue;
     }
   } while (!nestedPunctuation.empty());

   // Ok, we succeeded, remember where we stopped, reset the lexer to know it is
   // consuming all this stuff, and return.
   state.lex.resetPointer(curPtr);

   unsigned length = curPtr - prettyName.begin();
   prettyName = StringRef(prettyName.begin(), length);
   consumeToken();
   return success();
 }

 /// Parse an extended dialect symbol.
 template <typename Symbol, typename SymbolAliasMap, typename CreateFn>
 static Symbol parseExtendedSymbol(Parser &p, Token::Kind identifierTok,
                                   SymbolAliasMap &aliases,
                                   CreateFn &&createSymbol) {
   // Parse the dialect namespace.
   StringRef identifier = p.getTokenSpelling().drop_front();
   auto loc = p.getToken().getLoc();
   p.consumeToken(identifierTok);

   // If there is no '<' token following this, and if the typename contains no
   // dot, then we are parsing a symbol alias.
   if (p.getToken().isNot(Token::less) && !identifier.contains('.')) {
     // Check for an alias for this type.
     auto aliasIt = aliases.find(identifier);
     if (aliasIt == aliases.end())
       return (p.emitError("undefined symbol alias id '" + identifier + "'"),
               nullptr);
     return aliasIt->second;
   }

   // Otherwise, we are parsing a dialect-specific symbol.  If the name contains
   // a dot, then this is the "pretty" form.  If not, it is the verbose form that
   // looks like <"...">.
   std::string symbolData;
   auto dialectName = identifier;

   // Handle the verbose form, where "identifier" is a simple dialect name.
   if (!identifier.contains('.')) {
     // Consume the '<'.
     if (p.parseToken(Token::less, "expected '<' in dialect type"))
       return nullptr;

     // Parse the symbol specific data.
     if (p.getToken().isNot(Token::string))
       return (p.emitError("expected string literal data in dialect symbol"),
               nullptr);
     symbolData = p.getToken().getStringValue();
     loc = llvm::SMLoc::getFromPointer(p.getToken().getLoc().getPointer() + 1);
     p.consumeToken(Token::string);

     // Consume the '>'.
     if (p.parseToken(Token::greater, "expected '>' in dialect symbol"))
       return nullptr;
   } else {
     // Ok, the dialect name is the part of the identifier before the dot, the
     // part after the dot is the dialect's symbol, or the start thereof.
     auto dotHalves = identifier.split('.');
     dialectName = dotHalves.first;
     auto prettyName = dotHalves.second;
     loc = llvm::SMLoc::getFromPointer(prettyName.data());

     // If the dialect's symbol is followed immediately by a <, then lex the body
     // of it into prettyName.
     if (p.getToken().is(Token::less) &&
         prettyName.bytes_end() == p.getTokenSpelling().bytes_begin()) {
       if (p.parsePrettyDialectSymbolName(prettyName))
         return nullptr;
     }

     symbolData = prettyName.str();
   }

   // Record the name location of the type remapped to the top level buffer.
   llvm::SMLoc locInTopLevelBuffer = p.remapLocationToTopLevelBuffer(loc);
   p.getState().symbols.nestedParserLocs.push_back(locInTopLevelBuffer);

   // Call into the provided symbol construction function.
   Symbol sym = createSymbol(dialectName, symbolData, loc);

   // Pop the last parser location.
   p.getState().symbols.nestedParserLocs.pop_back();
   return sym;
 }

 /// Parses a symbol, of type 'T', and returns it if parsing was successful. If
 /// parsing failed, nullptr is returned. The number of bytes read from the input
 /// string is returned in 'numRead'.
 template <typename T, typename ParserFn>
 static T parseSymbol(StringRef inputStr, MLIRContext *context,
                      SymbolState &symbolState, ParserFn &&parserFn,
                      size_t *numRead = nullptr) {
   SourceMgr sourceMgr;
   auto memBuffer = MemoryBuffer::getMemBuffer(
       inputStr, /*BufferName=*/"<mlir_parser_buffer>",
       /*RequiresNullTerminator=*/false);
   sourceMgr.AddNewSourceBuffer(std::move(memBuffer), SMLoc());
   ParserState state(sourceMgr, context, symbolState);
   Parser parser(state);

   Token startTok = parser.getToken();
   T symbol = parserFn(parser);
   if (!symbol)
     return T();

   // If 'numRead' is valid, then provide the number of bytes that were read.
   Token endTok = parser.getToken();
   if (numRead) {
     *numRead = static_cast<size_t>(endTok.getLoc().getPointer() -
                                    startTok.getLoc().getPointer());

     // Otherwise, ensure that all of the tokens were parsed.
   } else if (startTok.getLoc() != endTok.getLoc() && endTok.isNot(Token::eof)) {
     parser.emitError(endTok.getLoc(), "encountered unexpected token");
     return T();
   }
   return symbol;
 }

 /// Parse an extended attribute.
 ///
 ///   extended-attribute ::= (dialect-attribute | attribute-alias)
 ///   dialect-attribute  ::= `#` dialect-namespace `<` `"` attr-data `"` `>`
 ///   dialect-attribute  ::= `#` alias-name pretty-dialect-sym-body?
 ///   attribute-alias    ::= `#` alias-name
 ///
 Attribute Parser::parseExtendedAttr(Type type) {
   Attribute attr = parseExtendedSymbol<Attribute>(
       *this, Token::hash_identifier, state.symbols.attributeAliasDefinitions,
       [&](StringRef dialectName, StringRef symbolData,
           llvm::SMLoc loc) -> Attribute {
         // Parse an optional trailing colon type.
         Type attrType = type;
         if (consumeIf(Token::colon) && !(attrType = parseType()))
           return Attribute();

         // If we found a registered dialect, then ask it to parse the attribute.
         if (Dialect *dialect =
                 builder.getContext()->getOrLoadDialect(dialectName)) {
           return parseSymbol<Attribute>(
               symbolData, state.context, state.symbols, [&](Parser &parser) {
                 CustomDialectAsmParser customParser(symbolData, parser);
                 return dialect->parseAttribute(customParser, attrType);
               });
         }

         // Otherwise, form a new opaque attribute.
         return OpaqueAttr::getChecked(
             Identifier::get(dialectName, state.context), symbolData,
             attrType ? attrType : NoneType::get(state.context),
             getEncodedSourceLocation(loc));
       });

   // Ensure that the attribute has the same type as requested.
   if (attr && type && attr.getType() != type) {
     emitError("attribute type different than expected: expected ")
         << type << ", but got " << attr.getType();
     return nullptr;
   }
   return attr;
 }

 /// Parse an extended type.
 ///
 ///   extended-type ::= (dialect-type | type-alias)
 ///   dialect-type  ::= `!` dialect-namespace `<` `"` type-data `"` `>`
 ///   dialect-type  ::= `!` alias-name pretty-dialect-attribute-body?
 ///   type-alias    ::= `!` alias-name
 ///
 Type Parser::parseExtendedType() {
   return parseExtendedSymbol<Type>(
       *this, Token::exclamation_identifier, state.symbols.typeAliasDefinitions,
       [&](StringRef dialectName, StringRef symbolData,
           llvm::SMLoc loc) -> Type {
         // If we found a registered dialect, then ask it to parse the type.
         auto *dialect = state.context->getOrLoadDialect(dialectName);

         if (dialect) {
           return parseSymbol<Type>(
               symbolData, state.context, state.symbols, [&](Parser &parser) {
                 CustomDialectAsmParser customParser(symbolData, parser);
                 return dialect->parseType(customParser);
               });
         }

         // Otherwise, form a new opaque type.
         return OpaqueType::getChecked(
             getEncodedSourceLocation(loc),
             Identifier::get(dialectName, state.context), symbolData);
       });
 }

 //===----------------------------------------------------------------------===//
 // mlir::parseAttribute/parseType
 //===----------------------------------------------------------------------===//

 /// Parses a symbol, of type 'T', and returns it if parsing was successful. If
 /// parsing failed, nullptr is returned. The number of bytes read from the input
 /// string is returned in 'numRead'.
 template <typename T, typename ParserFn>
 static T parseSymbol(StringRef inputStr, MLIRContext *context, size_t &numRead,
                      ParserFn &&parserFn) {
   SymbolState aliasState;
   return parseSymbol<T>(
       inputStr, context, aliasState,
       [&](Parser &parser) {
         SourceMgrDiagnosticHandler handler(
             const_cast<llvm::SourceMgr &>(parser.getSourceMgr()),
             parser.getContext());
         return parserFn(parser);
       },
       &numRead);
 }

 Attribute mlir::parseAttribute(StringRef attrStr, MLIRContext *context) {
   size_t numRead = 0;
   return parseAttribute(attrStr, context, numRead);
 }
 Attribute mlir::parseAttribute(StringRef attrStr, Type type) {
   size_t numRead = 0;
   return parseAttribute(attrStr, type, numRead);
 }

 Attribute mlir::parseAttribute(StringRef attrStr, MLIRContext *context,
                                size_t &numRead) {
   return parseSymbol<Attribute>(attrStr, context, numRead, [](Parser &parser) {
     return parser.parseAttribute();
   });
 }
 Attribute mlir::parseAttribute(StringRef attrStr, Type type, size_t &numRead) {
   return parseSymbol<Attribute>(
       attrStr, type.getContext(), numRead,
       [type](Parser &parser) { return parser.parseAttribute(type); });
 }

 Type mlir::parseType(StringRef typeStr, MLIRContext *context) {
   size_t numRead = 0;
   return parseType(typeStr, context, numRead);
 }

 Type mlir::parseType(StringRef typeStr, MLIRContext *context, size_t &numRead) {
   return parseSymbol<Type>(typeStr, context, numRead,
                            [](Parser &parser) { return parser.parseType(); });
 }
	//===- DialectSymbolParser.cpp - MLIR Dialect Symbol Parser --------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the parser for the dialect symbols, such as extended
	// attributes and types.
	//
	//===----------------------------------------------------------------------===//

	#include "Parser.h"
	#include "mlir/IR/BuiltinTypes.h"
	#include "mlir/IR/Dialect.h"
	#include "mlir/IR/DialectImplementation.h"
	#include "llvm/Support/SourceMgr.h"

	using namespace mlir;
	using namespace mlir::detail;
	using llvm::MemoryBuffer;
	using llvm::SMLoc;
	using llvm::SourceMgr;

	namespace {
	/// This class provides the main implementation of the DialectAsmParser that
	/// allows for dialects to parse attributes and types. This allows for dialect
	/// hooking into the main MLIR parsing logic.
	class CustomDialectAsmParser : public DialectAsmParser {
	public:
	CustomDialectAsmParser(StringRef fullSpec, Parser &parser)
	: fullSpec(fullSpec), nameLoc(parser.getToken().getLoc()),
	parser(parser) {}
	~CustomDialectAsmParser() override {}

	/// Emit a diagnostic at the specified location and return failure.
	InFlightDiagnostic emitError(llvm::SMLoc loc, const Twine &message) override {
	return parser.emitError(loc, message);
	}

	/// Return a builder which provides useful access to MLIRContext, global
	/// objects like types and attributes.
	Builder &getBuilder() const override { return parser.builder; }

	/// Get the location of the next token and store it into the argument. This
	/// always succeeds.
	llvm::SMLoc getCurrentLocation() override {
	return parser.getToken().getLoc();
	}

	/// Return the location of the original name token.
	llvm::SMLoc getNameLoc() const override { return nameLoc; }

	/// Re-encode the given source location as an MLIR location and return it.
	Location getEncodedSourceLoc(llvm::SMLoc loc) override {
	return parser.getEncodedSourceLocation(loc);
	}

	/// Returns the full specification of the symbol being parsed. This allows
	/// for using a separate parser if necessary.
	StringRef getFullSymbolSpec() const override { return fullSpec; }

	/// Parse a floating point value from the stream.
	ParseResult parseFloat(double &result) override {
	bool negative = parser.consumeIf(Token::minus);
	Token curTok = parser.getToken();

	// Check for a floating point value.
	if (curTok.is(Token::floatliteral)) {
	auto val = curTok.getFloatingPointValue();
	if (!val.hasValue())
	return emitError(curTok.getLoc(), "floating point value too large");
	parser.consumeToken(Token::floatliteral);
	result = negative ? -val : val;
	return success();
	}

	// TODO: support hex floating point values.
	return emitError(getCurrentLocation(), "expected floating point literal");
	}

	/// Parse an optional integer value from the stream.
	OptionalParseResult parseOptionalInteger(uint64_t &result) override {
	return parser.parseOptionalInteger(result);
	}

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

	/// Parse a `->` token.
	ParseResult parseArrow() override {
	return parser.parseToken(Token::arrow, "expected '->'");
	}

	/// Parses a `->` if present.
	ParseResult parseOptionalArrow() override {
	return success(parser.consumeIf(Token::arrow));
	}

	/// Parse a '{' token.
	ParseResult parseLBrace() override {
	return parser.parseToken(Token::l_brace, "expected '{'");
	}

	/// Parse a '{' token if present
	ParseResult parseOptionalLBrace() override {
	return success(parser.consumeIf(Token::l_brace));
	}

	/// Parse a `}` token.
	ParseResult parseRBrace() override {
	return parser.parseToken(Token::r_brace, "expected '}'");
	}

	/// Parse a `}` token if present
	ParseResult parseOptionalRBrace() override {
	return success(parser.consumeIf(Token::r_brace));
	}

	/// Parse a `:` token.
	ParseResult parseColon() override {
	return parser.parseToken(Token::colon, "expected ':'");
	}

	/// Parse a `:` token if present.
	ParseResult parseOptionalColon() override {
	return success(parser.consumeIf(Token::colon));
	}

	/// Parse a `,` token.
	ParseResult parseComma() override {
	return parser.parseToken(Token::comma, "expected ','");
	}

	/// Parse a `,` token if present.
	ParseResult parseOptionalComma() override {
	return success(parser.consumeIf(Token::comma));
	}

	/// Parses a `...` if present.
	ParseResult parseOptionalEllipsis() override {
	return success(parser.consumeIf(Token::ellipsis));
	}

	/// Parse a `=` token.
	ParseResult parseEqual() override {
	return parser.parseToken(Token::equal, "expected '='");
	}

	/// Parse a `=` token if present.
	ParseResult parseOptionalEqual() override {
	return success(parser.consumeIf(Token::equal));
	}

	/// Parse a '<' token.
	ParseResult parseLess() override {
	return parser.parseToken(Token::less, "expected '<'");
	}

	/// Parse a `<` token if present.
	ParseResult parseOptionalLess() override {
	return success(parser.consumeIf(Token::less));
	}

	/// Parse a '>' token.
	ParseResult parseGreater() override {
	return parser.parseToken(Token::greater, "expected '>'");
	}

	/// Parse a `>` token if present.
	ParseResult parseOptionalGreater() override {
	return success(parser.consumeIf(Token::greater));
	}

	/// Parse a `(` token.
	ParseResult parseLParen() override {
	return parser.parseToken(Token::l_paren, "expected '('");
	}

	/// Parses a '(' if present.
	ParseResult parseOptionalLParen() override {
	return success(parser.consumeIf(Token::l_paren));
	}

	/// Parse a `)` token.
	ParseResult parseRParen() override {
	return parser.parseToken(Token::r_paren, "expected ')'");
	}

	/// Parses a ')' if present.
	ParseResult parseOptionalRParen() override {
	return success(parser.consumeIf(Token::r_paren));
	}

	/// Parse a `[` token.
	ParseResult parseLSquare() override {
	return parser.parseToken(Token::l_square, "expected '['");
	}

	/// Parses a '[' if present.
	ParseResult parseOptionalLSquare() override {
	return success(parser.consumeIf(Token::l_square));
	}

	/// Parse a `]` token.
	ParseResult parseRSquare() override {
	return parser.parseToken(Token::r_square, "expected ']'");
	}

	/// Parses a ']' if present.
	ParseResult parseOptionalRSquare() override {
	return success(parser.consumeIf(Token::r_square));
	}

	/// Parses a '?' if present.
	ParseResult parseOptionalQuestion() override {
	return success(parser.consumeIf(Token::question));
	}

	/// Parses a '*' if present.
	ParseResult parseOptionalStar() override {
	return success(parser.consumeIf(Token::star));
	}

	/// Parses a quoted string token if present.
	ParseResult parseOptionalString(StringRef *string) override {
	if (!parser.getToken().is(Token::string))
	return failure();

	if (string)
	*string = parser.getTokenSpelling().drop_front().drop_back();
	parser.consumeToken();
	return success();
	}

	/// Returns true if the current token corresponds to a keyword.
	bool isCurrentTokenAKeyword() const {
	return parser.getToken().is(Token::bare_identifier) \|\|
	parser.getToken().isKeyword();
	}

	/// Parse the given keyword if present.
	ParseResult parseOptionalKeyword(StringRef keyword) override {
	// Check that the current token has the same spelling.
	if (!isCurrentTokenAKeyword() \|\| parser.getTokenSpelling() != keyword)
	return failure();
	parser.consumeToken();
	return success();
	}

	/// Parse a keyword, if present, into 'keyword'.
	ParseResult parseOptionalKeyword(StringRef *keyword) override {
	// Check that the current token is a keyword.
	if (!isCurrentTokenAKeyword())
	return failure();

	*keyword = parser.getTokenSpelling();
	parser.consumeToken();
	return success();
	}

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

	/// Parse an arbitrary attribute and return it in result.
	ParseResult parseAttribute(Attribute &result, Type type) override {
	result = parser.parseAttribute(type);
	return success(static_cast<bool>(result));
	}

	/// Parse an affine map instance into 'map'.
	ParseResult parseAffineMap(AffineMap &map) override {
	return parser.parseAffineMapReference(map);
	}

	/// Parse an integer set instance into 'set'.
	ParseResult printIntegerSet(IntegerSet &set) override {
	return parser.parseIntegerSetReference(set);
	}

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

	ParseResult parseType(Type &result) override {
	result = parser.parseType();
	return success(static_cast<bool>(result));
	}

	ParseResult parseDimensionList(SmallVectorImpl<int64_t> &dimensions,
	bool allowDynamic) override {
	return parser.parseDimensionListRanked(dimensions, allowDynamic);
	}

	OptionalParseResult parseOptionalType(Type &result) override {
	return parser.parseOptionalType(result);
	}

	private:
	/// The full symbol specification.
	StringRef fullSpec;

	/// The source location of the dialect symbol.
	SMLoc nameLoc;

	/// The main parser.
	Parser &parser;
	};
	} // namespace

	/// Parse the body of a pretty dialect symbol, which starts and ends with <>'s,
	/// and may be recursive. Return with the 'prettyName' StringRef encompassing
	/// the entire pretty name.
	///
	/// pretty-dialect-sym-body ::= '<' pretty-dialect-sym-contents+ '>'
	/// pretty-dialect-sym-contents ::= pretty-dialect-sym-body
	/// \| '(' pretty-dialect-sym-contents+ ')'
	/// \| '[' pretty-dialect-sym-contents+ ']'
	/// \| '{' pretty-dialect-sym-contents+ '}'
	/// \| '[^[<({>\])}\0]+'
	///
	ParseResult Parser::parsePrettyDialectSymbolName(StringRef &prettyName) {
	// Pretty symbol names are a relatively unstructured format that contains a
	// series of properly nested punctuation, with anything else in the middle.
	// Scan ahead to find it and consume it if successful, otherwise emit an
	// error.
	auto *curPtr = getTokenSpelling().data();

	SmallVector<char, 8> nestedPunctuation;

	// Scan over the nested punctuation, bailing out on error and consuming until
	// we find the end. We know that we're currently looking at the '<', so we
	// can go until we find the matching '>' character.
	assert(*curPtr == '<');
	do {
	char c = *curPtr++;
	switch (c) {
	case '\0':
	// This also handles the EOF case.
	return emitError("unexpected nul or EOF in pretty dialect name");
	case '<':
	case '[':
	case '(':
	case '{':
	nestedPunctuation.push_back(c);
	continue;

	case '-':
	// The sequence `->` is treated as special token.
	if (*curPtr == '>')
	++curPtr;
	continue;

	case '>':
	if (nestedPunctuation.pop_back_val() != '<')
	return emitError("unbalanced '>' character in pretty dialect name");
	break;
	case ']':
	if (nestedPunctuation.pop_back_val() != '[')
	return emitError("unbalanced ']' character in pretty dialect name");
	break;
	case ')':
	if (nestedPunctuation.pop_back_val() != '(')
	return emitError("unbalanced ')' character in pretty dialect name");
	break;
	case '}':
	if (nestedPunctuation.pop_back_val() != '{')
	return emitError("unbalanced '}' character in pretty dialect name");
	break;

	default:
	continue;
	}
	} while (!nestedPunctuation.empty());

	// Ok, we succeeded, remember where we stopped, reset the lexer to know it is
	// consuming all this stuff, and return.
	state.lex.resetPointer(curPtr);

	unsigned length = curPtr - prettyName.begin();
	prettyName = StringRef(prettyName.begin(), length);
	consumeToken();
	return success();
	}

	/// Parse an extended dialect symbol.
	template <typename Symbol, typename SymbolAliasMap, typename CreateFn>
	static Symbol parseExtendedSymbol(Parser &p, Token::Kind identifierTok,
	SymbolAliasMap &aliases,
	CreateFn &&createSymbol) {
	// Parse the dialect namespace.
	StringRef identifier = p.getTokenSpelling().drop_front();
	auto loc = p.getToken().getLoc();
	p.consumeToken(identifierTok);

	// If there is no '<' token following this, and if the typename contains no
	// dot, then we are parsing a symbol alias.
	if (p.getToken().isNot(Token::less) && !identifier.contains('.')) {
	// Check for an alias for this type.
	auto aliasIt = aliases.find(identifier);
	if (aliasIt == aliases.end())
	return (p.emitError("undefined symbol alias id '" + identifier + "'"),
	nullptr);
	return aliasIt->second;
	}

	// Otherwise, we are parsing a dialect-specific symbol. If the name contains
	// a dot, then this is the "pretty" form. If not, it is the verbose form that
	// looks like <"...">.
	std::string symbolData;
	auto dialectName = identifier;

	// Handle the verbose form, where "identifier" is a simple dialect name.
	if (!identifier.contains('.')) {
	// Consume the '<'.
	if (p.parseToken(Token::less, "expected '<' in dialect type"))
	return nullptr;

	// Parse the symbol specific data.
	if (p.getToken().isNot(Token::string))
	return (p.emitError("expected string literal data in dialect symbol"),
	nullptr);
	symbolData = p.getToken().getStringValue();
	loc = llvm::SMLoc::getFromPointer(p.getToken().getLoc().getPointer() + 1);
	p.consumeToken(Token::string);

	// Consume the '>'.
	if (p.parseToken(Token::greater, "expected '>' in dialect symbol"))
	return nullptr;
	} else {
	// Ok, the dialect name is the part of the identifier before the dot, the
	// part after the dot is the dialect's symbol, or the start thereof.
	auto dotHalves = identifier.split('.');
	dialectName = dotHalves.first;
	auto prettyName = dotHalves.second;
	loc = llvm::SMLoc::getFromPointer(prettyName.data());

	// If the dialect's symbol is followed immediately by a <, then lex the body
	// of it into prettyName.
	if (p.getToken().is(Token::less) &&
	prettyName.bytes_end() == p.getTokenSpelling().bytes_begin()) {
	if (p.parsePrettyDialectSymbolName(prettyName))
	return nullptr;
	}

	symbolData = prettyName.str();
	}

	// Record the name location of the type remapped to the top level buffer.
	llvm::SMLoc locInTopLevelBuffer = p.remapLocationToTopLevelBuffer(loc);
	p.getState().symbols.nestedParserLocs.push_back(locInTopLevelBuffer);

	// Call into the provided symbol construction function.
	Symbol sym = createSymbol(dialectName, symbolData, loc);

	// Pop the last parser location.
	p.getState().symbols.nestedParserLocs.pop_back();
	return sym;
	}

	/// Parses a symbol, of type 'T', and returns it if parsing was successful. If
	/// parsing failed, nullptr is returned. The number of bytes read from the input
	/// string is returned in 'numRead'.
	template <typename T, typename ParserFn>
	static T parseSymbol(StringRef inputStr, MLIRContext *context,
	SymbolState &symbolState, ParserFn &&parserFn,
	size_t *numRead = nullptr) {
	SourceMgr sourceMgr;
	auto memBuffer = MemoryBuffer::getMemBuffer(
	inputStr, /BufferName=/"<mlir_parser_buffer>",
	/RequiresNullTerminator=/false);
	sourceMgr.AddNewSourceBuffer(std::move(memBuffer), SMLoc());
	ParserState state(sourceMgr, context, symbolState);
	Parser parser(state);

	Token startTok = parser.getToken();
	T symbol = parserFn(parser);
	if (!symbol)
	return T();

	// If 'numRead' is valid, then provide the number of bytes that were read.
	Token endTok = parser.getToken();
	if (numRead) {
	*numRead = static_cast<size_t>(endTok.getLoc().getPointer() -
	startTok.getLoc().getPointer());

	// Otherwise, ensure that all of the tokens were parsed.
	} else if (startTok.getLoc() != endTok.getLoc() && endTok.isNot(Token::eof)) {
	parser.emitError(endTok.getLoc(), "encountered unexpected token");
	return T();
	}
	return symbol;
	}

	/// Parse an extended attribute.
	///
	/// extended-attribute ::= (dialect-attribute \| attribute-alias)
	/// dialect-attribute ::= `#` dialect-namespace `<` `"` attr-data `"` `>`
	/// dialect-attribute ::= `#` alias-name pretty-dialect-sym-body?
	/// attribute-alias ::= `#` alias-name
	///
	Attribute Parser::parseExtendedAttr(Type type) {
	Attribute attr = parseExtendedSymbol<Attribute>(
	*this, Token::hash_identifier, state.symbols.attributeAliasDefinitions,
	[&](StringRef dialectName, StringRef symbolData,
	llvm::SMLoc loc) -> Attribute {
	// Parse an optional trailing colon type.
	Type attrType = type;
	if (consumeIf(Token::colon) && !(attrType = parseType()))
	return Attribute();

	// If we found a registered dialect, then ask it to parse the attribute.
	if (Dialect *dialect =
	builder.getContext()->getOrLoadDialect(dialectName)) {
	return parseSymbol<Attribute>(
	symbolData, state.context, state.symbols, [&](Parser &parser) {
	CustomDialectAsmParser customParser(symbolData, parser);
	return dialect->parseAttribute(customParser, attrType);
	});
	}

	// Otherwise, form a new opaque attribute.
	return OpaqueAttr::getChecked(
	Identifier::get(dialectName, state.context), symbolData,
	attrType ? attrType : NoneType::get(state.context),
	getEncodedSourceLocation(loc));
	});

	// Ensure that the attribute has the same type as requested.
	if (attr && type && attr.getType() != type) {
	emitError("attribute type different than expected: expected ")
	<< type << ", but got " << attr.getType();
	return nullptr;
	}
	return attr;
	}

	/// Parse an extended type.
	///
	/// extended-type ::= (dialect-type \| type-alias)
	/// dialect-type ::= `!` dialect-namespace `<` `"` type-data `"` `>`
	/// dialect-type ::= `!` alias-name pretty-dialect-attribute-body?
	/// type-alias ::= `!` alias-name
	///
	Type Parser::parseExtendedType() {
	return parseExtendedSymbol<Type>(
	*this, Token::exclamation_identifier, state.symbols.typeAliasDefinitions,
	[&](StringRef dialectName, StringRef symbolData,
	llvm::SMLoc loc) -> Type {
	// If we found a registered dialect, then ask it to parse the type.
	auto *dialect = state.context->getOrLoadDialect(dialectName);

	if (dialect) {
	return parseSymbol<Type>(
	symbolData, state.context, state.symbols, [&](Parser &parser) {
	CustomDialectAsmParser customParser(symbolData, parser);
	return dialect->parseType(customParser);
	});
	}

	// Otherwise, form a new opaque type.
	return OpaqueType::getChecked(
	getEncodedSourceLocation(loc),
	Identifier::get(dialectName, state.context), symbolData);
	});
	}

	//===----------------------------------------------------------------------===//
	// mlir::parseAttribute/parseType
	//===----------------------------------------------------------------------===//

	/// Parses a symbol, of type 'T', and returns it if parsing was successful. If
	/// parsing failed, nullptr is returned. The number of bytes read from the input
	/// string is returned in 'numRead'.
	template <typename T, typename ParserFn>
	static T parseSymbol(StringRef inputStr, MLIRContext *context, size_t &numRead,
	ParserFn &&parserFn) {
	SymbolState aliasState;
	return parseSymbol<T>(
	inputStr, context, aliasState,
	[&](Parser &parser) {
	SourceMgrDiagnosticHandler handler(
	const_cast<llvm::SourceMgr &>(parser.getSourceMgr()),
	parser.getContext());
	return parserFn(parser);
	},
	&numRead);
	}

	Attribute mlir::parseAttribute(StringRef attrStr, MLIRContext *context) {
	size_t numRead = 0;
	return parseAttribute(attrStr, context, numRead);
	}
	Attribute mlir::parseAttribute(StringRef attrStr, Type type) {
	size_t numRead = 0;
	return parseAttribute(attrStr, type, numRead);
	}

	Attribute mlir::parseAttribute(StringRef attrStr, MLIRContext *context,
	size_t &numRead) {
	return parseSymbol<Attribute>(attrStr, context, numRead, [](Parser &parser) {
	return parser.parseAttribute();
	});
	}
	Attribute mlir::parseAttribute(StringRef attrStr, Type type, size_t &numRead) {
	return parseSymbol<Attribute>(
	attrStr, type.getContext(), numRead,
	[type](Parser &parser) { return parser.parseAttribute(type); });
	}

	Type mlir::parseType(StringRef typeStr, MLIRContext *context) {
	size_t numRead = 0;
	return parseType(typeStr, context, numRead);
	}

	Type mlir::parseType(StringRef typeStr, MLIRContext *context, size_t &numRead) {
	return parseSymbol<Type>(typeStr, context, numRead,
	[](Parser &parser) { return parser.parseType(); });
	}