mlir/lib/IR/FunctionImplementation.cpp - llvm-project - Git at Google

 //===- FunctionImplementation.cpp - Utilities for function-like ops -------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/IR/FunctionImplementation.h"
 #include "mlir/IR/Builders.h"
 #include "mlir/IR/FunctionSupport.h"
 #include "mlir/IR/SymbolTable.h"

 using namespace mlir;

 ParseResult mlir::function_like_impl::parseFunctionArgumentList(
     OpAsmParser &parser, bool allowAttributes, bool allowVariadic,
     SmallVectorImpl<OpAsmParser::OperandType> &argNames,
     SmallVectorImpl<Type> &argTypes, SmallVectorImpl<NamedAttrList> &argAttrs,
     bool &isVariadic) {
   if (parser.parseLParen())
     return failure();

   // The argument list either has to consistently have ssa-id's followed by
   // types, or just be a type list.  It isn't ok to sometimes have SSA ID's and
   // sometimes not.
   auto parseArgument = [&]() -> ParseResult {
     llvm::SMLoc loc = parser.getCurrentLocation();

     // Parse argument name if present.
     OpAsmParser::OperandType argument;
     Type argumentType;
     if (succeeded(parser.parseOptionalRegionArgument(argument)) &&
         !argument.name.empty()) {
       // Reject this if the preceding argument was missing a name.
       if (argNames.empty() && !argTypes.empty())
         return parser.emitError(loc, "expected type instead of SSA identifier");
       argNames.push_back(argument);

       if (parser.parseColonType(argumentType))
         return failure();
     } else if (allowVariadic && succeeded(parser.parseOptionalEllipsis())) {
       isVariadic = true;
       return success();
     } else if (!argNames.empty()) {
       // Reject this if the preceding argument had a name.
       return parser.emitError(loc, "expected SSA identifier");
     } else if (parser.parseType(argumentType)) {
       return failure();
     }

     // Add the argument type.
     argTypes.push_back(argumentType);

     // Parse any argument attributes.
     NamedAttrList attrs;
     if (parser.parseOptionalAttrDict(attrs))
       return failure();
     if (!allowAttributes && !attrs.empty())
       return parser.emitError(loc, "expected arguments without attributes");
     argAttrs.push_back(attrs);

     // Parse a location if specified.  TODO: Don't drop it on the floor.
     Optional<Location> explicitLoc;
     if (!argument.name.empty() &&
         parser.parseOptionalLocationSpecifier(explicitLoc))
       return failure();

     return success();
   };

   // Parse the function arguments.
   isVariadic = false;
   if (failed(parser.parseOptionalRParen())) {
     do {
       unsigned numTypedArguments = argTypes.size();
       if (parseArgument())
         return failure();

       llvm::SMLoc loc = parser.getCurrentLocation();
       if (argTypes.size() == numTypedArguments &&
           succeeded(parser.parseOptionalComma()))
         return parser.emitError(
             loc, "variadic arguments must be in the end of the argument list");
     } while (succeeded(parser.parseOptionalComma()));
     parser.parseRParen();
   }

   return success();
 }

 /// Parse a function result list.
 ///
 ///   function-result-list ::= function-result-list-parens
 ///                          | non-function-type
 ///   function-result-list-parens ::= `(` `)`
 ///                                 | `(` function-result-list-no-parens `)`
 ///   function-result-list-no-parens ::= function-result (`,` function-result)*
 ///   function-result ::= type attribute-dict?
 ///
 static ParseResult
 parseFunctionResultList(OpAsmParser &parser, SmallVectorImpl<Type> &resultTypes,
                         SmallVectorImpl<NamedAttrList> &resultAttrs) {
   if (failed(parser.parseOptionalLParen())) {
     // We already know that there is no `(`, so parse a type.
     // Because there is no `(`, it cannot be a function type.
     Type ty;
     if (parser.parseType(ty))
       return failure();
     resultTypes.push_back(ty);
     resultAttrs.emplace_back();
     return success();
   }

   // Special case for an empty set of parens.
   if (succeeded(parser.parseOptionalRParen()))
     return success();

   // Parse individual function results.
   do {
     resultTypes.emplace_back();
     resultAttrs.emplace_back();
     if (parser.parseType(resultTypes.back()) ||
         parser.parseOptionalAttrDict(resultAttrs.back())) {
       return failure();
     }
   } while (succeeded(parser.parseOptionalComma()));
   return parser.parseRParen();
 }

 /// Parses a function signature using `parser`. The `allowVariadic` argument
 /// indicates whether functions with variadic arguments are supported. The
 /// trailing arguments are populated by this function with names, types and
 /// attributes of the arguments and those of the results.
 ParseResult mlir::function_like_impl::parseFunctionSignature(
     OpAsmParser &parser, bool allowVariadic,
     SmallVectorImpl<OpAsmParser::OperandType> &argNames,
     SmallVectorImpl<Type> &argTypes, SmallVectorImpl<NamedAttrList> &argAttrs,
     bool &isVariadic, SmallVectorImpl<Type> &resultTypes,
     SmallVectorImpl<NamedAttrList> &resultAttrs) {
   bool allowArgAttrs = true;
   if (parseFunctionArgumentList(parser, allowArgAttrs, allowVariadic, argNames,
                                 argTypes, argAttrs, isVariadic))
     return failure();
   if (succeeded(parser.parseOptionalArrow()))
     return parseFunctionResultList(parser, resultTypes, resultAttrs);
   return success();
 }

 /// Implementation of `addArgAndResultAttrs` that is attribute list type
 /// agnostic.
 template <typename AttrListT, typename AttrArrayBuildFnT>
 static void addArgAndResultAttrsImpl(Builder &builder, OperationState &result,
                                      ArrayRef<AttrListT> argAttrs,
                                      ArrayRef<AttrListT> resultAttrs,
                                      AttrArrayBuildFnT &&buildAttrArrayFn) {
   auto nonEmptyAttrsFn = [](const AttrListT &attrs) { return !attrs.empty(); };

   // Add the attributes to the function arguments.
   if (!argAttrs.empty() && llvm::any_of(argAttrs, nonEmptyAttrsFn)) {
     ArrayAttr attrDicts = builder.getArrayAttr(buildAttrArrayFn(argAttrs));
     result.addAttribute(function_like_impl::getArgDictAttrName(), attrDicts);
   }
   // Add the attributes to the function results.
   if (!resultAttrs.empty() && llvm::any_of(resultAttrs, nonEmptyAttrsFn)) {
     ArrayAttr attrDicts = builder.getArrayAttr(buildAttrArrayFn(resultAttrs));
     result.addAttribute(function_like_impl::getResultDictAttrName(), attrDicts);
   }
 }

 void mlir::function_like_impl::addArgAndResultAttrs(
     Builder &builder, OperationState &result, ArrayRef<DictionaryAttr> argAttrs,
     ArrayRef<DictionaryAttr> resultAttrs) {
   auto buildFn = [](ArrayRef<DictionaryAttr> attrs) {
     return ArrayRef<Attribute>(attrs.data(), attrs.size());
   };
   addArgAndResultAttrsImpl(builder, result, argAttrs, resultAttrs, buildFn);
 }
 void mlir::function_like_impl::addArgAndResultAttrs(
     Builder &builder, OperationState &result, ArrayRef<NamedAttrList> argAttrs,
     ArrayRef<NamedAttrList> resultAttrs) {
   MLIRContext *context = builder.getContext();
   auto buildFn = [=](ArrayRef<NamedAttrList> attrs) {
     return llvm::to_vector<8>(
         llvm::map_range(attrs, [=](const NamedAttrList &attrList) -> Attribute {
           return attrList.getDictionary(context);
         }));
   };
   addArgAndResultAttrsImpl(builder, result, argAttrs, resultAttrs, buildFn);
 }

 /// Parser implementation for function-like operations.  Uses `funcTypeBuilder`
 /// to construct the custom function type given lists of input and output types.
 ParseResult mlir::function_like_impl::parseFunctionLikeOp(
     OpAsmParser &parser, OperationState &result, bool allowVariadic,
     FuncTypeBuilder funcTypeBuilder) {
   SmallVector<OpAsmParser::OperandType, 4> entryArgs;
   SmallVector<NamedAttrList, 4> argAttrs;
   SmallVector<NamedAttrList, 4> resultAttrs;
   SmallVector<Type, 4> argTypes;
   SmallVector<Type, 4> resultTypes;
   auto &builder = parser.getBuilder();

   // Parse visibility.
   impl::parseOptionalVisibilityKeyword(parser, result.attributes);

   // Parse the name as a symbol.
   StringAttr nameAttr;
   if (parser.parseSymbolName(nameAttr, SymbolTable::getSymbolAttrName(),
                              result.attributes))
     return failure();

   // Parse the function signature.
   llvm::SMLoc signatureLocation = parser.getCurrentLocation();
   bool isVariadic = false;
   if (parseFunctionSignature(parser, allowVariadic, entryArgs, argTypes,
                              argAttrs, isVariadic, resultTypes, resultAttrs))
     return failure();

   std::string errorMessage;
   Type type = funcTypeBuilder(builder, argTypes, resultTypes,
                               VariadicFlag(isVariadic), errorMessage);
   if (!type) {
     return parser.emitError(signatureLocation)
            << "failed to construct function type"
            << (errorMessage.empty() ? "" : ": ") << errorMessage;
   }
   result.addAttribute(getTypeAttrName(), TypeAttr::get(type));

   // If function attributes are present, parse them.
   NamedAttrList parsedAttributes;
   llvm::SMLoc attributeDictLocation = parser.getCurrentLocation();
   if (parser.parseOptionalAttrDictWithKeyword(parsedAttributes))
     return failure();

   // Disallow attributes that are inferred from elsewhere in the attribute
   // dictionary.
   for (StringRef disallowed :
        {SymbolTable::getVisibilityAttrName(), SymbolTable::getSymbolAttrName(),
         getTypeAttrName()}) {
     if (parsedAttributes.get(disallowed))
       return parser.emitError(attributeDictLocation, "'")
              << disallowed
              << "' is an inferred attribute and should not be specified in the "
                 "explicit attribute dictionary";
   }
   result.attributes.append(parsedAttributes);

   // Add the attributes to the function arguments.
   assert(argAttrs.size() == argTypes.size());
   assert(resultAttrs.size() == resultTypes.size());
   addArgAndResultAttrs(builder, result, argAttrs, resultAttrs);

   // Parse the optional function body. The printer will not print the body if
   // its empty, so disallow parsing of empty body in the parser.
   auto *body = result.addRegion();
   llvm::SMLoc loc = parser.getCurrentLocation();
   OptionalParseResult parseResult = parser.parseOptionalRegion(
       *body, entryArgs, entryArgs.empty() ? ArrayRef<Type>() : argTypes,
       /*enableNameShadowing=*/false);
   if (parseResult.hasValue()) {
     if (failed(*parseResult))
       return failure();
     // Function body was parsed, make sure its not empty.
     if (body->empty())
       return parser.emitError(loc, "expected non-empty function body");
   }
   return success();
 }

 /// Print a function result list. The provided `attrs` must either be null, or
 /// contain a set of DictionaryAttrs of the same arity as `types`.
 static void printFunctionResultList(OpAsmPrinter &p, ArrayRef<Type> types,
                                     ArrayAttr attrs) {
   assert(!types.empty() && "Should not be called for empty result list.");
   assert((!attrs || attrs.size() == types.size()) &&
          "Invalid number of attributes.");

   auto &os = p.getStream();
   bool needsParens = types.size() > 1 || types[0].isa<FunctionType>() ||
                      (attrs && !attrs[0].cast<DictionaryAttr>().empty());
   if (needsParens)
     os << '(';
   llvm::interleaveComma(llvm::seq<size_t>(0, types.size()), os, [&](size_t i) {
     p.printType(types[i]);
     if (attrs)
       p.printOptionalAttrDict(attrs[i].cast<DictionaryAttr>().getValue());
   });
   if (needsParens)
     os << ')';
 }

 /// Print the signature of the function-like operation `op`.  Assumes `op` has
 /// the FunctionLike trait and passed the verification.
 void mlir::function_like_impl::printFunctionSignature(
     OpAsmPrinter &p, Operation *op, ArrayRef<Type> argTypes, bool isVariadic,
     ArrayRef<Type> resultTypes) {
   Region &body = op->getRegion(0);
   bool isExternal = body.empty();

   p << '(';
   ArrayAttr argAttrs = op->getAttrOfType<ArrayAttr>(getArgDictAttrName());
   for (unsigned i = 0, e = argTypes.size(); i < e; ++i) {
     if (i > 0)
       p << ", ";

     if (!isExternal) {
       ArrayRef<NamedAttribute> attrs;
       if (argAttrs)
         attrs = argAttrs[i].cast<DictionaryAttr>().getValue();
       p.printRegionArgument(body.getArgument(i), attrs);
     } else {
       p.printType(argTypes[i]);
       if (argAttrs)
         p.printOptionalAttrDict(argAttrs[i].cast<DictionaryAttr>().getValue());
     }
   }

   if (isVariadic) {
     if (!argTypes.empty())
       p << ", ";
     p << "...";
   }

   p << ')';

   if (!resultTypes.empty()) {
     p.getStream() << " -> ";
     auto resultAttrs = op->getAttrOfType<ArrayAttr>(getResultDictAttrName());
     printFunctionResultList(p, resultTypes, resultAttrs);
   }
 }

 /// Prints the list of function prefixed with the "attributes" keyword. The
 /// attributes with names listed in "elided" as well as those used by the
 /// function-like operation internally are not printed. Nothing is printed
 /// if all attributes are elided. Assumes `op` has the `FunctionLike` trait and
 /// passed the verification.
 void mlir::function_like_impl::printFunctionAttributes(
     OpAsmPrinter &p, Operation *op, unsigned numInputs, unsigned numResults,
     ArrayRef<StringRef> elided) {
   // Print out function attributes, if present.
   SmallVector<StringRef, 2> ignoredAttrs = {
       ::mlir::SymbolTable::getSymbolAttrName(), getTypeAttrName(),
       getArgDictAttrName(), getResultDictAttrName()};
   ignoredAttrs.append(elided.begin(), elided.end());

   p.printOptionalAttrDictWithKeyword(op->getAttrs(), ignoredAttrs);
 }

 /// Printer implementation for function-like operations.  Accepts lists of
 /// argument and result types to use while printing.
 void mlir::function_like_impl::printFunctionLikeOp(OpAsmPrinter &p,
                                                    Operation *op,
                                                    ArrayRef<Type> argTypes,
                                                    bool isVariadic,
                                                    ArrayRef<Type> resultTypes) {
   // Print the operation and the function name.
   auto funcName =
       op->getAttrOfType<StringAttr>(SymbolTable::getSymbolAttrName())
           .getValue();
   p << ' ';

   StringRef visibilityAttrName = SymbolTable::getVisibilityAttrName();
   if (auto visibility = op->getAttrOfType<StringAttr>(visibilityAttrName))
     p << visibility.getValue() << ' ';
   p.printSymbolName(funcName);

   printFunctionSignature(p, op, argTypes, isVariadic, resultTypes);
   printFunctionAttributes(p, op, argTypes.size(), resultTypes.size(),
                           {visibilityAttrName});
   // Print the body if this is not an external function.
   Region &body = op->getRegion(0);
   if (!body.empty())
     p.printRegion(body, /*printEntryBlockArgs=*/false,
                   /*printBlockTerminators=*/true);
 }
	//===- FunctionImplementation.cpp - Utilities for function-like ops -------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/IR/FunctionImplementation.h"
	#include "mlir/IR/Builders.h"
	#include "mlir/IR/FunctionSupport.h"
	#include "mlir/IR/SymbolTable.h"

	using namespace mlir;

	ParseResult mlir::function_like_impl::parseFunctionArgumentList(
	OpAsmParser &parser, bool allowAttributes, bool allowVariadic,
	SmallVectorImpl<OpAsmParser::OperandType> &argNames,
	SmallVectorImpl<Type> &argTypes, SmallVectorImpl<NamedAttrList> &argAttrs,
	bool &isVariadic) {
	if (parser.parseLParen())
	return failure();

	// The argument list either has to consistently have ssa-id's followed by
	// types, or just be a type list. It isn't ok to sometimes have SSA ID's and
	// sometimes not.
	auto parseArgument = [&]() -> ParseResult {
	llvm::SMLoc loc = parser.getCurrentLocation();

	// Parse argument name if present.
	OpAsmParser::OperandType argument;
	Type argumentType;
	if (succeeded(parser.parseOptionalRegionArgument(argument)) &&
	!argument.name.empty()) {
	// Reject this if the preceding argument was missing a name.
	if (argNames.empty() && !argTypes.empty())
	return parser.emitError(loc, "expected type instead of SSA identifier");
	argNames.push_back(argument);

	if (parser.parseColonType(argumentType))
	return failure();
	} else if (allowVariadic && succeeded(parser.parseOptionalEllipsis())) {
	isVariadic = true;
	return success();
	} else if (!argNames.empty()) {
	// Reject this if the preceding argument had a name.
	return parser.emitError(loc, "expected SSA identifier");
	} else if (parser.parseType(argumentType)) {
	return failure();
	}

	// Add the argument type.
	argTypes.push_back(argumentType);

	// Parse any argument attributes.
	NamedAttrList attrs;
	if (parser.parseOptionalAttrDict(attrs))
	return failure();
	if (!allowAttributes && !attrs.empty())
	return parser.emitError(loc, "expected arguments without attributes");
	argAttrs.push_back(attrs);

	// Parse a location if specified. TODO: Don't drop it on the floor.
	Optional<Location> explicitLoc;
	if (!argument.name.empty() &&
	parser.parseOptionalLocationSpecifier(explicitLoc))
	return failure();

	return success();
	};

	// Parse the function arguments.
	isVariadic = false;
	if (failed(parser.parseOptionalRParen())) {
	do {
	unsigned numTypedArguments = argTypes.size();
	if (parseArgument())
	return failure();

	llvm::SMLoc loc = parser.getCurrentLocation();
	if (argTypes.size() == numTypedArguments &&
	succeeded(parser.parseOptionalComma()))
	return parser.emitError(
	loc, "variadic arguments must be in the end of the argument list");
	} while (succeeded(parser.parseOptionalComma()));
	parser.parseRParen();
	}

	return success();
	}

	/// Parse a function result list.
	///
	/// function-result-list ::= function-result-list-parens
	/// \| non-function-type
	/// function-result-list-parens ::= `(` `)`
	/// \| `(` function-result-list-no-parens `)`
	/// function-result-list-no-parens ::= function-result (`,` function-result)*
	/// function-result ::= type attribute-dict?
	///
	static ParseResult
	parseFunctionResultList(OpAsmParser &parser, SmallVectorImpl<Type> &resultTypes,
	SmallVectorImpl<NamedAttrList> &resultAttrs) {
	if (failed(parser.parseOptionalLParen())) {
	// We already know that there is no `(`, so parse a type.
	// Because there is no `(`, it cannot be a function type.
	Type ty;
	if (parser.parseType(ty))
	return failure();
	resultTypes.push_back(ty);
	resultAttrs.emplace_back();
	return success();
	}

	// Special case for an empty set of parens.
	if (succeeded(parser.parseOptionalRParen()))
	return success();

	// Parse individual function results.
	do {
	resultTypes.emplace_back();
	resultAttrs.emplace_back();
	if (parser.parseType(resultTypes.back()) \|\|
	parser.parseOptionalAttrDict(resultAttrs.back())) {
	return failure();
	}
	} while (succeeded(parser.parseOptionalComma()));
	return parser.parseRParen();
	}

	/// Parses a function signature using `parser`. The `allowVariadic` argument
	/// indicates whether functions with variadic arguments are supported. The
	/// trailing arguments are populated by this function with names, types and
	/// attributes of the arguments and those of the results.
	ParseResult mlir::function_like_impl::parseFunctionSignature(
	OpAsmParser &parser, bool allowVariadic,
	SmallVectorImpl<OpAsmParser::OperandType> &argNames,
	SmallVectorImpl<Type> &argTypes, SmallVectorImpl<NamedAttrList> &argAttrs,
	bool &isVariadic, SmallVectorImpl<Type> &resultTypes,
	SmallVectorImpl<NamedAttrList> &resultAttrs) {
	bool allowArgAttrs = true;
	if (parseFunctionArgumentList(parser, allowArgAttrs, allowVariadic, argNames,
	argTypes, argAttrs, isVariadic))
	return failure();
	if (succeeded(parser.parseOptionalArrow()))
	return parseFunctionResultList(parser, resultTypes, resultAttrs);
	return success();
	}

	/// Implementation of `addArgAndResultAttrs` that is attribute list type
	/// agnostic.
	template <typename AttrListT, typename AttrArrayBuildFnT>
	static void addArgAndResultAttrsImpl(Builder &builder, OperationState &result,
	ArrayRef<AttrListT> argAttrs,
	ArrayRef<AttrListT> resultAttrs,
	AttrArrayBuildFnT &&buildAttrArrayFn) {
	auto nonEmptyAttrsFn = [](const AttrListT &attrs) { return !attrs.empty(); };

	// Add the attributes to the function arguments.
	if (!argAttrs.empty() && llvm::any_of(argAttrs, nonEmptyAttrsFn)) {
	ArrayAttr attrDicts = builder.getArrayAttr(buildAttrArrayFn(argAttrs));
	result.addAttribute(function_like_impl::getArgDictAttrName(), attrDicts);
	}
	// Add the attributes to the function results.
	if (!resultAttrs.empty() && llvm::any_of(resultAttrs, nonEmptyAttrsFn)) {
	ArrayAttr attrDicts = builder.getArrayAttr(buildAttrArrayFn(resultAttrs));
	result.addAttribute(function_like_impl::getResultDictAttrName(), attrDicts);
	}
	}

	void mlir::function_like_impl::addArgAndResultAttrs(
	Builder &builder, OperationState &result, ArrayRef<DictionaryAttr> argAttrs,
	ArrayRef<DictionaryAttr> resultAttrs) {
	auto buildFn = [](ArrayRef<DictionaryAttr> attrs) {
	return ArrayRef<Attribute>(attrs.data(), attrs.size());
	};
	addArgAndResultAttrsImpl(builder, result, argAttrs, resultAttrs, buildFn);
	}
	void mlir::function_like_impl::addArgAndResultAttrs(
	Builder &builder, OperationState &result, ArrayRef<NamedAttrList> argAttrs,
	ArrayRef<NamedAttrList> resultAttrs) {
	MLIRContext *context = builder.getContext();
	auto buildFn = [=](ArrayRef<NamedAttrList> attrs) {
	return llvm::to_vector<8>(
	llvm::map_range(attrs, [=](const NamedAttrList &attrList) -> Attribute {
	return attrList.getDictionary(context);
	}));
	};
	addArgAndResultAttrsImpl(builder, result, argAttrs, resultAttrs, buildFn);
	}

	/// Parser implementation for function-like operations. Uses `funcTypeBuilder`
	/// to construct the custom function type given lists of input and output types.
	ParseResult mlir::function_like_impl::parseFunctionLikeOp(
	OpAsmParser &parser, OperationState &result, bool allowVariadic,
	FuncTypeBuilder funcTypeBuilder) {
	SmallVector<OpAsmParser::OperandType, 4> entryArgs;
	SmallVector<NamedAttrList, 4> argAttrs;
	SmallVector<NamedAttrList, 4> resultAttrs;
	SmallVector<Type, 4> argTypes;
	SmallVector<Type, 4> resultTypes;
	auto &builder = parser.getBuilder();

	// Parse visibility.
	impl::parseOptionalVisibilityKeyword(parser, result.attributes);

	// Parse the name as a symbol.
	StringAttr nameAttr;
	if (parser.parseSymbolName(nameAttr, SymbolTable::getSymbolAttrName(),
	result.attributes))
	return failure();

	// Parse the function signature.
	llvm::SMLoc signatureLocation = parser.getCurrentLocation();
	bool isVariadic = false;
	if (parseFunctionSignature(parser, allowVariadic, entryArgs, argTypes,
	argAttrs, isVariadic, resultTypes, resultAttrs))
	return failure();

	std::string errorMessage;
	Type type = funcTypeBuilder(builder, argTypes, resultTypes,
	VariadicFlag(isVariadic), errorMessage);
	if (!type) {
	return parser.emitError(signatureLocation)
	<< "failed to construct function type"
	<< (errorMessage.empty() ? "" : ": ") << errorMessage;
	}
	result.addAttribute(getTypeAttrName(), TypeAttr::get(type));

	// If function attributes are present, parse them.
	NamedAttrList parsedAttributes;
	llvm::SMLoc attributeDictLocation = parser.getCurrentLocation();
	if (parser.parseOptionalAttrDictWithKeyword(parsedAttributes))
	return failure();

	// Disallow attributes that are inferred from elsewhere in the attribute
	// dictionary.
	for (StringRef disallowed :
	{SymbolTable::getVisibilityAttrName(), SymbolTable::getSymbolAttrName(),
	getTypeAttrName()}) {
	if (parsedAttributes.get(disallowed))
	return parser.emitError(attributeDictLocation, "'")
	<< disallowed
	<< "' is an inferred attribute and should not be specified in the "
	"explicit attribute dictionary";
	}
	result.attributes.append(parsedAttributes);

	// Add the attributes to the function arguments.
	assert(argAttrs.size() == argTypes.size());
	assert(resultAttrs.size() == resultTypes.size());
	addArgAndResultAttrs(builder, result, argAttrs, resultAttrs);

	// Parse the optional function body. The printer will not print the body if
	// its empty, so disallow parsing of empty body in the parser.
	auto *body = result.addRegion();
	llvm::SMLoc loc = parser.getCurrentLocation();
	OptionalParseResult parseResult = parser.parseOptionalRegion(
	*body, entryArgs, entryArgs.empty() ? ArrayRef<Type>() : argTypes,
	/enableNameShadowing=/false);
	if (parseResult.hasValue()) {
	if (failed(*parseResult))
	return failure();
	// Function body was parsed, make sure its not empty.
	if (body->empty())
	return parser.emitError(loc, "expected non-empty function body");
	}
	return success();
	}

	/// Print a function result list. The provided `attrs` must either be null, or
	/// contain a set of DictionaryAttrs of the same arity as `types`.
	static void printFunctionResultList(OpAsmPrinter &p, ArrayRef<Type> types,
	ArrayAttr attrs) {
	assert(!types.empty() && "Should not be called for empty result list.");
	assert((!attrs \|\| attrs.size() == types.size()) &&
	"Invalid number of attributes.");

	auto &os = p.getStream();
	bool needsParens = types.size() > 1 \|\| types[0].isa<FunctionType>() \|\|
	(attrs && !attrs[0].cast<DictionaryAttr>().empty());
	if (needsParens)
	os << '(';
	llvm::interleaveComma(llvm::seq<size_t>(0, types.size()), os, [&](size_t i) {
	p.printType(types[i]);
	if (attrs)
	p.printOptionalAttrDict(attrs[i].cast<DictionaryAttr>().getValue());
	});
	if (needsParens)
	os << ')';
	}

	/// Print the signature of the function-like operation `op`. Assumes `op` has
	/// the FunctionLike trait and passed the verification.
	void mlir::function_like_impl::printFunctionSignature(
	OpAsmPrinter &p, Operation *op, ArrayRef<Type> argTypes, bool isVariadic,
	ArrayRef<Type> resultTypes) {
	Region &body = op->getRegion(0);
	bool isExternal = body.empty();

	p << '(';
	ArrayAttr argAttrs = op->getAttrOfType<ArrayAttr>(getArgDictAttrName());
	for (unsigned i = 0, e = argTypes.size(); i < e; ++i) {
	if (i > 0)
	p << ", ";

	if (!isExternal) {
	ArrayRef<NamedAttribute> attrs;
	if (argAttrs)
	attrs = argAttrs[i].cast<DictionaryAttr>().getValue();
	p.printRegionArgument(body.getArgument(i), attrs);
	} else {
	p.printType(argTypes[i]);
	if (argAttrs)
	p.printOptionalAttrDict(argAttrs[i].cast<DictionaryAttr>().getValue());
	}
	}

	if (isVariadic) {
	if (!argTypes.empty())
	p << ", ";
	p << "...";
	}

	p << ')';

	if (!resultTypes.empty()) {
	p.getStream() << " -> ";
	auto resultAttrs = op->getAttrOfType<ArrayAttr>(getResultDictAttrName());
	printFunctionResultList(p, resultTypes, resultAttrs);
	}
	}

	/// Prints the list of function prefixed with the "attributes" keyword. The
	/// attributes with names listed in "elided" as well as those used by the
	/// function-like operation internally are not printed. Nothing is printed
	/// if all attributes are elided. Assumes `op` has the `FunctionLike` trait and
	/// passed the verification.
	void mlir::function_like_impl::printFunctionAttributes(
	OpAsmPrinter &p, Operation *op, unsigned numInputs, unsigned numResults,
	ArrayRef<StringRef> elided) {
	// Print out function attributes, if present.
	SmallVector<StringRef, 2> ignoredAttrs = {
	::mlir::SymbolTable::getSymbolAttrName(), getTypeAttrName(),
	getArgDictAttrName(), getResultDictAttrName()};
	ignoredAttrs.append(elided.begin(), elided.end());

	p.printOptionalAttrDictWithKeyword(op->getAttrs(), ignoredAttrs);
	}

	/// Printer implementation for function-like operations. Accepts lists of
	/// argument and result types to use while printing.
	void mlir::function_like_impl::printFunctionLikeOp(OpAsmPrinter &p,
	Operation *op,
	ArrayRef<Type> argTypes,
	bool isVariadic,
	ArrayRef<Type> resultTypes) {
	// Print the operation and the function name.
	auto funcName =
	op->getAttrOfType<StringAttr>(SymbolTable::getSymbolAttrName())
	.getValue();
	p << ' ';

	StringRef visibilityAttrName = SymbolTable::getVisibilityAttrName();
	if (auto visibility = op->getAttrOfType<StringAttr>(visibilityAttrName))
	p << visibility.getValue() << ' ';
	p.printSymbolName(funcName);

	printFunctionSignature(p, op, argTypes, isVariadic, resultTypes);
	printFunctionAttributes(p, op, argTypes.size(), resultTypes.size(),
	{visibilityAttrName});
	// Print the body if this is not an external function.
	Region &body = op->getRegion(0);
	if (!body.empty())
	p.printRegion(body, /printEntryBlockArgs=/false,
	/printBlockTerminators=/true);
	}