clang-r437112/include/clang/AST/AbstractBasicReader.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //==--- AbstractBasiceReader.h - Abstract basic value deserialization -----===//
 //
 // 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 CLANG_AST_ABSTRACTBASICREADER_H
 #define CLANG_AST_ABSTRACTBASICREADER_H

 #include "clang/AST/DeclTemplate.h"

 namespace clang {
 namespace serialization {

 template <class T>
 inline T makeNullableFromOptional(const Optional<T> &value) {
   return (value ? *value : T());
 }

 template <class T>
 inline T *makePointerFromOptional(Optional<T *> value) {
   return (value ? *value : nullptr);
 }

 // PropertyReader is a class concept that requires the following method:
 //   BasicReader find(llvm::StringRef propertyName);
 // where BasicReader is some class conforming to the BasicReader concept.
 // An abstract AST-node reader is created with a PropertyReader and
 // performs a sequence of calls like so:
 //   propertyReader.find(propertyName).read##TypeName()
 // to read the properties of the node it is deserializing.

 // BasicReader is a class concept that requires methods like:
 //   ValueType read##TypeName();
 // where TypeName is the name of a PropertyType node from PropertiesBase.td
 // and ValueType is the corresponding C++ type name.  The read method may
 // require one or more buffer arguments.
 //
 // In addition to the concrete type names, BasicReader is expected to
 // implement these methods:
 //
 //   template <class EnumType>
 //   void writeEnum(T value);
 //
 //     Reads an enum value from the current property.  EnumType will always
 //     be an enum type.  Only necessary if the BasicReader doesn't provide
 //     type-specific readers for all the enum types.
 //
 //   template <class ValueType>
 //   Optional<ValueType> writeOptional();
 //
 //     Reads an optional value from the current property.
 //
 //   template <class ValueType>
 //   ArrayRef<ValueType> readArray(llvm::SmallVectorImpl<ValueType> &buffer);
 //
 //     Reads an array of values from the current property.
 //
 //   PropertyReader readObject();
 //
 //     Reads an object from the current property; the returned property
 //     reader will be subjected to a sequence of property reads and then
 //     discarded before any other properties are reader from the "outer"
 //     property reader (which need not be the same type).  The sub-reader
 //     will be used as if with the following code:
 //
 //       {
 //         auto &&widget = W.find("widget").readObject();
 //         auto kind = widget.find("kind").readWidgetKind();
 //         auto declaration = widget.find("declaration").readDeclRef();
 //         return Widget(kind, declaration);
 //       }

 // ReadDispatcher does type-based forwarding to one of the read methods
 // on the BasicReader passed in:
 //
 // template <class ValueType>
 // struct ReadDispatcher {
 //   template <class BasicReader, class... BufferTypes>
 //   static ValueType read(BasicReader &R, BufferTypes &&...);
 // };

 // BasicReaderBase provides convenience implementations of the read methods
 // for EnumPropertyType and SubclassPropertyType types that just defer to
 // the "underlying" implementations (for UInt32 and the base class,
 // respectively).
 //
 // template <class Impl>
 // class BasicReaderBase {
 // protected:
 //   BasicReaderBase(ASTContext &ctx);
 //   Impl &asImpl();
 // public:
 //   ASTContext &getASTContext();
 //   ...
 // };

 // The actual classes are auto-generated; see ClangASTPropertiesEmitter.cpp.
 #include "clang/AST/AbstractBasicReader.inc"

 /// DataStreamBasicReader provides convenience implementations for many
 /// BasicReader methods based on the assumption that the
 /// ultimate reader implementation is based on a variable-length stream
 /// of unstructured data (like Clang's module files).  It is designed
 /// to pair with DataStreamBasicWriter.
 ///
 /// This class can also act as a PropertyReader, implementing find("...")
 /// by simply forwarding to itself.
 ///
 /// Unimplemented methods:
 ///   readBool
 ///   readUInt32
 ///   readUInt64
 ///   readIdentifier
 ///   readSelector
 ///   readSourceLocation
 ///   readQualType
 ///   readStmtRef
 ///   readDeclRef
 template <class Impl>
 class DataStreamBasicReader : public BasicReaderBase<Impl> {
 protected:
   using BasicReaderBase<Impl>::asImpl;
   DataStreamBasicReader(ASTContext &ctx) : BasicReaderBase<Impl>(ctx) {}

 public:
   using BasicReaderBase<Impl>::getASTContext;

   /// Implement property-find by ignoring it.  We rely on properties being
   /// serialized and deserialized in a reliable order instead.
   Impl &find(const char *propertyName) {
     return asImpl();
   }

   template <class T>
   T readEnum() {
     return T(asImpl().readUInt32());
   }

   // Implement object reading by forwarding to this, collapsing the
   // structure into a single data stream.
   Impl &readObject() { return asImpl(); }

   template <class T>
   llvm::ArrayRef<T> readArray(llvm::SmallVectorImpl<T> &buffer) {
     assert(buffer.empty());

     uint32_t size = asImpl().readUInt32();
     buffer.reserve(size);

     for (uint32_t i = 0; i != size; ++i) {
       buffer.push_back(ReadDispatcher<T>::read(asImpl()));
     }
     return buffer;
   }

   template <class T, class... Args>
   llvm::Optional<T> readOptional(Args &&...args) {
     return UnpackOptionalValue<T>::unpack(
              ReadDispatcher<T>::read(asImpl(), std::forward<Args>(args)...));
   }

   llvm::APSInt readAPSInt() {
     bool isUnsigned = asImpl().readBool();
     llvm::APInt value = asImpl().readAPInt();
     return llvm::APSInt(std::move(value), isUnsigned);
   }

   llvm::APInt readAPInt() {
     unsigned bitWidth = asImpl().readUInt32();
     unsigned numWords = llvm::APInt::getNumWords(bitWidth);
     llvm::SmallVector<uint64_t, 4> data;
     for (uint32_t i = 0; i != numWords; ++i)
       data.push_back(asImpl().readUInt64());
     return llvm::APInt(bitWidth, numWords, &data[0]);
   }

   llvm::FixedPointSemantics readFixedPointSemantics() {
     unsigned width = asImpl().readUInt32();
     unsigned scale = asImpl().readUInt32();
     unsigned tmp = asImpl().readUInt32();
     bool isSigned = tmp & 0x1;
     bool isSaturated = tmp & 0x2;
     bool hasUnsignedPadding = tmp & 0x4;
     return llvm::FixedPointSemantics(width, scale, isSigned, isSaturated,
                                      hasUnsignedPadding);
   }

   APValue::LValuePathSerializationHelper readLValuePathSerializationHelper(
       SmallVectorImpl<APValue::LValuePathEntry> &path) {
     auto elemTy = asImpl().readQualType();
     unsigned pathLength = asImpl().readUInt32();
     for (unsigned i = 0; i < pathLength; ++i) {
       if (elemTy->template getAs<RecordType>()) {
         unsigned int_ = asImpl().readUInt32();
         Decl *decl = asImpl().template readDeclAs<Decl>();
         if (auto *recordDecl = dyn_cast<CXXRecordDecl>(decl))
           elemTy = getASTContext().getRecordType(recordDecl);
         else
           elemTy = cast<ValueDecl>(decl)->getType();
         path.push_back(
             APValue::LValuePathEntry(APValue::BaseOrMemberType(decl, int_)));
       } else {
         elemTy = getASTContext().getAsArrayType(elemTy)->getElementType();
         path.push_back(
             APValue::LValuePathEntry::ArrayIndex(asImpl().readUInt32()));
       }
     }
     return APValue::LValuePathSerializationHelper(path, elemTy);
   }

   Qualifiers readQualifiers() {
     static_assert(sizeof(Qualifiers().getAsOpaqueValue()) <= sizeof(uint32_t),
                   "update this if the value size changes");
     uint32_t value = asImpl().readUInt32();
     return Qualifiers::fromOpaqueValue(value);
   }

   FunctionProtoType::ExceptionSpecInfo
   readExceptionSpecInfo(llvm::SmallVectorImpl<QualType> &buffer) {
     FunctionProtoType::ExceptionSpecInfo esi;
     esi.Type = ExceptionSpecificationType(asImpl().readUInt32());
     if (esi.Type == EST_Dynamic) {
       esi.Exceptions = asImpl().template readArray<QualType>(buffer);
     } else if (isComputedNoexcept(esi.Type)) {
       esi.NoexceptExpr = asImpl().readExprRef();
     } else if (esi.Type == EST_Uninstantiated) {
       esi.SourceDecl = asImpl().readFunctionDeclRef();
       esi.SourceTemplate = asImpl().readFunctionDeclRef();
     } else if (esi.Type == EST_Unevaluated) {
       esi.SourceDecl = asImpl().readFunctionDeclRef();
     }
     return esi;
   }

   FunctionProtoType::ExtParameterInfo readExtParameterInfo() {
     static_assert(sizeof(FunctionProtoType::ExtParameterInfo().getOpaqueValue())
                     <= sizeof(uint32_t),
                   "opaque value doesn't fit into uint32_t");
     uint32_t value = asImpl().readUInt32();
     return FunctionProtoType::ExtParameterInfo::getFromOpaqueValue(value);
   }

   NestedNameSpecifier *readNestedNameSpecifier() {
     auto &ctx = getASTContext();

     // We build this up iteratively.
     NestedNameSpecifier *cur = nullptr;

     uint32_t depth = asImpl().readUInt32();
     for (uint32_t i = 0; i != depth; ++i) {
       auto kind = asImpl().readNestedNameSpecifierKind();
       switch (kind) {
       case NestedNameSpecifier::Identifier:
         cur = NestedNameSpecifier::Create(ctx, cur,
                                           asImpl().readIdentifier());
         continue;

       case NestedNameSpecifier::Namespace:
         cur = NestedNameSpecifier::Create(ctx, cur,
                                           asImpl().readNamespaceDeclRef());
         continue;

       case NestedNameSpecifier::NamespaceAlias:
         cur = NestedNameSpecifier::Create(ctx, cur,
                                      asImpl().readNamespaceAliasDeclRef());
         continue;

       case NestedNameSpecifier::TypeSpec:
       case NestedNameSpecifier::TypeSpecWithTemplate:
         cur = NestedNameSpecifier::Create(ctx, cur,
                           kind == NestedNameSpecifier::TypeSpecWithTemplate,
                           asImpl().readQualType().getTypePtr());
         continue;

       case NestedNameSpecifier::Global:
         cur = NestedNameSpecifier::GlobalSpecifier(ctx);
         continue;

       case NestedNameSpecifier::Super:
         cur = NestedNameSpecifier::SuperSpecifier(ctx,
                                             asImpl().readCXXRecordDeclRef());
         continue;
       }
       llvm_unreachable("bad nested name specifier kind");
     }

     return cur;
   }
 };

 } // end namespace serialization
 } // end namespace clang

 #endif
	//==--- AbstractBasiceReader.h - Abstract basic value deserialization -----===//
	//
	// 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 CLANG_AST_ABSTRACTBASICREADER_H
	#define CLANG_AST_ABSTRACTBASICREADER_H

	#include "clang/AST/DeclTemplate.h"

	namespace clang {
	namespace serialization {

	template <class T>
	inline T makeNullableFromOptional(const Optional<T> &value) {
	return (value ? *value : T());
	}

	template <class T>
	inline T makePointerFromOptional(Optional<T > value) {
	return (value ? *value : nullptr);
	}

	// PropertyReader is a class concept that requires the following method:
	// BasicReader find(llvm::StringRef propertyName);
	// where BasicReader is some class conforming to the BasicReader concept.
	// An abstract AST-node reader is created with a PropertyReader and
	// performs a sequence of calls like so:
	// propertyReader.find(propertyName).read##TypeName()
	// to read the properties of the node it is deserializing.

	// BasicReader is a class concept that requires methods like:
	// ValueType read##TypeName();
	// where TypeName is the name of a PropertyType node from PropertiesBase.td
	// and ValueType is the corresponding C++ type name. The read method may
	// require one or more buffer arguments.
	//
	// In addition to the concrete type names, BasicReader is expected to
	// implement these methods:
	//
	// template <class EnumType>
	// void writeEnum(T value);
	//
	// Reads an enum value from the current property. EnumType will always
	// be an enum type. Only necessary if the BasicReader doesn't provide
	// type-specific readers for all the enum types.
	//
	// template <class ValueType>
	// Optional<ValueType> writeOptional();
	//
	// Reads an optional value from the current property.
	//
	// template <class ValueType>
	// ArrayRef<ValueType> readArray(llvm::SmallVectorImpl<ValueType> &buffer);
	//
	// Reads an array of values from the current property.
	//
	// PropertyReader readObject();
	//
	// Reads an object from the current property; the returned property
	// reader will be subjected to a sequence of property reads and then
	// discarded before any other properties are reader from the "outer"
	// property reader (which need not be the same type). The sub-reader
	// will be used as if with the following code:
	//
	// {
	// auto &&widget = W.find("widget").readObject();
	// auto kind = widget.find("kind").readWidgetKind();
	// auto declaration = widget.find("declaration").readDeclRef();
	// return Widget(kind, declaration);
	// }

	// ReadDispatcher does type-based forwarding to one of the read methods
	// on the BasicReader passed in:
	//
	// template <class ValueType>
	// struct ReadDispatcher {
	// template <class BasicReader, class... BufferTypes>
	// static ValueType read(BasicReader &R, BufferTypes &&...);
	// };

	// BasicReaderBase provides convenience implementations of the read methods
	// for EnumPropertyType and SubclassPropertyType types that just defer to
	// the "underlying" implementations (for UInt32 and the base class,
	// respectively).
	//
	// template <class Impl>
	// class BasicReaderBase {
	// protected:
	// BasicReaderBase(ASTContext &ctx);
	// Impl &asImpl();
	// public:
	// ASTContext &getASTContext();
	// ...
	// };

	// The actual classes are auto-generated; see ClangASTPropertiesEmitter.cpp.
	#include "clang/AST/AbstractBasicReader.inc"

	/// DataStreamBasicReader provides convenience implementations for many
	/// BasicReader methods based on the assumption that the
	/// ultimate reader implementation is based on a variable-length stream
	/// of unstructured data (like Clang's module files). It is designed
	/// to pair with DataStreamBasicWriter.
	///
	/// This class can also act as a PropertyReader, implementing find("...")
	/// by simply forwarding to itself.
	///
	/// Unimplemented methods:
	/// readBool
	/// readUInt32
	/// readUInt64
	/// readIdentifier
	/// readSelector
	/// readSourceLocation
	/// readQualType
	/// readStmtRef
	/// readDeclRef
	template <class Impl>
	class DataStreamBasicReader : public BasicReaderBase<Impl> {
	protected:
	using BasicReaderBase<Impl>::asImpl;
	DataStreamBasicReader(ASTContext &ctx) : BasicReaderBase<Impl>(ctx) {}

	public:
	using BasicReaderBase<Impl>::getASTContext;

	/// Implement property-find by ignoring it. We rely on properties being
	/// serialized and deserialized in a reliable order instead.
	Impl &find(const char *propertyName) {
	return asImpl();
	}

	template <class T>
	T readEnum() {
	return T(asImpl().readUInt32());
	}

	// Implement object reading by forwarding to this, collapsing the
	// structure into a single data stream.
	Impl &readObject() { return asImpl(); }

	template <class T>
	llvm::ArrayRef<T> readArray(llvm::SmallVectorImpl<T> &buffer) {
	assert(buffer.empty());

	uint32_t size = asImpl().readUInt32();
	buffer.reserve(size);

	for (uint32_t i = 0; i != size; ++i) {
	buffer.push_back(ReadDispatcher<T>::read(asImpl()));
	}
	return buffer;
	}

	template <class T, class... Args>
	llvm::Optional<T> readOptional(Args &&...args) {
	return UnpackOptionalValue<T>::unpack(
	ReadDispatcher<T>::read(asImpl(), std::forward<Args>(args)...));
	}

	llvm::APSInt readAPSInt() {
	bool isUnsigned = asImpl().readBool();
	llvm::APInt value = asImpl().readAPInt();
	return llvm::APSInt(std::move(value), isUnsigned);
	}

	llvm::APInt readAPInt() {
	unsigned bitWidth = asImpl().readUInt32();
	unsigned numWords = llvm::APInt::getNumWords(bitWidth);
	llvm::SmallVector<uint64_t, 4> data;
	for (uint32_t i = 0; i != numWords; ++i)
	data.push_back(asImpl().readUInt64());
	return llvm::APInt(bitWidth, numWords, &data[0]);
	}

	llvm::FixedPointSemantics readFixedPointSemantics() {
	unsigned width = asImpl().readUInt32();
	unsigned scale = asImpl().readUInt32();
	unsigned tmp = asImpl().readUInt32();
	bool isSigned = tmp & 0x1;
	bool isSaturated = tmp & 0x2;
	bool hasUnsignedPadding = tmp & 0x4;
	return llvm::FixedPointSemantics(width, scale, isSigned, isSaturated,
	hasUnsignedPadding);
	}

	APValue::LValuePathSerializationHelper readLValuePathSerializationHelper(
	SmallVectorImpl<APValue::LValuePathEntry> &path) {
	auto elemTy = asImpl().readQualType();
	unsigned pathLength = asImpl().readUInt32();
	for (unsigned i = 0; i < pathLength; ++i) {
	if (elemTy->template getAs<RecordType>()) {
	unsigned int_ = asImpl().readUInt32();
	Decl *decl = asImpl().template readDeclAs<Decl>();
	if (auto *recordDecl = dyn_cast<CXXRecordDecl>(decl))
	elemTy = getASTContext().getRecordType(recordDecl);
	else
	elemTy = cast<ValueDecl>(decl)->getType();
	path.push_back(
	APValue::LValuePathEntry(APValue::BaseOrMemberType(decl, int_)));
	} else {
	elemTy = getASTContext().getAsArrayType(elemTy)->getElementType();
	path.push_back(
	APValue::LValuePathEntry::ArrayIndex(asImpl().readUInt32()));
	}
	}
	return APValue::LValuePathSerializationHelper(path, elemTy);
	}

	Qualifiers readQualifiers() {
	static_assert(sizeof(Qualifiers().getAsOpaqueValue()) <= sizeof(uint32_t),
	"update this if the value size changes");
	uint32_t value = asImpl().readUInt32();
	return Qualifiers::fromOpaqueValue(value);
	}

	FunctionProtoType::ExceptionSpecInfo
	readExceptionSpecInfo(llvm::SmallVectorImpl<QualType> &buffer) {
	FunctionProtoType::ExceptionSpecInfo esi;
	esi.Type = ExceptionSpecificationType(asImpl().readUInt32());
	if (esi.Type == EST_Dynamic) {
	esi.Exceptions = asImpl().template readArray<QualType>(buffer);
	} else if (isComputedNoexcept(esi.Type)) {
	esi.NoexceptExpr = asImpl().readExprRef();
	} else if (esi.Type == EST_Uninstantiated) {
	esi.SourceDecl = asImpl().readFunctionDeclRef();
	esi.SourceTemplate = asImpl().readFunctionDeclRef();
	} else if (esi.Type == EST_Unevaluated) {
	esi.SourceDecl = asImpl().readFunctionDeclRef();
	}
	return esi;
	}

	FunctionProtoType::ExtParameterInfo readExtParameterInfo() {
	static_assert(sizeof(FunctionProtoType::ExtParameterInfo().getOpaqueValue())
	<= sizeof(uint32_t),
	"opaque value doesn't fit into uint32_t");
	uint32_t value = asImpl().readUInt32();
	return FunctionProtoType::ExtParameterInfo::getFromOpaqueValue(value);
	}

	NestedNameSpecifier *readNestedNameSpecifier() {
	auto &ctx = getASTContext();

	// We build this up iteratively.
	NestedNameSpecifier *cur = nullptr;

	uint32_t depth = asImpl().readUInt32();
	for (uint32_t i = 0; i != depth; ++i) {
	auto kind = asImpl().readNestedNameSpecifierKind();
	switch (kind) {
	case NestedNameSpecifier::Identifier:
	cur = NestedNameSpecifier::Create(ctx, cur,
	asImpl().readIdentifier());
	continue;

	case NestedNameSpecifier::Namespace:
	cur = NestedNameSpecifier::Create(ctx, cur,
	asImpl().readNamespaceDeclRef());
	continue;

	case NestedNameSpecifier::NamespaceAlias:
	cur = NestedNameSpecifier::Create(ctx, cur,
	asImpl().readNamespaceAliasDeclRef());
	continue;

	case NestedNameSpecifier::TypeSpec:
	case NestedNameSpecifier::TypeSpecWithTemplate:
	cur = NestedNameSpecifier::Create(ctx, cur,
	kind == NestedNameSpecifier::TypeSpecWithTemplate,
	asImpl().readQualType().getTypePtr());
	continue;

	case NestedNameSpecifier::Global:
	cur = NestedNameSpecifier::GlobalSpecifier(ctx);
	continue;

	case NestedNameSpecifier::Super:
	cur = NestedNameSpecifier::SuperSpecifier(ctx,
	asImpl().readCXXRecordDeclRef());
	continue;
	}
	llvm_unreachable("bad nested name specifier kind");
	}

	return cur;
	}
	};

	} // end namespace serialization
	} // end namespace clang

	#endif