src/third_party/llvm-project/clang-tools-extra/clangd/Context.h - cobalt - Git at Google

 //===--- Context.h - Mechanism for passing implicit data --------*- C++-*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Context for storing and retrieving implicit data. Useful for passing implicit
 // parameters on a per-request basis.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_TOOLS_EXTRA_CLANGD_CONTEXT_H_
 #define LLVM_CLANG_TOOLS_EXTRA_CLANGD_CONTEXT_H_

 #include "llvm/ADT/STLExtras.h"
 #include "llvm/Support/Compiler.h"
 #include <memory>
 #include <type_traits>

 namespace clang {
 namespace clangd {

 /// Values in a Context are indexed by typed keys.
 /// Key<T> serves two purposes:
 ///   - it provides a lookup key for the context (each Key is unique),
 ///   - it makes lookup type-safe: a Key<T> can only map to a T (or nothing).
 ///
 /// Example:
 ///    Key<int> RequestID;
 ///    Key<int> Version;
 ///
 ///    Context Ctx = Context::empty().derive(RequestID, 10).derive(Version, 3);
 ///    assert(*Ctx.get(RequestID) == 10);
 ///    assert(*Ctx.get(Version) == 3);
 ///
 /// Keys are typically used across multiple functions, so most of the time you
 /// would want to make them static class members or global variables.
 template <class Type> class Key {
 public:
   static_assert(!std::is_reference<Type>::value,
                 "Reference arguments to Key<> are not allowed");

   constexpr Key() = default;

   Key(Key const &) = delete;
   Key &operator=(Key const &) = delete;
   Key(Key &&) = delete;
   Key &operator=(Key &&) = delete;
 };

 /// A context is an immutable container for per-request data that must be
 /// propagated through layers that don't care about it. An example is a request
 /// ID that we may want to use when logging.
 ///
 /// Conceptually, a context is a heterogeneous map<Key<T>, T>. Each key has
 /// an associated value type, which allows the map to be typesafe.
 ///
 /// There is an "ambient" context for each thread, Context::current().
 /// Most functions should read from this, and use WithContextValue or
 /// WithContext to extend or replace the context within a block scope.
 /// Only code dealing with threads and extension points should need to use
 /// other Context objects.
 ///
 /// You can't add data to an existing context, instead you create a new
 /// immutable context derived from it with extra data added. When you retrieve
 /// data, the context will walk up the parent chain until the key is found.
 class Context {
 public:
   /// Returns an empty root context that contains no data.
   static Context empty();
   /// Returns the context for the current thread, creating it if needed.
   static const Context &current();
   // Sets the current() context to Replacement, and returns the old context.
   // Prefer to use WithContext or WithContextValue to do this safely.
   static Context swapCurrent(Context Replacement);

 private:
   struct Data;
   Context(std::shared_ptr<const Data> DataPtr);

 public:
   /// Same as Context::empty(), please use Context::empty() instead.
   /// Constructor is defined to workaround a bug in MSVC's version of STL.
   /// (arguments of std::future<> must be default-construcitble in MSVC).
   Context() = default;

   /// Copy operations for this class are deleted, use an explicit clone() method
   /// when you need a copy of the context instead.
   Context(Context const &) = delete;
   Context &operator=(const Context &) = delete;

   Context(Context &&) = default;
   Context &operator=(Context &&) = default;

   /// Get data stored for a typed \p Key. If values are not found
   /// \returns Pointer to the data associated with \p Key. If no data is
   /// specified for \p Key, return null.
   template <class Type> const Type *get(const Key<Type> &Key) const {
     for (const Data *DataPtr = this->DataPtr.get(); DataPtr != nullptr;
          DataPtr = DataPtr->Parent.get()) {
       if (DataPtr->KeyPtr == &Key)
         return static_cast<const Type *>(DataPtr->Value->getValuePtr());
     }
     return nullptr;
   }

   /// A helper to get a reference to a \p Key that must exist in the map.
   /// Must not be called for keys that are not in the map.
   template <class Type> const Type &getExisting(const Key<Type> &Key) const {
     auto Val = get(Key);
     assert(Val && "Key does not exist");
     return *Val;
   }

   /// Derives a child context
   /// It is safe to move or destroy a parent context after calling derive().
   /// The child will keep its parent alive, and its data remains accessible.
   template <class Type>
   Context derive(const Key<Type> &Key,
                  typename std::decay<Type>::type Value) const & {
     return Context(std::make_shared<Data>(Data{
         /*Parent=*/DataPtr, &Key,
         llvm::make_unique<TypedAnyStorage<typename std::decay<Type>::type>>(
             std::move(Value))}));
   }

   template <class Type>
   Context
   derive(const Key<Type> &Key,
          typename std::decay<Type>::type Value) && /* takes ownership */ {
     return Context(std::make_shared<Data>(Data{
         /*Parent=*/std::move(DataPtr), &Key,
         llvm::make_unique<TypedAnyStorage<typename std::decay<Type>::type>>(
             std::move(Value))}));
   }

   /// Derives a child context, using an anonymous key.
   /// Intended for objects stored only for their destructor's side-effect.
   template <class Type> Context derive(Type &&Value) const & {
     static Key<typename std::decay<Type>::type> Private;
     return derive(Private, std::forward<Type>(Value));
   }

   template <class Type> Context derive(Type &&Value) && {
     static Key<typename std::decay<Type>::type> Private;
     return std::move(*this).derive(Private, std::forward<Type>(Value));
   }

   /// Clone this context object.
   Context clone() const;

 private:
   class AnyStorage {
   public:
     virtual ~AnyStorage() = default;
     virtual void *getValuePtr() = 0;
   };

   template <class T> class TypedAnyStorage : public Context::AnyStorage {
     static_assert(std::is_same<typename std::decay<T>::type, T>::value,
                   "Argument to TypedAnyStorage must be decayed");

   public:
     TypedAnyStorage(T &&Value) : Value(std::move(Value)) {}

     void *getValuePtr() override { return &Value; }

   private:
     T Value;
   };

   struct Data {
     // We need to make sure Parent outlives the Value, so the order of members
     // is important. We do that to allow classes stored in Context's child
     // layers to store references to the data in the parent layers.
     std::shared_ptr<const Data> Parent;
     const void *KeyPtr;
     std::unique_ptr<AnyStorage> Value;
   };

   std::shared_ptr<const Data> DataPtr;
 };

 /// WithContext replaces Context::current() with a provided scope.
 /// When the WithContext is destroyed, the original scope is restored.
 /// For extending the current context with new value, prefer WithContextValue.
 class LLVM_NODISCARD WithContext {
 public:
   WithContext(Context C) : Restore(Context::swapCurrent(std::move(C))) {}
   ~WithContext() { Context::swapCurrent(std::move(Restore)); }
   WithContext(const WithContext &) = delete;
   WithContext &operator=(const WithContext &) = delete;
   WithContext(WithContext &&) = delete;
   WithContext &operator=(WithContext &&) = delete;

 private:
   Context Restore;
 };

 /// WithContextValue extends Context::current() with a single value.
 /// When the WithContextValue is destroyed, the original scope is restored.
 class LLVM_NODISCARD WithContextValue {
 public:
   template <typename T>
   WithContextValue(const Key<T> &K, typename std::decay<T>::type V)
       : Restore(Context::current().derive(K, std::move(V))) {}

   // Anonymous values can be used for the destructor side-effect.
   template <typename T>
   WithContextValue(T &&V)
       : Restore(Context::current().derive(std::forward<T>(V))) {}

 private:
   WithContext Restore;
 };

 } // namespace clangd
 } // namespace clang

 #endif // LLVM_CLANG_TOOLS_EXTRA_CLANGD_CONTEXT_H_
	//===--- Context.h - Mechanism for passing implicit data --------- C++--===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Context for storing and retrieving implicit data. Useful for passing implicit
	// parameters on a per-request basis.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_TOOLS_EXTRA_CLANGD_CONTEXT_H_
	#define LLVM_CLANG_TOOLS_EXTRA_CLANGD_CONTEXT_H_

	#include "llvm/ADT/STLExtras.h"
	#include "llvm/Support/Compiler.h"
	#include <memory>
	#include <type_traits>

	namespace clang {
	namespace clangd {

	/// Values in a Context are indexed by typed keys.
	/// Key<T> serves two purposes:
	/// - it provides a lookup key for the context (each Key is unique),
	/// - it makes lookup type-safe: a Key<T> can only map to a T (or nothing).
	///
	/// Example:
	/// Key<int> RequestID;
	/// Key<int> Version;
	///
	/// Context Ctx = Context::empty().derive(RequestID, 10).derive(Version, 3);
	/// assert(*Ctx.get(RequestID) == 10);
	/// assert(*Ctx.get(Version) == 3);
	///
	/// Keys are typically used across multiple functions, so most of the time you
	/// would want to make them static class members or global variables.
	template <class Type> class Key {
	public:
	static_assert(!std::is_reference<Type>::value,
	"Reference arguments to Key<> are not allowed");

	constexpr Key() = default;

	Key(Key const &) = delete;
	Key &operator=(Key const &) = delete;
	Key(Key &&) = delete;
	Key &operator=(Key &&) = delete;
	};

	/// A context is an immutable container for per-request data that must be
	/// propagated through layers that don't care about it. An example is a request
	/// ID that we may want to use when logging.
	///
	/// Conceptually, a context is a heterogeneous map<Key<T>, T>. Each key has
	/// an associated value type, which allows the map to be typesafe.
	///
	/// There is an "ambient" context for each thread, Context::current().
	/// Most functions should read from this, and use WithContextValue or
	/// WithContext to extend or replace the context within a block scope.
	/// Only code dealing with threads and extension points should need to use
	/// other Context objects.
	///
	/// You can't add data to an existing context, instead you create a new
	/// immutable context derived from it with extra data added. When you retrieve
	/// data, the context will walk up the parent chain until the key is found.
	class Context {
	public:
	/// Returns an empty root context that contains no data.
	static Context empty();
	/// Returns the context for the current thread, creating it if needed.
	static const Context &current();
	// Sets the current() context to Replacement, and returns the old context.
	// Prefer to use WithContext or WithContextValue to do this safely.
	static Context swapCurrent(Context Replacement);

	private:
	struct Data;
	Context(std::shared_ptr<const Data> DataPtr);

	public:
	/// Same as Context::empty(), please use Context::empty() instead.
	/// Constructor is defined to workaround a bug in MSVC's version of STL.
	/// (arguments of std::future<> must be default-construcitble in MSVC).
	Context() = default;

	/// Copy operations for this class are deleted, use an explicit clone() method
	/// when you need a copy of the context instead.
	Context(Context const &) = delete;
	Context &operator=(const Context &) = delete;

	Context(Context &&) = default;
	Context &operator=(Context &&) = default;

	/// Get data stored for a typed \p Key. If values are not found
	/// \returns Pointer to the data associated with \p Key. If no data is
	/// specified for \p Key, return null.
	template <class Type> const Type *get(const Key<Type> &Key) const {
	for (const Data *DataPtr = this->DataPtr.get(); DataPtr != nullptr;
	DataPtr = DataPtr->Parent.get()) {
	if (DataPtr->KeyPtr == &Key)
	return static_cast<const Type *>(DataPtr->Value->getValuePtr());
	}
	return nullptr;
	}

	/// A helper to get a reference to a \p Key that must exist in the map.
	/// Must not be called for keys that are not in the map.
	template <class Type> const Type &getExisting(const Key<Type> &Key) const {
	auto Val = get(Key);
	assert(Val && "Key does not exist");
	return *Val;
	}

	/// Derives a child context
	/// It is safe to move or destroy a parent context after calling derive().
	/// The child will keep its parent alive, and its data remains accessible.
	template <class Type>
	Context derive(const Key<Type> &Key,
	typename std::decay<Type>::type Value) const & {
	return Context(std::make_shared<Data>(Data{
	/Parent=/DataPtr, &Key,
	llvm::make_unique<TypedAnyStorage<typename std::decay<Type>::type>>(
	std::move(Value))}));
	}

	template <class Type>
	Context
	derive(const Key<Type> &Key,
	typename std::decay<Type>::type Value) && /* takes ownership */ {
	return Context(std::make_shared<Data>(Data{
	/Parent=/std::move(DataPtr), &Key,
	llvm::make_unique<TypedAnyStorage<typename std::decay<Type>::type>>(
	std::move(Value))}));
	}

	/// Derives a child context, using an anonymous key.
	/// Intended for objects stored only for their destructor's side-effect.
	template <class Type> Context derive(Type &&Value) const & {
	static Key<typename std::decay<Type>::type> Private;
	return derive(Private, std::forward<Type>(Value));
	}

	template <class Type> Context derive(Type &&Value) && {
	static Key<typename std::decay<Type>::type> Private;
	return std::move(*this).derive(Private, std::forward<Type>(Value));
	}

	/// Clone this context object.
	Context clone() const;

	private:
	class AnyStorage {
	public:
	virtual ~AnyStorage() = default;
	virtual void *getValuePtr() = 0;
	};

	template <class T> class TypedAnyStorage : public Context::AnyStorage {
	static_assert(std::is_same<typename std::decay<T>::type, T>::value,
	"Argument to TypedAnyStorage must be decayed");

	public:
	TypedAnyStorage(T &&Value) : Value(std::move(Value)) {}

	void *getValuePtr() override { return &Value; }

	private:
	T Value;
	};

	struct Data {
	// We need to make sure Parent outlives the Value, so the order of members
	// is important. We do that to allow classes stored in Context's child
	// layers to store references to the data in the parent layers.
	std::shared_ptr<const Data> Parent;
	const void *KeyPtr;
	std::unique_ptr<AnyStorage> Value;
	};

	std::shared_ptr<const Data> DataPtr;
	};

	/// WithContext replaces Context::current() with a provided scope.
	/// When the WithContext is destroyed, the original scope is restored.
	/// For extending the current context with new value, prefer WithContextValue.
	class LLVM_NODISCARD WithContext {
	public:
	WithContext(Context C) : Restore(Context::swapCurrent(std::move(C))) {}
	~WithContext() { Context::swapCurrent(std::move(Restore)); }
	WithContext(const WithContext &) = delete;
	WithContext &operator=(const WithContext &) = delete;
	WithContext(WithContext &&) = delete;
	WithContext &operator=(WithContext &&) = delete;

	private:
	Context Restore;
	};

	/// WithContextValue extends Context::current() with a single value.
	/// When the WithContextValue is destroyed, the original scope is restored.
	class LLVM_NODISCARD WithContextValue {
	public:
	template <typename T>
	WithContextValue(const Key<T> &K, typename std::decay<T>::type V)
	: Restore(Context::current().derive(K, std::move(V))) {}

	// Anonymous values can be used for the destructor side-effect.
	template <typename T>
	WithContextValue(T &&V)
	: Restore(Context::current().derive(std::forward<T>(V))) {}

	private:
	WithContext Restore;
	};

	} // namespace clangd
	} // namespace clang

	#endif // LLVM_CLANG_TOOLS_EXTRA_CLANGD_CONTEXT_H_