third_party/skia/src/gpu/GrRefCnt.h - cobalt - Git at Google

 /*
  * Copyright 2020 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrRefCnt_DEFINED
 #define GrRefCnt_DEFINED

 #include "include/core/SkRefCnt.h"
 #include "src/gpu/GrGpuResource.h"
 #include "src/gpu/GrManagedResource.h"

 // We have to use auto for the function pointers here because if the actual functions live on the
 // base class of T we need the function here to be a pointer to a function of the base class and not
 // a function on T. Thus we can't have something like void(T::*Ref)() since we may need T or we may
 // need some base class of T.
 template <typename T, auto Ref, auto Unref> class gr_sp {
 private:
     static inline T* SafeRef(T* obj) {
         if (obj) {
             (obj->*Ref)();
         }
         return obj;
     }

     static inline void SafeUnref(T* obj) {
         if (obj) {
             (obj->*Unref)();
         }
     }

 public:
     using element_type = T;

     constexpr gr_sp() : fPtr(nullptr) {}
     constexpr gr_sp(std::nullptr_t) : fPtr(nullptr) {}

     /**
      * Shares the underlying object by calling Ref(), so that both the argument and the newly
      * created gr_sp both have a reference to it.
      */
     gr_sp(const gr_sp<T, Ref, Unref>& that) : fPtr(SafeRef(that.get())) {}
     template <typename U,
               typename = typename std::enable_if<std::is_convertible<U*, T*>::value>::type>
     gr_sp(const gr_sp<U, Ref, Unref>& that) : fPtr(SafeRef(that.get())) {}

     gr_sp(const sk_sp<T>& that) : fPtr(SafeRef(that.get())) {}


     /**
      * Move the underlying object from the argument to the newly created gr_sp. Afterwards only the
      * new gr_sp will have a reference to the object, and the argument will point to null.
      * No call to Ref() or Unref() will be made.
      */
     gr_sp(gr_sp<T, Ref, Unref>&& that) : fPtr(that.release()) {}

     /**
      * Copies the underlying object pointer from the argument to the gr_sp. It will then call
      * Ref() on the new object.
      */
     gr_sp(sk_sp<T>&& that) : fPtr(SafeRef(that.get())) {}

     /**
      *  Adopt the bare pointer into the newly created gr_sp.
      *  No call to Ref() or Unref() will be made.
      */
     explicit gr_sp(T* obj) : fPtr(obj) {}

     /**
      * Calls Unref() on the underlying object pointer.
      */
     ~gr_sp() {
         SafeUnref(fPtr);
         SkDEBUGCODE(fPtr = nullptr);
     }

     gr_sp& operator=(std::nullptr_t) {
         this->reset();
         return *this;
     }

     /**
      * Shares the underlying object referenced by the argument by calling Ref() on it. If this gr_sp
      * previously had a reference to an object (i.e. not null) it will call Unref() on that object.
      */
     gr_sp& operator=(const gr_sp<T, Ref, Unref>& that) {
         if (this != &that) {
             this->reset(SafeRef(that.get()));
         }
         return *this;
     }

     /**
      * Copies the underlying object pointer from the argument to the gr_sp. If the gr_sp previously
      * held a reference to another object, Unref() will be called on that object. It will then call
      * Ref() on the new object.
      */
     gr_sp& operator=(const sk_sp<T>& that) {
         this->reset(SafeRef(that.get()));
         return *this;
     }

     /**
      * Move the underlying object from the argument to the gr_sp. If the gr_sp previously held
      * a reference to another object, Unref() will be called on that object. No call to Ref() will
      * be made.
      */
     gr_sp& operator=(gr_sp<T, Ref, Unref>&& that) {
         this->reset(that.release());
         return *this;
     }

     /**
      * Copies the underlying object pointer from the argument to the gr_sp. If the gr_sp previously
      * held a reference to another object, Unref() will be called on that object. It will then call
      * Ref() on the new object.
      */
     gr_sp& operator=(sk_sp<T>&& that) {
         this->reset(SafeRef(that.get()));
         return *this;
     }

     T& operator*() const {
         SkASSERT(this->get() != nullptr);
         return *this->get();
     }

     explicit operator bool() const { return this->get() != nullptr; }

     T* get() const { return fPtr; }
     T* operator->() const { return fPtr; }

     /**
      * Adopt the new bare pointer, and call Unref() on any previously held object (if not null).
      * No call to Ref() will be made.
      */
     void reset(T* ptr = nullptr) {
         T* oldPtr = fPtr;
         fPtr = ptr;
         SafeUnref(oldPtr);
     }

 private:
     /**
      * Return the bare pointer, and set the internal object pointer to nullptr.
      * The caller must assume ownership of the object, and manage its reference count directly.
      * No call to Unref() will be made.
      */
     T* SK_WARN_UNUSED_RESULT release() {
         T* ptr = fPtr;
         fPtr = nullptr;
         return ptr;
     }

     T* fPtr;
 };

 ////////////////////////////////////////////////////////////////////////////////////////////////////

 /**
  * Shared pointer class to wrap classes that support a addCommandBufferUsage() and
  * removeCommandBufferUsage() interface.
  *
  * This class supports copying, moving, and assigning an sk_sp into it. In general these commands do
  * not modify the sk_sp at all but just call addCommandBufferUsage() on the underlying object.
  *
  * This class is designed to be used by GrGpuResources that need to track when they are in use on
  * gpu (usually via a command buffer) separately from tracking if there are any current logical
  * usages in Ganesh. This allows for a scratch GrGpuResource to be reused for new draw calls even
  * if it is in use on the GPU.
  */
 template <typename T>
 using gr_cb = gr_sp<T, &T::addCommandBufferUsage, &T::removeCommandBufferUsage>;

 ////////////////////////////////////////////////////////////////////////////////////////////////////

 /**
  * This class mimics sk_sp but instead of calling unref it calls recycle instead.
  */
 template <typename T> using gr_rp = gr_sp<T, &T::ref, &T::recycle>;

 /**
  *  Returns a gr_rp wrapping the provided ptr AND calls ref on it (if not null).
  *
  *  This is different than the semantics of the constructor for gr_rp, which just wraps the ptr,
  *  effectively "adopting" it.
  */
 template <typename T> gr_rp<T> gr_ref_rp(T* obj) { return gr_rp<T>(SkSafeRef(obj)); }

 template <typename T> gr_rp<T> gr_ref_rp(const T* obj) {
     return gr_rp<T>(const_cast<T*>(SkSafeRef(obj)));
 }
 #endif
	/*
	* Copyright 2020 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrRefCnt_DEFINED
	#define GrRefCnt_DEFINED

	#include "include/core/SkRefCnt.h"
	#include "src/gpu/GrGpuResource.h"
	#include "src/gpu/GrManagedResource.h"

	// We have to use auto for the function pointers here because if the actual functions live on the
	// base class of T we need the function here to be a pointer to a function of the base class and not
	// a function on T. Thus we can't have something like void(T::*Ref)() since we may need T or we may
	// need some base class of T.
	template <typename T, auto Ref, auto Unref> class gr_sp {
	private:
	static inline T* SafeRef(T* obj) {
	if (obj) {
	(obj->*Ref)();
	}
	return obj;
	}

	static inline void SafeUnref(T* obj) {
	if (obj) {
	(obj->*Unref)();
	}
	}

	public:
	using element_type = T;

	constexpr gr_sp() : fPtr(nullptr) {}
	constexpr gr_sp(std::nullptr_t) : fPtr(nullptr) {}

	/**
	* Shares the underlying object by calling Ref(), so that both the argument and the newly
	* created gr_sp both have a reference to it.
	*/
	gr_sp(const gr_sp<T, Ref, Unref>& that) : fPtr(SafeRef(that.get())) {}
	template <typename U,
	typename = typename std::enable_if<std::is_convertible<U, T>::value>::type>
	gr_sp(const gr_sp<U, Ref, Unref>& that) : fPtr(SafeRef(that.get())) {}

	gr_sp(const sk_sp<T>& that) : fPtr(SafeRef(that.get())) {}


	/**
	* Move the underlying object from the argument to the newly created gr_sp. Afterwards only the
	* new gr_sp will have a reference to the object, and the argument will point to null.
	* No call to Ref() or Unref() will be made.
	*/
	gr_sp(gr_sp<T, Ref, Unref>&& that) : fPtr(that.release()) {}

	/**
	* Copies the underlying object pointer from the argument to the gr_sp. It will then call
	* Ref() on the new object.
	*/
	gr_sp(sk_sp<T>&& that) : fPtr(SafeRef(that.get())) {}

	/**
	* Adopt the bare pointer into the newly created gr_sp.
	* No call to Ref() or Unref() will be made.
	*/
	explicit gr_sp(T* obj) : fPtr(obj) {}

	/**
	* Calls Unref() on the underlying object pointer.
	*/
	~gr_sp() {
	SafeUnref(fPtr);
	SkDEBUGCODE(fPtr = nullptr);
	}

	gr_sp& operator=(std::nullptr_t) {
	this->reset();
	return *this;
	}

	/**
	* Shares the underlying object referenced by the argument by calling Ref() on it. If this gr_sp
	* previously had a reference to an object (i.e. not null) it will call Unref() on that object.
	*/
	gr_sp& operator=(const gr_sp<T, Ref, Unref>& that) {
	if (this != &that) {
	this->reset(SafeRef(that.get()));
	}
	return *this;
	}

	/**
	* Copies the underlying object pointer from the argument to the gr_sp. If the gr_sp previously
	* held a reference to another object, Unref() will be called on that object. It will then call
	* Ref() on the new object.
	*/
	gr_sp& operator=(const sk_sp<T>& that) {
	this->reset(SafeRef(that.get()));
	return *this;
	}

	/**
	* Move the underlying object from the argument to the gr_sp. If the gr_sp previously held
	* a reference to another object, Unref() will be called on that object. No call to Ref() will
	* be made.
	*/
	gr_sp& operator=(gr_sp<T, Ref, Unref>&& that) {
	this->reset(that.release());
	return *this;
	}

	/**
	* Copies the underlying object pointer from the argument to the gr_sp. If the gr_sp previously
	* held a reference to another object, Unref() will be called on that object. It will then call
	* Ref() on the new object.
	*/
	gr_sp& operator=(sk_sp<T>&& that) {
	this->reset(SafeRef(that.get()));
	return *this;
	}

	T& operator*() const {
	SkASSERT(this->get() != nullptr);
	return *this->get();
	}

	explicit operator bool() const { return this->get() != nullptr; }

	T* get() const { return fPtr; }
	T* operator->() const { return fPtr; }

	/**
	* Adopt the new bare pointer, and call Unref() on any previously held object (if not null).
	* No call to Ref() will be made.
	*/
	void reset(T* ptr = nullptr) {
	T* oldPtr = fPtr;
	fPtr = ptr;
	SafeUnref(oldPtr);
	}

	private:
	/**
	* Return the bare pointer, and set the internal object pointer to nullptr.
	* The caller must assume ownership of the object, and manage its reference count directly.
	* No call to Unref() will be made.
	*/
	T* SK_WARN_UNUSED_RESULT release() {
	T* ptr = fPtr;
	fPtr = nullptr;
	return ptr;
	}

	T* fPtr;
	};

	////////////////////////////////////////////////////////////////////////////////////////////////////

	/**
	* Shared pointer class to wrap classes that support a addCommandBufferUsage() and
	* removeCommandBufferUsage() interface.
	*
	* This class supports copying, moving, and assigning an sk_sp into it. In general these commands do
	* not modify the sk_sp at all but just call addCommandBufferUsage() on the underlying object.
	*
	* This class is designed to be used by GrGpuResources that need to track when they are in use on
	* gpu (usually via a command buffer) separately from tracking if there are any current logical
	* usages in Ganesh. This allows for a scratch GrGpuResource to be reused for new draw calls even
	* if it is in use on the GPU.
	*/
	template <typename T>
	using gr_cb = gr_sp<T, &T::addCommandBufferUsage, &T::removeCommandBufferUsage>;

	////////////////////////////////////////////////////////////////////////////////////////////////////

	/**
	* This class mimics sk_sp but instead of calling unref it calls recycle instead.
	*/
	template <typename T> using gr_rp = gr_sp<T, &T::ref, &T::recycle>;

	/**
	* Returns a gr_rp wrapping the provided ptr AND calls ref on it (if not null).
	*
	* This is different than the semantics of the constructor for gr_rp, which just wraps the ptr,
	* effectively "adopting" it.
	*/
	template <typename T> gr_rp<T> gr_ref_rp(T* obj) { return gr_rp<T>(SkSafeRef(obj)); }

	template <typename T> gr_rp<T> gr_ref_rp(const T* obj) {
	return gr_rp<T>(const_cast<T*>(SkSafeRef(obj)));
	}
	#endif