/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #ifndef WEBGLOBJECTMODEL_H_ #define WEBGLOBJECTMODEL_H_ #include "nsCycleCollectionNoteChild.h" #include "nsICanvasRenderingContextInternal.h" #include "WebGLTypes.h" namespace mozilla { class WebGLBuffer; class WebGLContext; /* Each WebGL object class WebGLFoo wants to: * - inherit WebGLRefCountedObject * - implement a Delete() method * - have its destructor call DeleteOnce() * * This base class provides two features to WebGL object types: * 1. support for OpenGL object reference counting * 2. support for OpenGL deletion statuses * ***** 1. OpenGL object reference counting ***** * * WebGL objects such as WebGLTexture's really have two different refcounts: * the XPCOM refcount, that is directly exposed to JavaScript, and the OpenGL * refcount. * * For example, when in JavaScript one does: var newname = existingTexture; * that increments the XPCOM refcount, but doesn't affect the OpenGL refcount. * When one attaches the texture to a framebuffer object, that does increment * its OpenGL refcount (and also its XPCOM refcount, to prevent the regular * XPCOM refcounting mechanism from destroying objects prematurely). * * The actual OpenGL refcount is opaque to us (it's internal to the OpenGL * implementation) but is affects the WebGL semantics that we have to implement: * for example, a WebGLTexture that is attached to a WebGLFramebuffer must not * be actually deleted, even if deleteTexture has been called on it, and even * if JavaScript doesn't have references to it anymore. We can't just rely on * OpenGL to keep alive the underlying OpenGL texture for us, for a variety of * reasons, most importantly: we'd need to know when OpenGL objects are actually * deleted, and OpenGL doesn't notify us about that, so we would have to query * status very often with glIsXxx calls which isn't practical. * * This means that we have to keep track of the OpenGL refcount ourselves, * in addition to the XPCOM refcount. * * This class implements such a refcount, see the mWebGLRefCnt * member. In order to avoid name clashes (with regular XPCOM refcounting) * in the derived class, we prefix members with 'WebGL', whence the names * WebGLAddRef, WebGLRelease, etc. * * In practice, WebGLAddRef and WebGLRelease are only called from the * WebGLRefPtr class. * ***** 2. OpenGL deletion statuses ***** * * In OpenGL, an object can go through 3 different deletion statuses during its * lifetime, which correspond to the 3 enum values for DeletionStatus in this class: * - the Default status, which it has from its creation to when the * suitable glDeleteXxx function is called on it; * - the DeleteRequested status, which is has from when the suitable glDeleteXxx * function is called on it to when it is no longer referenced by other OpenGL * objects. For example, a texture that is attached to a non-current FBO * will enter that status when glDeleteTexture is called on it. For objects * with that status, GL_DELETE_STATUS queries return true, but glIsXxx * functions still return true. * - the Deleted status, which is the status of objects on which the * suitable glDeleteXxx function has been called, and that are not referenced * by other OpenGL objects. * * This state is stored in the mDeletionStatus member of this class. * * When the GL refcount hits zero, if the status is DeleteRequested then we call * the Delete() method on the derived class and the status becomes Deleted. This is * what the MaybeDelete() function does. * * The DeleteOnce() function implemented here is a helper to ensure that we don't * call Delete() twice on the same object. Since the derived class' destructor * needs to call DeleteOnce() which calls Delete(), we can't allow either to be * virtual. Strictly speaking, we could let them be virtual if the derived class * were final, but that would be impossible to enforce and would lead to strange * bugs if it were subclassed. * * This WebGLRefCountedObject class takes the Derived type * as template parameter, as a means to allow DeleteOnce to call Delete() * on the Derived class, without either method being virtual. This is a common * C++ pattern known as the "curiously recursive template pattern (CRTP)". */ template class WebGLRefCountedObject { public: enum DeletionStatus { Default, DeleteRequested, Deleted }; WebGLRefCountedObject() : mDeletionStatus(Default) { } ~WebGLRefCountedObject() { MOZ_ASSERT(mWebGLRefCnt == 0, "destroying WebGL object still referenced by other WebGL objects"); MOZ_ASSERT(mDeletionStatus == Deleted, "Derived class destructor must call DeleteOnce()"); } // called by WebGLRefPtr void WebGLAddRef() { ++mWebGLRefCnt; } // called by WebGLRefPtr void WebGLRelease() { MOZ_ASSERT(mWebGLRefCnt > 0, "releasing WebGL object with WebGL refcnt already zero"); --mWebGLRefCnt; MaybeDelete(); } // this is the function that WebGL.deleteXxx() functions want to call void RequestDelete() { if (mDeletionStatus == Default) mDeletionStatus = DeleteRequested; MaybeDelete(); } bool IsDeleted() const { return mDeletionStatus == Deleted; } bool IsDeleteRequested() const { return mDeletionStatus != Default; } void DeleteOnce() { if (mDeletionStatus != Deleted) { static_cast(this)->Delete(); mDeletionStatus = Deleted; } } private: void MaybeDelete() { if (mWebGLRefCnt == 0 && mDeletionStatus == DeleteRequested) { DeleteOnce(); } } protected: nsAutoRefCnt mWebGLRefCnt; DeletionStatus mDeletionStatus; }; /* This WebGLRefPtr class is meant to be used for references between WebGL objects. * For example, a WebGLProgram holds WebGLRefPtr's to the WebGLShader's attached * to it. * * Why the need for a separate refptr class? The only special thing that WebGLRefPtr * does is that it increments and decrements the WebGL refcount of * WebGLRefCountedObject's, in addition to incrementing and decrementing the * usual XPCOM refcount. * * This means that by using a WebGLRefPtr instead of a nsRefPtr, you ensure that * the WebGL refcount is incremented, which means that the object will be kept * alive by this reference even if the matching webgl.deleteXxx() function is * called on it. */ template class WebGLRefPtr { public: WebGLRefPtr() : mRawPtr(0) { } WebGLRefPtr(const WebGLRefPtr& aSmartPtr) : mRawPtr(aSmartPtr.mRawPtr) { AddRefOnPtr(mRawPtr); } WebGLRefPtr(T *aRawPtr) : mRawPtr(aRawPtr) { AddRefOnPtr(mRawPtr); } ~WebGLRefPtr() { ReleasePtr(mRawPtr); } WebGLRefPtr& operator=(const WebGLRefPtr& rhs) { assign_with_AddRef(rhs.mRawPtr); return *this; } WebGLRefPtr& operator=(T* rhs) { assign_with_AddRef(rhs); return *this; } T* get() const { return static_cast(mRawPtr); } operator T*() const { return get(); } T* operator->() const { MOZ_ASSERT(mRawPtr != 0, "You can't dereference a nullptr WebGLRefPtr with operator->()!"); return get(); } T& operator*() const { MOZ_ASSERT(mRawPtr != 0, "You can't dereference a nullptr WebGLRefPtr with operator*()!"); return *get(); } private: static void AddRefOnPtr(T* rawPtr) { if (rawPtr) { rawPtr->WebGLAddRef(); rawPtr->AddRef(); } } static void ReleasePtr(T* rawPtr) { if (rawPtr) { rawPtr->WebGLRelease(); // must be done first before Release(), as Release() might actually destroy the object rawPtr->Release(); } } void assign_with_AddRef(T* rawPtr) { AddRefOnPtr(rawPtr); assign_assuming_AddRef(rawPtr); } void assign_assuming_AddRef(T* newPtr) { T* oldPtr = mRawPtr; mRawPtr = newPtr; ReleasePtr(oldPtr); } protected: T *mRawPtr; }; // This class is a mixin for objects that are tied to a specific // context (which is to say, all of them). They provide initialization // as well as comparison with the current context. class WebGLContextBoundObject { public: WebGLContextBoundObject(WebGLContext *context); bool IsCompatibleWithContext(WebGLContext *other); WebGLContext *Context() const { return mContext; } protected: WebGLContext *mContext; uint32_t mContextGeneration; }; // this class is a mixin for GL objects that have dimensions // that we need to track. class WebGLRectangleObject { public: WebGLRectangleObject() : mWidth(0), mHeight(0) { } WebGLRectangleObject(GLsizei width, GLsizei height) : mWidth(width), mHeight(height) { } GLsizei Width() const { return mWidth; } void width(GLsizei value) { mWidth = value; } GLsizei Height() const { return mHeight; } void height(GLsizei value) { mHeight = value; } void setDimensions(GLsizei width, GLsizei height) { mWidth = width; mHeight = height; } void setDimensions(WebGLRectangleObject *rect) { if (rect) { mWidth = rect->Width(); mHeight = rect->Height(); } else { mWidth = 0; mHeight = 0; } } bool HasSameDimensionsAs(const WebGLRectangleObject& other) const { return Width() == other.Width() && Height() == other.Height(); } protected: GLsizei mWidth; GLsizei mHeight; }; }// namespace mozilla template inline void ImplCycleCollectionUnlink(mozilla::WebGLRefPtr& aField) { aField = nullptr; } template inline void ImplCycleCollectionTraverse(nsCycleCollectionTraversalCallback& aCallback, mozilla::WebGLRefPtr& aField, const char* aName, uint32_t aFlags = 0) { CycleCollectionNoteChild(aCallback, aField.get(), aName, aFlags); } #endif