/*
* Copyright 2006 The Android Open Source Project
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef SkRefCnt_DEFINED
#define SkRefCnt_DEFINED
#include "SkThread.h"
#include "SkInstCnt.h"
#include "SkTemplates.h"
/** \class SkRefCntBase
SkRefCntBase is the base class for objects that may be shared by multiple
objects. When an existing owner wants to share a reference, it calls ref().
When an owner wants to release its reference, it calls unref(). When the
shared object's reference count goes to zero as the result of an unref()
call, its (virtual) destructor is called. It is an error for the
destructor to be called explicitly (or via the object going out of scope on
the stack or calling delete) if getRefCnt() > 1.
*/
class SK_API SkRefCntBase : public SkNoncopyable {
public:
SK_DECLARE_INST_COUNT_ROOT(SkRefCntBase)
/** Default construct, initializing the reference count to 1.
*/
SkRefCntBase() : fRefCnt(1) {}
/** Destruct, asserting that the reference count is 1.
*/
virtual ~SkRefCntBase() {
#ifdef SK_DEBUG
SkASSERT(fRefCnt == 1);
fRefCnt = 0; // illegal value, to catch us if we reuse after delete
#endif
}
/** Return the reference count. Use only for debugging. */
int32_t getRefCnt() const { return fRefCnt; }
/** Returns true if the caller is the only owner.
* Ensures that all previous owner's actions are complete.
*/
bool unique() const {
bool const unique = (1 == fRefCnt);
if (unique) {
// Aquire barrier (L/SL), if not provided by load of fRefCnt.
// Prevents user's 'unique' code from happening before decrements.
//TODO: issue the barrier.
}
return unique;
}
/** Increment the reference count. Must be balanced by a call to unref().
*/
void ref() const {
SkASSERT(fRefCnt > 0);
sk_atomic_inc(&fRefCnt); // No barrier required.
}
/** Decrement the reference count. If the reference count is 1 before the
decrement, then delete the object. Note that if this is the case, then
the object needs to have been allocated via new, and not on the stack.
*/
void unref() const {
SkASSERT(fRefCnt > 0);
// Release barrier (SL/S), if not provided below.
if (sk_atomic_dec(&fRefCnt) == 1) {
// Aquire barrier (L/SL), if not provided above.
// Prevents code in dispose from happening before the decrement.
sk_membar_aquire__after_atomic_dec();
internal_dispose();
}
}
#ifdef SK_DEBUG
void validate() const {
SkASSERT(fRefCnt > 0);
}
#endif
protected:
/**
* Allow subclasses to call this if they've overridden internal_dispose
* so they can reset fRefCnt before the destructor is called. Should only
* be called right before calling through to inherited internal_dispose()
* or before calling the destructor.
*/
void internal_dispose_restore_refcnt_to_1() const {
#ifdef SK_DEBUG
SkASSERT(0 == fRefCnt);
fRefCnt = 1;
#endif
}
private:
/**
* Called when the ref count goes to 0.
*/
virtual void internal_dispose() const {
this->internal_dispose_restore_refcnt_to_1();
SkDELETE(this);
}
// The following friends are those which override internal_dispose()
// and conditionally call SkRefCnt::internal_dispose().
friend class GrTexture;
friend class SkWeakRefCnt;
mutable int32_t fRefCnt;
typedef SkNoncopyable INHERITED;
};
#ifdef SK_REF_CNT_MIXIN_INCLUDE
// It is the responsibility of the following include to define the type SkRefCnt.
// This SkRefCnt should normally derive from SkRefCntBase.
#include SK_REF_CNT_MIXIN_INCLUDE
#else
class SK_API SkRefCnt : public SkRefCntBase { };
#endif
///////////////////////////////////////////////////////////////////////////////
/** Helper macro to safely assign one SkRefCnt[TS]* to another, checking for
null in on each side of the assignment, and ensuring that ref() is called
before unref(), in case the two pointers point to the same object.
*/
#define SkRefCnt_SafeAssign(dst, src) \
do { \
if (src) src->ref(); \
if (dst) dst->unref(); \
dst = src; \
} while (0)
/** Call obj->ref() and return obj. The obj must not be NULL.
*/
template <typename T> static inline T* SkRef(T* obj) {
SkASSERT(obj);
obj->ref();
return obj;
}
/** Check if the argument is non-null, and if so, call obj->ref() and return obj.
*/
template <typename T> static inline T* SkSafeRef(T* obj) {
if (obj) {
obj->ref();
}
return obj;
}
/** Check if the argument is non-null, and if so, call obj->unref()
*/
template <typename T> static inline void SkSafeUnref(T* obj) {
if (obj) {
obj->unref();
}
}
template<typename T> static inline void SkSafeSetNull(T*& obj) {
if (NULL != obj) {
obj->unref();
obj = NULL;
}
}
///////////////////////////////////////////////////////////////////////////////
/**
* Utility class that simply unref's its argument in the destructor.
*/
template <typename T> class SkAutoTUnref : SkNoncopyable {
public:
explicit SkAutoTUnref(T* obj = NULL) : fObj(obj) {}
~SkAutoTUnref() { SkSafeUnref(fObj); }
T* get() const { return fObj; }
T* reset(T* obj) {
SkSafeUnref(fObj);
fObj = obj;
return obj;
}
void swap(SkAutoTUnref* other) {
T* tmp = fObj;
fObj = other->fObj;
other->fObj = tmp;
}
/**
* Return the hosted object (which may be null), transferring ownership.
* The reference count is not modified, and the internal ptr is set to NULL
* so unref() will not be called in our destructor. A subsequent call to
* detach() will do nothing and return null.
*/
T* detach() {
T* obj = fObj;
fObj = NULL;
return obj;
}
/**
* BlockRef<B> is a type which inherits from B, cannot be created,
* cannot be deleted, and makes ref and unref private.
*/
template<typename B> class BlockRef : public B {
private:
BlockRef();
~BlockRef();
void ref() const;
void unref() const;
};
/** If T is const, the type returned from operator-> will also be const. */
typedef typename SkTConstType<BlockRef<T>, SkTIsConst<T>::value>::type BlockRefType;
/**
* SkAutoTUnref assumes ownership of the ref. As a result, it is an error
* for the user to ref or unref through SkAutoTUnref. Therefore
* SkAutoTUnref::operator-> returns BlockRef<T>*. This prevents use of
* skAutoTUnrefInstance->ref() and skAutoTUnrefInstance->unref().
*/
BlockRefType *operator->() const {
return static_cast<BlockRefType*>(fObj);
}
operator T*() { return fObj; }
private:
T* fObj;
};
// Can't use the #define trick below to guard a bare SkAutoTUnref(...) because it's templated. :(
class SkAutoUnref : public SkAutoTUnref<SkRefCnt> {
public:
SkAutoUnref(SkRefCnt* obj) : SkAutoTUnref<SkRefCnt>(obj) {}
};
#define SkAutoUnref(...) SK_REQUIRE_LOCAL_VAR(SkAutoUnref)
class SkAutoRef : SkNoncopyable {
public:
SkAutoRef(SkRefCnt* obj) : fObj(obj) { SkSafeRef(obj); }
~SkAutoRef() { SkSafeUnref(fObj); }
private:
SkRefCnt* fObj;
};
#define SkAutoRef(...) SK_REQUIRE_LOCAL_VAR(SkAutoRef)
/** Wrapper class for SkRefCnt pointers. This manages ref/unref of a pointer to
a SkRefCnt (or subclass) object.
*/
template <typename T> class SkRefPtr {
public:
SkRefPtr() : fObj(NULL) {}
SkRefPtr(T* obj) : fObj(obj) { SkSafeRef(fObj); }
SkRefPtr(const SkRefPtr& o) : fObj(o.fObj) { SkSafeRef(fObj); }
~SkRefPtr() { SkSafeUnref(fObj); }
SkRefPtr& operator=(const SkRefPtr& rp) {
SkRefCnt_SafeAssign(fObj, rp.fObj);
return *this;
}
SkRefPtr& operator=(T* obj) {
SkRefCnt_SafeAssign(fObj, obj);
return *this;
}
T* get() const { return fObj; }
T& operator*() const { return *fObj; }
T* operator->() const { return fObj; }
typedef T* SkRefPtr::*unspecified_bool_type;
operator unspecified_bool_type() const {
return fObj ? &SkRefPtr::fObj : NULL;
}
private:
T* fObj;
};
#endif