目录
- 前言
- alloc方法源码探索
- 1. `alloc`方法:
- 2. `_objc_rootAlloc()`方法:
- 3. `callAlloc()`方法:
- 4. 里面有个`_objc_rootAllocWithZone()`方法:
- 5. `_class_createInstance()`方法:
- `instanceSize()`方法
- `malloc_instance`方法
- `initInstanceIsa`方法
- alloc流程总结
- init方法
- new方法
前言
先来看看下面这段代码:
Person* person = [Person alloc];
Person* person1 = [person init];
Person* person2 = [person init];
NSLog(@"person = %@ ** %p ** %p", person, person, &person);
NSLog(@"person1 = %@ ** %p ** %p", person1, person1, &person1);
NSLog(@"person2 = %@ ** %p ** %p", person2, person2, &person2);
运行结果:
可以看出person、person1以及person2的指针变量是不同的,但却指向了同一个内存地址,所以内存的申请开辟是在alloc方法里实现的,init方法只是生成对象指针并初始化一些信息,并没有对内存空间做任何处理
alloc方法源码探索
objc4 源码下载地址
1. alloc方法:
+ (id)alloc {return _objc_rootAlloc(self);
}
2. _objc_rootAlloc()方法:
// Base class implementation of +alloc. cls is not nil.
// Calls [cls allocWithZone:nil]. 从OC视角来看,alloc 实际会调用 allocWithZone:
id
_objc_rootAlloc(Class cls)
{return callAlloc(cls, false/*checkNil*/, true/*allocWithZone*/);
}
3. callAlloc()方法:
// Call [cls alloc] or [cls allocWithZone:nil], with appropriate
// shortcutting optimizations.
static ALWAYS_INLINE id
callAlloc(Class cls, bool checkNil, bool allocWithZone=false)
{if (slowpath(checkNil && !cls)) return nil;// 判断该类是否实现了自定义的 +allocWithZone:,没有则进入 if 条件语句if (fastpath(!cls->ISA()->hasCustomAWZ())) {return _objc_rootAllocWithZone(cls, nil);}// No shortcuts available.if (allocWithZone) {return ((id(*)(id, SEL, struct _NSZone *))objc_msgSend)(cls, @selector(allocWithZone:), nil);}return ((id(*)(id, SEL))objc_msgSend)(cls, @selector(alloc));
}
4. 里面有个_objc_rootAllocWithZone()方法:
id
_objc_rootAllocWithZone(Class cls, objc_zone_t)
{// allocWithZone under __OBJC2__ ignores the zone parameterreturn _class_createInstance(cls, 0, OBJECT_CONSTRUCT_CALL_BADALLOC);
}
5. _class_createInstance()方法:
static ALWAYS_INLINE id
_class_createInstance(Class cls, size_t extraBytes,int construct_flags = OBJECT_CONSTRUCT_NONE,bool cxxConstruct = true,size_t *outAllocatedSize = nil)
{ASSERT(cls->isRealized());// Read class's info bits all at once for performancebool hasCxxCtor = cxxConstruct && cls->hasCxxCtor();bool hasCxxDtor = cls->hasCxxDtor();bool fast = cls->canAllocNonpointer();size_t size;size = cls->instanceSize(extraBytes); //计算开辟内存大小if (outAllocatedSize) *outAllocatedSize = size;id obj = objc::malloc_instance(size, cls); //申请内存if (slowpath(!obj)) {if (construct_flags & OBJECT_CONSTRUCT_CALL_BADALLOC) {return _objc_callBadAllocHandler(cls);}return nil;}if (fast) {obj->initInstanceIsa(cls, hasCxxDtor); //关联当前类的 isa} else {// Use raw pointer isa on the assumption that they might be// doing something weird with the zone or RR.// 使用原始指针 isa,假设它们可能在处理区域(zone)或资源记录(RR)时做了一些特殊操作。obj->initIsa(cls);}if (fastpath(!hasCxxCtor)) {return obj;}construct_flags |= OBJECT_CONSTRUCT_FREE_ONFAILURE;return object_cxxConstructFromClass(obj, cls, construct_flags);
}
这个方法真正开辟了内存,3个关键步骤:instanceSize()计算开辟内存大小、objc::malloc_instance()开辟内存、initInstanceIsa()关联当前类的 isa
上面第 1 个方法提到alloc实际上调用的是allocWithZone:(struct _NSZone *)zone方法,查allocWithZone:的源码同样的能寻到上述后续步骤的方法
instanceSize()方法
inline size_t instanceSize(size_t extraBytes) const {// 快速计算内存大小if (fastpath(cache.hasFastInstanceSize(extraBytes))) {return cache.fastInstanceSize(extraBytes);}//计算类中所有变量需要的内存大小 extraBytes额外字节数一般是0size_t size = alignedInstanceSize() + extraBytes;// CF requires all objects be at least 16 bytes.if (size < 16) size = 16;return size;
}
fastInstanceSize()方法
size_t fastInstanceSize(size_t extra) const
{ASSERT(hasFastInstanceSize(extra));if (__builtin_constant_p(extra) && extra == 0) {return _flags & FAST_CACHE_ALLOC_MASK16;} else {size_t size = _flags & FAST_CACHE_ALLOC_MASK;// remove the FAST_CACHE_ALLOC_DELTA16 that was added// by setFastInstanceSizereturn align16(size + extra - FAST_CACHE_ALLOC_DELTA16);}
}
align16()方法(16 字节对齐)
static inline size_t align16(size_t x) {return (x + size_t(15)) & ~size_t(15);
}
这个函数是为了确保,传进去的
x值按照 16 字节对齐,也就是返回值必须是 16 的倍数。
因为掩码的最低4位为0,对 x + 15 的结果进行 & 操作后,会把结果中的最低4位清零,这意味着结果必定是16的倍数。原因是二进制中的数如果最后四位是0,则该数可以被16整除。
malloc_instance方法
static inline id
malloc_instance(size_t size, Class cls __unused)
{
#if _MALLOC_TYPE_ENABLEDmalloc_type_descriptor_t desc = {};desc.summary.type_kind = MALLOC_TYPE_KIND_OBJC;return (id)malloc_type_calloc(1, size, desc.type_id);
#elsereturn (id)calloc(1, size);
#endif
}
实际是调用calloc函数开辟内存
initInstanceIsa方法
inline void
objc_object::initInstanceIsa(Class cls, bool hasCxxDtor)
{ASSERT(!cls->instancesRequireRawIsa());ASSERT(hasCxxDtor == cls->hasCxxDtor());initIsa(cls, true, hasCxxDtor);
}
初始化 isa 指针,和类关联起来
alloc流程总结
init方法
- (id)init {return _objc_rootInit(self);
}id
_objc_rootInit(id obj)
{// In practice, it will be hard to rely on this function.// Many classes do not properly chain -init calls.return obj;
}
init方法返回的是对象本身,类似工厂模式,init方法的意义除了初始化内存,还可以扩展更多的初始化方法
new方法
+ (id)new {return [callAlloc(self, false/*checkNil*/) init];
}
new方法的底层实现就是调用alloc流程 + init方法
