selector

OC对象的本质 - objc_object

2021-07-26  本文已影响0人  希尔罗斯沃德_董

通过编译查看对象的本质

研究OC对象的底层结构可以通过将OC对象代码编译成C++代码来进行分析,然后结合源码学习。
首先创建一个demo,在main.c创建一个对象,代码如下:

@interface MyObject : NSObject

@property (nonatomic, copy) NSString *name;
@property (nonatomic, assign) int age;
@end

@implementation MyObject
@end

int main(int argc, char * argv[]) {
    
    MyObject *object = [[MyObject alloc] init];
    object.name = @"LN";
    object.age = 18;
}

通过xcrun -sdk iphonesimulator clang -arch arm64 -rewrite-objc main.m -o main.cpp命令将main.c文件编译成C++代码文件main.cpp。打开,找到MyObject相关的代码:

extern "C" unsigned long OBJC_IVAR_$_MyObject$_name;
extern "C" unsigned long OBJC_IVAR_$_MyObject$_age;
struct MyObject_IMPL {
    struct NSObject_IMPL NSObject_IVARS;
    int _age;
    NSString *_name;
};


// @property (nonatomic, copy) NSString *name;
// @property (nonatomic, assign) int age;
/* @end */


// @implementation MyObject

static NSString * _I_MyObject_name(MyObject * self, SEL _cmd) { return (*(NSString **)((char *)self + OBJC_IVAR_$_MyObject$_name)); }
extern "C" __declspec(dllimport) void objc_setProperty (id, SEL, long, id, bool, bool);

static void _I_MyObject_setName_(MyObject * self, SEL _cmd, NSString *name) { objc_setProperty (self, _cmd, __OFFSETOFIVAR__(struct MyObject, _name), (id)name, 0, 1); }

static int _I_MyObject_age(MyObject * self, SEL _cmd) { return (*(int *)((char *)self + OBJC_IVAR_$_MyObject$_age)); }
static void _I_MyObject_setAge_(MyObject * self, SEL _cmd, int age) { (*(int *)((char *)self + OBJC_IVAR_$_MyObject$_age)) = age; }
// @end

int main(int argc, char * argv[]) {

    MyObject *object = ((MyObject *(*)(id, SEL))(void *)objc_msgSend)((id)((MyObject *(*)(id, SEL))(void *)objc_msgSend)((id)objc_getClass("MyObject"), sel_registerName("alloc")), sel_registerName("init"));
    ((void (*)(id, SEL, NSString *))(void *)objc_msgSend)((id)object, sel_registerName("setName:"), (NSString *)&__NSConstantStringImpl__var_folders_kz_91163dcd57j_zw_xyry904bc0000gn_T_main_0e80b4_mi_0);
    ((void (*)(id, SEL, int))(void *)objc_msgSend)((id)object, sel_registerName("setAge:"), 18);

}

可以看到实际上MyObject在编译时被转换成结构体MyObject_IMPL,由此可知MyObject的本质是一个结构体。MyObject_IMPL里面除了自身的两个属性name和age之外,还有继承自NSObject的属性NSObject_IVARS, NSObject_IVARS就是NSObject的实例变量集,其实里面就是一个isa。通过源码查看NSObject的信息:

@interface NSObject <NSObject> {
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wobjc-interface-ivars"
    Class isa  OBJC_ISA_AVAILABILITY;
#pragma clang diagnostic pop
}
简化就是:
@interface NSObject <NSObject> {
    Class isa;
}

对象的基础objc_object

对象的底层结构就是一个结构体objc_object。objc_object是所有对象的根对象。类本身也是个对象,它的底层结构objc_class也是继承自objc_object的。那首先我们来看一下objc_object到底长什么样:

struct objc_object {
private:
    isa_t isa;

public:

    // ISA() assumes this is NOT a tagged pointer object
    Class ISA();

    // rawISA() assumes this is NOT a tagged pointer object or a non pointer ISA
    Class rawISA();

    // getIsa() allows this to be a tagged pointer object
    Class getIsa();
    
    uintptr_t isaBits() const;

    // initIsa() should be used to init the isa of new objects only.
    // If this object already has an isa, use changeIsa() for correctness.
    // initInstanceIsa(): objects with no custom RR/AWZ
    // initClassIsa(): class objects
    // initProtocolIsa(): protocol objects
    // initIsa(): other objects
    void initIsa(Class cls /*nonpointer=false*/);
    void initClassIsa(Class cls /*nonpointer=maybe*/);
    void initProtocolIsa(Class cls /*nonpointer=maybe*/);
    void initInstanceIsa(Class cls, bool hasCxxDtor);

    // changeIsa() should be used to change the isa of existing objects.
    // If this is a new object, use initIsa() for performance.
    Class changeIsa(Class newCls);

    bool hasNonpointerIsa();
    bool isTaggedPointer();
    bool isBasicTaggedPointer();
    bool isExtTaggedPointer();
    bool isClass();

    // object may have associated objects?
    bool hasAssociatedObjects();
    void setHasAssociatedObjects();

    // object may be weakly referenced?
    bool isWeaklyReferenced();
    void setWeaklyReferenced_nolock();

    // object may have -.cxx_destruct implementation?
    bool hasCxxDtor();

    // Optimized calls to retain/release methods
    id retain();
    void release();
    id autorelease();

    // Implementations of retain/release methods
    id rootRetain();
    bool rootRelease();
    id rootAutorelease();
    bool rootTryRetain();
    bool rootReleaseShouldDealloc();
    uintptr_t rootRetainCount();

    // Implementation of dealloc methods
    bool rootIsDeallocating();
    void clearDeallocating();
    void rootDealloc();

private:
    void initIsa(Class newCls, bool nonpointer, bool hasCxxDtor);

    // Slow paths for inline control
    id rootAutorelease2();
    uintptr_t overrelease_error();

#if SUPPORT_NONPOINTER_ISA
    // Unified retain count manipulation for nonpointer isa
    id rootRetain(bool tryRetain, bool handleOverflow);
    bool rootRelease(bool performDealloc, bool handleUnderflow);
    id rootRetain_overflow(bool tryRetain);
    uintptr_t rootRelease_underflow(bool performDealloc);

    void clearDeallocating_slow();

    // Side table retain count overflow for nonpointer isa
    void sidetable_lock();
    void sidetable_unlock();

    void sidetable_moveExtraRC_nolock(size_t extra_rc, bool isDeallocating, bool weaklyReferenced);
    bool sidetable_addExtraRC_nolock(size_t delta_rc);
    size_t sidetable_subExtraRC_nolock(size_t delta_rc);
    size_t sidetable_getExtraRC_nolock();
#endif

    // Side-table-only retain count
    bool sidetable_isDeallocating();
    void sidetable_clearDeallocating();

    bool sidetable_isWeaklyReferenced();
    void sidetable_setWeaklyReferenced_nolock();

    id sidetable_retain();
    id sidetable_retain_slow(SideTable& table);

    uintptr_t sidetable_release(bool performDealloc = true);
    uintptr_t sidetable_release_slow(SideTable& table, bool performDealloc = true);

    bool sidetable_tryRetain();

    uintptr_t sidetable_retainCount();
#if DEBUG
    bool sidetable_present();
#endif
};

通过源码可以发现,对象的底层方法还是很多的。许多关于retain、release的内存管理方法,还能判断是否是弱引用,还能判断是否是关联对象,方便了引用计数管理。当然还有很多关于isa的方法和isa指针。

isa指针

从源码可以看到,结构体objc_object唯一的属性是isa,这个isa是用来存储类指针的。对象的方法列表、缓存等信息都是存储在类结构中。所以对象需要通过isa关联类,以便访问类结构。isa在对象创建时被初始化。(点击了解对象创建流程):

inline void 
objc_object::initIsa(Class cls, bool nonpointer, UNUSED_WITHOUT_INDEXED_ISA_AND_DTOR_BIT bool hasCxxDtor)
objc_object类底层结构objc_class的基类

类也是对象,类的底层结构objc_class是继承自objc_object:

struct objc_class : objc_object {
  objc_class(const objc_class&) = delete;
  objc_class(objc_class&&) = delete;
  void operator=(const objc_class&) = delete;
  void operator=(objc_class&&) = delete;
    // Class ISA;
    Class superclass;
    cache_t cache;             // formerly cache pointer and vtable
    class_data_bits_t bits;    // class_rw_t * plus custom rr/alloc flags
......
}

关于更多类的详细的底层结构,可以参考OC类的底层结构objc_class

protocol底层结构也继承自objc_object

objc_object底层的存在形式也是对象,所以我们才可以像对象一样使用protocol。

struct protocol_t : objc_object {
    const char *mangledName;
    struct protocol_list_t *protocols;
    method_list_t *instanceMethods;
    method_list_t *classMethods;
    method_list_t *optionalInstanceMethods;
    method_list_t *optionalClassMethods;
    property_list_t *instanceProperties;
    uint32_t size;   // sizeof(protocol_t)
    uint32_t flags;
    // Fields below this point are not always present on disk.
    const char **_extendedMethodTypes;
    const char *_demangledName;
    property_list_t *_classProperties;

    const char *demangledName();

    const char *nameForLogging() {
        return demangledName();
    }

    bool isFixedUp() const;
    void setFixedUp();

    bool isCanonical() const;
    void clearIsCanonical();

#   define HAS_FIELD(f) ((uintptr_t)(&f) < ((uintptr_t)this + size))

    bool hasExtendedMethodTypesField() const {
        return HAS_FIELD(_extendedMethodTypes);
    }
    bool hasDemangledNameField() const {
        return HAS_FIELD(_demangledName);
    }
    bool hasClassPropertiesField() const {
        return HAS_FIELD(_classProperties);
    }

#   undef HAS_FIELD

    const char **extendedMethodTypes() const {
        return hasExtendedMethodTypesField() ? _extendedMethodTypes : nil;
    }

    property_list_t *classProperties() const {
        return hasClassPropertiesField() ? _classProperties : nil;
    }
};

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