之前分析了objc_class中的class_data_bits_t和isa,还剩下cache_t,今天来进行分析一下
结构
总结下来主要有4个参数:
bucket_t * _buckets; //缓存方法的散列表 explicit_atomic是原子性
mask_t _mask; //散列表的长度
uint16_t _flags;//标志位
uint16_t _occupied;//占用的空间
验证
1.
//创建Person类
@interface Person : NSObject
- (void)method1;
- (void)method2;
- (void)method3;
- (void)method4;
@end
//调用
Person *p = [Person alloc];
Class pClass = [Person class];
[p method1];
[p method2];
[p method3];
[p method4];
2. 先将断点断在[p method1];处,lldb调试
ps:如果不使用pClass,使用p.class,会调用class方法,并将class写入cache中,这样查看的mask与occupied不为0
3.点击step over执行一步,调试
此时,散列表长度变成了3,占用为1,查看缓存可以看到:
这里可以看到
method1已经在缓存中了。
注意点
1.cache_t结构体中,buckets的定义为explicit_atomic<struct bucket_t *> _buckets,你如果通过.buckets或->buckets 会发现根本无法获取到buckets,仔细阅读源码会发现cache_t中提供了struct bucket_t *buckets()用于获取buckets。所以如图,通过.buckets()获取,sel同理。
2.buckets是存在散列表中,如果有多个buckets可以通过指针偏移获取,再执行[p method2]:
3.继续执行[p method3],会发现mask变成了7,occupied变成了1
需要了解为什么会这样变化,我们需要从
cache_t的插入源码入手。
ALWAYS_INLINE
void cache_t::insert(Class cls, SEL sel, IMP imp, id receiver)
{
#if CONFIG_USE_CACHE_LOCK
cacheUpdateLock.assertLocked();
#else
runtimeLock.assertLocked();
#endif
ASSERT(sel != 0 && cls->isInitialized());
// Use the cache as-is if it is less than 3/4 full
mask_t newOccupied = occupied() + 1;
unsigned oldCapacity = capacity(), capacity = oldCapacity;
if (slowpath(isConstantEmptyCache())) {
// Cache is read-only. Replace it.
if (!capacity) capacity = INIT_CACHE_SIZE;
reallocate(oldCapacity, capacity, /* freeOld */false);
}
else if (fastpath(newOccupied + CACHE_END_MARKER <= capacity / 4 * 3)) { // 4 3 + 1 bucket cache_t
// Cache is less than 3/4 full. Use it as-is.
}
else {
capacity = capacity ? capacity * 2 : INIT_CACHE_SIZE; // 扩容两倍 4
if (capacity > MAX_CACHE_SIZE) {
capacity = MAX_CACHE_SIZE;
}
reallocate(oldCapacity, capacity, true); // 内存 库容完毕
}
bucket_t *b = buckets();
mask_t m = capacity - 1;
mask_t begin = cache_hash(sel, m);
mask_t i = begin;
// Scan for the first unused slot and insert there.
// There is guaranteed to be an empty slot because the
// minimum size is 4 and we resized at 3/4 full.
do {
if (fastpath(b[i].sel() == 0)) {
incrementOccupied();
b[i].set<Atomic, Encoded>(sel, imp, cls);
return;
}
if (b[i].sel() == sel) {
// The entry was added to the cache by some other thread
// before we grabbed the cacheUpdateLock.
return;
}
} while (fastpath((i = cache_next(i, m)) != begin));
cache_t::bad_cache(receiver, (SEL)sel, cls);
}
- 当缓存为空时,会初始化缓存
if (slowpath(isConstantEmptyCache())) {
// Cache is read-only. Replace it.
if (!capacity) capacity = INIT_CACHE_SIZE;
reallocate(oldCapacity, capacity, /* freeOld */false);
}
2.当缓存不为空,且不大于总大小的3/4减1时,不进行任何操作(#define CACHE_END_MARKER 1)
else if (fastpath(newOccupied + CACHE_END_MARKER <= capacity / 4 * 3)) { // 4 3 + 1 bucket cache_t
// Cache is less than 3/4 full. Use it as-is.
}
3.当总大小不够时,会进行扩容
else {
capacity = capacity ? capacity * 2 : INIT_CACHE_SIZE; // 扩容两倍 4
if (capacity > MAX_CACHE_SIZE) {
capacity = MAX_CACHE_SIZE;
}
reallocate(oldCapacity, capacity, true); // 内存 库容完毕
}
如此可以找到原因:第一次申请空间为4,mask为capacity-1=3,method1和method2插入时,满足newOccupied + CACHE_END_MARKER <= capacity / 4 * 3,而当method3插入时,newOccupied变为3,3+1>4/4*3所以要进行扩容,原有缓存被舍去,只插入了method3,故occupied变成了1,mask变成了7。
其他
cache的插入时乱序的。
bucket_t *b = buckets();
mask_t m = capacity - 1;
mask_t begin = cache_hash(sel, m);
mask_t i = begin;
// Scan for the first unused slot and insert there.
// There is guaranteed to be an empty slot because the
// minimum size is 4 and we resized at 3/4 full.
do {
if (fastpath(b[i].sel() == 0)) {
incrementOccupied();
b[i].set<Atomic, Encoded>(sel, imp, cls);
return;
}
if (b[i].sel() == sel) {
// The entry was added to the cache by some other thread
// before we grabbed the cacheUpdateLock.
return;
}
} while (fastpath((i = cache_next(i, m)) != begin));
-
cache的插入不是顺序插入,是先做一次哈希计算,由这个值开始mask_t begin = cache_hash(sel, m)
2.cache当哈希计算出的位置中值为空时,插入。
if (fastpath(b[i].sel() == 0)) {
incrementOccupied();
b[i].set<Atomic, Encoded>(sel, imp, cls);
return;
}
3.哈希计算的位置值相同时跳过,不再插入。
if (b[i].sel() == sel) {
// The entry was added to the cache by some other thread
// before we grabbed the cacheUpdateLock.
return;
}
4.继续哈希,直到找到合适的位置插入while (fastpath((i = cache_next(i, m)) != begin))
