《STL源代码剖析》---stl_alloc.h阅读笔记
这一节是讲空间的配置与释放,但不涉及对象的构造和析构,仅仅是解说对象构造前空前的申请以及对象析构后空间怎么释放。
SGI版本号的STL对空间的的申请和释放做了例如以下考虑:
1、向堆申请空间
2、考虑了多线程。可是这节目的仅仅是解说空间配置与释放,因此忽略了多线程。集中学习空间的申请和释放。
3、内存不足时的应变措施
4、考虑到了内存碎片的问题。多次申请释放小块内存可能会造成内存碎片。
在C++中。内存的申请和释放是通过operator new函数和operator delete函数,这两个函数相当于C语言中的malloc和free,可是SGI使用的是malloc和free来完毕空间配置与释放的。原因一方面可能是历史原因。还有一方面是C++并没有提供对应于realloc()函数的类似函数。这样就不能直接用C++的set_new_hanlder()来处理内存分配失败的情况,所以仿真一个set_malloc_hanlder()函数。
为了解决内存碎片问题。SGI设计了双层级配置器。
第一级配置器直接使用malloc和free函数,当申请内存大于128bytes,就觉得“足够大”,使用第一级配置器。
第二级配置器使用了memory pool的方式。在pool中维护着已经开辟“小内存”。使用一个free list维护,当使用时。直接从free list中取。使用完后,还给free list。当free list中内存不足时。从memory pool中取内存填入free list中。
SGI维护着16个free lists,这16个list各自管理大小分别为8、16、24、32、40、48、56、64、72、80、88、96、104、112、120、128bytes大小的内存,当申请内存小鱼128bytes时,自己主动向上添加到8的倍数以便于在free lists中取。
以下是源码和加的一些凝视
G++ 2.91.57,cygnus\cygwin-b20\include\g++\stl_alloc.h 完整列表 /* * Copyright (c) 1996-1997 * Silicon Graphics Computer Systems, Inc. * * Permission to use, copy, modify, distribute and sell this software * and its documentation for any purpose is hereby granted without fee, * provided that the above copyright notice appear in all copies and * that both that copyright notice and this permission notice appear * in supporting documentation. Silicon Graphics makes no * representations about the suitability of this software for any * purpose. It is provided "as is" without express or implied warranty. */ /* NOTE: This is an internal header file, included by other STL headers. * You should not attempt to use it directly. */ #ifndef __SGI_STL_INTERNAL_ALLOC_H #define __SGI_STL_INTERNAL_ALLOC_H #ifdef __SUNPRO_CC # define __PRIVATE public // Extra access restrictions prevent us from really making some things // private. #else # define __PRIVATE private #endif #ifdef __STL_STATIC_TEMPLATE_MEMBER_BUG # define __USE_MALLOC #endif #if 0 # include <new> # define __THROW_BAD_ALLOC throw bad_alloc #elif !defined(__THROW_BAD_ALLOC)//定义内存申请出错处理 # include <iostream.h> # define __THROW_BAD_ALLOC cerr << "out of memory" << endl; exit(1) #endif #ifndef __ALLOC # define __ALLOC alloc #endif #ifdef __STL_WIN32THREADS # include <windows.h> #endif #include <stddef.h> #include <stdlib.h> #include <string.h> #include <assert.h> #ifndef __RESTRICT # define __RESTRICT #endif /* 假设编译器不支持多线程,那么就不用多线程 __STL_PTHREADS gcc编译器,POSIX接口 __STL_WIN32THREADS msvc编译器 */ #if !defined(__STL_PTHREADS) && !defined(_NOTHREADS) \ && !defined(__STL_SGI_THREADS) && !defined(__STL_WIN32THREADS) # define _NOTHREADS //不支持多线程 #endif /* 假设是gcc编译器,那么增加对相互排斥锁的支持 */ # ifdef __STL_PTHREADS // POSIX Threads // This is dubious, since this is likely to be a high contention // lock. Performance may not be adequate. # include <pthread.h> # define __NODE_ALLOCATOR_LOCK \ if (threads) pthread_mutex_lock(&__node_allocator_lock) # define __NODE_ALLOCATOR_UNLOCK \ if (threads) pthread_mutex_unlock(&__node_allocator_lock) # define __NODE_ALLOCATOR_THREADS true # define __VOLATILE volatile // Needed at -O3 on SGI # endif /* msvc编译器 */ # ifdef __STL_WIN32THREADS // The lock needs to be initialized by constructing an allocator // objects of the right type. We do that here explicitly for alloc. # define __NODE_ALLOCATOR_LOCK \ EnterCriticalSection(&__node_allocator_lock) # define __NODE_ALLOCATOR_UNLOCK \ LeaveCriticalSection(&__node_allocator_lock) # define __NODE_ALLOCATOR_THREADS true # define __VOLATILE volatile // may not be needed # endif /* WIN32THREADS */ /*SGI专用*/ # ifdef __STL_SGI_THREADS // This should work without threads, with sproc threads, or with // pthreads. It is suboptimal in all cases. // It is unlikely to even compile on nonSGI machines. extern "C" { extern int __us_rsthread_malloc; } // The above is copied from malloc.h. Including <malloc.h> // would be cleaner but fails with certain levels of standard // conformance. # define __NODE_ALLOCATOR_LOCK if (threads && __us_rsthread_malloc) \ { __lock(&__node_allocator_lock); } # define __NODE_ALLOCATOR_UNLOCK if (threads && __us_rsthread_malloc) \ { __unlock(&__node_allocator_lock); } # define __NODE_ALLOCATOR_THREADS true # define __VOLATILE volatile // Needed at -O3 on SGI # endif /*不支持多线程*/ # ifdef _NOTHREADS // Thread-unsafe # define __NODE_ALLOCATOR_LOCK # define __NODE_ALLOCATOR_UNLOCK # define __NODE_ALLOCATOR_THREADS false # define __VOLATILE # endif __STL_BEGIN_NAMESPACE #if defined(__sgi) && !defined(__GNUC__) && (_MIPS_SIM != _MIPS_SIM_ABI32) #pragma set woff 1174 #endif // malloc-based allocator. 通常比稍後介紹的 default alloc 速度慢, // 一般而言是 thread-safe,並且對於空間的運用比较高效(efficient)。 #ifdef __STL_STATIC_TEMPLATE_MEMBER_BUG # ifdef __DECLARE_GLOBALS_HERE void (* __malloc_alloc_oom_handler)() = 0; // g++ 2.7.2 不支持 static template data members. # else extern void (* __malloc_alloc_oom_handler)(); # endif #endif /* 以下就是第一级配置器,没有template參数,inst没实用 */ template <int inst> class __malloc_alloc_template { private: /* oom是指out of memory 定义函数指针。用来处理内存申请失败的情况,C++ 的 set_new_handler() */ static void *oom_malloc(size_t); static void *oom_realloc(void *, size_t); /* 在以下set_malloc_handler函数设置,用于内存申请失败时的处理,C++ 的 set_new_handler() */ #ifndef __STL_STATIC_TEMPLATE_MEMBER_BUG//假设编译器支持静态模板类 static void (* __malloc_alloc_oom_handler)(); #endif public: static void * allocate(size_t n) { void *result = malloc(n); // 第一级配置器直接用malloc申请内存 //当malloc申请失败,使用oom_malloc if (0 == result) result = oom_malloc(n); return result; } static void deallocate(void *p, size_t /* n */) { free(p); // 第一级配置器直接用free释放内存 } static void * reallocate(void *p, size_t /* old_sz */, size_t new_sz) { void * result = realloc(p, new_sz); // 第一级配置器直接使用 realloc() if (0 == result) result = oom_realloc(p, new_sz); return result; } /* 设置内存申请失败的错误处理函数,相似 C++ 的 set_new_handler()。这个是客端设置的。而不是编译器设置。假设不设置。则内存配置失败立即终止 */ static void (* set_malloc_handler(void (*f)()))() { void (* old)() = __malloc_alloc_oom_handler; __malloc_alloc_oom_handler = f; return(old); } }; // malloc_alloc out-of-memory handling。初始值为0 #ifndef __STL_STATIC_TEMPLATE_MEMBER_BUG template <int inst> void (* __malloc_alloc_template<inst>::__malloc_alloc_oom_handler)() = 0; #endif template <int inst> void * __malloc_alloc_template<inst>::oom_malloc(size_t n) { void (* my_malloc_handler)(); void *result; for (;;) { // 不断尝试释放、配置、再释放、再配置…… my_malloc_handler = __malloc_alloc_oom_handler; //假设没有设置out-of-memory handling处理函数。则抛出异常,终止 if (0 == my_malloc_handler) { __THROW_BAD_ALLOC; } (*my_malloc_handler)(); // 调用处理函数。企图释放内存 result = malloc(n); //再次尝试配置内存 if (result) return(result); } } //和上面的函数相似 template <int inst> void * __malloc_alloc_template<inst>::oom_realloc(void *p, size_t n) { void (* my_malloc_handler)(); void *result; for (;;) { // 不断尝试释放、配置、再释放、再配置…… my_malloc_handler = __malloc_alloc_oom_handler; if (0 == my_malloc_handler) { __THROW_BAD_ALLOC; } (*my_malloc_handler)(); result = realloc(p, n); if (result) return(result); } } //将參数inst设为0 typedef __malloc_alloc_template<0> malloc_alloc; /* 不管alloc是第一级配置器还是第二级配置器,SGI还为它包装一个接口。使之 符合STL规范 */ template<class T, class Alloc> class simple_alloc { public: /* 以下四个函数都是单纯的转调用,调用传递给配置器(可能是第一级,也可能是第二级)。 依据sizeof(T)或n*sizeof(T)的大小 */ static T *allocate(size_t n) { return 0 == n? 0 : (T*) Alloc::allocate(n * sizeof (T)); } static T *allocate(void) { return (T*) Alloc::allocate(sizeof (T)); } static void deallocate(T *p, size_t n) { if (0 != n) Alloc::deallocate(p, n * sizeof (T)); } static void deallocate(T *p) { Alloc::deallocate(p, sizeof (T)); } }; // Allocator adaptor to check size arguments for debugging. // Reports errors using assert. Checking can be disabled with // NDEBUG, but it's far better to just use the underlying allocator // instead when no checking is desired. // There is some evidence that this can confuse Purify. template <class Alloc> class debug_alloc { private: /* extra用于记录配置内存大小,同一时候保证字节对齐 */ enum {extra = 8}; // Size of space used to store size. Note // that this must be large enough to preserve // alignment. public: static void * allocate(size_t n) { char *result = (char *)Alloc::allocate(n + extra); *(size_t *)result = n;//内存分配前面记录分配内存的大小 return result + extra;//返回内存不包含extra大小 } static void deallocate(void *p, size_t n) { char * real_p = (char *)p - extra;//释放时,要加上extra大小内存 assert(*(size_t *)real_p == n);//推断前面的数据是否被改动,假设改动则说明有越界 Alloc::deallocate(real_p, n + extra); } static void * reallocate(void *p, size_t old_sz, size_t new_sz) { char * real_p = (char *)p - extra; assert(*(size_t *)real_p == old_sz); char * result = (char *) Alloc::reallocate(real_p, old_sz + extra, new_sz + extra); *(size_t *)result = new_sz; return result + extra; } }; # ifdef __USE_MALLOC typedef malloc_alloc alloc; // 令 alloc 为第一级配置器 typedef malloc_alloc single_client_alloc; # else // Default node allocator. // With a reasonable compiler, this should be roughly as fast as the // original STL class-specific allocators, but with less fragmentation. // Default_alloc_template parameters are experimental and MAY // DISAPPEAR in the future. Clients should just use alloc for now. /* 翻译:默认的内存配置器。在合适的编译器上,它的性能(SGI版本号的)应该和STL原版 的配置器性能大致同样,可是SGi版本号的使内存碎片更少。
默认的内存配置器仅仅是实验性的且以后可能会消失。
客端如今应该仅仅是用alloc */ // // Important implementation properties: // 1. If the client request an object of size > __MAX_BYTES, the resulting // object will be obtained directly from malloc. // 2. In all other cases, we allocate an object of size exactly // ROUND_UP(requested_size). Thus the client has enough size // information that we can return the object to the proper free list // without permanently losing part of the object. // /* 翻译:实现中的特性 1、当客端请求内存大小size>__MAX_BYTES时。对象直接调用malloc 2、否则,把size ROUND_UP为8的整数倍。从free list中 */ // The first template parameter specifies whether more than one thread // may use this allocator. It is safe to allocate an object from // one instance of a default_alloc and deallocate it with another // one. This effectively transfers its ownership to the second one. // This may have undesirable effects on reference locality. // The second parameter is unreferenced and serves only to allow the // creation of multiple default_alloc instances. // Node that containers built on different allocator instances have // different types, limiting the utility of this approach. /* 翻译:模板的第一个參数来指定是否有多于一个线程在使用这个alloctor。 在一个实例中配置内存,在还有一个实例中释放是安全的。这样能够有效的转换内存 使用权。
这可能会在引用区域产生意想不到的影响。
第二个參数是非引用的,仅用于创建多个default_alloc实例。 注意:使用不同的allocator创建的容器有不同特性。这限制了通用性。 */ #ifdef __SUNPRO_CC // breaks if we make these template class members: enum {__ALIGN = 8}; // 小型区块的上上调界 enum {__MAX_BYTES = 128}; // 小型区块的上限 enum {__NFREELISTS = __MAX_BYTES/__ALIGN}; // free-lists 个数,共16个 #endif // 以下是第二级配置器。 // 注意,没有模板參数,inst没实用,第一个參数用于多线程。 template <bool threads, int inst> class __default_alloc_template { private: /* 实际上。我们应该使用static const int x = N来代替enum { x = N }, 可是眼下支持该性能的编译器不多 */ # ifndef __SUNPRO_CC enum {__ALIGN = 8}; enum {__MAX_BYTES = 128}; enum {__NFREELISTS = __MAX_BYTES/__ALIGN}; # endif //将bytes上调至8的整数倍 static size_t ROUND_UP(size_t bytes) { return (((bytes) + __ALIGN-1) & ~(__ALIGN - 1)); } __PRIVATE: /* 这是free list内的结点。 採用union,尽量降低占用内存。 假设使用free_list_link,则指向同样的union结构,这个供链表free list使用。 假设使用client_data[1],则给客端使用 */ union obj { union obj * free_list_link; char client_data[1]; /* The client sees this. */ }; private: # ifdef __SUNPRO_CC static obj * __VOLATILE free_list[]; // Specifying a size results in duplicate def for 4.1 # else //__NFREELISTS值为16。相应链表维护内存大小为8、16、…、128 static obj * __VOLATILE free_list[__NFREELISTS]; # endif //依据bytes大小。在16个链表中选取合适的那个 static size_t FREELIST_INDEX(size_t bytes) { return (((bytes) + __ALIGN-1)/__ALIGN - 1); } // Returns an object of size n, and optionally adds to size n free list. //返回一个大小为n的对象。而且可能增加大小为n的其它区块到free list static void *refill(size_t n); // Allocates a chunk for nobjs of size "size". nobjs may be reduced // if it is inconvenient to allocate the requested number. /* 配置一大块空间。可容纳nobjs个size大小的区块,假设配置 nobjs个区块有所不便,nobjs可能会降低。
*/ static char *chunk_alloc(size_t size, int &nobjs); // Chunk allocation state. static char *start_free;//内存池起始位置 static char *end_free;//内存池结束位置 static size_t heap_size;//在堆上已有内存的大小 //假设支持多SGI线程。则提供锁支持 # ifdef __STL_SGI_THREADS static volatile unsigned long __node_allocator_lock; static void __lock(volatile unsigned long *); static inline void __unlock(volatile unsigned long *); # endif //假设支持多线程,则提供相互排斥锁 # ifdef __STL_PTHREADS static pthread_mutex_t __node_allocator_lock; # endif //win32多线程 # ifdef __STL_WIN32THREADS static CRITICAL_SECTION __node_allocator_lock; static bool __node_allocator_lock_initialized; public: __default_alloc_template() { // This assumes the first constructor is called before threads // are started. //假设构造函数在多线程启动前已经调用 if (!__node_allocator_lock_initialized) { InitializeCriticalSection(&__node_allocator_lock); __node_allocator_lock_initialized = true; } } private: # endif class lock { public: lock() { __NODE_ALLOCATOR_LOCK; } ~lock() { __NODE_ALLOCATOR_UNLOCK; } }; friend class lock; public: /* n must be > 0 */ static void * allocate(size_t n) { obj * __VOLATILE * my_free_list; obj * __RESTRICT result; if (n > (size_t) __MAX_BYTES) {//假设配置内存大于__MAX_BYTES,使用第一级配置器 return(malloc_alloc::allocate(n)); } my_free_list = free_list + FREELIST_INDEX(n);//在16个free lists中找到相应的那个 // Acquire the lock here with a constructor call. // This ensures that it is released in exit or during stack // unwinding. # ifndef _NOTHREADS /*REFERENCED*/ lock lock_instance; # endif result = *my_free_list; if (result == 0) {//假设没找可用的free list,那么又一次填充free list void *r = refill(ROUND_UP(n)); return r; } //调整free list *my_free_list = result -> free_list_link; return (result); }; /* p may not be 0 */ static void deallocate(void *p, size_t n) { obj *q = (obj *)p; obj * __VOLATILE * my_free_list; if (n > (size_t) __MAX_BYTES) {//调用第一级配置器的释放函数 malloc_alloc::deallocate(p, n); return; } //在16个free lists中找到相应的那个 my_free_list = free_list + FREELIST_INDEX(n); // acquire lock # ifndef _NOTHREADS /*REFERENCED*/ lock lock_instance; # endif /* _NOTHREADS */ //回收内存到free list q -> free_list_link = *my_free_list; *my_free_list = q; // lock is released here } static void * reallocate(void *p, size_t old_sz, size_t new_sz); } ; typedef __default_alloc_template<__NODE_ALLOCATOR_THREADS, 0> alloc; typedef __default_alloc_template<false, 0> single_client_alloc; /* We allocate memory in large chunks in order to avoid fragmenting */ /* the malloc heap too much. */ /* We assume that size is properly aligned. */ /* We hold the allocation lock. */ /* 分配内存时分配一大块,防止多次分配小内存造成内存碎片 假设size已经对齐 持有allocation锁 */ //从内存池中去空间给free list,nobjs是引用调用,原因是可能会改动其值。 //当不够nobjs个区块时。可能适当调小nobjs的值 template <bool threads, int inst> char* __default_alloc_template<threads, inst>::chunk_alloc(size_t size, int& nobjs) { char * result; size_t total_bytes = size * nobjs;//要配置的空间大小 size_t bytes_left = end_free - start_free;//内存池大小 if (bytes_left >= total_bytes) {//内存池空间满足需求 result = start_free; start_free += total_bytes; return(result); } else if (bytes_left >= size) { //内存池空间不够,可是足够供应一个(含)以上的块 nobjs = bytes_left/size; total_bytes = size * nobjs; result = start_free; start_free += total_bytes; return(result); } else { //内存池剩余空间大小连一个块大小都无法提供 size_t bytes_to_get = 2 * total_bytes + ROUND_UP(heap_size >> 4); // Try to make use of the left-over piece. //尝试内存池中的參与零头还有利用价值 if (bytes_left > 0) { obj * __VOLATILE * my_free_list =//找到相应的free list free_list + FREELIST_INDEX(bytes_left); //调整free list。将内存池空间编入 ((obj *)start_free) -> free_list_link = *my_free_list; *my_free_list = (obj *)start_free; } //配置heap,用来补充内存池 start_free = (char *)malloc(bytes_to_get); if (0 == start_free) { int i; obj * __VOLATILE * my_free_list, *p; // Try to make do with what we have. That can't // hurt. We do not try smaller requests, since that tends // to result in disaster on multi-process machines. /* 尝试用现有的,这不会造成破坏。我们不尝试配置较小的区块, 由于这样做将会在多线程机器上造成灾难 */ //搜索适当free list,适当是指“尚未用区块,且足够大”的free list for (i = size; i <= __MAX_BYTES; i += __ALIGN) { my_free_list = free_list + FREELIST_INDEX(i); p = *my_free_list; if (0 != p) {//free内有尚未用区块 //调整free list。释出未用区块 *my_free_list = p -> free_list_link; start_free = (char *)p; end_free = start_free + i; //递归调用自己,修正nobjs return(chunk_alloc(size, nobjs)); // Any leftover piece will eventually make it to the // right free list. //不论什么參与的零头将会被编入适当地free list中备用 } } //假设出现意外,到处无可用内存 end_free = 0; // In case of exception. //调用第一级配置器,看看out-of-memory机制是否能尽点力 start_free = (char *)malloc_alloc::allocate(bytes_to_get); // This should either throw an // exception or remedy the situation. Thus we assume it // succeeded. //这里可能会抛出异常,或内存不足情况得到改善。 } heap_size += bytes_to_get; end_free = start_free + bytes_to_get; //递归调用自己。修正nobjs return(chunk_alloc(size, nobjs)); } } /* Returns an object of size n, and optionally adds to size n free list.*/ /* We assume that n is properly aligned. */ /* We hold the allocation lock. */ /* 这个函数和上一个差点儿相同,没有第二个參数nobjs。
这个函数在函数体中设置了其大小为20. 返回大小为n的对象,且增加到free list中 我们假设n已经对齐 持有allocation锁 */ template <bool threads, int inst> void* __default_alloc_template<threads, inst>::refill(size_t n) { int nobjs = 20; char * chunk = chunk_alloc(n, nobjs); obj * __VOLATILE * my_free_list; obj * result; obj * current_obj, * next_obj; int i; //假设仅仅够一个块的大小 if (1 == nobjs) return(chunk); my_free_list = free_list + FREELIST_INDEX(n); /* Build free list in chunk */ //在chunk中建立free list result = (obj *)chunk; *my_free_list = next_obj = (obj *)(chunk + n); for (i = 1; ; i++) { current_obj = next_obj; next_obj = (obj *)((char *)next_obj + n); if (nobjs - 1 == i) { current_obj -> free_list_link = 0; break; } else { current_obj -> free_list_link = next_obj; } } return(result); } /* 扩展现有内存,又一次分配内存,要把旧内存内容复制到新内存 */ template <bool threads, int inst> void* __default_alloc_template<threads, inst>::reallocate(void *p, size_t old_sz, size_t new_sz) { void * result; size_t copy_sz; //假设就内存和新内存都大于_MAX_BYTES。直接调用realloc if (old_sz > (size_t) __MAX_BYTES && new_sz > (size_t) __MAX_BYTES) { return(realloc(p, new_sz)); } //内存大小没变化(没变化是指经过上调为8的整数倍后没变化),直接返回 if (ROUND_UP(old_sz) == ROUND_UP(new_sz)) return(p); result = allocate(new_sz);//分配新内存 copy_sz = new_sz > old_sz?
old_sz : new_sz; memcpy(result, p, copy_sz);//拷贝旧内存的数据到新内存 deallocate(p, old_sz);//释放就内存 return(result); } #ifdef __STL_PTHREADS template <bool threads, int inst> pthread_mutex_t __default_alloc_template<threads, inst>::__node_allocator_lock = PTHREAD_MUTEX_INITIALIZER; #endif #ifdef __STL_WIN32THREADS template <bool threads, int inst> CRITICAL_SECTION __default_alloc_template<threads, inst>::__node_allocator_lock; template <bool threads, int inst> bool __default_alloc_template<threads, inst>::__node_allocator_lock_initialized = false; #endif #ifdef __STL_SGI_THREADS __STL_END_NAMESPACE #include <mutex.h> #include <time.h> __STL_BEGIN_NAMESPACE // Somewhat generic lock implementations. We need only test-and-set // and some way to sleep. These should work with both SGI pthreads // and sproc threads. They may be useful on other systems. template <bool threads, int inst> volatile unsigned long __default_alloc_template<threads, inst>::__node_allocator_lock = 0; #if __mips < 3 || !(defined (_ABIN32) || defined(_ABI64)) || defined(__GNUC__) # define __test_and_set(l,v) test_and_set(l,v) #endif template <bool threads, int inst> void __default_alloc_template<threads, inst>::__lock(volatile unsigned long *lock) { const unsigned low_spin_max = 30; // spin cycles if we suspect uniprocessor const unsigned high_spin_max = 1000; // spin cycles for multiprocessor static unsigned spin_max = low_spin_max; unsigned my_spin_max; static unsigned last_spins = 0; unsigned my_last_spins; static struct timespec ts = {0, 1000}; unsigned junk; # define __ALLOC_PAUSE junk *= junk; junk *= junk; junk *= junk; junk *= junk int i; if (!__test_and_set((unsigned long *)lock, 1)) { return; } my_spin_max = spin_max; my_last_spins = last_spins; for (i = 0; i < my_spin_max; i++) { if (i < my_last_spins/2 || *lock) { __ALLOC_PAUSE; continue; } if (!__test_and_set((unsigned long *)lock, 1)) { // got it! // Spinning worked. Thus we're probably not being scheduled // against the other process with which we were contending. // Thus it makes sense to spin longer the next time. last_spins = i; spin_max = high_spin_max; return; } } // We are probably being scheduled against the other process. Sleep. spin_max = low_spin_max; for (;;) { if (!__test_and_set((unsigned long *)lock, 1)) { return; } nanosleep(&ts, 0); } } template <bool threads, int inst> inline void __default_alloc_template<threads, inst>::__unlock(volatile unsigned long *lock) { # if defined(__GNUC__) && __mips >= 3 asm("sync"); *lock = 0; # elif __mips >= 3 && (defined (_ABIN32) || defined(_ABI64)) __lock_release(lock); # else *lock = 0; // This is not sufficient on many multiprocessors, since // writes to protected variables and the lock may be reordered. # endif } #endif //内存池的起始地址、结束地址以及大小的初始化 template <bool threads, int inst> char *__default_alloc_template<threads, inst>::start_free = 0; template <bool threads, int inst> char *__default_alloc_template<threads, inst>::end_free = 0; template <bool threads, int inst> size_t __default_alloc_template<threads, inst>::heap_size = 0; template <bool threads, int inst> __default_alloc_template<threads, inst>::obj * __VOLATILE __default_alloc_template<threads, inst> ::free_list[ # ifdef __SUNPRO_CC __NFREELISTS # else __default_alloc_template<threads, inst>::__NFREELISTS # endif//free list的初始化 ] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, }; // The 16 zeros are necessary to make version 4.1 of the SunPro // compiler happy. Otherwise it appears to allocate too little // space for the array. # ifdef __STL_WIN32THREADS // Create one to get critical section initialized. // We do this onece per file, but only the first constructor // does anything. static alloc __node_allocator_dummy_instance; # endif #endif /* ! __USE_MALLOC */ #if defined(__sgi) && !defined(__GNUC__) && (_MIPS_SIM != _MIPS_SIM_ABI32) #pragma reset woff 1174 #endif __STL_END_NAMESPACE #undef __PRIVATE #endif /* __SGI_STL_INTERNAL_ALLOC_H */ // Local Variables: // mode:C++ // End: