// MT-optimized allocator -*- C++ -*- // Copyright (C) 2003, 2004 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 2, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License along // with this library; see the file COPYING. If not, write to the Free // Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, // USA. // As a special exception, you may use this file as part of a free software // library without restriction. Specifically, if other files instantiate // templates or use macros or inline functions from this file, or you compile // this file and link it with other files to produce an executable, this // file does not by itself cause the resulting executable to be covered by // the GNU General Public License. This exception does not however // invalidate any other reasons why the executable file might be covered by // the GNU General Public License. /** @file ext/mt_allocator.h * This file is a GNU extension to the Standard C++ Library. * You should only include this header if you are using GCC 3 or later. */ #ifndef _MT_ALLOCATOR_H #define _MT_ALLOCATOR_H 1 #include #include #include #include #include namespace __gnu_cxx { /** * This is a fixed size (power of 2) allocator which - when * compiled with thread support - will maintain one freelist per * size per thread plus a "global" one. Steps are taken to limit * the per thread freelist sizes (by returning excess back to * "global"). * * Further details: * http://gcc.gnu.org/onlinedocs/libstdc++/ext/mt_allocator.html */ typedef void (*__destroy_handler)(void*); typedef void (*__create_handler)(void); struct __pool_base { // Using short int as type for the binmap implies we are never // caching blocks larger than 65535 with this allocator. typedef unsigned short int _Binmap_type; // Variables used to configure the behavior of the allocator, // assigned and explained in detail below. struct _Tune { // Compile time constants for the default _Tune values. enum { _S_align = 8 }; enum { _S_max_bytes = 128 }; enum { _S_min_bin = 8 }; enum { _S_chunk_size = 4096 - 4 * sizeof(void*) }; enum { _S_max_threads = 4096 }; enum { _S_freelist_headroom = 10 }; // Alignment needed. // NB: In any case must be >= sizeof(_Block_record), that // is 4 on 32 bit machines and 8 on 64 bit machines. size_t _M_align; // Allocation requests (after round-up to power of 2) below // this value will be handled by the allocator. A raw new/ // call will be used for requests larger than this value. size_t _M_max_bytes; // Size in bytes of the smallest bin. // NB: Must be a power of 2 and >= _M_align. size_t _M_min_bin; // In order to avoid fragmenting and minimize the number of // new() calls we always request new memory using this // value. Based on previous discussions on the libstdc++ // mailing list we have choosen the value below. // See http://gcc.gnu.org/ml/libstdc++/2001-07/msg00077.html size_t _M_chunk_size; // The maximum number of supported threads. For // single-threaded operation, use one. Maximum values will // vary depending on details of the underlying system. (For // instance, Linux 2.4.18 reports 4070 in // /proc/sys/kernel/threads-max, while Linux 2.6.6 reports // 65534) size_t _M_max_threads; // Each time a deallocation occurs in a threaded application // we make sure that there are no more than // _M_freelist_headroom % of used memory on the freelist. If // the number of additional records is more than // _M_freelist_headroom % of the freelist, we move these // records back to the global pool. size_t _M_freelist_headroom; // Set to true forces all allocations to use new(). bool _M_force_new; explicit _Tune() : _M_align(_S_align), _M_max_bytes(_S_max_bytes), _M_min_bin(_S_min_bin), _M_chunk_size(_S_chunk_size), _M_max_threads(_S_max_threads), _M_freelist_headroom(_S_freelist_headroom), _M_force_new(getenv("GLIBCXX_FORCE_NEW") ? true : false) { } explicit _Tune(size_t __align, size_t __maxb, size_t __minbin, size_t __chunk, size_t __maxthreads, size_t __headroom, bool __force) : _M_align(__align), _M_max_bytes(__maxb), _M_min_bin(__minbin), _M_chunk_size(__chunk), _M_max_threads(__maxthreads), _M_freelist_headroom(__headroom), _M_force_new(__force) { } bool is_default() const { bool __ret = true; __ret &= _M_align == _S_align; __ret &= _M_max_bytes == _S_max_bytes; __ret &= _M_min_bin == _S_min_bin; __ret &= _M_chunk_size == _S_chunk_size; __ret &= _M_max_threads == _S_max_threads; __ret &= _M_freelist_headroom == _S_freelist_headroom; return __ret; } }; struct _Block_address { void* _M_initial; _Block_address* _M_next; }; const _Tune& _M_get_options() const { return _M_options; } void _M_set_options(_Tune __t) { if (!_M_init) _M_options = __t; } bool _M_check_threshold(size_t __bytes) { return __bytes > _M_options._M_max_bytes || _M_options._M_force_new; } size_t _M_get_binmap(size_t __bytes) { return _M_binmap[__bytes]; } const size_t _M_get_align() { return _M_options._M_align; } explicit __pool_base() : _M_options(_Tune()), _M_binmap(NULL), _M_init(false) { } explicit __pool_base(const _Tune& __tune) : _M_options(__tune), _M_binmap(NULL), _M_init(false) { } protected: // Configuration options. _Tune _M_options; _Binmap_type* _M_binmap; // We need to create the initial lists and set up some variables // before we can answer to the first request for memory. bool _M_init; }; // Data describing the underlying memory pool, parameterized on // threading support. template class __pool; template<> class __pool; template<> class __pool; #ifdef __GTHREADS // Specialization for thread enabled, via gthreads.h. template<> class __pool : public __pool_base { public: // Each requesting thread is assigned an id ranging from 1 to // _S_max_threads. Thread id 0 is used as a global memory pool. // In order to get constant performance on the thread assignment // routine, we keep a list of free ids. When a thread first // requests memory we remove the first record in this list and // stores the address in a __gthread_key. When initializing the // __gthread_key we specify a destructor. When this destructor // (i.e. the thread dies) is called, we return the thread id to // the front of this list. struct _Thread_record { // Points to next free thread id record. NULL if last record in list. _Thread_record* volatile _M_next; // Thread id ranging from 1 to _S_max_threads. size_t _M_id; }; union _Block_record { // Points to the block_record of the next free block. _Block_record* volatile _M_next; // The thread id of the thread which has requested this block. size_t _M_thread_id; }; struct _Bin_record { // An "array" of pointers to the first free block for each // thread id. Memory to this "array" is allocated in // _S_initialize() for _S_max_threads + global pool 0. _Block_record** volatile _M_first; // A list of the initial addresses of all allocated blocks. _Block_address* _M_address; // An "array" of counters used to keep track of the amount of // blocks that are on the freelist/used for each thread id. // Memory to these "arrays" is allocated in _S_initialize() for // _S_max_threads + global pool 0. size_t* volatile _M_free; size_t* volatile _M_used; // Each bin has its own mutex which is used to ensure data // integrity while changing "ownership" on a block. The mutex // is initialized in _S_initialize(). __gthread_mutex_t* _M_mutex; }; void _M_initialize(__destroy_handler __d); void _M_initialize_once(__create_handler __c) { // Although the test in __gthread_once() would suffice, we // wrap test of the once condition in our own unlocked // check. This saves one function call to pthread_once() // (which itself only tests for the once value unlocked anyway // and immediately returns if set) if (__builtin_expect(_M_init == false, false)) { if (__gthread_active_p()) __gthread_once(&_M_once, __c); if (!_M_init) __c(); } } void _M_destroy() throw(); char* _M_reserve_block(size_t __bytes, const size_t __thread_id); void _M_reclaim_block(char* __p, size_t __bytes); const _Bin_record& _M_get_bin(size_t __which) { return _M_bin[__which]; } void _M_adjust_freelist(const _Bin_record& __bin, _Block_record* __block, size_t __thread_id) { if (__gthread_active_p()) { __block->_M_thread_id = __thread_id; --__bin._M_free[__thread_id]; ++__bin._M_used[__thread_id]; } } void _M_destroy_thread_key(void* __freelist_pos); size_t _M_get_thread_id(); explicit __pool() : _M_bin(NULL), _M_bin_size(1), _M_thread_freelist(NULL) { // On some platforms, __gthread_once_t is an aggregate. __gthread_once_t __tmp = __GTHREAD_ONCE_INIT; _M_once = __tmp; } explicit __pool(const __pool_base::_Tune& __tune) : __pool_base(__tune), _M_bin(NULL), _M_bin_size(1), _M_thread_freelist(NULL) { // On some platforms, __gthread_once_t is an aggregate. __gthread_once_t __tmp = __GTHREAD_ONCE_INIT; _M_once = __tmp; } ~__pool() { } private: // An "array" of bin_records each of which represents a specific // power of 2 size. Memory to this "array" is allocated in // _M_initialize(). _Bin_record* volatile _M_bin; // Actual value calculated in _M_initialize(). size_t _M_bin_size; __gthread_once_t _M_once; _Thread_record* _M_thread_freelist; void* _M_thread_freelist_initial; }; #endif // Specialization for single thread. template<> class __pool : public __pool_base { public: union _Block_record { // Points to the block_record of the next free block. _Block_record* volatile _M_next; }; struct _Bin_record { // An "array" of pointers to the first free block. _Block_record** volatile _M_first; // A list of the initial addresses of all allocated blocks. _Block_address* _M_address; }; void _M_initialize_once() { if (__builtin_expect(_M_init == false, false)) _M_initialize(); } void _M_destroy() throw(); char* _M_reserve_block(size_t __bytes, const size_t __thread_id); void _M_reclaim_block(char* __p, size_t __bytes); size_t _M_get_thread_id() { return 0; } const _Bin_record& _M_get_bin(size_t __which) { return _M_bin[__which]; } void _M_adjust_freelist(const _Bin_record&, _Block_record*, size_t) { } explicit __pool() : _M_bin(NULL), _M_bin_size(1) { } explicit __pool(const __pool_base::_Tune& __tune) : __pool_base(__tune), _M_bin(NULL), _M_bin_size(1) { } ~__pool() { } private: // An "array" of bin_records each of which represents a specific // power of 2 size. Memory to this "array" is allocated in // _M_initialize(). _Bin_record* volatile _M_bin; // Actual value calculated in _M_initialize(). size_t _M_bin_size; void _M_initialize(); }; template struct __common_pool_policy { typedef __pool<_Thread> __pool_type; template struct _M_rebind; template struct _M_rebind<_Tp1, true> { typedef __common_pool_policy other; }; template struct _M_rebind<_Tp1, false> { typedef __common_pool_policy other; }; static __pool_type& _S_get_pool() { static __pool_type _S_pool; return _S_pool; } static void _S_initialize_once() { static bool __init; if (__builtin_expect(__init == false, false)) { _S_get_pool()._M_initialize_once(); __init = true; } } }; template<> struct __common_pool_policy; #ifdef __GTHREADS template<> struct __common_pool_policy { typedef __pool __pool_type; template struct _M_rebind; template struct _M_rebind<_Tp1, true> { typedef __common_pool_policy other; }; template struct _M_rebind<_Tp1, false> { typedef __common_pool_policy other; }; static __pool_type& _S_get_pool() { static __pool_type _S_pool; return _S_pool; } static void _S_destroy_thread_key(void* __freelist_pos) { _S_get_pool()._M_destroy_thread_key(__freelist_pos); } static void _S_initialize() { _S_get_pool()._M_initialize(_S_destroy_thread_key); } static void _S_initialize_once() { static bool __init; if (__builtin_expect(__init == false, false)) { _S_get_pool()._M_initialize_once(_S_initialize); __init = true; } } }; #endif template struct __per_type_pool_policy { typedef __pool<_Thread> __pool_type; template struct _M_rebind; template struct _M_rebind<_Tp1, false> { typedef __per_type_pool_policy<_Tp1, false> other; }; template struct _M_rebind<_Tp1, true> { typedef __per_type_pool_policy<_Tp1, true> other; }; // Avoid static initialization ordering issues. static __pool_type& _S_get_pool() { // Sane defaults for the __pool_type. const static size_t __align = __alignof__(_Tp) >= sizeof(typename __pool_type::_Block_record) ? __alignof__(_Tp) : sizeof(typename __pool_type::_Block_record); static __pool_base::_Tune _S_tune(__align, sizeof(_Tp) * 128, (sizeof(_Tp) * 2) >= __align ? sizeof(_Tp) * 2 : __align, __pool_type::_Tune::_S_chunk_size, __pool_type::_Tune::_S_max_threads, __pool_type::_Tune::_S_freelist_headroom, getenv("GLIBCXX_FORCE_NEW") ? true : false); static __pool_type _S_pool(_S_tune); return _S_pool; } static void _S_initialize_once() { static bool __init; if (__builtin_expect(__init == false, false)) { _S_get_pool()._M_initialize_once(); __init = true; } } }; template struct __per_type_pool_policy<_Tp, true>; #ifdef __GTHREADS template struct __per_type_pool_policy<_Tp, true> { typedef __pool __pool_type; template struct _M_rebind; template struct _M_rebind<_Tp1, false> { typedef __per_type_pool_policy<_Tp1, false> other; }; template struct _M_rebind<_Tp1, true> { typedef __per_type_pool_policy<_Tp1, true> other; }; // Avoid static initialization ordering issues. static __pool_type& _S_get_pool( ) { // Sane defaults for the __pool_type. const static size_t __align = __alignof__(_Tp) >= sizeof(typename __pool_type::_Block_record) ? __alignof__(_Tp) : sizeof(typename __pool_type::_Block_record); static __pool_base::_Tune _S_tune(__align, sizeof(_Tp) * 128, (sizeof(_Tp) * 2) >= __align ? sizeof(_Tp) * 2 : __align, __pool_type::_Tune::_S_chunk_size, __pool_type::_Tune::_S_max_threads, __pool_type::_Tune::_S_freelist_headroom, getenv("GLIBCXX_FORCE_NEW") ? true : false); static __pool_type _S_pool(_S_tune); return _S_pool; } static void _S_destroy_thread_key(void* __freelist_pos) { _S_get_pool()._M_destroy_thread_key(__freelist_pos); } static void _S_initialize() { _S_get_pool()._M_initialize(_S_destroy_thread_key); } static void _S_initialize_once() { static bool __init; if (__builtin_expect(__init == false, false)) { _S_get_pool()._M_initialize_once(_S_initialize); __init = true; } } }; #endif template class __mt_alloc_base { public: typedef size_t size_type; typedef ptrdiff_t difference_type; typedef _Tp* pointer; typedef const _Tp* const_pointer; typedef _Tp& reference; typedef const _Tp& const_reference; typedef _Tp value_type; pointer address(reference __x) const { return &__x; } const_pointer address(const_reference __x) const { return &__x; } size_type max_size() const throw() { return size_t(-1) / sizeof(_Tp); } // _GLIBCXX_RESOLVE_LIB_DEFECTS // 402. wrong new expression in [some_] allocator::construct void construct(pointer __p, const _Tp& __val) { ::new(__p) _Tp(__val); } void destroy(pointer __p) { __p->~_Tp(); } }; #ifdef __GTHREADS #define __default_policy __common_pool_policy #else #define __default_policy __common_pool_policy #endif template class __mt_alloc : public __mt_alloc_base<_Tp>, _Poolp { public: typedef size_t size_type; typedef ptrdiff_t difference_type; typedef _Tp* pointer; typedef const _Tp* const_pointer; typedef _Tp& reference; typedef const _Tp& const_reference; typedef _Tp value_type; typedef _Poolp __policy_type; typedef typename _Poolp::__pool_type __pool_type; template struct rebind { typedef typename _Poolp1::template _M_rebind<_Tp1>::other pol_type; typedef __mt_alloc<_Tp1, pol_type> other; }; __mt_alloc() throw() { __policy_type::_S_get_pool(); } __mt_alloc(const __mt_alloc&) throw() { __policy_type::_S_get_pool(); } template __mt_alloc(const __mt_alloc<_Tp1, _Poolp1>& obj) throw() { __policy_type::_S_get_pool(); } ~__mt_alloc() throw() { } pointer allocate(size_type __n, const void* = 0); void deallocate(pointer __p, size_type __n); const __pool_base::_Tune _M_get_options() { // Return a copy, not a reference, for external consumption. return __pool_base::_Tune(this->_S_get_pool()._M_get_options()); } void _M_set_options(__pool_base::_Tune __t) { this->_S_get_pool()._M_set_options(__t); } }; template typename __mt_alloc<_Tp, _Poolp>::pointer __mt_alloc<_Tp, _Poolp>:: allocate(size_type __n, const void*) { this->_S_initialize_once(); if (__builtin_expect(__n > this->max_size(), false)) std::__throw_bad_alloc(); // Requests larger than _M_max_bytes are handled by operator // new/delete directly. __pool_type& __pool = this->_S_get_pool(); const size_t __bytes = __n * sizeof(_Tp); if (__pool._M_check_threshold(__bytes)) { void* __ret = ::operator new(__bytes); return static_cast<_Tp*>(__ret); } // Round up to power of 2 and figure out which bin to use. const size_t __which = __pool._M_get_binmap(__bytes); const size_t __thread_id = __pool._M_get_thread_id(); // Find out if we have blocks on our freelist. If so, go ahead // and use them directly without having to lock anything. char* __c; typedef typename __pool_type::_Bin_record _Bin_record; const _Bin_record& __bin = __pool._M_get_bin(__which); if (__bin._M_first[__thread_id]) { // Already reserved. typedef typename __pool_type::_Block_record _Block_record; _Block_record* __block = __bin._M_first[__thread_id]; __bin._M_first[__thread_id] = __block->_M_next; __pool._M_adjust_freelist(__bin, __block, __thread_id); __c = reinterpret_cast(__block) + __pool._M_get_align(); } else { // Null, reserve. __c = __pool._M_reserve_block(__bytes, __thread_id); } return static_cast<_Tp*>(static_cast(__c)); } template void __mt_alloc<_Tp, _Poolp>:: deallocate(pointer __p, size_type __n) { if (__builtin_expect(__p != 0, true)) { // Requests larger than _M_max_bytes are handled by // operators new/delete directly. __pool_type& __pool = this->_S_get_pool(); const size_t __bytes = __n * sizeof(_Tp); if (__pool._M_check_threshold(__bytes)) ::operator delete(__p); else __pool._M_reclaim_block(reinterpret_cast(__p), __bytes); } } template inline bool operator==(const __mt_alloc<_Tp, _Poolp>&, const __mt_alloc<_Tp, _Poolp>&) { return true; } template inline bool operator!=(const __mt_alloc<_Tp, _Poolp>&, const __mt_alloc<_Tp, _Poolp>&) { return false; } #undef __default_policy } // namespace __gnu_cxx #endif