类STL的内存分配，释放接口

　　近几日一直在开发偶的 EasyCode Windows 版（EasyCode Pro），不过，对于内存管理，自己写了一套，不用借助任何的 include 文件。 由于时间关系，没有写自己的 set_handler 代码，不过有时间会加上去的 :) 该代码您可以任意使用，但是如果出现意外，如硬盘烧毁，无故断电，光驱飞盘等等现象，DarkSpy一律不负任何责任 :-) 有一部分代码没有很完善，不过90％可以正常使用。 代码全部遵循是ISO C++98标准，如果您的编译器无法通过，则是编译器不支持，而不是代码问题。 如果您修改了它，请给我一份拷贝，谢谢！ #ifdef __GNUC__ typedef long unsigned int size_t; #else #define size_t unsigned int #endif namespace __easycode_pro { template <typename T> struct _type_traits { typedef T _type; ~_type_traits() { _type().~_type(); } }; template <typename T> struct _type_traits<T *> { typedef _type_traits<T *> _type; ~_type_traits() { _type().~_type(); } }; template <typename T> struct _type_traits<const T> { typedef _type_traits<T> _type; ~_type_traits() { _type().~_type(); } }; template <typename T> struct _type_traits<const T *> { typedef _type_traits<T *> _type; ~_type_traits() { _type().~_type(); } }; template <> struct _type_traits<int> { ~_type_traits() { } }; template <> struct _type_traits<unsigned int> { ~_type_traits() { } }; template <> struct _type_traits<int *> { ~_type_traits() { } }; template <> struct _type_traits<unsigned int *> { ~_type_traits() { } }; template <> struct _type_traits<char> { ~_type_traits() { } }; template <> struct _type_traits<unsigned char> { ~_type_traits() { } }; template <> struct _type_traits<char *> { ~_type_traits() { } }; template <> struct _type_traits<unsigned char *> { ~_type_traits() { } }; template <> struct _type_traits<long> { ~_type_traits() { } }; template <> struct _type_traits<unsigned long> { ~_type_traits() { } }; template <> struct _type_traits<long *> { ~_type_traits() { } }; template <> struct _type_traits<unsigned long *>
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{ ~_type_traits() { } }; template <> struct _type_traits<short> { ~_type_traits() { } }; template <> struct _type_traits<unsigned short> { ~_type_traits() { } }; template <> struct _type_traits<short *> { ~_type_traits() { } }; template <> struct _type_traits<bool> { ~_type_traits() { } }; template <> struct _type_traits<float> { ~_type_traits() { } }; template <> struct _type_traits<float *> { ~_type_traits() { } }; template <> struct _type_traits<double> { ~_type_traits() { } }; template <> struct _type_traits<double *> { ~_type_traits() { } }; }; namespace __easycode_pro { template <typename T> class allocator { protected: void * operator new (size_t size) { return ::operator new (size); } void operator delete(void * p) { ::operator delete (p); } void * operator new[](size_t size, int i) { return ::operator new (size * i + 1); } void operator delete[](void *p, int i) { ::operator delete (p); } void * operator new(size_t size, void *p) { return p; } void operator delete(void *p, void *p2) { ::operator delete(p); } public: typedef T t_type; typedef t_type* t_pointer; typedef t_type& t_reference; typedef int t_value; public: allocator(t_pointer pt = 0) { } ~allocator() { } static t_pointer allocate(allocator<T> p, int how_many) throw(bool); static void deallocate(t_pointer p) throw(bool); template <typename U> static t_pointer placement_allocate(U *p) throw(bool); template <typename U> static void placement_deallocate(U *p) throw(bool); t_pointer operator()(t_pointer t) { return t; } }; template <typename T, typename Alloc = allocator<T> > struct mem_alloc { static typename Alloc::t_pointer alloc(int how_many) { return Alloc::allocate(Alloc(), how_many); } static void dealloc(T *p) { Alloc::deallocate(p); } template <typename U> static typename Alloc::t_pointer p_alloc(U *p) { return Alloc::template placement_allocate<T>(p); } template <typename U> static void p_dealloc(U *p)
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{ Alloc::template placement_deallocate<T>(p); } }; template <typename T> struct __convert { T *data; __convert() : data(0) {} operator T(){ return *data; } operator void *(){} void * got(T &p) { return &p; } }; }; #define set_alloc_name(_alloc_type) \ typedef __easycode_pro::mem_alloc<_alloc_type> _alloc_type##_allocator #define get_address(__type, __value) \ __easycode_pro::__convert<__type>().got(__value) template <typename T> inline typename __easycode_pro::allocator<T>::t_pointer __easycode_pro::allocator<T>::allocate(__easycode_pro::allocator<T> p, int how_many) throw(bool) { t_pointer tmp; if(how_many<=0) //allocator one of sizeof type memory tmp = (t_pointer)(allocator<T>::operator new(sizeof(T))); else tmp = (t_pointer)(allocator<T>::operator new[](sizeof(T), how_many)); if(!tmp) throw(false); p(tmp); return tmp; } template <typename T> inline void __easycode_pro::allocator<T>::deallocate(t_pointer p) throw(bool) { get_address(t_type, *p); __easycode_pro::allocator<T>::operator delete[](p, 0); } template <typename T> template <typename U> inline typename __easycode_pro::allocator<T>::t_pointer __easycode_pro::allocator<T>::placement_allocate(U *p) throw(bool) { const int __ADJUST = (sizeof(U) + 3) & ~ (3); U * u_tmp(0); p = allocator<U>::allocate(u_tmp, __ADJUST); delete u_tmp; t_pointer tmp; tmp = (t_pointer)(allocator<T>::operator new(sizeof(t_type), p)); if(!tmp) throw(false); return tmp; } template <typename T> template <typename U> inline void __easycode_pro::allocator<T>::placement_deallocate(U *p) throw(bool) { get_address(t_type, *p); _type_traits<U>().~_type_traits<U>(); } template <typename T> template <typename U> inline typename __easycode_pro::allocator<T>::t_pointer __easycode_pro::allocator<T>::placement_allocate(U *p) throw(bool) { const int __ADJUST = (sizeof(U) + 3) & ~ (3); U * u_tmp(0); p = allocator<U>::allocate(u_tmp, __ADJUST); delete u_tmp; t_pointer tmp; tmp = (t_pointer)(allocator<T>::operator new(sizeof(t_type), p)); if(!tmp) throw(false); return tmp; } template <typename T> template <typename U> inline void __easycode_pro::allocator<T>::placement_deallocate(U *p) throw(bool) { get_address(t_type, *p); _type_traits<U>().~_type_traits<U>(); if(!tmp) throw(false); return tmp; } template <typename T> template <typename U> inline void __easycode_pro::allocator<T>::placement_deallocate(U *p) throw(bool) { get_address(t_type, *p); _type_traits<U>().~_type_traits<U>();