#ifndef SQL_PLIST_H #define SQL_PLIST_H /* Copyright (c) 2008, 2011, Oracle and/or its affiliates. All rights reserved. This program 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; version 2 of the License. This program 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 program; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */ #include template class I_P_List_iterator; class I_P_List_null_counter; template class I_P_List_no_push_back; /** Intrusive parameterized list. Unlike I_List does not require its elements to be descendant of ilink class and therefore allows them to participate in several such lists simultaneously. Unlike List is doubly-linked list and thus supports efficient deletion of element without iterator. @param T Type of elements which will belong to list. @param B Class which via its methods specifies which members of T should be used for participating in this list. Here is typical layout of such class: struct B { static inline T **next_ptr(T *el) { return &el->next; } static inline T ***prev_ptr(T *el) { return &el->prev; } }; @param C Policy class specifying how counting of elements in the list should be done. Instance of this class is also used as a place where information about number of list elements is stored. @sa I_P_List_null_counter, I_P_List_counter @param I Policy class specifying whether I_P_List should support efficient push_back() operation. Instance of this class is used as place where we store information to support this operation. @sa I_P_List_no_push_back, I_P_List_fast_push_back. */ template > class I_P_List : public C, public I { T *m_first; /* Do not prohibit copying of I_P_List object to simplify their usage in backup/restore scenarios. Note that performing any operations on such is a bad idea. */ public: I_P_List() : I(&m_first), m_first(NULL) {}; /* empty() is used in many places in the code instead of a constructor, to initialize a bzero-ed I_P_List instance. */ inline void empty() { m_first= NULL; C::reset(); I::set_last(&m_first); } inline bool is_empty() const { return (m_first == NULL); } inline void push_front(T* a) { *B::next_ptr(a)= m_first; if (m_first) *B::prev_ptr(m_first)= B::next_ptr(a); else I::set_last(B::next_ptr(a)); m_first= a; *B::prev_ptr(a)= &m_first; C::inc(); } inline void push_back(T *a) { T **last= I::get_last(); *B::next_ptr(a)= *last; *last= a; *B::prev_ptr(a)= last; I::set_last(B::next_ptr(a)); C::inc(); } inline void insert_after(T *pos, T *a) { if (pos == NULL) push_front(a); else { *B::next_ptr(a)= *B::next_ptr(pos); *B::prev_ptr(a)= B::next_ptr(pos); *B::next_ptr(pos)= a; if (*B::next_ptr(a)) { T *old_next= *B::next_ptr(a); *B::prev_ptr(old_next)= B::next_ptr(a); } else I::set_last(B::next_ptr(a)); C::inc(); } } inline void remove(T *a) { T *next= *B::next_ptr(a); if (next) *B::prev_ptr(next)= *B::prev_ptr(a); else I::set_last(*B::prev_ptr(a)); **B::prev_ptr(a)= next; C::dec(); } inline T* front() { return m_first; } inline const T *front() const { return m_first; } inline T* pop_front() { T *result= front(); if (result) remove(result); return result; } void swap(I_P_List &rhs) { swap_variables(T *, m_first, rhs.m_first); I::swap(rhs); if (m_first) *B::prev_ptr(m_first)= &m_first; else I::set_last(&m_first); if (rhs.m_first) *B::prev_ptr(rhs.m_first)= &rhs.m_first; else I::set_last(&rhs.m_first); C::swap(rhs); } typedef B Adapter; typedef I_P_List Base; typedef I_P_List_iterator Iterator; typedef I_P_List_iterator Const_Iterator; #ifndef _lint friend class I_P_List_iterator; friend class I_P_List_iterator; #endif }; /** Iterator for I_P_List. */ template class I_P_List_iterator { const L *list; T *current; public: I_P_List_iterator(const L &a) : list(&a), current(a.m_first) {} I_P_List_iterator(const L &a, T* current_arg) : list(&a), current(current_arg) {} inline void init(const L &a) { list= &a; current= a.m_first; } /* Operator for it++ */ inline T* operator++(int) { T *result= current; if (result) current= *L::Adapter::next_ptr(current); return result; } /* Operator for ++it */ inline T* operator++() { current= *L::Adapter::next_ptr(current); return current; } inline void rewind() { current= list->m_first; } }; /** Hook class which via its methods specifies which members of T should be used for participating in a intrusive list. */ template struct I_P_List_adapter { static inline T **next_ptr(T *el) { return &(el->*next); } static inline const T* const* next_ptr(const T *el) { return &(el->*next); } static inline T ***prev_ptr(T *el) { return &(el->*prev); } }; /** Element counting policy class for I_P_List to be used in cases when no element counting should be done. */ class I_P_List_null_counter { protected: void reset() {} void inc() {} void dec() {} void swap(I_P_List_null_counter &rhs) {} }; /** Element counting policy class for I_P_List which provides basic element counting. */ class I_P_List_counter { uint m_counter; protected: I_P_List_counter() : m_counter (0) {} void reset() {m_counter= 0;} void inc() {m_counter++;} void dec() {m_counter--;} void swap(I_P_List_counter &rhs) { swap_variables(uint, m_counter, rhs.m_counter); } public: uint elements() const { return m_counter; } }; /** A null insertion policy class for I_P_List to be used in cases when push_back() operation is not necessary. */ template class I_P_List_no_push_back { protected: I_P_List_no_push_back(T **a) {}; void set_last(T **a) {} /* T** get_last() const method is intentionally left unimplemented in order to prohibit usage of push_back() method in lists which use this policy. */ void swap(I_P_List_no_push_back &rhs) {} }; /** An insertion policy class for I_P_List which can be used when fast push_back() operation is required. */ template class I_P_List_fast_push_back { T **m_last; protected: I_P_List_fast_push_back(T **a) : m_last(a) { }; void set_last(T **a) { m_last= a; } T** get_last() const { return m_last; } void swap(I_P_List_fast_push_back &rhs) { swap_variables(T**, m_last, rhs.m_last); } }; #endif