virtualx-engine/core/list.h

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/*************************************************************************/
/* list.h */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* https://godotengine.org */
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/*************************************************************************/
/* Copyright (c) 2007-2019 Juan Linietsky, Ariel Manzur. */
/* Copyright (c) 2014-2019 Godot Engine contributors (cf. AUTHORS.md) */
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/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
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#ifndef GLOBALS_LIST_H
#define GLOBALS_LIST_H
#include "core/os/memory.h"
#include "core/sort_array.h"
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/**
* Generic Templatized Linked List Implementation.
* The implementation differs from the STL one because
* a compatible preallocated linked list can be written
* using the same API, or features such as erasing an element
* from the iterator.
*/
template <class T, class A = DefaultAllocator>
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class List {
struct _Data;
public:
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class Element {
private:
friend class List<T, A>;
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T value;
Element *next_ptr;
Element *prev_ptr;
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_Data *data;
public:
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/**
* Get NEXT Element iterator, for constant lists.
*/
_FORCE_INLINE_ const Element *next() const {
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return next_ptr;
};
/**
* Get NEXT Element iterator,
*/
_FORCE_INLINE_ Element *next() {
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return next_ptr;
};
/**
* Get PREV Element iterator, for constant lists.
*/
_FORCE_INLINE_ const Element *prev() const {
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return prev_ptr;
};
/**
* Get PREV Element iterator,
*/
_FORCE_INLINE_ Element *prev() {
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return prev_ptr;
};
/**
* * operator, for using as *iterator, when iterators are defined on stack.
*/
_FORCE_INLINE_ const T &operator*() const {
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return value;
};
/**
* operator->, for using as iterator->, when iterators are defined on stack, for constant lists.
*/
_FORCE_INLINE_ const T *operator->() const {
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return &value;
};
/**
* * operator, for using as *iterator, when iterators are defined on stack,
*/
_FORCE_INLINE_ T &operator*() {
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return value;
};
/**
* operator->, for using as iterator->, when iterators are defined on stack, for constant lists.
*/
_FORCE_INLINE_ T *operator->() {
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return &value;
};
/**
* get the value stored in this element.
*/
_FORCE_INLINE_ T &get() {
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return value;
};
/**
* get the value stored in this element, for constant lists
*/
_FORCE_INLINE_ const T &get() const {
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return value;
};
/**
* set the value stored in this element.
*/
_FORCE_INLINE_ void set(const T &p_value) {
value = (T &)p_value;
};
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void erase() {
data->erase(this);
}
_FORCE_INLINE_ Element() {
next_ptr = 0;
prev_ptr = 0;
data = NULL;
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};
};
private:
struct _Data {
Element *first;
Element *last;
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int size_cache;
bool erase(const Element *p_I) {
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ERR_FAIL_COND_V(!p_I, false);
ERR_FAIL_COND_V(p_I->data != this, false);
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if (first == p_I) {
first = p_I->next_ptr;
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};
if (last == p_I)
last = p_I->prev_ptr;
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if (p_I->prev_ptr)
p_I->prev_ptr->next_ptr = p_I->next_ptr;
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if (p_I->next_ptr)
p_I->next_ptr->prev_ptr = p_I->prev_ptr;
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memdelete_allocator<Element, A>(const_cast<Element *>(p_I));
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size_cache--;
return true;
}
};
_Data *_data;
public:
/**
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* return a const iterator to the beginning of the list.
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*/
_FORCE_INLINE_ const Element *front() const {
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return _data ? _data->first : 0;
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};
/**
* return an iterator to the beginning of the list.
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*/
_FORCE_INLINE_ Element *front() {
return _data ? _data->first : 0;
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};
/**
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* return a const iterator to the last member of the list.
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*/
_FORCE_INLINE_ const Element *back() const {
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return _data ? _data->last : 0;
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};
/**
* return an iterator to the last member of the list.
*/
_FORCE_INLINE_ Element *back() {
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return _data ? _data->last : 0;
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};
/**
* store a new element at the end of the list
*/
Element *push_back(const T &value) {
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if (!_data) {
_data = memnew_allocator(_Data, A);
_data->first = NULL;
_data->last = NULL;
_data->size_cache = 0;
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}
Element *n = memnew_allocator(Element, A);
n->value = (T &)value;
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n->prev_ptr = _data->last;
n->next_ptr = 0;
n->data = _data;
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if (_data->last) {
_data->last->next_ptr = n;
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}
_data->last = n;
if (!_data->first)
_data->first = n;
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_data->size_cache++;
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return n;
};
void pop_back() {
if (_data && _data->last)
erase(_data->last);
}
/**
* store a new element at the beginning of the list
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*/
Element *push_front(const T &value) {
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if (!_data) {
_data = memnew_allocator(_Data, A);
_data->first = NULL;
_data->last = NULL;
_data->size_cache = 0;
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}
Element *n = memnew_allocator(Element, A);
n->value = (T &)value;
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n->prev_ptr = 0;
n->next_ptr = _data->first;
n->data = _data;
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if (_data->first) {
_data->first->prev_ptr = n;
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}
_data->first = n;
if (!_data->last)
_data->last = n;
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_data->size_cache++;
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return n;
};
void pop_front() {
if (_data && _data->first)
erase(_data->first);
}
Element *insert_after(Element *p_element, const T &p_value) {
CRASH_COND(p_element && (!_data || p_element->data != _data));
if (!p_element) {
return push_back(p_value);
}
Element *n = memnew_allocator(Element, A);
n->value = (T &)p_value;
n->prev_ptr = p_element;
n->next_ptr = p_element->next_ptr;
n->data = _data;
if (!p_element->next_ptr) {
_data->last = n;
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} else {
p_element->next_ptr->prev_ptr = n;
}
p_element->next_ptr = n;
_data->size_cache++;
return n;
}
Element *insert_before(Element *p_element, const T &p_value) {
CRASH_COND(p_element && (!_data || p_element->data != _data));
if (!p_element) {
return push_back(p_value);
}
Element *n = memnew_allocator(Element, A);
n->value = (T &)p_value;
n->prev_ptr = p_element->prev_ptr;
n->next_ptr = p_element;
n->data = _data;
if (!p_element->prev_ptr) {
_data->first = n;
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} else {
p_element->prev_ptr->next_ptr = n;
}
p_element->prev_ptr = n;
_data->size_cache++;
return n;
}
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/**
* find an element in the list,
*/
template <class T_v>
Element *find(const T_v &p_val) {
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Element *it = front();
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while (it) {
if (it->value == p_val) return it;
it = it->next();
};
return NULL;
};
/**
* erase an element in the list, by iterator pointing to it. Return true if it was found/erased.
*/
bool erase(const Element *p_I) {
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if (_data) {
bool ret = _data->erase(p_I);
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if (_data->size_cache == 0) {
memdelete_allocator<_Data, A>(_data);
_data = NULL;
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}
return ret;
}
return false;
};
/**
* erase the first element in the list, that contains value
*/
bool erase(const T &value) {
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Element *I = find(value);
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return erase(I);
};
/**
* return whether the list is empty
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*/
_FORCE_INLINE_ bool empty() const {
return (!_data || !_data->size_cache);
}
/**
* clear the list
*/
void clear() {
while (front()) {
erase(front());
};
};
_FORCE_INLINE_ int size() const {
return _data ? _data->size_cache : 0;
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}
void swap(Element *p_A, Element *p_B) {
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ERR_FAIL_COND(!p_A || !p_B);
ERR_FAIL_COND(p_A->data != _data);
ERR_FAIL_COND(p_B->data != _data);
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Element *A_prev = p_A->prev_ptr;
Element *A_next = p_A->next_ptr;
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p_A->next_ptr = p_B->next_ptr;
p_A->prev_ptr = p_B->prev_ptr;
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p_B->next_ptr = A_next;
p_B->prev_ptr = A_prev;
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if (p_A->prev_ptr)
p_A->prev_ptr->next_ptr = p_A;
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if (p_A->next_ptr)
p_A->next_ptr->prev_ptr = p_A;
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if (p_B->prev_ptr)
p_B->prev_ptr->next_ptr = p_B;
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if (p_B->next_ptr)
p_B->next_ptr->prev_ptr = p_B;
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}
/**
* copy the list
*/
void operator=(const List &p_list) {
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clear();
const Element *it = p_list.front();
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while (it) {
push_back(it->get());
it = it->next();
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}
}
T &operator[](int p_index) {
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CRASH_BAD_INDEX(p_index, size());
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Element *I = front();
int c = 0;
while (I) {
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if (c == p_index) {
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return I->get();
}
I = I->next();
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c++;
}
CRASH_NOW(); // bug!!
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}
const T &operator[](int p_index) const {
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CRASH_BAD_INDEX(p_index, size());
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const Element *I = front();
int c = 0;
while (I) {
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if (c == p_index) {
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return I->get();
}
I = I->next();
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c++;
}
CRASH_NOW(); // bug!!
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}
void move_to_back(Element *p_I) {
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ERR_FAIL_COND(p_I->data != _data);
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if (!p_I->next_ptr)
return;
if (_data->first == p_I) {
_data->first = p_I->next_ptr;
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};
if (_data->last == p_I)
_data->last = p_I->prev_ptr;
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if (p_I->prev_ptr)
p_I->prev_ptr->next_ptr = p_I->next_ptr;
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p_I->next_ptr->prev_ptr = p_I->prev_ptr;
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_data->last->next_ptr = p_I;
p_I->prev_ptr = _data->last;
p_I->next_ptr = NULL;
_data->last = p_I;
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}
void invert() {
int s = size() / 2;
Element *F = front();
Element *B = back();
for (int i = 0; i < s; i++) {
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SWAP(F->value, B->value);
F = F->next();
B = B->prev();
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}
}
void move_to_front(Element *p_I) {
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ERR_FAIL_COND(p_I->data != _data);
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if (!p_I->prev_ptr)
return;
if (_data->first == p_I) {
_data->first = p_I->next_ptr;
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};
if (_data->last == p_I)
_data->last = p_I->prev_ptr;
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p_I->prev_ptr->next_ptr = p_I->next_ptr;
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if (p_I->next_ptr)
p_I->next_ptr->prev_ptr = p_I->prev_ptr;
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_data->first->prev_ptr = p_I;
p_I->next_ptr = _data->first;
p_I->prev_ptr = NULL;
_data->first = p_I;
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}
void move_before(Element *value, Element *where) {
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if (value->prev_ptr) {
value->prev_ptr->next_ptr = value->next_ptr;
} else {
_data->first = value->next_ptr;
}
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if (value->next_ptr) {
value->next_ptr->prev_ptr = value->prev_ptr;
} else {
_data->last = value->prev_ptr;
}
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value->next_ptr = where;
if (!where) {
value->prev_ptr = _data->last;
_data->last = value;
return;
};
value->prev_ptr = where->prev_ptr;
if (where->prev_ptr) {
where->prev_ptr->next_ptr = value;
} else {
_data->first = value;
};
where->prev_ptr = value;
};
/**
* simple insertion sort
*/
void sort() {
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sort_custom<Comparator<T> >();
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}
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template <class C>
void sort_custom_inplace() {
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if (size() < 2)
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return;
Element *from = front();
Element *current = from;
Element *to = from;
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while (current) {
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Element *next = current->next_ptr;
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if (from != current) {
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current->prev_ptr = NULL;
current->next_ptr = from;
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Element *find = from;
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C less;
while (find && less(find->value, current->value)) {
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current->prev_ptr = find;
current->next_ptr = find->next_ptr;
find = find->next_ptr;
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}
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if (current->prev_ptr)
current->prev_ptr->next_ptr = current;
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else
from = current;
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if (current->next_ptr)
current->next_ptr->prev_ptr = current;
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else
to = current;
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} else {
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current->prev_ptr = NULL;
current->next_ptr = NULL;
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}
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current = next;
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}
_data->first = from;
_data->last = to;
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}
template <class C>
struct AuxiliaryComparator {
C compare;
_FORCE_INLINE_ bool operator()(const Element *a, const Element *b) const {
return compare(a->value, b->value);
}
};
template <class C>
void sort_custom() {
//this version uses auxiliary memory for speed.
//if you don't want to use auxiliary memory, use the in_place version
int s = size();
if (s < 2)
return;
Element **aux_buffer = memnew_arr(Element *, s);
int idx = 0;
for (Element *E = front(); E; E = E->next_ptr) {
aux_buffer[idx] = E;
idx++;
}
SortArray<Element *, AuxiliaryComparator<C> > sort;
sort.sort(aux_buffer, s);
_data->first = aux_buffer[0];
aux_buffer[0]->prev_ptr = NULL;
aux_buffer[0]->next_ptr = aux_buffer[1];
_data->last = aux_buffer[s - 1];
aux_buffer[s - 1]->prev_ptr = aux_buffer[s - 2];
aux_buffer[s - 1]->next_ptr = NULL;
for (int i = 1; i < s - 1; i++) {
aux_buffer[i]->prev_ptr = aux_buffer[i - 1];
aux_buffer[i]->next_ptr = aux_buffer[i + 1];
}
memdelete_arr(aux_buffer);
}
const void *id() const {
return (void *)_data;
}
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/**
* copy constructor for the list
*/
List(const List &p_list) {
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_data = NULL;
const Element *it = p_list.front();
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while (it) {
push_back(it->get());
it = it->next();
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}
}
List() {
_data = NULL;
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};
~List() {
clear();
if (_data) {
ERR_FAIL_COND(_data->size_cache);
memdelete_allocator<_Data, A>(_data);
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}
};
};
#endif