pallas · August 29, 2015 13:58
diff --git a/intrusive_order.hh b/intrusive_order.hh
 // All rights reserved,
 // Derrick Pallas
 // License: zlib

 #ifndef INTRUSIVE_ORDER_H
 #define INTRUSIVE_ORDER_H

 #include <cassert>
 #include <cstddef>
 #include <algorithm>

 template <class X>
 struct intrusive_order_link {
  intrusive_order_link() : p(NULL) { }
  ~intrusive_order_link() { assert(!p); }

  typedef intrusive_order_link type;
  template <class T, typename intrusive_order_link<T>::type T::*link,
            typename K, K T::*key>
    class intrusive_order;

  bool bound() const { return p; }

 private:
  X* p;
 };

 template <class T, typename intrusive_order_link<T>::type T::*link,
          typename K, K T::*key>
 class intrusive_order {
 public:
  intrusive_order() : head(NULL), tail(&head) { }
  ~intrusive_order() { assert(empty()); }

  bool empty() const { return !head; }

  intrusive_order & insert(T* t) {
    assert(!(t->*link).bound());
    assert(!empty() || &head == tail);

    if (empty() || !(t->*key < (*tail)->*key)) {
      *tail = t;
      tail = &(t->*link).p;
      *tail = t;
    } else {
      T ** c;
      for (c = &head ; c != tail ; c = &((*c)->*link).p)
        if (!((*c)->*key < t->*key))
          break;
      (t->*link).p = *c;
      *c = t;
    }

    assert((t->*link).bound());
    assert(!empty());
    return *this;
  }

  T & front() {
    assert(!empty());
    return *head;
  }

  const T & front() const {
    assert(!empty());
    return *head;
  }

  T & back() {
    assert (!empty());
    return **tail;
  }

  const T & back() const {
    assert (!empty());
    return **tail;
  }

  T* remove() {
    assert(!empty());

    T* t = head;
    assert((t->*link).bound());

    head = *tail != head
         ? (head->*link).p
         : NULL;

    if (empty())
      tail = &head;

    (t->*link).p = NULL;

    assert(!(t->*link).bound());
    return t;
  }

  intrusive_order & merge(intrusive_order & that) {
    assert(this != &that);
    intrusive_order result;

    while (!this->empty() && !that.empty())
      result.insert( this->head->*key < that.head->*key
                   ? this->remove()
                   : that.remove() );

    if (!this->empty())
      result.chain(*this);

    if (!that.empty())
      result.chain(that);

    swap(result);
    return *this;
  }

  void swap(intrusive_order & that) {
    std::swap(this->head, that.head);
    std::swap(this->tail, that.tail);
  }

 private:
  intrusive_order(const intrusive_order &);
  intrusive_order & operator=(const intrusive_order &);

  T * head;
  T ** tail;

  intrusive_order & chain(intrusive_order & that) {
    assert(this != &that);
    assert(!that.empty());

    *tail = that.head;
    tail = that.tail;
    assert(!empty());

    that.head = NULL;
    that.tail = &that.head;
    assert(that.empty());

    return *this;
  }
 };

 #endif//INTRUSIVE_ORDER
	// All rights reserved,
	// Derrick Pallas
	// License: zlib

	#ifndef INTRUSIVE_ORDER_H
	#define INTRUSIVE_ORDER_H

	#include <cassert>
	#include <cstddef>
	#include <algorithm>

	template <class X>
	struct intrusive_order_link {
	intrusive_order_link() : p(NULL) { }
	~intrusive_order_link() { assert(!p); }

	typedef intrusive_order_link type;
	template <class T, typename intrusive_order_link<T>::type T::*link,
	typename K, K T::*key>
	class intrusive_order;

	bool bound() const { return p; }

	private:
	X* p;
	};

	template <class T, typename intrusive_order_link<T>::type T::*link,
	typename K, K T::*key>
	class intrusive_order {
	public:
	intrusive_order() : head(NULL), tail(&head) { }
	~intrusive_order() { assert(empty()); }

	bool empty() const { return !head; }

	intrusive_order & insert(T* t) {
	assert(!(t->*link).bound());
	assert(!empty() \|\| &head == tail);

	if (empty() \|\| !(t->key < (tail)->*key)) {
	*tail = t;
	tail = &(t->*link).p;
	*tail = t;
	} else {
	T ** c;
	for (c = &head ; c != tail ; c = &((c)->link).p)
	if (!((c)->key < t->*key))
	break;
	(t->link).p = c;
	*c = t;
	}

	assert((t->*link).bound());
	assert(!empty());
	return *this;
	}

	T & front() {
	assert(!empty());
	return *head;
	}

	const T & front() const {
	assert(!empty());
	return *head;
	}

	T & back() {
	assert (!empty());
	return **tail;
	}

	const T & back() const {
	assert (!empty());
	return **tail;
	}

	T* remove() {
	assert(!empty());

	T* t = head;
	assert((t->*link).bound());

	head = *tail != head
	? (head->*link).p
	: NULL;

	if (empty())
	tail = &head;

	(t->*link).p = NULL;

	assert(!(t->*link).bound());
	return t;
	}

	intrusive_order & merge(intrusive_order & that) {
	assert(this != &that);
	intrusive_order result;

	while (!this->empty() && !that.empty())
	result.insert( this->head->key < that.head->key
	? this->remove()
	: that.remove() );

	if (!this->empty())
	result.chain(*this);

	if (!that.empty())
	result.chain(that);

	swap(result);
	return *this;
	}

	void swap(intrusive_order & that) {
	std::swap(this->head, that.head);
	std::swap(this->tail, that.tail);
	}

	private:
	intrusive_order(const intrusive_order &);
	intrusive_order & operator=(const intrusive_order &);

	T * head;
	T ** tail;

	intrusive_order & chain(intrusive_order & that) {
	assert(this != &that);
	assert(!that.empty());

	*tail = that.head;
	tail = that.tail;
	assert(!empty());

	that.head = NULL;
	that.tail = &that.head;
	assert(that.empty());

	return *this;
	}
	};

	#endif//INTRUSIVE_ORDER