/*
* This file is part of OpenTTD.
* OpenTTD 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.
* OpenTTD 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 OpenTTD. If not, see .
*/
/** @file multimap.hpp Multimap with deterministic ordering of items with equal keys. */
#ifndef MULTIMAP_HPP
#define MULTIMAP_HPP
template
class MultiMap;
/**
* STL-style iterator for MultiMap.
* @tparam Tmap_iter Iterator type for the map in the MultiMap.
* @tparam Tlist_iter Iterator type for the lists in the MultiMap.
* @tparam Tkey Key type of the MultiMap.
* @tparam Tvalue Value type of the MultMap.
* @tparam Tcompare Comparator type for keys of the MultiMap.
*/
template
class MultiMapIterator {
protected:
friend class MultiMap;
typedef MultiMapIterator Self;
Tlist_iter list_iter; ///< Iterator pointing to current position in the current list of items with equal keys.
Tmap_iter map_iter; ///< Iterator pointing to the position of the current list of items with equal keys in the map.
/**
* Flag to show that the iterator has just "walked" a step in the map.
* We cannot check the current list for that as we might have reached end() of the map. In that case we'd need to
* set list_iter to some sort of "invalid" state, but that's impossible as operator== yields undefined behaviour
* if the iterators don't belong to the same list and there is no list at end(). So if we created a static empty
* list and an "invalid" iterator in that we could not determine if the iterator is invalid while it's valid. We
* can also not determine if the map iterator is valid while we don't have the map; so in the end it's easiest to
* just introduce an extra flag.
*/
bool list_valid;
public:
/**
* Simple, dangerous constructor to allow later assignment with operator=.
*/
MultiMapIterator() : list_valid(false) {}
/**
* Constructor to allow possibly const iterators to be assigned from possibly
* non-const map iterators. You can assign end() like this.
* @tparam Tnon_const Iterator type assignable to Tmap_iter (which might be const).
* @param mi One such iterator.
*/
template
MultiMapIterator(Tnon_const mi) : map_iter(mi), list_valid(false) {}
/**
* Constructor to allow specifying an exact position in map and list. You cannot
* construct end() like this as the constructor will actually check li and mi->second
* for list_valid.
* @param mi Iterator in the map.
* @param li Iterator in the list.
*/
MultiMapIterator(Tmap_iter mi, Tlist_iter li) : list_iter(li), map_iter(mi)
{
this->list_valid = (this->list_iter != this->map_iter->second.begin());
}
/**
* Assignment iterator like constructor with the same signature.
* @tparam Tnon_const Iterator type assignable to Tmap_iter (which might be const).
* @param mi One such iterator.
* @return This iterator.
*/
template
Self &operator=(Tnon_const mi)
{
this->map_iter = mi;
this->list_valid = false;
return *this;
}
/**
* Dereference operator. Works just like usual STL operator*() on various containers.
* Doesn't do a lot of checks for sanity, just like STL.
* @return The value associated with the item this iterator points to.
*/
Tvalue &operator*() const
{
assert(!this->map_iter->second.empty());
return this->list_valid ?
this->list_iter.operator*() :
this->map_iter->second.begin().operator*();
}
/**
* Same as operator*(), but returns a pointer.
* @return Pointer to the value this iterator points to.
*/
Tvalue *operator->() const
{
assert(!this->map_iter->second.empty());
return this->list_valid ?
this->list_iter.operator->() :
this->map_iter->second.begin().operator->();
}
inline const Tmap_iter &GetMapIter() const { return this->map_iter; }
inline const Tlist_iter &GetListIter() const { return this->list_iter; }
inline bool ListValid() const { return this->list_valid; }
const Tkey &GetKey() const { return this->map_iter->first; }
/**
* Prefix increment operator. Increment the iterator and set it to the
* next item in the MultiMap. This either increments the list iterator
* or the map iterator and sets list_valid accordingly.
* @return This iterator after incrementing.
*/
Self &operator++()
{
assert(!this->map_iter->second.empty());
if (this->list_valid) {
if (++this->list_iter == this->map_iter->second.end()) {
++this->map_iter;
this->list_valid = false;
}
} else {
this->list_iter = ++(this->map_iter->second.begin());
if (this->list_iter == this->map_iter->second.end()) {
++this->map_iter;
} else {
this->list_valid = true;
}
}
return *this;
}
/**
* Postfix increment operator. Same as prefix increment, but return the
* previous state.
* @param dummy param to mark postfix.
* @return This iterator before incrementing.
*/
Self operator++(int)
{
Self tmp = *this;
this->operator++();
return tmp;
}
/**
* Prefix decrement operator. Decrement the iterator and set it to the
* previous item in the MultiMap.
* @return This iterator after decrementing.
*/
Self &operator--()
{
assert(!this->map_iter->second.empty());
if (!this->list_valid) {
--this->map_iter;
this->list_iter = this->map_iter->second.end();
assert(!this->map_iter->second.empty());
}
this->list_valid = (--this->list_iter != this->map_iter->second.begin());
return *this;
}
/**
* Postfix decrement operator. Same as prefix decrement, but return the
* previous state.
* @param dummy param to mark postfix.
* @return This iterator before decrementing.
*/
Self operator--(int)
{
Self tmp = *this;
this->operator--();
return tmp;
}
};
/* Generic comparison functions for const/non-const MultiMap iterators and map iterators */
/**
* Compare two MultiMap iterators. Iterators are equal if
* 1. Their map iterators are equal.
* 2. They agree about list_valid.
* 3. If list_valid they agree about list_iter.
* Lots of template parameters to make all possible const and non-const types of MultiMap iterators
* (on maps with const and non-const values) comparable to each other.
* @param iter1 First iterator to compare.
* @param iter2 Second iterator to compare.
* @return If iter1 and iter2 are equal.
*/
template
bool operator==(const MultiMapIterator &iter1, const MultiMapIterator &iter2)
{
if (iter1.GetMapIter() != iter2.GetMapIter()) return false;
if (!iter1.ListValid()) return !iter2.ListValid();
return iter2.ListValid() ?
iter1.GetListIter() == iter2.GetListIter() : false;
}
/**
* Inverse of operator==().
* Lots of template parameters to make all possible const and non-const types of MultiMap iterators
* (on maps with const and non-const values) comparable to each other.
* @param iter1 First iterator to compare.
* @param iter2 Second iterator to compare.
* @return If iter1 and iter2 are not equal.
*/
template
bool operator!=(const MultiMapIterator &iter1, const MultiMapIterator &iter2)
{
return !(iter1 == iter2);
}
/**
* Check if a MultiMap iterator is at the begin of a list pointed to by the given map iterator.
* Lots of template parameters to make all possible const and non-const types of MultiMap iterators
* (on maps with const and non-const values) comparable to all possible types of map iterators.
* @param iter1 MultiMap iterator.
* @param iter2 Map iterator.
* @return If iter1 points to the begin of the list pointed to by iter2.
*/
template
bool operator==(const MultiMapIterator &iter1, const Tmap_iter2 &iter2)
{
return !iter1.ListValid() && iter1.GetMapIter() == iter2;
}
/**
* Inverse of operator==() with same signature.
* @param iter1 MultiMap iterator.
* @param iter2 Map iterator.
* @return If iter1 doesn't point to the begin of the list pointed to by iter2.
*/
template
bool operator!=(const MultiMapIterator &iter1, const Tmap_iter2 &iter2)
{
return iter1.ListValid() || iter1.GetMapIter() != iter2;
}
/**
* Same as operator==() with reversed order of arguments.
* @param iter2 Map iterator.
* @param iter1 MultiMap iterator.
* @return If iter1 points to the begin of the list pointed to by iter2.
*/
template
bool operator==(const Tmap_iter2 &iter2, const MultiMapIterator &iter1)
{
return !iter1.ListValid() && iter1.GetMapIter() == iter2;
}
/**
* Same as operator!=() with reversed order of arguments.
* @param iter2 Map iterator.
* @param iter1 MultiMap iterator.
* @return If iter1 doesn't point to the begin of the list pointed to by iter2.
*/
template
bool operator!=(const Tmap_iter2 &iter2, const MultiMapIterator &iter1)
{
return iter1.ListValid() || iter1.GetMapIter() != iter2;
}
/**
* Hand-rolled multimap as map of lists. Behaves mostly like a list, but is sorted
* by Tkey so that you can easily look up ranges of equal keys. Those ranges are
* internally ordered in a deterministic way (contrary to STL multimap). All
* STL-compatible members are named in STL style, all others are named in OpenTTD
* style.
*/
template >
class MultiMap : public std::map, Tcompare > {
public:
typedef typename std::list List;
typedef typename List::iterator ListIterator;
typedef typename List::const_iterator ConstListIterator;
typedef typename std::map Map;
typedef typename Map::iterator MapIterator;
typedef typename Map::const_iterator ConstMapIterator;
typedef MultiMapIterator iterator;
typedef MultiMapIterator const_iterator;
/**
* Erase the value pointed to by an iterator. The iterator may be invalid afterwards.
* @param it Iterator pointing at some value.
* @return Iterator to the element after the deleted one (or invalid).
*/
iterator erase(iterator it)
{
List &list = it.map_iter->second;
assert(!list.empty());
if (it.list_valid) {
it.list_iter = list.erase(it.list_iter);
/* This can't be the first list element as otherwise list_valid would have
* to be false. So the list cannot be empty here. */
if (it.list_iter == list.end()) {
++it.map_iter;
it.list_valid = false;
}
} else {
list.erase(list.begin());
if (list.empty()) this->Map::erase(it.map_iter++);
}
return it;
}
/**
* Insert a value at the end of the range with the specified key.
* @param key Key to be inserted at.
* @param val Value to be inserted.
*/
void Insert(const Tkey &key, const Tvalue &val)
{
List &list = (*this)[key];
list.push_back(val);
assert(!list.empty());
}
/**
* Count all items in this MultiMap. This involves iterating over the map.
* @return Number of items in the MultiMap.
*/
size_t size() const
{
size_t ret = 0;
for (ConstMapIterator it = this->Map::begin(); it != this->Map::end(); ++it) {
ret += it->second.size();
}
return ret;
}
/**
* Count the number of ranges with equal keys in this MultiMap.
* @return Number of ranges with equal keys.
*/
size_t MapSize() const
{
return this->Map::size();
}
/**
* Get a pair of iterators specifying a range of items with equal keys.
* @param key Key to look for.
* @return Range of items with given key.
*/
std::pair equal_range(const Tkey &key)
{
MapIterator begin(this->lower_bound(key));
if (begin != this->Map::end() && begin->first == key) {
MapIterator end = begin;
return std::make_pair(begin, ++end);
}
return std::make_pair(begin, begin);
}
/**
* Get a pair of constant iterators specifying a range of items with equal keys.
* @param key Key to look for.
* @return Constant range of items with given key.
*/
std::pair equal_range(const Tkey &key) const
{
ConstMapIterator begin(this->lower_bound(key));
if (begin != this->Map::end() && begin->first == key) {
ConstMapIterator end = begin;
return std::make_pair(begin, ++end);
}
return std::make_pair(begin, begin);
}
};
#endif /* MULTIMAP_HPP */