.
17 /// \brief A map with "small integers" as value set which can enumarate it
20 /// \todo Decide whether we need all the range checkings!!!
22 /// \todo Implement dynamic map behaviour. Is it necessary? Yes it is.
24 template<typename KeyIntMap, uint8_t N, typename Val = uint8_t>
28 typedef typename KeyIntMap::KeyType KeyType;
29 typedef Val ValueType;
31 typedef typename std::vector<KeyType>::const_iterator iterator;
35 std::vector<KeyType> data;
39 Val find(size_t a) const {
40 for(uint8_t n=0; n<N; ++n) {
47 void half_swap(size_t &a, size_t b) {
55 size_t move(size_t a, uint8_t m, uint8_t n) {
58 KeyType orig_key = data[a];
61 half_swap(a, bounds[m]++);
63 // FIXME: range check ide?
65 half_swap(a, --bounds[m]);
69 base.set(orig_key, a);
78 IterableMap(KeyIntMap &_base, Val d = N+1) : base(_base), def_val(d) {
79 memset(bounds, 0, sizeof(bounds));
80 // for(int i=0; i<N; ++i) { bounds[i]=0; }
83 Val operator[](const KeyType& k) const {
87 void set(const KeyType& k, Val n) {
88 // FIXME: range check?
98 void insert(const KeyType& k, Val n) {
100 base.set(k, move(bounds[N-1]++, N-1, n));
103 /// This func is not very usable, but necessary to implement
104 /// dynamic map behaviour.
105 void remove(const KeyType& k) {
107 if(a < bounds[N-1]) {
114 iterator begin(Val n) const {
115 return data.begin() + (n ? bounds[n-1] : 0);
118 iterator end(Val n) const {
119 return data.begin() + bounds[n];
122 size_t size(Val n) const {
123 return bounds[n] - (n ? bounds[n-1] : 0);
126 size_t size() const {
127 // assert(bounds[N-1] == data.size());
132 /// For use as an iterator...
133 KeyType& first(KeyType &k, Val n) {
134 size_t i = (n ? bounds[n-1] : 0);
135 if( i < bounds[n] ) {
144 /// For use as an iterator...
145 KeyType& next(KeyType &k) {
149 if( i < bounds[n] ) {
163 template<typename KeyIntMap>
164 class IterableBoolMap : public IterableMap<KeyIntMap, 2, bool> {
165 typedef IterableMap<KeyIntMap, 2, bool> Parent;
168 IterableBoolMap(KeyIntMap &_base, bool d = false) : Parent(_base, d) {}