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[nit.git] / lib / standard / collection / array.nit
1 # This file is part of NIT ( http://www.nitlanguage.org ).
2 #
3 # Copyright 2004-2008 Jean Privat <jean@pryen.org>
4 # Copyright 2008 Floréal Morandat <morandat@lirmm.fr>
5 #
6 # This file is free software, which comes along with NIT. This software is
7 # distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
8 # without even the implied warranty of MERCHANTABILITY or FITNESS FOR A
9 # PARTICULAR PURPOSE. You can modify it is you want, provided this header
10 # is kept unaltered, and a notification of the changes is added.
11 # You are allowed to redistribute it and sell it, alone or is a part of
12 # another product.
13
14 # This module introduces the standard array structure.
15 # It also implements two other abstract collections : ArrayMap and ArraySet
16 module array
17
18 import abstract_collection
19
20 # One dimension array of objects.
21 abstract class AbstractArrayRead[E]
22 super SequenceRead[E]
23
24 redef var length = 0
25
26 redef fun is_empty do return _length == 0
27
28 redef fun has(item)
29 do
30 var i = 0
31 var l = length
32 while i < l do
33 if self[i] == item then return true
34 i += 1
35 end
36 return false
37 end
38
39 redef fun has_only(item)
40 do
41 var i = 0
42 var l = length
43 while i < l do
44 if self[i] != item then return false
45 i += 1
46 end
47 return true
48 end
49
50 redef fun count(item)
51 do
52 var res = 0
53 var i = 0
54 var l = length
55 while i < l do
56 if self[i] == item then res += 1
57 i += 1
58 end
59 return res
60 end
61
62 redef fun index_of(item) do return index_of_from(item, 0)
63
64 redef fun last_index_of(item: E): Int do return last_index_of_from(item, length-1)
65
66 redef fun index_of_from(item: E, pos: Int): Int
67 do
68 var i = pos
69 var len = length
70 while i < len do
71 if self[i] == item then
72 return i
73 end
74 i += 1
75 end
76 return -1
77 end
78
79 redef fun last_index_of_from(item: E, pos: Int): Int
80 do
81 var i = pos
82 while i >= 0 do
83 if self[i] == item then
84 return i
85 else
86 i -= 1
87 end
88 end
89 return -1
90 end
91
92 # Return a new array that is the reverse of `self`
93 #
94 # assert [1,2,3].reversed == [3, 2, 1]
95 fun reversed: Array[E]
96 do
97 var cmp = _length
98 var result = new Array[E].with_capacity(cmp)
99 while cmp > 0 do
100 cmp -= 1
101 result.add(self[cmp])
102 end
103 return result
104 end
105
106 # Copy a portion of `self` to an other array.
107 #
108 # var a = [1, 2, 3, 4]
109 # var b = [10, 20, 30, 40, 50]
110 # a.copy_to(1, 2, b, 2)
111 # assert b == [10, 20, 2, 3, 50]
112 fun copy_to(start: Int, len: Int, dest: AbstractArray[E], new_start: Int)
113 do
114 # TODO native one
115 var i = len
116 while i > 0 do
117 i -= 1
118 dest[new_start+i] = self[start+i]
119 end
120 end
121
122 redef fun output
123 do
124 var i = 0
125 var l = length
126 while i < l do
127 var e = self[i]
128 if e != null then e.output
129 i += 1
130 end
131 end
132
133 redef fun iterator: ArrayIterator[E] do return new ArrayIterator[E](self)
134 redef fun reverse_iterator do return new ArrayReverseIterator[E](self)
135 end
136
137 # Resizable one dimension array of objects.
138 abstract class AbstractArray[E]
139 super AbstractArrayRead[E]
140 super Sequence[E]
141
142 # Force the capacity to be at least `cap`.
143 # The capacity of the array is an internal information.
144 # However, this method can be used to prepare a large amount of add
145 fun enlarge(cap: Int) is abstract
146
147 redef fun push(item) do add(item)
148
149 redef fun pop
150 do
151 assert not_empty: not is_empty
152 var r = last
153 _length -= 1
154 return r
155 end
156
157 redef fun shift
158 do
159 assert not_empty: not is_empty
160 var r = first
161 var i = 1
162 var l = length
163 while i < l do
164 self[i-1] = self[i]
165 i += 1
166 end
167 _length = l - 1
168 return r
169 end
170
171 redef fun unshift(item)
172 do
173 var i = length - 1
174 while i >= 0 do
175 self[i+1] = self[i]
176 i -= 1
177 end
178 self[0] = item
179 end
180
181 redef fun insert(item: E, pos: Int)
182 do
183 enlarge(length + 1)
184 copy_to(pos, length-pos, self, pos + 1)
185 self[pos] = item
186 end
187
188 redef fun insert_all(coll, pos)
189 do
190 var l = coll.length
191 if l == 0 then return
192 enlarge(length + l)
193 _length += l
194 copy_to(pos, length-pos-l, self, pos + l)
195 for c in coll do
196 self[pos] = c
197 pos += 1
198 end
199 end
200
201 redef fun add(item) do self[length] = item
202
203 redef fun clear do _length = 0
204
205 redef fun remove(item) do remove_at(index_of(item))
206
207 redef fun remove_all(item)
208 do
209 var i = index_of(item)
210 while i >= 0 do
211 remove_at(i)
212 i = index_of_from(item, i)
213 end
214 end
215
216 redef fun remove_at(i)
217 do
218 var l = length
219 if i >= 0 and i < l then
220 var j = i + 1
221 while j < l do
222 self[j-1] = self[j]
223 j += 1
224 end
225 _length = l - 1
226 end
227 end
228
229 # Invert two elements in the array
230 #
231 # var a = [10, 20, 30, 40]
232 # a.swap_at(1, 3)
233 # assert a == [10, 40, 30, 20]
234 fun swap_at(a: Int,b: Int)
235 do
236 var e = self[a]
237 self[a] = self[b]
238 self[b] = e
239 end
240 end
241
242 # Resizable one dimension array of objects.
243 #
244 # Arrays have a literal representation.
245 #
246 # var a = [12, 32, 8]
247 # # is equivalent with:
248 # var b = new Array[Int]
249 # b.push(12)
250 # b.push(32)
251 # b.push(8)
252 # assert a == b
253 class Array[E]
254 super AbstractArray[E]
255
256 redef fun [](index)
257 do
258 assert index: index >= 0 and index < _length
259 return _items[index]
260 end
261
262 redef fun []=(index, item)
263 do
264 assert index: index >= 0 and index < _length + 1
265 if _capacity <= index then
266 enlarge(index + 1)
267 end
268 if _length <= index then
269 _length = index + 1
270 end
271 _items[index] = item
272 end
273
274 redef fun add(item)
275 do
276 var l = _length
277 if _capacity <= l then
278 enlarge(l + 1)
279 end
280 _length = l + 1
281 _items[l] = item
282 end
283
284 # Slight optimization for arrays
285 redef fun add_all(items)
286 do
287 var l = _length
288 var nl = l + items.length
289 if _capacity < nl then
290 enlarge nl
291 end
292
293 if items isa Array[E] then
294 var k = 0
295 while l < nl do
296 _items[l] = items._items[k]
297 l += 1
298 k += 1
299 end
300 else
301 for item in items do
302 _items[l] = item
303 l += 1
304 end
305 end
306
307 _length = nl
308 end
309
310 redef fun enlarge(cap)
311 do
312 var c = _capacity
313 if cap <= c then return
314 while c <= cap do c = c * 2 + 2
315 var a = new NativeArray[E](c)
316 if _capacity > 0 then _items.copy_to(a, _length)
317 _items = a
318 _capacity = c
319 end
320
321 # Create an empty array.
322 init
323 do
324 _capacity = 0
325 _length = 0
326 end
327
328 # Create an array from a collection.
329 init from(items: Collection[E]) do
330 with_capacity(items.length)
331 self.add_all(items)
332 end
333
334 # Create an array with some `objects`.
335 init with_items(objects: E...)
336 do
337 _items = objects._items
338 _capacity = objects._capacity
339 _length = objects.length
340 end
341
342 # Create an empty array with a given capacity.
343 init with_capacity(cap: Int)
344 do
345 assert positive: cap >= 0
346 _items = new NativeArray[E](cap)
347 _capacity = cap
348 _length = 0
349 end
350
351 # Create an array of `count` elements
352 init filled_with(value: E, count: Int)
353 do
354 assert positive: count >= 0
355 _items = new NativeArray[E](count)
356 _capacity = count
357 _length = count
358 var i = 0
359 while i < count do
360 self[i] = value
361 i += 1
362 end
363 end
364
365 # Create a array filled with a given native array.
366 init with_native(nat: NativeArray[E], size: Int)
367 do
368 assert positive: size >= 0
369 _items = nat
370 _capacity = size
371 _length = size
372 end
373
374 # The internal storage.
375 private var items: nullable NativeArray[E] = null
376
377 # The size of `_items`.
378 private var capacity: Int = 0
379
380 redef fun ==(o)
381 do
382 if not o isa Array[nullable Object] then return super
383 # Efficient implementation
384 var l = length
385 if l != o.length then return false
386 var i = 0
387 var it = _items
388 var oit = o._items
389 while i < l do
390 if it[i] != oit[i] then return false
391 i += 1
392 end
393 return true
394 end
395
396 # Concatenation of arrays.
397 #
398 # Returns a new array built by concatenating `self` and `other` together.
399 #
400 # var a1 = [1,2,3]
401 # var a2 = [4,5,6]
402 # var a3 = a1 + a2
403 # assert a3 == [1,2,3,4,5,6]
404 #
405 # Because a new array is always created, future modification on `self` and `other`
406 # does not impact the previously computed result.
407 #
408 # a1.add(30)
409 # a2.add(60)
410 # assert a3 == [1,2,3,4,5,6] # unchanged
411 # assert a1 + a2 == [1,2,3,30,4,5,6,60]
412 fun +(other: Array[E]): Array[E]
413 do
414 var res = new Array[E].with_capacity(length + other.length)
415 res.append(self)
416 res.append(other)
417 return res
418 end
419
420 # Repetition of arrays.
421 #
422 # returns a new array built by concatenating `self` `repeat` times.
423 #
424 # var a = [1,2,3]
425 # assert (a * 0).is_empty
426 # assert a * 1 == [1,2,3]
427 # assert a * 2 == [1,2,3,1,2,3]
428 # assert (a * 10).length == 30
429 fun *(repeat: Int): Array[E]
430 do
431 assert repeat >= 0
432 var res = new Array[E].with_capacity(length * repeat)
433 while repeat > 0 do
434 res.add_all(self)
435 repeat -= 1
436 end
437 return res
438 end
439 end
440
441 # An `Iterator` on `AbstractArray`
442 private class ArrayIterator[E]
443 super IndexedIterator[E]
444
445 redef fun item do return _array[_index]
446
447 # redef fun item=(e) do _array[_index] = e
448
449 redef fun is_ok do return _index < _array.length
450
451 redef fun next do _index += 1
452
453 redef var index = 0
454
455 var array: AbstractArrayRead[E]
456 end
457
458 private class ArrayReverseIterator[E]
459 super ArrayIterator[E]
460
461 redef fun is_ok do return _index >= 0
462
463 redef fun next do _index -= 1
464
465 init
466 do
467 _index = _array.length - 1
468 end
469 end
470
471 # Others collections ##########################################################
472
473 # A set implemented with an Array.
474 class ArraySet[E: Object]
475 super Set[E]
476
477 # The stored elements.
478 private var array: Array[E] is noinit
479
480 redef fun has(e) do return _array.has(e)
481
482 redef fun add(e) do if not _array.has(e) then _array.add(e)
483
484 redef fun is_empty do return _array.is_empty
485
486 redef fun length do return _array.length
487
488 redef fun first
489 do
490 assert _array.length > 0
491 return _array.first
492 end
493
494 redef fun remove(item)
495 do
496 var i = _array.index_of(item)
497 if i >= 0 then remove_at(i)
498 end
499
500 redef fun remove_all(item) do remove(item)
501
502 redef fun clear do _array.clear
503
504 redef fun iterator do return new ArraySetIterator[E](_array.iterator)
505
506 # Assume the capacity is at least `cap`.
507 fun enlarge(cap: Int) do _array.enlarge(cap)
508
509 private fun remove_at(i: Int)
510 do
511 _array[i] = _array.last
512 _array.pop
513 end
514
515 # Create an empty set
516 init do _array = new Array[E]
517
518 # Create an empty set with a given capacity.
519 init with_capacity(i: Int) do _array = new Array[E].with_capacity(i)
520
521 redef fun new_set do return new ArraySet[E]
522 end
523
524 # Iterators on sets implemented with arrays.
525 private class ArraySetIterator[E: Object]
526 super Iterator[E]
527
528 redef fun is_ok do return _iter.is_ok
529
530 redef fun next do _iter.next
531
532 redef fun item: E do return _iter.item
533
534 var iter: ArrayIterator[E]
535 end
536
537
538 # Associative arrays implemented with an array of (key, value) pairs.
539 class ArrayMap[K: Object, E]
540 super CoupleMap[K, E]
541
542 # O(n)
543 redef fun [](key)
544 do
545 var i = index(key)
546 if i >= 0 then
547 return _items[i].second
548 else
549 return provide_default_value(key)
550 end
551 end
552
553 # O(n)
554 redef fun []=(key, item)
555 do
556 var i = index(key)
557 if i >= 0 then
558 _items[i].second = item
559 else
560 _items.push(new Couple[K,E](key, item))
561 end
562 end
563
564 redef var keys: RemovableCollection[K] = new ArrayMapKeys[K, E](self)
565 redef var values: RemovableCollection[E] = new ArrayMapValues[K, E](self)
566
567 # O(1)
568 redef fun length do return _items.length
569
570 redef fun couple_iterator do return _items.iterator
571
572 redef fun is_empty do return _items.is_empty
573
574 redef fun clear do _items.clear
575
576 # Assume the capacity to be at least `cap`.
577 fun enlarge(cap: Int) do _items.enlarge(cap)
578
579 redef fun couple_at(key)
580 do
581 var i = index(key)
582 if i >= 0 then
583 return _items[i]
584 else
585 return null
586 end
587 end
588
589 # Internal storage.
590 private var items = new Array[Couple[K,E]]
591
592 # fast remove the ith element of the array
593 private fun remove_at_index(i: Int)
594 do
595 _items[i] = _items.last
596 _items.pop
597 end
598
599 # The last positive result given by a index(1) call
600 private var last_index: Int = 0
601
602 # Where is the `key` in `_item`?
603 # return -1 if not found
604 private fun index(key: K): Int
605 do
606 var l = _last_index
607 if l < _items.length and _items[l].first == key then return l
608
609 var i = 0
610 while i < _items.length do
611 if _items[i].first == key then
612 _last_index = i
613 return i
614 end
615 i += 1
616 end
617 return -1
618 end
619 end
620
621 private class ArrayMapKeys[K: Object, E]
622 super RemovableCollection[K]
623 # The original map
624 var map: ArrayMap[K, E]
625 redef fun count(k) do if self.has(k) then return 1 else return 0
626 redef fun first do return self.map._items.first.first
627 redef fun has(k) do return self.map.index(k) >= 0
628 redef fun has_only(k) do return (self.has(k) and self.length == 1) or self.is_empty
629 redef fun is_empty do return self.map.is_empty
630 redef fun length do return self.map.length
631 redef fun iterator do return new MapKeysIterator[K, E](self.map.iterator)
632 redef fun clear do self.map.clear
633 redef fun remove(key)
634 do
635 var i = self.map.index(key)
636 if i >= 0 then self.map.remove_at_index(i)
637 end
638 redef fun remove_all(key) do self.remove(key)
639 end
640
641 private class ArrayMapValues[K: Object, E]
642 super RemovableCollection[E]
643 # The original map
644 var map: ArrayMap[K, E]
645 redef fun first do return self.map._items.first.second
646 redef fun is_empty do return self.map.is_empty
647 redef fun length do return self.map.length
648 redef fun iterator do return new MapValuesIterator[K, E](self.map.iterator)
649
650 # O(n)
651 redef fun has(item)
652 do
653 for i in self.map._items do if i.second == item then return true
654 return false
655 end
656
657 # O(n)
658 redef fun has_only(item)
659 do
660 for i in self.map._items do if i.second != item then return false
661 return true
662 end
663
664 # O(n)
665 redef fun count(item)
666 do
667 var nb = 0
668 for i in self.map._items do if i.second == item then nb += 1
669 return nb
670 end
671
672 redef fun clear do self.map.clear
673
674 redef fun remove(item)
675 do
676 var map = self.map
677 var i = map._items.length - 1
678 while i >= 0 do
679 if map._items[i].second == item then
680 map.remove_at_index(i)
681 return
682 end
683 i -= 1
684 end
685 end
686
687 redef fun remove_all(item)
688 do
689 var map = self.map
690 var i = map._items.length - 1
691 while i >= 0 do
692 if map._items[i].second == item then
693 map.remove_at_index(i)
694 end
695 i -= 1
696 end
697 end
698 end
699
700 # Comparable array for comparable elements.
701 #
702 # For two arrays, if one is a prefix, then it is lower.
703 #
704 # ~~~
705 # var a12 = new ArrayCmp[nullable Int].with_items(1,2)
706 # var a123 = new ArrayCmp[nullable Int].with_items(1,2,3)
707 # assert a12 < a123
708 # ~~~
709 #
710 # Otherwise, the first element just after the longest
711 # common prefix gives the order between the two arrays.
712 #
713 # ~~~
714 # var a124 = new ArrayCmp[nullable Int].with_items(1,2,4)
715 # var a13 = new ArrayCmp[nullable Int].with_items(1,3)
716 # assert a12 < a123
717 # assert a123 < a13
718 # ~~~
719 #
720 # Obviously, two equal arrays are equal.
721 #
722 # ~~~
723 # var b12 = new ArrayCmp[nullable Int].with_items(1,2)
724 # assert (a12 <=> b12) == 0
725 # ~~~
726 #
727 # `null` is considered lower than any other elements.
728 # But is still greater than no element.
729 #
730 # ~~~
731 # var a12n = new ArrayCmp[nullable Int].with_items(1,2,null)
732 # assert a12n < a123
733 # assert a12 < a12n
734 # ~~~
735 class ArrayCmp[E: nullable Comparable]
736 super Array[E]
737 super Comparable
738 redef type OTHER: ArrayCmp[E] is fixed
739
740 redef fun <(o) do return (self <=> o) < 0
741
742 redef fun <=>(o)
743 do
744 var it = _items
745 var oit = o._items
746 var i = 0
747 var l = length
748 var ol = o.length
749 var len
750 if l < ol then len = l else len = ol
751 while i < len do
752 var a = it[i]
753 var b = oit[i]
754 if a != null then
755 if b == null then return 1
756 var d = a <=> b.as(Comparable)
757 if d != 0 then return d
758 else
759 if b != null then return -1
760 end
761 i += 1
762 end
763 return l <=> ol
764 end
765 end
766
767 # Others tools ################################################################
768
769 redef class Iterator[E]
770 # Interate on `self` and build an array
771 fun to_a: Array[E]
772 do
773 var res = new Array[E]
774 while is_ok do
775 res.add(item)
776 next
777 end
778 return res
779 end
780 end
781
782 redef class Collection[E]
783 # Build a new array from a collection
784 fun to_a: Array[E]
785 do
786 var res = new Array[E].with_capacity(length)
787 res.add_all(self)
788 return res
789 end
790 end
791
792 # Native classes ##############################################################
793
794 # Native Nit array
795 # Access are unchecked and it has a fixed size
796 # Not for public use: may become private.
797 universal NativeArray[E]
798 # Creates a new NativeArray of capacity `length`
799 new(length: Int) is intern
800 # The length of the array
801 fun length: Int is intern
802 # Use `self` to initialize a standard Nit Array.
803 fun to_a: Array[E] do return new Array[E].with_native(self, length)
804
805 # Get item at `index`.
806 fun [](index: Int): E is intern
807
808 # Set `item` at `index`.
809 fun []=(index: Int, item: E) is intern
810
811 # Copy `length` items to `dest`.
812 fun copy_to(dest: NativeArray[E], length: Int) is intern
813 #fun =(o: NativeArray[E]): Bool is intern
814 #fun !=(o: NativeArray[E]): Bool is intern
815 end
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