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view libphobos/src/std/container/binaryheap.d @ 158:494b0b89df80 default tip
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| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Mon, 25 May 2020 18:13:55 +0900 |
| parents | 1830386684a0 |
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/** This module provides a $(D BinaryHeap) (aka priority queue) adaptor that makes a binary heap out of any user-provided random-access range. This module is a submodule of $(MREF std, container). Source: $(PHOBOSSRC std/container/_binaryheap.d) Copyright: 2010- Andrei Alexandrescu. All rights reserved by the respective holders. License: Distributed under the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at $(HTTP boost.org/LICENSE_1_0.txt)). Authors: $(HTTP erdani.com, Andrei Alexandrescu) */ module std.container.binaryheap; import std.range.primitives; import std.traits; public import std.container.util; /// @system unittest { import std.algorithm.comparison : equal; import std.range : take; auto maxHeap = heapify([4, 7, 3, 1, 5]); assert(maxHeap.take(3).equal([7, 5, 4])); auto minHeap = heapify!"a > b"([4, 7, 3, 1, 5]); assert(minHeap.take(3).equal([1, 3, 4])); } // BinaryHeap /** Implements a $(HTTP en.wikipedia.org/wiki/Binary_heap, binary heap) container on top of a given random-access range type (usually $(D T[])) or a random-access container type (usually $(D Array!T)). The documentation of $(D BinaryHeap) will refer to the underlying range or container as the $(I store) of the heap. The binary heap induces structure over the underlying store such that accessing the largest element (by using the $(D front) property) is a $(BIGOH 1) operation and extracting it (by using the $(D removeFront()) method) is done fast in $(BIGOH log n) time. If $(D less) is the less-than operator, which is the default option, then $(D BinaryHeap) defines a so-called max-heap that optimizes extraction of the $(I largest) elements. To define a min-heap, instantiate BinaryHeap with $(D "a > b") as its predicate. Simply extracting elements from a $(D BinaryHeap) container is tantamount to lazily fetching elements of $(D Store) in descending order. Extracting elements from the $(D BinaryHeap) to completion leaves the underlying store sorted in ascending order but, again, yields elements in descending order. If $(D Store) is a range, the $(D BinaryHeap) cannot grow beyond the size of that range. If $(D Store) is a container that supports $(D insertBack), the $(D BinaryHeap) may grow by adding elements to the container. */ struct BinaryHeap(Store, alias less = "a < b") if (isRandomAccessRange!(Store) || isRandomAccessRange!(typeof(Store.init[]))) { import std.algorithm.comparison : min; import std.algorithm.mutation : move, swapAt; import std.algorithm.sorting : HeapOps; import std.exception : enforce; import std.functional : binaryFun; import std.typecons : RefCounted, RefCountedAutoInitialize; static if (isRandomAccessRange!Store) alias Range = Store; else alias Range = typeof(Store.init[]); alias percolate = HeapOps!(less, Range).percolate; alias buildHeap = HeapOps!(less, Range).buildHeap; // Really weird @@BUG@@: if you comment out the "private:" label below, // std.algorithm can't unittest anymore //private: // The payload includes the support store and the effective length private static struct Data { Store _store; size_t _length; } private RefCounted!(Data, RefCountedAutoInitialize.no) _payload; // Comparison predicate private alias comp = binaryFun!(less); // Convenience accessors private @property ref Store _store() { assert(_payload.refCountedStore.isInitialized); return _payload._store; } private @property ref size_t _length() { assert(_payload.refCountedStore.isInitialized); return _payload._length; } // Asserts that the heap property is respected. private void assertValid() { debug { import std.conv : to; if (!_payload.refCountedStore.isInitialized) return; if (_length < 2) return; for (size_t n = _length - 1; n >= 1; --n) { auto parentIdx = (n - 1) / 2; assert(!comp(_store[parentIdx], _store[n]), to!string(n)); } } } // @@@BUG@@@: add private here, std.algorithm doesn't unittest anymore /*private*/ void pop(Store store) { assert(!store.empty, "Cannot pop an empty store."); if (store.length == 1) return; auto t1 = store[].moveFront(); auto t2 = store[].moveBack(); store.front = move(t2); store.back = move(t1); percolate(store[], 0, store.length - 1); } public: /** Converts the store $(D s) into a heap. If $(D initialSize) is specified, only the first $(D initialSize) elements in $(D s) are transformed into a heap, after which the heap can grow up to $(D r.length) (if $(D Store) is a range) or indefinitely (if $(D Store) is a container with $(D insertBack)). Performs $(BIGOH min(r.length, initialSize)) evaluations of $(D less). */ this(Store s, size_t initialSize = size_t.max) { acquire(s, initialSize); } /** Takes ownership of a store. After this, manipulating $(D s) may make the heap work incorrectly. */ void acquire(Store s, size_t initialSize = size_t.max) { _payload.refCountedStore.ensureInitialized(); _store = move(s); _length = min(_store.length, initialSize); if (_length < 2) return; buildHeap(_store[]); assertValid(); } /** Takes ownership of a store assuming it already was organized as a heap. */ void assume(Store s, size_t initialSize = size_t.max) { _payload.refCountedStore.ensureInitialized(); _store = s; _length = min(_store.length, initialSize); assertValid(); } /** Clears the heap. Returns the portion of the store from $(D 0) up to $(D length), which satisfies the $(LINK2 https://en.wikipedia.org/wiki/Heap_(data_structure), heap property). */ auto release() { if (!_payload.refCountedStore.isInitialized) { return typeof(_store[0 .. _length]).init; } assertValid(); auto result = _store[0 .. _length]; _payload = _payload.init; return result; } /** Returns $(D true) if the heap is _empty, $(D false) otherwise. */ @property bool empty() { return !length; } /** Returns a duplicate of the heap. The $(D dup) method is available only if the underlying store supports it. */ static if (is(typeof((Store s) { return s.dup; }(Store.init)) == Store)) { @property BinaryHeap dup() { BinaryHeap result; if (!_payload.refCountedStore.isInitialized) return result; result.assume(_store.dup, length); return result; } } /** Returns the _length of the heap. */ @property size_t length() { return _payload.refCountedStore.isInitialized ? _length : 0; } /** Returns the _capacity of the heap, which is the length of the underlying store (if the store is a range) or the _capacity of the underlying store (if the store is a container). */ @property size_t capacity() { if (!_payload.refCountedStore.isInitialized) return 0; static if (is(typeof(_store.capacity) : size_t)) { return _store.capacity; } else { return _store.length; } } /** Returns a copy of the _front of the heap, which is the largest element according to $(D less). */ @property ElementType!Store front() { enforce(!empty, "Cannot call front on an empty heap."); return _store.front; } /** Clears the heap by detaching it from the underlying store. */ void clear() { _payload = _payload.init; } /** Inserts $(D value) into the store. If the underlying store is a range and $(D length == capacity), throws an exception. */ size_t insert(ElementType!Store value) { static if (is(typeof(_store.insertBack(value)))) { _payload.refCountedStore.ensureInitialized(); if (length == _store.length) { // reallocate _store.insertBack(value); } else { // no reallocation _store[_length] = value; } } else { import std.traits : isDynamicArray; static if (isDynamicArray!Store) { if (length == _store.length) _store.length = (length < 6 ? 8 : length * 3 / 2); _store[_length] = value; } else { // can't grow enforce(length < _store.length, "Cannot grow a heap created over a range"); } } // sink down the element for (size_t n = _length; n; ) { auto parentIdx = (n - 1) / 2; if (!comp(_store[parentIdx], _store[n])) break; // done! // must swap and continue _store.swapAt(parentIdx, n); n = parentIdx; } ++_length; debug(BinaryHeap) assertValid(); return 1; } /** Removes the largest element from the heap. */ void removeFront() { enforce(!empty, "Cannot call removeFront on an empty heap."); if (_length > 1) { auto t1 = _store[].moveFront(); auto t2 = _store[].moveAt(_length - 1); _store.front = move(t2); _store[_length - 1] = move(t1); } --_length; percolate(_store[], 0, _length); } /// ditto alias popFront = removeFront; /** Removes the largest element from the heap and returns a copy of it. The element still resides in the heap's store. For performance reasons you may want to use $(D removeFront) with heaps of objects that are expensive to copy. */ ElementType!Store removeAny() { removeFront(); return _store[_length]; } /** Replaces the largest element in the store with $(D value). */ void replaceFront(ElementType!Store value) { // must replace the top assert(!empty, "Cannot call replaceFront on an empty heap."); _store.front = value; percolate(_store[], 0, _length); debug(BinaryHeap) assertValid(); } /** If the heap has room to grow, inserts $(D value) into the store and returns $(D true). Otherwise, if $(D less(value, front)), calls $(D replaceFront(value)) and returns again $(D true). Otherwise, leaves the heap unaffected and returns $(D false). This method is useful in scenarios where the smallest $(D k) elements of a set of candidates must be collected. */ bool conditionalInsert(ElementType!Store value) { _payload.refCountedStore.ensureInitialized(); if (_length < _store.length) { insert(value); return true; } assert(!_store.empty, "Cannot replace front of an empty heap."); if (!comp(value, _store.front)) return false; // value >= largest _store.front = value; percolate(_store[], 0, _length); debug(BinaryHeap) assertValid(); return true; } /** Swapping is allowed if the heap is full. If $(D less(value, front)), the method exchanges store.front and value and returns $(D true). Otherwise, it leaves the heap unaffected and returns $(D false). */ bool conditionalSwap(ref ElementType!Store value) { _payload.refCountedStore.ensureInitialized(); assert(_length == _store.length); assert(!_store.empty, "Cannot swap front of an empty heap."); if (!comp(value, _store.front)) return false; // value >= largest import std.algorithm.mutation : swap; swap(_store.front, value); percolate(_store[], 0, _length); debug(BinaryHeap) assertValid(); return true; } } /// Example from "Introduction to Algorithms" Cormen et al, p 146 @system unittest { import std.algorithm.comparison : equal; int[] a = [ 4, 1, 3, 2, 16, 9, 10, 14, 8, 7 ]; auto h = heapify(a); // largest element assert(h.front == 16); // a has the heap property assert(equal(a, [ 16, 14, 10, 8, 7, 9, 3, 2, 4, 1 ])); } /// $(D BinaryHeap) implements the standard input range interface, allowing /// lazy iteration of the underlying range in descending order. @system unittest { import std.algorithm.comparison : equal; import std.range : take; int[] a = [4, 1, 3, 2, 16, 9, 10, 14, 8, 7]; auto top5 = heapify(a).take(5); assert(top5.equal([16, 14, 10, 9, 8])); } /** Convenience function that returns a $(D BinaryHeap!Store) object initialized with $(D s) and $(D initialSize). */ BinaryHeap!(Store, less) heapify(alias less = "a < b", Store)(Store s, size_t initialSize = size_t.max) { return BinaryHeap!(Store, less)(s, initialSize); } /// @system unittest { import std.conv : to; import std.range.primitives; { // example from "Introduction to Algorithms" Cormen et al., p 146 int[] a = [ 4, 1, 3, 2, 16, 9, 10, 14, 8, 7 ]; auto h = heapify(a); h = heapify!"a < b"(a); assert(h.front == 16); assert(a == [ 16, 14, 10, 8, 7, 9, 3, 2, 4, 1 ]); auto witness = [ 16, 14, 10, 9, 8, 7, 4, 3, 2, 1 ]; for (; !h.empty; h.removeFront(), witness.popFront()) { assert(!witness.empty); assert(witness.front == h.front); } assert(witness.empty); } { int[] a = [ 4, 1, 3, 2, 16, 9, 10, 14, 8, 7 ]; int[] b = new int[a.length]; BinaryHeap!(int[]) h = BinaryHeap!(int[])(b, 0); foreach (e; a) { h.insert(e); } assert(b == [ 16, 14, 10, 8, 7, 3, 9, 1, 4, 2 ], to!string(b)); } } @system unittest { // Test range interface. import std.algorithm.comparison : equal; int[] a = [4, 1, 3, 2, 16, 9, 10, 14, 8, 7]; auto h = heapify(a); static assert(isInputRange!(typeof(h))); assert(h.equal([16, 14, 10, 9, 8, 7, 4, 3, 2, 1])); } @system unittest // 15675 { import std.container.array : Array; Array!int elements = [1, 2, 10, 12]; auto heap = heapify(elements); assert(heap.front == 12); } @system unittest // 16072 { auto q = heapify!"a > b"([2, 4, 5]); q.insert(1); q.insert(6); assert(q.front == 1); // test more multiple grows int[] arr; auto r = heapify!"a < b"(arr); foreach (i; 0 .. 100) r.insert(i); assert(r.front == 99); } @system unittest { import std.algorithm.comparison : equal; int[] a = [4, 1, 3, 2, 16, 9, 10, 14, 8, 7]; auto heap = heapify(a); auto dup = heap.dup(); assert(dup.equal([16, 14, 10, 9, 8, 7, 4, 3, 2, 1])); } @safe unittest { static struct StructWithoutDup { int[] a; @disable StructWithoutDup dup() { StructWithoutDup d; return d; } alias a this; } // Assert Binary heap can be created when Store doesn't have dup // if dup is not used. assert(__traits(compiles, () { auto s = StructWithoutDup([1,2]); auto h = heapify(s); })); // Assert dup can't be used on BinaryHeaps when Store doesn't have dup assert(!__traits(compiles, () { auto s = StructWithoutDup([1,2]); auto h = heapify(s); h.dup(); })); } @safe unittest { static struct StructWithDup { int[] a; StructWithDup dup() { StructWithDup d; return d; } alias a this; } // Assert dup can be used on BinaryHeaps when Store has dup assert(__traits(compiles, () { auto s = StructWithDup([1, 2]); auto h = heapify(s); h.dup(); })); } @system unittest { import std.algorithm.comparison : equal; import std.internal.test.dummyrange; alias RefRange = DummyRange!(ReturnBy.Reference, Length.Yes, RangeType.Random); RefRange a; RefRange b; a.reinit(); b.reinit(); auto heap = heapify(a); foreach (ref elem; b) { heap.conditionalSwap(elem); } assert(equal(heap, [ 5, 5, 4, 4, 3, 3, 2, 2, 1, 1])); assert(equal(b, [10, 9, 8, 7, 6, 6, 7, 8, 9, 10])); } @system unittest // Issue 17314 { import std.algorithm.comparison : equal; int[] a = [5]; auto heap = heapify(a); heap.insert(6); assert(equal(heap, [6, 5])); }