Расширения декартова дерева
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Multimap с getMinValue
getMinValue(lKey, rKey) class Treap { inline static minstd_rand gen; struct Node { int key, priority, value, minValue; Node *left = 0, *right = 0; Node(int key, int value) : key(key), priority(gen()), value(value), minValue(value) {} } *root = 0; int getMinValue(Node *n) const { return n ? n->minValue : 2e9; } void update(Node *n) { if (n) n->minValue = min({ getMinValue(n->left), n->value, getMinValue(n->right) }); } Node *merge(Node *a, Node *b) { if (!a || !b) return a ? a : b; if (a->priority > b->priority) { a->right = merge(a->right, b); update(a); return a; } else { b->left = merge(a, b->left); update(b); return b; } } void split(Node *t, int key, Node *&a, Node *&b) { if (!t) { a = b = 0; return; } if (t->key < key) { split(t->right, key, t->right, b); a = t; } else { split(t->left, key, a, t->left); b = t; } update(a); update(b); } public: void insert(int key, int value) { Node *a, *b; split(root, key, a, b); root = merge(a, merge(new Node(key, value), b)); } void erase(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); root = merge(a, c); } void eraseOne(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); if (b) b = merge(b->left, b->right); root = merge(a, merge(b, c)); } int getMinValue(int lKey, int rKey) { Node *a, *b, *c; split(root, lKey, a, b); split(b, rKey + 1, b, c); int res = getMinValue(b); root = merge(a, merge(b, c)); return res; } }; |
getMinValue(lIndex, rIndex) class Treap { inline static minstd_rand gen; struct Node { int key, priority, size = 1, value, minValue; Node *left = 0, *right = 0; Node(int key, int value) : key(key), priority(gen()), value(value), minValue(value) {} } *root = 0; int getSize(Node *n) const { return n ? n->size : 0; } int getMinValue(Node *n) const { return n ? n->minValue : 2e9; } void update(Node *n) { if (n) { n->size = getSize(n->left) + 1 + getSize(n->right); n->minValue = min({ getMinValue(n->left), n->value, getMinValue(n->right) }); } } Node *merge(Node *a, Node *b) { if (!a || !b) return a ? a : b; if (a->priority > b->priority) { a->right = merge(a->right, b); update(a); return a; } else { b->left = merge(a, b->left); update(b); return b; } } void split(Node *t, int key, Node *&a, Node *&b) { if (!t) { a = b = 0; return; } if (t->key < key) { split(t->right, key, t->right, b); a = t; } else { split(t->left, key, a, t->left); b = t; } update(a); update(b); } void splitByIndex(Node *t, int index, Node *&a, Node *&b) { if (!t) { a = b = 0; return; } int leftSize = getSize(t->left); if (leftSize < index) { splitByIndex(t->right, index - leftSize - 1, t->right, b); a = t; } else { splitByIndex(t->left, index, a, t->left); b = t; } update(a); update(b); } public: void insert(int key, int value) { Node *a, *b; split(root, key, a, b); root = merge(a, merge(new Node(key, value), b)); } void erase(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); root = merge(a, c); } void eraseOne(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); if (b) b = merge(b->left, b->right); root = merge(a, merge(b, c)); } int getMinValue(int lIndex, int rIndex) { Node *a, *b, *c; splitByIndex(root, lIndex, a, b); splitByIndex(b, rIndex - lIndex + 1, b, c); int res = getMinValue(b); root = merge(a, merge(b, c)); return res; } }; |
Multiset с indexOf(key), operator[], lessCount(key), greaterCount(key)
Одинаковые элементы хранятся в нескольких узлах class Treap { inline static minstd_rand gen; struct Node { int key, priority, size = 1; Node *left = 0, *right = 0; Node(int key) : key(key), priority(gen()) {} } *root = 0; int getSize(Node *n) const { return n ? n->size : 0; } void update(Node *n) { if (n) n->size = getSize(n->left) + 1 + getSize(n->right); } Node *merge(Node *a, Node *b) { if (!a || !b) return a ? a : b; if (a->priority > b->priority) { a->right = merge(a->right, b); update(a); return a; } else { b->left = merge(a, b->left); update(b); return b; } } void split(Node *t, int key, Node *&a, Node *&b) { if (!t) { a = b = 0; return; } if (t->key < key) { split(t->right, key, t->right, b); a = t; } else { split(t->left, key, a, t->left); b = t; } update(a); update(b); } int indexOf(Node *n, int key) const { if (!n) return 0; else if (key < n->key) return indexOf(n->left, key); else if (n->key == key) return getSize(n->left); else return getSize(n->left) + 1 + indexOf(n->right, key); } int getByIndex(Node *n, int index) const { int leftSize = getSize(n->left); if (leftSize > index) return getByIndex(n->left, index); else if (leftSize == index) return n->key; else return getByIndex(n->right, index - leftSize - 1); } public: int size() const { return getSize(root); } int indexOf(int key) const { return indexOf(root, key); } int operator[](int index) const { return getByIndex(root, index); } void insert(int key) { Node *a, *b; split(root, key, a, b); root = merge(a, merge(new Node(key), b)); } void erase(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); root = merge(a, c); } void eraseOne(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); if (b) b = merge(b->left, b->right); root = merge(a, merge(b, c)); } int lessCount(int key) { Node *a, *b; split(root, key, a, b); int res = getSize(a); root = merge(a, b); return res; } int lessEqualCount(int key) { Node *a, *b; split(root, key + 1, a, b); int res = getSize(a); root = merge(a, b); return res; } int greaterCount(int key) { Node *a, *b; split(root, key + 1, a, b); int res = getSize(b); root = merge(a, b); return res; } int greaterEqualCount(int key) { Node *a, *b; split(root, key, a, b); int res = getSize(b); root = merge(a, b); return res; } }; |
Одинаковые элементы хранятся в одном узле class Treap { inline static minstd_rand gen; struct Node { int key, priority, nodeSize = 1, subtreeSize = 1; Node *left = 0, *right = 0; Node(int key) : key(key), priority(gen()) {} } *root = 0; int getSubtreeSize(Node *n) const { return n ? n->subtreeSize : 0; } void update(Node *n) { if (n) n->subtreeSize = getSubtreeSize(n->left) + n->nodeSize + getSubtreeSize(n->right); } Node *merge(Node *a, Node *b) { if (!a || !b) return a ? a : b; if (a->priority > b->priority) { a->right = merge(a->right, b); update(a); return a; } else { b->left = merge(a, b->left); update(b); return b; } } void split(Node *t, int key, Node *&a, Node *&b) { if (!t) { a = b = 0; return; } if (t->key < key) { split(t->right, key, t->right, b); a = t; } else { split(t->left, key, a, t->left); b = t; } update(a); update(b); } int indexOf(Node *n, int key) const { if (!n) return 0; else if (key < n->key) return indexOf(n->left, key); else if (n->key == key) return getSubtreeSize(n->left); else return getSubtreeSize(n->left) + n->nodeSize + indexOf(n->right, key); } int getByIndex(Node *n, int index) const { int leftSize = getSubtreeSize(n->left); if (leftSize > index) return getByIndex(n->left, index); else if (leftSize + n->nodeSize >= index) return n->key; else return getByIndex(n->right, index - leftSize - n->nodeSize); } public: int size() const { return getSubtreeSize(root); } int indexOf(int key) const { return indexOf(root, key); } int operator[](int index) const { return getByIndex(root, index); } void insert(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); if (b) { b->nodeSize++; b->subtreeSize++; } else { b = new Node(key); } root = merge(a, merge(b, c)); } void erase(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); root = merge(a, c); } void eraseOne(int key) { Node *a, *b, *c; split(root, key, a, b); split(b, key + 1, b, c); if (b) { b->nodeSize--; b->subtreeSize--; if (!b->nodeSize) b = 0; } root = merge(a, merge(b, c)); } int lessCount(int key) { Node *a, *b; split(root, key, a, b); int res = getSize(a); root = merge(a, b); return res; } int lessEqualCount(int key) { Node *a, *b; split(root, key + 1, a, b); int res = getSize(a); root = merge(a, b); return res; } int greaterCount(int key) { Node *a, *b; split(root, key + 1, a, b); int res = getSize(b); root = merge(a, b); return res; } int greaterEqualCount(int key) { Node *a, *b; split(root, key, a, b); int res = getSize(b); root = merge(a, b); return res; } }; |
Set с find_by_order(index) и order_of_key(key) через __gnu_pbds
#include <ext/pb_ds/assoc_container.hpp> #include <ext/pb_ds/tree_policy.hpp> using namespace __gnu_pbds; using ordered_set = tree<int, null_type, less<int>, rb_tree_tag, tree_order_statistics_node_update>;
Vector
getMinValue(lIndex, rIndex) class ImplicitTreap { inline static minstd_rand gen; struct Node { int value, priority, size = 1, minValue; Node *left = 0, *right = 0; Node(int value) : value(value), priority(gen()), minValue(value) {} } *root = 0; int getSize(Node *n) { return n ? n->size : 0; } int getMinValue(Node *n) { return n ? n->minValue : 2e9; } void update(Node *n) { if (n) { n->size = getSize(n->left) + 1 + getSize(n->right); n->minValue = min({ getMinValue(n->left), n->value, getMinValue(n->right) }); } } Node *merge(Node *a, Node *b) { if (!a || !b) return a ? a : b; if (a->priority > b->priority) { a->right = merge(a->right, b); update(a); return a; } else { b->left = merge(a, b->left); update(b); return b; } } void split(Node *t, int k, Node *&a, Node *&b) { if (!t) { a = b = 0; return; } if (getSize(t->left) < k) { split(t->right, k - getSize(t->left) - 1, t->right, b); a = t; } else { split(t->left, k, a, t->left); b = t; } update(a); update(b); } public: void pushBack(int value) { root = merge(root, new Node(value)); } void pushFront(int value) { root = merge(new Node(value), root); } void insertAfter(int index, int value) { Node *a, *b; split(root, index, a, b); root = merge(a, merge(new Node(value), b)); } void erase(int index) { Node *a, *b, *c; split(root, index, a, b); split(b, 1, b, c); root = merge(a, c); } void erase(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); root = merge(a, c); } int operator[](int index) { Node *a, *b, *c; split(root, index, a, b); split(b, 1, b, c); int res = b->value; root = merge(a, merge(b, c)); return res; } void moveToFront(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); root = merge(b, merge(a, c)); } void moveToBack(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); root = merge(a, merge(c, b)); } int getMinValue(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); int res = getMinValue(b); root = merge(a, merge(b, c)); return res; } }; |
reverse(lIndex, rIndex) class ImplicitTreap { inline static minstd_rand gen; struct Node { int value, priority, size = 1, rev = 0; Node *left = 0, *right = 0; Node(int value) : value(value), priority(gen()) {} } *root = 0; int getSize(Node *n) { return n ? n->size : 0; } void push(Node *n) { if (n && n->rev) { swap(n->left, n->right); if (n->left) n->left->rev ^= 1; if (n->right) n->right->rev ^= 1; n->rev = 0; } } void update(Node *n) { if (n) n->size = getSize(n->left) + 1 + getSize(n->right); } Node *merge(Node *a, Node *b) { push(a); push(b); if (!a || !b) return a ? a : b; if (a->priority > b->priority) { a->right = merge(a->right, b); update(a); return a; } else { b->left = merge(a, b->left); update(b); return b; } } void split(Node *t, int k, Node *&a, Node *&b) { push(t); if (!t) { a = b = 0; return; } if (getSize(t->left) < k) { split(t->right, k - getSize(t->left) - 1, t->right, b); a = t; } else { split(t->left, k, a, t->left); b = t; } update(a); update(b); } public: void pushBack(int value) { root = merge(root, new Node(value)); } void pushFront(int value) { root = merge(new Node(value), root); } void insertAfter(int index, int value) { Node *a, *b; split(root, index, a, b); root = merge(a, merge(new Node(value), b)); } void erase(int index) { Node *a, *b, *c; split(root, index, a, b); split(b, 1, b, c); root = merge(a, c); } void erase(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); root = merge(a, c); } int operator[](int index) { Node *a, *b, *c; split(root, index, a, b); split(b, 1, b, c); int res = b->value; root = merge(a, merge(b, c)); return res; } void moveToFront(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); root = merge(b, merge(a, c)); } void moveToBack(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); root = merge(a, merge(c, b)); } void reverse(int lIndex, int rIndex) { Node *a, *b, *c; split(root, lIndex, a, b); split(b, rIndex - lIndex + 1, b, c); b->rev = 1; root = merge(a, merge(b, c)); } }; |
Ссылки
Теория:
- Фолунин В. — Декартово дерево по неявному ключу
- e-maxx.ru — Неявные декартовы деревья
- neerc.ifmo.ru/wiki — Декартово дерево по неявному ключу
- habrahabr.ru — Декартово дерево: Часть 3. Декартово дерево по неявному ключу
- Иващенко Д., Семенов К. Декартово дерево
Код:
- github.com/indy256/codelibrary/blob/master/cpp/structures/treap_indexed.cpp
- Algos — Cartesian tree using implicit keys
Задачи: