forked from OctaForge/libostd
632 lines
17 KiB
C++
632 lines
17 KiB
C++
/* Algorithms for OctaSTD.
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*
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* This file is part of OctaSTD. See COPYING.md for futher information.
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*/
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#ifndef OSTD_ALGORITHM_HH
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#define OSTD_ALGORITHM_HH
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#include <math.h>
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#include "ostd/functional.hh"
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#include "ostd/range.hh"
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#include "ostd/utility.hh"
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#include "ostd/initializer_list.hh"
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namespace ostd {
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/* partitioning */
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template<typename R, typename U>
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R partition(R range, U pred) {
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R ret = range;
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for (; !range.empty(); range.pop_front()) {
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if (pred(range.front())) {
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detail::swap_adl(range.front(), ret.front());
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ret.pop_front();
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}
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}
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return ret;
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}
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template<typename R, typename P>
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bool is_partitioned(R range, P pred) {
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for (; !range.empty() && pred(range.front()); range.pop_front());
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for (; !range.empty(); range.pop_front())
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if (pred(range.front())) return false;
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return true;
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}
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/* sorting */
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namespace detail {
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template<typename R, typename C>
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void insort(R range, C compare) {
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RangeSize<R> rlen = range.size();
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for (RangeSize<R> i = 1; i < rlen; ++i) {
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RangeSize<R> j = i;
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RangeValue<R> v(move(range[i]));
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while (j > 0 && !compare(range[j - 1], v)) {
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range[j] = range[j - 1];
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--j;
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}
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range[j] = move(v);
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}
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}
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template<typename R, typename C>
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void hs_sift_down(R range, RangeSize<R> s,
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RangeSize<R> e, C compare) {
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RangeSize<R> r = s;
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while ((r * 2 + 1) <= e) {
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RangeSize<R> ch = r * 2 + 1;
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RangeSize<R> sw = r;
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if (compare(range[sw], range[ch]))
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sw = ch;
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if (((ch + 1) <= e) && compare(range[sw], range[ch + 1]))
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sw = ch + 1;
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if (sw != r) {
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detail::swap_adl(range[r], range[sw]);
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r = sw;
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} else return;
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}
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}
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template<typename R, typename C>
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void heapsort(R range, C compare) {
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RangeSize<R> len = range.size();
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RangeSize<R> st = (len - 2) / 2;
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for (;;) {
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detail::hs_sift_down(range, st, len - 1, compare);
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if (st-- == 0) break;
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}
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RangeSize<R> e = len - 1;
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while (e > 0) {
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detail::swap_adl(range[e], range[0]);
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--e;
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detail::hs_sift_down(range, 0, e, compare);
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}
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}
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template<typename R, typename C>
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void introloop(R range, C compare, RangeSize<R> depth) {
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if (range.size() <= 10) {
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detail::insort(range, compare);
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return;
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}
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if (depth == 0) {
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detail::heapsort(range, compare);
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return;
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}
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detail::swap_adl(range[range.size() / 2], range.back());
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RangeSize<R> pi = 0;
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R pr = range;
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pr.pop_back();
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for (; !pr.empty(); pr.pop_front()) {
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if (compare(pr.front(), range.back()))
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detail::swap_adl(pr.front(), range[pi++]);
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}
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detail::swap_adl(range[pi], range.back());
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detail::introloop(range.slice(0, pi), compare, depth - 1);
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detail::introloop(range.slice(pi + 1, range.size()), compare,
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depth - 1);
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}
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template<typename R, typename C>
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void introsort(R range, C compare) {
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detail::introloop(range, compare, RangeSize<R>(2
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* (log(range.size()) / log(2))));
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}
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} /* namespace detail */
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template<typename R, typename C>
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void sort(R range, C compare) {
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detail::introsort(range, compare);
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}
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template<typename R>
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void sort(R range) {
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sort(range, Less<RangeValue<R>>());
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}
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/* min/max(_element) */
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template<typename T>
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inline const T &min(const T &a, const T &b) {
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return (a < b) ? a : b;
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}
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template<typename T, typename C>
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inline const T &min(const T &a, const T &b, C compare) {
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return compare(a, b) ? a : b;
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}
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template<typename T>
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inline const T &max(const T &a, const T &b) {
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return (a < b) ? b : a;
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}
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template<typename T, typename C>
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inline const T &max(const T &a, const T &b, C compare) {
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return compare(a, b) ? b : a;
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}
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template<typename R>
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inline R min_element(R range) {
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R r = range;
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for (; !range.empty(); range.pop_front())
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if (ostd::min(r.front(), range.front()) == range.front())
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r = range;
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return r;
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}
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template<typename R, typename C>
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inline R min_element(R range, C compare) {
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R r = range;
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for (; !range.empty(); range.pop_front())
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if (ostd::min(r.front(), range.front(), compare) == range.front())
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r = range;
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return r;
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}
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template<typename R>
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inline R max_element(R range) {
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R r = range;
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for (; !range.empty(); range.pop_front())
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if (ostd::max(r.front(), range.front()) == range.front())
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r = range;
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return r;
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}
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template<typename R, typename C>
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inline R max_element(R range, C compare) {
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R r = range;
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for (; !range.empty(); range.pop_front())
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if (ostd::max(r.front(), range.front(), compare) == range.front())
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r = range;
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return r;
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}
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template<typename T>
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inline T min(std::initializer_list<T> il) {
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return ostd::min_element(ostd::iter(il)).front();
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}
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template<typename T, typename C>
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inline T min(std::initializer_list<T> il, C compare) {
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return ostd::min_element(ostd::iter(il), compare).front();
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}
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template<typename T>
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inline T max(std::initializer_list<T> il) {
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return ostd::max_element(ostd::iter(il)).front();
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}
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template<typename T, typename C>
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inline T max(std::initializer_list<T> il, C compare) {
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return ostd::max_element(ostd::iter(il), compare).front();
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}
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/* clamp */
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template<typename T, typename U>
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inline T clamp(const T &v, const U &lo, const U &hi) {
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return ostd::max(T(lo), ostd::min(v, T(hi)));
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}
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template<typename T, typename U, typename C>
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inline T clamp(const T &v, const U &lo, const U &hi, C compare) {
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return ostd::max(T(lo), ostd::min(v, T(hi), compare), compare);
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}
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/* lexicographical compare */
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template<typename R1, typename R2>
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bool lexicographical_compare(R1 range1, R2 range2) {
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while (!range1.empty() && !range2.empty()) {
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if (range1.front() < range2.front()) return true;
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if (range2.front() < range1.front()) return false;
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range1.pop_front();
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range2.pop_front();
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}
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return (range1.empty() && !range2.empty());
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}
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template<typename R1, typename R2, typename C>
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bool lexicographical_compare(R1 range1, R2 range2, C compare) {
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while (!range1.empty() && !range2.empty()) {
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if (compare(range1.front(), range2.front())) return true;
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if (compare(range2.front(), range1.front())) return false;
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range1.pop_front();
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range2.pop_front();
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}
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return (range1.empty() && !range2.empty());
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}
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/* algos that don't change the range */
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template<typename R, typename F>
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F for_each(R range, F func) {
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for (; !range.empty(); range.pop_front())
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func(range.front());
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return move(func);
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}
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template<typename R, typename P>
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bool all_of(R range, P pred) {
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for (; !range.empty(); range.pop_front())
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if (!pred(range.front())) return false;
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return true;
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}
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template<typename R, typename P>
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bool any_of(R range, P pred) {
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for (; !range.empty(); range.pop_front())
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if (pred(range.front())) return true;
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return false;
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}
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template<typename R, typename P>
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bool none_of(R range, P pred) {
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for (; !range.empty(); range.pop_front())
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if (pred(range.front())) return false;
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return true;
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}
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template<typename R, typename T>
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R find(R range, const T &v) {
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for (; !range.empty(); range.pop_front())
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if (range.front() == v)
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break;
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return range;
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}
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template<typename R, typename T>
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R find_last(R range, const T &v) {
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range = find(range, v);
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if (!range.empty()) for (;;) {
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R prev = range;
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prev.pop_front();
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R r = find(prev, v);
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if (r.empty())
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break;
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range = r;
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}
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return range;
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}
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template<typename R, typename P>
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R find_if(R range, P pred) {
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for (; !range.empty(); range.pop_front())
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if (pred(range.front()))
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break;
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return range;
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}
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template<typename R, typename P>
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R find_if_not(R range, P pred) {
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for (; !range.empty(); range.pop_front())
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if (!pred(range.front()))
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break;
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return range;
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}
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template<typename R1, typename R2, typename C>
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R1 find_one_of(R1 range, R2 values, C compare) {
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for (; !range.empty(); range.pop_front())
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for (R2 rv = values; !rv.empty(); rv.pop_front())
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if (compare(range.front(), rv.front()))
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return range;
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return range;
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}
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template<typename R1, typename R2>
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R1 find_one_of(R1 range, R2 values) {
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for (; !range.empty(); range.pop_front())
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for (R2 rv = values; !rv.empty(); rv.pop_front())
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if (range.front() == rv.front())
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return range;
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return range;
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}
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template<typename R, typename T>
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RangeSize<R> count(R range, const T &v) {
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RangeSize<R> ret = 0;
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for (; !range.empty(); range.pop_front())
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if (range.front() == v)
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++ret;
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return ret;
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}
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template<typename R, typename P>
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RangeSize<R> count_if(R range, P pred) {
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RangeSize<R> ret = 0;
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for (; !range.empty(); range.pop_front())
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if (pred(range.front()))
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++ret;
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return ret;
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}
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template<typename R, typename P>
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RangeSize<R> count_if_not(R range, P pred) {
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RangeSize<R> ret = 0;
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for (; !range.empty(); range.pop_front())
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if (!pred(range.front()))
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++ret;
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return ret;
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}
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template<typename R>
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bool equal(R range1, R range2) {
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for (; !range1.empty(); range1.pop_front()) {
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if (range2.empty() || (range1.front() != range2.front()))
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return false;
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range2.pop_front();
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}
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return range2.empty();
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}
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template<typename R>
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R slice_until(R range1, R range2) {
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return range1.slice(0, range1.distance_front(range2));
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}
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/* algos that modify ranges or work with output ranges */
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template<typename R1, typename R2>
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R2 copy(R1 irange, R2 orange) {
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for (; !irange.empty(); irange.pop_front())
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orange.put(irange.front());
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return orange;
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}
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template<typename R1, typename R2, typename P>
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R2 copy_if(R1 irange, R2 orange, P pred) {
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for (; !irange.empty(); irange.pop_front())
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if (pred(irange.front()))
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orange.put(irange.front());
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return orange;
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}
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template<typename R1, typename R2, typename P>
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R2 copy_if_not(R1 irange, R2 orange, P pred) {
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for (; !irange.empty(); irange.pop_front())
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if (!pred(irange.front()))
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orange.put(irange.front());
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return orange;
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}
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template<typename R1, typename R2>
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R2 move(R1 irange, R2 orange) {
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for (; !irange.empty(); irange.pop_front())
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orange.put(move(irange.front()));
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return orange;
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}
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template<typename R>
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void reverse(R range) {
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while (!range.empty()) {
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detail::swap_adl(range.front(), range.back());
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range.pop_front();
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range.pop_back();
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}
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}
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template<typename R1, typename R2>
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R2 reverse_copy(R1 irange, R2 orange) {
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for (; !irange.empty(); irange.pop_back())
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orange.put(irange.back());
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return orange;
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}
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template<typename R, typename T>
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void fill(R range, const T &v) {
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for (; !range.empty(); range.pop_front())
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range.front() = v;
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}
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template<typename R, typename F>
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void generate(R range, F gen) {
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for (; !range.empty(); range.pop_front())
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range.front() = gen();
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}
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template<typename R1, typename R2>
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Pair<R1, R2> swap_ranges(R1 range1, R2 range2) {
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while (!range1.empty() && !range2.empty()) {
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detail::swap_adl(range1.front(), range2.front());
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range1.pop_front();
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range2.pop_front();
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}
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return ostd::make_pair(range1, range2);
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}
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template<typename R, typename T>
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void iota(R range, T value) {
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for (; !range.empty(); range.pop_front())
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range.front() = value++;
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}
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template<typename R, typename T>
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T foldl(R range, T init) {
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for (; !range.empty(); range.pop_front())
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init = init + range.front();
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return init;
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}
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template<typename R, typename T, typename F>
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T foldl(R range, T init, F func) {
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for (; !range.empty(); range.pop_front())
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init = func(init, range.front());
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return init;
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}
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template<typename R, typename T>
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T foldr(R range, T init) {
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for (; !range.empty(); range.pop_back())
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init = init + range.back();
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return init;
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}
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template<typename R, typename T, typename F>
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T foldr(R range, T init, F func) {
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for (; !range.empty(); range.pop_back())
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init = func(init, range.back());
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return init;
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}
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template<typename T, typename F, typename R>
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struct MapRange: InputRange<
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MapRange<T, F, R>, RangeCategory<T>, R, R, RangeSize<T>
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> {
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private:
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T p_range;
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FunctionMakeDefaultConstructible<F> p_func;
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public:
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MapRange() = delete;
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MapRange(const T &range, const F &func):
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p_range(range), p_func(func) {}
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MapRange(const MapRange &it):
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p_range(it.p_range), p_func(it.p_func) {}
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MapRange(MapRange &&it):
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p_range(move(it.p_range)), p_func(move(it.p_func)) {}
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MapRange &operator=(const MapRange &v) {
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p_range = v.p_range;
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p_func = v.p_func;
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return *this;
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}
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MapRange &operator=(MapRange &&v) {
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p_range = move(v.p_range);
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p_func = move(v.p_func);
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return *this;
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}
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bool empty() const { return p_range.empty(); }
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RangeSize<T> size() const { return p_range.size(); }
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bool equals_front(const MapRange &r) const {
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return p_range.equals_front(r.p_range);
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}
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bool equals_back(const MapRange &r) const {
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return p_range.equals_front(r.p_range);
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}
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RangeDifference<T> distance_front(const MapRange &r) const {
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return p_range.distance_front(r.p_range);
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}
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RangeDifference<T> distance_back(const MapRange &r) const {
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return p_range.distance_back(r.p_range);
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}
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bool pop_front() { return p_range.pop_front(); }
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bool pop_back() { return p_range.pop_back(); }
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bool push_front() { return p_range.pop_front(); }
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bool push_back() { return p_range.push_back(); }
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RangeSize<T> pop_front_n(RangeSize<T> n) {
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p_range.pop_front_n(n);
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}
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RangeSize<T> pop_back_n(RangeSize<T> n) {
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p_range.pop_back_n(n);
|
|
}
|
|
|
|
RangeSize<T> push_front_n(RangeSize<T> n) {
|
|
return p_range.push_front_n(n);
|
|
}
|
|
RangeSize<T> push_back_n(RangeSize<T> n) {
|
|
return p_range.push_back_n(n);
|
|
}
|
|
|
|
R front() const { return p_func(p_range.front()); }
|
|
R back() const { return p_func(p_range.back()); }
|
|
|
|
R operator[](RangeSize<T> idx) const {
|
|
return p_func(p_range[idx]);
|
|
}
|
|
|
|
MapRange slice(RangeSize<T> start, RangeSize<T> end) {
|
|
return MapRange(p_range.slice(start, end), p_func);
|
|
}
|
|
};
|
|
|
|
namespace detail {
|
|
template<typename R, typename F> using MapReturnType
|
|
= decltype(declval<F>()(declval<RangeReference<R>>()));
|
|
}
|
|
|
|
template<typename R, typename F>
|
|
MapRange<R, F, detail::MapReturnType<R, F>> map(R range, F func) {
|
|
return MapRange<R, F, detail::MapReturnType<R, F>>(range,
|
|
func);
|
|
}
|
|
|
|
template<typename T, typename F>
|
|
struct FilterRange: InputRange<
|
|
FilterRange<T, F>, CommonType<RangeCategory<T>, ForwardRangeTag>,
|
|
RangeValue<T>, RangeReference<T>, RangeSize<T>
|
|
> {
|
|
private:
|
|
T p_range;
|
|
FunctionMakeDefaultConstructible<F> p_pred;
|
|
|
|
void advance_valid() {
|
|
while (!p_range.empty() && !p_pred(front())) p_range.pop_front();
|
|
}
|
|
|
|
public:
|
|
FilterRange() = delete;
|
|
template<typename P>
|
|
FilterRange(const T &range, const P &pred): p_range(range),
|
|
p_pred(pred) {
|
|
advance_valid();
|
|
}
|
|
FilterRange(const FilterRange &it): p_range(it.p_range),
|
|
p_pred(it.p_pred) {
|
|
advance_valid();
|
|
}
|
|
FilterRange(FilterRange &&it): p_range(move(it.p_range)),
|
|
p_pred(move(it.p_pred)) {
|
|
advance_valid();
|
|
}
|
|
|
|
FilterRange &operator=(const FilterRange &v) {
|
|
p_range = v.p_range;
|
|
p_pred = v.p_pred;
|
|
advance_valid();
|
|
return *this;
|
|
}
|
|
FilterRange &operator=(FilterRange &&v) {
|
|
p_range = move(v.p_range);
|
|
p_pred = move(v.p_pred);
|
|
advance_valid();
|
|
return *this;
|
|
}
|
|
|
|
bool empty() const { return p_range.empty(); }
|
|
|
|
bool equals_front(const FilterRange &r) const {
|
|
return p_range.equals_front(r.p_range);
|
|
}
|
|
|
|
bool pop_front() {
|
|
bool ret = p_range.pop_front();
|
|
advance_valid();
|
|
return ret;
|
|
}
|
|
|
|
RangeReference<T> front() const { return p_range.front(); }
|
|
};
|
|
|
|
namespace detail {
|
|
template<typename R, typename P> using FilterPred
|
|
= EnableIf<IsSame<
|
|
decltype(declval<P>()(declval<RangeReference<R>>())), bool
|
|
>, P>;
|
|
}
|
|
|
|
template<typename R, typename P>
|
|
FilterRange<R, detail::FilterPred<R, P>> filter(R range, P pred) {
|
|
return FilterRange<R, P>(range, pred);
|
|
}
|
|
|
|
} /* namespace ostd */
|
|
|
|
#endif |