import macros;macro ImportExpand(s:untyped):untyped = parseStmt($s[2]) # verification-helper: PROBLEM https://yukicoder.me/problems/no/2686 proc scanf(formatstr: cstring){.header: "", varargs.} proc ii(): int {.inline.} = scanf("%lld\n", addr result) include sequtils include strutils include algorithm include sugar ImportExpand "cplib/collections/segtree.nim" <=== "when not declared CPLIB_COLLECTIONS_SEGTREE:\n const CPLIB_COLLECTIONS_SEGTREE* = 1\n import algorithm\n type SegmentTree*[T] = ref object\n default: T\n merge: proc(x: T, y: T): T\n arr*: seq[T]\n lastnode: int\n length: int\n proc initSegmentTree*[T](v: seq[T], merge: proc(x: T, y: T): T, default: T): SegmentTree[T] =\n ## セグメントツリーを生成します。\n ## vに元となるリスト、mergeに二つの区間をマージする関数、デフォルトに単位元を与えてください。\n var lastnode = 1\n while lastnode < len(v):\n lastnode*=2\n var arr = newSeq[T](2*lastnode)\n arr.fill(default)\n var self = SegmentTree[T](default: default, merge: merge, arr: arr, lastnode: lastnode, length: len(v))\n #1-indexedで作成する\n for i in 0.. 1:\n x = x shr 1\n self.arr[x] = self.merge(self.arr[2*x], self.arr[2*x+1])\n proc get*[T](self: SegmentTree[T], q_left: Natural, q_right: Natural): T =\n ## 半解区間[q_left,q_right)についての演算結果を返します。\n assert q_left <= q_right and 0 <= q_left and q_right <= self.length\n var q_left = q_left\n var q_right = q_right\n q_left += self.lastnode\n q_right += self.lastnode\n var (lres, rres) = (self.default, self.default)\n while q_left < q_right:\n if (q_left and 1) > 0:\n lres = self.merge(lres, self.arr[q_left])\n q_left += 1\n if (q_right and 1) > 0:\n q_right -= 1\n rres = self.merge(self.arr[q_right], rres)\n q_left = q_left shr 1\n q_right = q_right shr 1\n return self.merge(lres, rres)\n proc get*[T](self: SegmentTree[T], segment: HSlice[int, int]): T =\n assert segment.a <= segment.b + 1 and 0 <= segment.a and segment.b+1 <= self.length\n return self.get(segment.a, segment.b+1)\n proc `[]`*[T](self: SegmentTree[T], index: Natural): T =\n assert index < self.length\n return self.arr[index+self.lastnode]\n proc `[]=`*[T](self: SegmentTree[T], index: Natural, val: T) =\n assert index < self.length\n self.update(index, val)\n proc get_all*[T](self: SegmentTree[T]): T =\n ## [0,len(self))区間の演算結果をO(1)で返す\n return self.arr[1]\n proc len*[T](self: SegmentTree[T]): int =\n return self.length\n\n template newSegWith*(V, merge, default: untyped): untyped =\n initSegmentTree(V, (l, r{.inject.}: typeof(default)) => merge, default)\n\n" ImportExpand "cplib/collections/hashtable.nim" <=== "when not declared CPLIB_COLLECTIONS_HASHTABLE:\n const CPLIB_COLLECTIONS_HASHTABLE* = 1\n import bitops\n import sequtils\n import hashes\n type State = enum\n empty, active, inactive\n type Node[K, V] = object\n state: State\n value: (K, V)\n type HashTable*[K, V] = object\n values*: seq[Node[K, V]]\n len: int\n fill: int\n mask: int\n proc vlen(x: int): int = (if x == 0: 4 else: 1 shl (fastLog2(x) + 2))\n proc len*[K, V](self: HashTable[K, V]): int = self.len\n proc initHashTable*[K, V](): HashTable[K, V] =\n var vlen = 4\n return HashTable[K, V](values: newSeqWith(vlen, Node[K, V](state: State.empty)), len: 0, fill: 0, mask: vlen - 1)\n proc initHashTable*[K, V](capacity: int): HashTable[K, V] =\n var vlen = capacity.vlen\n return HashTable[K, V](values: newSeqWith(vlen, Node[K, V](state: State.empty)), len: 0, fill: 0, mask: vlen - 1)\n iterator pairs*[K, V](self: HashTable[K, V]): (K, V) =\n for item in self.values:\n if item.state == State.active: yield item.value\n iterator keys*[K, V](self: HashTable[K, V]): K =\n for item in self.values:\n if item.state == State.active: yield item.value[0]\n iterator values*[K, V](self: HashTable[K, V]): V =\n for item in self.values:\n if item.state == State.active: yield item.value[1]\n proc find[K, V](self: HashTable[K, V], x: K): int =\n var sh: int = hash(x) and self.mask\n while self.values[sh].state != State.empty and self.values[sh].value[0] != x:\n sh = (sh + 1) and self.mask\n return sh\n proc add_item[K, V](self: var HashTable[K, V], key: K, val: V) =\n var pos = self.find(key)\n if self.values[pos].state == State.active:\n self.values[pos].value[1] = val\n return\n self.len += 1\n self.fill += 1\n self.values[pos].value = (key, val)\n self.values[pos].state = State.active\n proc resize[K, V](self: var HashTable[K, V]) =\n var vlen = self.len.vlen\n var vi = newSeq[Node[K, V]](vlen)\n self.mask = vlen - 1\n self.len = 0\n self.fill = 0\n swap(vi, self.values)\n for item in vi:\n if item.state == State.empty: continue\n var (key, val) = item.value\n self.add_item(key, val)\n proc incl*[K, V](self: var HashTable[K, V], val: (K, V)) =\n self.add_item(val)\n if self.fill.vlen > self.values.len: self.resize\n # if self.fill > self.values.len div HASHSET_INCL_RESIZE_RATIO: self.resize\n proc contains*[K, V](self: var HashTable[K, V], key: K): bool = (self.values[self.find(key)].state == State.active)\n proc hasKey*[K, V](self: var HashTable[K, V], key: K): bool = self.contains(key)\n proc `[]`*[K, V](self: HashTable[K, V], key: K): V =\n var pos = self.find(key)\n assert self.values[pos].state == State.active, \"Key \\\"\" & $key & \"\\\" not found\"\n return self.values[pos].value[1]\n proc `[]`*[K, V](self: var HashTable[K, V], key: K): var V =\n var pos = self.find(key)\n assert self.values[pos].state == State.active, \"Key \\\"\" & $key & \"\\\" not found\"\n return self.values[pos].value[1]\n proc `[]=`*[K, V](self: var HashTable[K, V], key: K, val: V) =\n var pos = self.find(key)\n self.values[pos].value = (key, val)\n self.values[pos].state = State.active\n self.len += 1\n self.fill += 1\n if self.fill.vlen > self.values.len: self.resize\n proc clear*[K, V](self: var HashTable[K, V]) = self = initHashTable[K, V]()\n proc del*[K, V](self: var HashTable[K, V], key: K) =\n var pos = self.find(key)\n if self.values[pos].state != State.active: return\n self.len -= 1\n self.values[pos].state = State.inactive\n proc excl*[K, V](self: var HashTable[K, V], key: K) = self.del(key)\n proc hash*[K, V](self: HashTable[K, V]): Hash =\n for item in self.pairs:\n result = result !& hash(item)\n" var n, m, q = ii() var a, b = newSeq[int](n) for i in 0..= c[pos]: for (yn, vn) in add[pos]: seg[c.lowerBound(yn)] = max(seg[c.lowerBound(yn)], vn) pos += 1 var r = c.upperBound(q - y) ans = max(ans, seg.get(0..