import macros;macro ImportExpand(s:untyped):untyped = parseStmt($s[2]) # source: https://github.com/kemuniku/cplib/tree/main/src/cplib/tmpl/citrus.nim ImportExpand "cplib/tmpl/citrus" <=== "when not declared CPLIB_TMPL_CITRUS:\n const CPLIB_TMPL_CITRUS* = 1\n {.warning[UnusedImport]: off.}\n {.hint[XDeclaredButNotUsed]: off.}\n import os\n import algorithm\n import sequtils\n import tables\n import macros\n import std/math\n import sets\n import strutils\n import strformat\n import sugar\n import streams\n import deques\n import bitops\n import heapqueue\n import options\n import hashes\n const MODINT998244353* = 998244353\n const MODINT1000000007* = 1000000007\n when not declared CPLIB_UTILS_CONSTANTS:\n const CPLIB_UTILS_CONSTANTS* = 1\n const INF32*: int32 = 100100111.int32\n const INF64*: int = int(3300300300300300491)\n \n const INFL = INF64\n type double* = float64\n let readNext = iterator(getsChar: bool = false): string {.closure.} =\n while true:\n var si: string\n try: si = stdin.readLine\n except EOFError: yield \"\"\n for s in si.split:\n if getsChar:\n for i in 0.. 0 and result < 0: result += y\n if y < 0 and result > 0: result += y\n proc `//`*(x: SomeInteger, y: SomeInteger): int =\n result = x div y\n if y > 0 and result * y > x: result -= 1\n if y < 0 and result * y < x: result -= 1\n proc `^`*(x: SomeInteger, y: SomeInteger): int = x xor y\n proc `&`*(x: SomeInteger, y: SomeInteger): int = x and y\n proc `|`*(x: SomeInteger, y: SomeInteger): int = x or y\n proc `>>`*(x: SomeInteger, y: SomeInteger): int = x shr y\n proc `<<`*(x: SomeInteger, y: SomeInteger): int = x shl y\n proc `%=`*(x: var SomeInteger, y: SomeInteger): void = x = x % y\n proc `//=`*(x: var SomeInteger, y: SomeInteger): void = x = x // y\n proc `^=`*(x: var SomeInteger, y: SomeInteger): void = x = x ^ y\n proc `&=`*(x: var SomeInteger, y: SomeInteger): void = x = x & y\n proc `|=`*(x: var SomeInteger, y: SomeInteger): void = x = x | y\n proc `>>=`*(x: var SomeInteger, y: SomeInteger): void = x = x >> y\n proc `<<=`*(x: var SomeInteger, y: SomeInteger): void = x = x << y\n proc `[]`*(x, n: int): bool = (x and (1 shl n)) != 0\n proc `[]=`*(x: var int, n: int, i: bool) =\n if i: x = x or (1 << n)\n else: (if x[n]: x = x xor (1 << n))\n proc pow*(a, n: int, m = INF64): int =\n var\n rev = 1\n a = a\n n = n\n while n > 0:\n if n % 2 != 0: rev = (rev * a) mod m\n if n > 1: a = (a * a) mod m\n n >>= 1\n return rev\n when not declared CPLIB_MATH_ISQRT:\n const CPLIB_MATH_ISQRT* = 1\n proc isqrt*(n: int): int =\n var x = n\n var y = (x + 1) shr 1\n while y < x:\n x = y\n y = (x + n div x) shr 1\n return x\n \n proc chmax*[T](x: var T, y: T): bool {.discardable.} = (if x < y: (x = y; return true; ) return false)\n proc chmin*[T](x: var T, y: T): bool {.discardable.} = (if x > y: (x = y; return true; ) return false)\n proc `max=`*[T](x: var T, y: T) = x = max(x, y)\n proc `min=`*[T](x: var T, y: T) = x = min(x, y)\n proc at*(x: char, a = '0'): int = int(x) - int(a)\n proc Yes*(b: bool = true): void = print(if b: \"Yes\" else: \"No\")\n proc No*(b: bool = true): void = Yes(not b)\n proc YES_upper*(b: bool = true): void = print(if b: \"YES\" else: \"NO\")\n proc NO_upper*(b: bool = true): void = Yes_upper(not b)\n const DXY* = [(0, -1), (0, 1), (-1, 0), (1, 0)]\n const DDXY* = [(1, -1), (1, 0), (1, 1), (0, -1), (0, 1), (-1, -1), (-1, 0), (-1, 1)]\n macro exit*(statement: untyped): untyped = (quote do: (`statement`; quit()))\n proc initHashSet[T](): Hashset[T] = initHashSet[T](0)\n" # source: https://github.com/kemuniku/cplib/tree/main/src/cplib/collections/lazysegtree.nim ImportExpand "cplib/collections/lazysegtree" <=== "when not declared CPLIB_COLLECTIONS_LAZYSEGTREE:\n const CPLIB_COLLECTIONS_LAZYSEGTREE* = 1\n import algorithm\n import sequtils\n import bitops\n import strutils\n type LazySegmentTree*[S, F] = ref object\n default: S\n merge: proc(x: S, y: S): S\n arr*: seq[S]\n lazy*: seq[F]\n mapping: proc(f: F, x: S): S\n composition: proc(f, g: F): F\n id: F\n lastnode: int\n log: int\n length: int\n proc initLazySegmentTree*[S, F](v_or_n: int or seq[S], merge: proc(x: S, y: S): S, default: S, mapping: proc(f: F, x: S): S, composition: proc(f, g: F): F, id: F): LazySegmentTree[S, F] =\n var v: seq[S]\n var n: int\n when v_or_n is seq[S]:\n v = v_or_n\n n = len(v)\n else:\n n = v_or_n\n var lastnode = 1\n while lastnode < n:\n lastnode*=2\n var log = countTrailingZeroBits(lastnode)\n var arr = newSeqWith(2*lastnode, default)\n var lazy = newSeqWith(lastnode, id)\n var self = LazySegmentTree[S, F](default: default, merge: merge, arr: arr, lazy: lazy, mapping: mapping, composition: composition, id: id, lastnode: lastnode, log: log, length: n)\n when v_or_n is seq[S]:\n for i in 0.. 0:\n lres = self.merge(lres, self.arr[q_left])\n q_left.inc\n if (q_right and 1) > 0:\n q_right.dec\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*[S, F](self: var LazySegmentTree[S, F], segment: HSlice[int, int]): S =\n return self.get(segment.a, segment.b+1)\n proc `[]`*[S, F](self: var LazySegmentTree[S, F], segment: HSlice[int, int]): S = self.get(segment)\n proc `[]=`*[S, F](self: var LazySegmentTree[S, F], p: Natural, val: S) = self.update(p, val)\n proc len*[S, F](self: var LazySegmentTree[S, F]): int =\n return self.length\n proc `$`*[S, F](self: var LazySegmentTree[S, F]): string =\n # var self = self\n return (0.. 0:\n self.all_apply(q_left, f)\n q_left.inc\n if (q_right and 1) > 0:\n q_right.dec\n self.all_apply(q_right, f)\n q_left = q_left shr 1\n q_right = q_right shr 1\n var mn = countTrailingZeroBits(q_left) + 1\n for i in mn..self.log:\n var p = q_left shr i\n self.arr[p] = self.merge(self.arr[2*p], self.arr[2*p+1])\n mn = countTrailingZeroBits(q_right) + 1\n for i in mn..self.log:\n var p = ((q_right - 1) shr i)\n self.arr[p] = self.merge(self.arr[2*p], self.arr[2*p+1])\n proc apply*[S, F](self: var LazySegmentTree[S, F], segment: HSlice[int, int], f: F) =\n self.apply(segment.a, segment.b+1, f)\n" # {.checks: off.} var n = input(int) var q = input(int) proc op(x, y: (int, int)): (int, int) = if x[0] < y[0]: return x if y[0] < x[0]: return y return (x[0], x[1] + y[1]) proc mapping(f: int, x: (int, int)): (int, int) = return (x[0] + f, x[1]) proc composition(f, g: int): int = return f+g var seg = initLazySegmentTree(newSeqWith(n, (0, 1)), op, (INFL, 0), mapping, composition, 0) var ans = n var query = newSeq[(int, int)](q) for i in 0..