結果

問題 No.2080 Simple Nim Query
ユーザー to-omerto-omer
提出日時 2022-09-25 21:38:02
言語 Rust
(1.72.1)
結果
AC  
実行時間 42 ms / 3,000 ms
コード長 39,664 bytes
コンパイル時間 2,008 ms
コンパイル使用メモリ 190,724 KB
実行使用メモリ 12,192 KB
最終ジャッジ日時 2023-09-03 02:48:48
合計ジャッジ時間 3,539 ms
ジャッジサーバーID
(参考情報)
judge13 / judge12
このコードへのチャレンジ(β)

テストケース

テストケース表示
入力 結果 実行時間
実行使用メモリ
testcase_00 AC 1 ms
4,376 KB
testcase_01 AC 1 ms
4,380 KB
testcase_02 AC 1 ms
4,376 KB
testcase_03 AC 20 ms
4,380 KB
testcase_04 AC 20 ms
4,376 KB
testcase_05 AC 36 ms
12,192 KB
testcase_06 AC 38 ms
8,128 KB
testcase_07 AC 38 ms
8,108 KB
testcase_08 AC 30 ms
8,100 KB
testcase_09 AC 31 ms
8,108 KB
testcase_10 AC 42 ms
8,112 KB
権限があれば一括ダウンロードができます

ソースコード

diff #

pub fn main() {
    crate::prepare!();
    sc!(n, q, a: [usize; n]);
    let mut bit =
        SegmentTree::<BitOrOperation<_>>::from_vec(a.iter().map(|&a| a > 1).collect::<Vec<_>>());
    for _ in 0..q {
        sc!(t, x: Usize1, y);
        if t == 1 {
            bit.set(x, y > 1);
        } else {
            let k = if let Some(k) = bit.rposition_acc(x..y, |&b| b) {
                y - 1 - k
            } else {
                y - x
            };
            pp!(if (k == y - x) ^ (k % 2 != 0) {
                'S'
            } else {
                'F'
            });
        }
    }
}
#[allow(unused_imports)]use std::{cmp::{Ordering,Reverse},collections::{BTreeMap,BTreeSet,BinaryHeap,HashMap,HashSet,VecDeque}};
mod main_macros{#[doc=" Prepare useful macros."]#[doc=" - `prepare!();`: default (all input scanner (`sc!`, `sv!`) + buf print (`pp!`, `dg!`))"]#[doc=" - `prepare!(?);`: interactive (line scanner (`scln!`) + buf print (`pp!`, `dg!`))"]#[macro_export]macro_rules!prepare{(@output($dol:tt))=>{#[allow(unused_imports)]use std::io::Write as _;let __out=std::io::stdout();#[allow(unused_mut,unused_variables)]let mut __out=std::io::BufWriter::new(__out.lock());#[allow(unused_macros)]#[doc=" [`iter_print!`] for buffered stdout."]macro_rules!pp{($dol($dol t:tt)*)=>{$dol crate::iter_print!(__out,$dol($dol t)*)}}#[cfg(debug_assertions)]#[allow(unused_macros)]#[doc=" [`iter_print!`] for buffered stderr. Do nothing in release mode."]macro_rules!dg{($dol($dol t:tt)*)=>{{#[allow(unused_imports)]use std::io::Write as _;let __err=std::io::stderr();#[allow(unused_mut,unused_variables)]let mut __err=std::io::BufWriter::new(__err.lock());$dol crate::iter_print!(__err,$dol($dol t)*);let _=__err.flush();}}}#[cfg(not(debug_assertions))]#[allow(unused_macros)]#[doc=" [`iter_print!`] for buffered stderr. Do nothing in release mode."]macro_rules!dg{($dol($dol t:tt)*)=>{}}};(@normal($dol:tt))=>{let __in_buf=read_stdin_all_unchecked();#[allow(unused_mut,unused_variables)]let mut __scanner=Scanner::new(&__in_buf);#[allow(unused_macros)]macro_rules!sc{($dol($dol t:tt)*)=>{$dol crate::scan!(__scanner,$dol($dol t)*)}}#[allow(unused_macros)]macro_rules!sv{($dol($dol t:tt)*)=>{$dol crate::scan_value!(__scanner,$dol($dol t)*)}}};(@interactive($dol:tt))=>{#[allow(unused_macros)]#[doc=" Scan a line, and previous line will be truncated in the next call."]macro_rules!scln{($dol($dol t:tt)*)=>{let __in_buf=read_stdin_line();#[allow(unused_mut,unused_variables)]let mut __scanner=Scanner::new(&__in_buf);$dol crate::scan!(__scanner,$dol($dol t)*)}}};()=>{$crate::prepare!(@output($));$crate::prepare!(@normal($))};(?)=>{$crate::prepare!(@output($));$crate::prepare!(@interactive($))};}}
pub use self::iter_print::IterPrint;
mod iter_print{use std::{fmt::Display,io::{Error,Write}};pub trait IterPrint{fn iter_print<W,S>(self,writer:&mut W,sep:S,is_head:bool)->Result<(),Error>where W:Write,S:Display;}macro_rules!iter_print_tuple_impl{(@impl$($A:ident$a:ident)?,$($B:ident$b:ident)*)=>{impl<$($A,)?$($B),*>IterPrint for($($A,)?$($B),*)where$($A:Display,)?$($B:Display),*{#[allow(unused_variables)]fn iter_print<W,S>(self,writer:&mut W,sep:S,is_head:bool)->Result<(),Error>where W:Write,S:Display{let($($a,)?$($b,)*)=self;$(if is_head{::std::write!(writer,"{}",$a)?;}else{::std::write!(writer,"{}{}",sep,$a)?;})?$(::std::write!(writer,"{}{}",sep,$b)?;)*Ok(())}}};(@inc,,$C:ident$c:ident$($D:ident$d:ident)*)=>{iter_print_tuple_impl!(@impl,);iter_print_tuple_impl!(@inc$C$c,,$($D$d)*);};(@inc$A:ident$a:ident,$($B:ident$b:ident)*,$C:ident$c:ident$($D:ident$d:ident)*)=>{iter_print_tuple_impl!(@impl$A$a,$($B$b)*);iter_print_tuple_impl!(@inc$A$a,$($B$b)*$C$c,$($D$d)*);};(@inc$A:ident$a:ident,$($B:ident$b:ident)*,)=>{iter_print_tuple_impl!(@impl$A$a,$($B$b)*);};($($t:tt)*)=>{iter_print_tuple_impl!(@inc,,$($t)*);};}iter_print_tuple_impl!(A a B b C c D d E e F f G g H h I i J j K k);#[doc=" Print expressions with a separator."]#[doc=" - `iter_print!(writer, args...)`"]#[doc=" - `@sep $expr`: set separator (default: `' '`)"]#[doc=" - `@ns`: alias for `@sep \"\"`"]#[doc=" - `@lf`: alias for `@sep '\\n'`"]#[doc=" - `@sp`: alias for `@sep ' '`"]#[doc=" - `@fmt $lit => {$($expr),*}`: print `format!($lit, $($expr),*)`"]#[doc=" - `@flush`: flush writer (auto insert `!`)"]#[doc=" - `@it $expr`: print iterator"]#[doc=" - `@it2d $expr`: print 2d-iterator"]#[doc=" - `@tup $expr`: print tuple (need to import [`IterPrint`])"]#[doc=" - `@ittup $expr`: print iterative tuple (need to import [`IterPrint`])"]#[doc=" - `$expr`: print expr"]#[doc=" - `{ args... }`: scoped"]#[doc=" - `;`: print `'\\n'`"]#[doc=" - `!`: not print `'\\n'` at the end"]#[macro_export]macro_rules!iter_print{(@@fmt$writer:expr,$sep:expr,$is_head:expr,$lit:literal,$($e:expr),*)=>{if!$is_head{::std::write!($writer,"{}",$sep).expect("io error");}::std::write!($writer,$lit,$($e),*).expect("io error");};(@@item$writer:expr,$sep:expr,$is_head:expr,$e:expr)=>{$crate::iter_print!(@@fmt$writer,$sep,$is_head,"{}",$e);};(@@line_feed$writer:expr$(,)?)=>{::std::writeln!($writer).expect("io error");};(@@it$writer:expr,$sep:expr,$is_head:expr,$iter:expr)=>{{let mut iter=$iter.into_iter();if let Some(item)=iter.next(){$crate::iter_print!(@@item$writer,$sep,$is_head,item);}for item in iter{$crate::iter_print!(@@item$writer,$sep,false,item);}}};(@@it2d$writer:expr,$sep:expr,$is_head:expr,$iter:expr)=>{let mut iter=$iter.into_iter();if let Some(item)=iter.next(){$crate::iter_print!(@@it$writer,$sep,$is_head,item);}for item in iter{$crate::iter_print!(@@line_feed$writer);$crate::iter_print!(@@it$writer,$sep,true,item);}};(@@tup$writer:expr,$sep:expr,$is_head:expr,$tuple:expr)=>{IterPrint::iter_print($tuple,&mut$writer,$sep,$is_head).expect("io error");};(@@ittup$writer:expr,$sep:expr,$is_head:expr,$iter:expr)=>{let mut iter=$iter.into_iter();if let Some(item)=iter.next(){$crate::iter_print!(@@tup$writer,$sep,$is_head,item);}for item in iter{$crate::iter_print!(@@line_feed$writer);$crate::iter_print!(@@tup$writer,$sep,true,item);}};(@@assert_tag item)=>{};(@@assert_tag it)=>{};(@@assert_tag it2d)=>{};(@@assert_tag tup)=>{};(@@assert_tag ittup)=>{};(@@assert_tag$tag:ident)=>{::std::compile_error!(::std::concat!("invalid tag in `iter_print!`: `",std::stringify!($tag),"`"));};(@@inner$writer:expr,$sep:expr,$is_head:expr,@sep$e:expr,$($t:tt)*)=>{$crate::iter_print!(@@inner$writer,$e,$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@ns$($t:tt)*)=>{$crate::iter_print!(@@inner$writer,"",$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@lf$($t:tt)*)=>{$crate::iter_print!(@@inner$writer,'\n',$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@sp$($t:tt)*)=>{$crate::iter_print!(@@inner$writer,' ',$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@flush$($t:tt)*)=>{$writer.flush().expect("io error");$crate::iter_print!(@@inner$writer,$sep,$is_head,!$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@fmt$lit:literal=>{$($e:expr),*$(,)?}$($t:tt)*)=>{$crate::iter_print!(@@fmt$writer,$sep,$is_head,$lit,$($e),*);$crate::iter_print!(@@inner$writer,$sep,$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@$tag:ident$e:expr,$($t:tt)*)=>{$crate::iter_print!(@@assert_tag$tag);$crate::iter_print!(@@$tag$writer,$sep,$is_head,$e);$crate::iter_print!(@@inner$writer,$sep,false,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@$tag:ident$e:expr;$($t:tt)*)=>{$crate::iter_print!(@@assert_tag$tag);$crate::iter_print!(@@$tag$writer,$sep,$is_head,$e);$crate::iter_print!(@@line_feed$writer);$crate::iter_print!(@@inner$writer,$sep,true,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@$tag:ident$e:expr)=>{$crate::iter_print!(@@assert_tag$tag);$crate::iter_print!(@@$tag$writer,$sep,$is_head,$e);$crate::iter_print!(@@inner$writer,$sep,false,);};(@@inner$writer:expr,$sep:expr,$is_head:expr,@$tag:ident$($t:tt)*)=>{::std::compile_error!(::std::concat!("invalid expr in `iter_print!`: `",std::stringify!($($t)*),"`"));};(@@inner$writer:expr,$sep:expr,$is_head:expr,,$($t:tt)*)=>{$crate::iter_print!(@@inner$writer,$sep,$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,;$($t:tt)*)=>{$crate::iter_print!(@@line_feed$writer);$crate::iter_print!(@@inner$writer,$sep,$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,!$(,)?)=>{};(@@inner$writer:expr,$sep:expr,$is_head:expr,!$($t:tt)*)=>{$crate::iter_print!(@@inner$writer,$sep,$is_head,$($t)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,)=>{$crate::iter_print!(@@line_feed$writer);};(@@inner$writer:expr,$sep:expr,$is_head:expr,{$($t:tt)*}$($rest:tt)*)=>{$crate::iter_print!(@@inner$writer,$sep,$is_head,$($t)*,!);$crate::iter_print!(@@inner$writer,$sep,$is_head,$($rest)*);};(@@inner$writer:expr,$sep:expr,$is_head:expr,$($t:tt)*)=>{$crate::iter_print!(@@inner$writer,$sep,$is_head,@item$($t)*);};($writer:expr,$($t:tt)*)=>{{$crate::iter_print!(@@inner$writer,' ',true,$($t)*);}};}}
pub use self::scanner::*;
mod scanner{use std::{iter::{from_fn,repeat_with,FromIterator},marker::PhantomData};pub fn read_stdin_all()->String{use std::io::Read as _;let mut s=String::new();std::io::stdin().read_to_string(&mut s).expect("io error");s}pub fn read_stdin_all_unchecked()->String{use std::io::Read as _;let mut buf=Vec::new();std::io::stdin().read_to_end(&mut buf).expect("io error");unsafe{String::from_utf8_unchecked(buf)}}pub fn read_all(mut reader:impl std::io::Read)->String{let mut s=String::new();reader.read_to_string(&mut s).expect("io error");s}pub fn read_all_unchecked(mut reader:impl std::io::Read)->String{let mut buf=Vec::new();reader.read_to_end(&mut buf).expect("io error");unsafe{String::from_utf8_unchecked(buf)}}pub fn read_stdin_line()->String{let mut s=String::new();std::io::stdin().read_line(&mut s).expect("io error");s}pub trait IterScan:Sized{type Output;fn scan<'a,I:Iterator<Item=&'a str>>(iter:&mut I)->Option<Self::Output>;}pub trait MarkedIterScan:Sized{type Output;fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>;}#[derive(Clone,Debug)]pub struct Scanner<'a>{iter:std::str::SplitAsciiWhitespace<'a>}impl<'a>Scanner<'a>{#[inline]pub fn new(s:&'a str)->Self{let iter=s.split_ascii_whitespace();Self{iter}}#[inline]pub fn scan<T>(&mut self)-><T as IterScan>::Output where T:IterScan{<T as IterScan>::scan(&mut self.iter).expect("scan error")}#[inline]pub fn mscan<T>(&mut self,marker:T)-><T as MarkedIterScan>::Output where T:MarkedIterScan{marker.mscan(&mut self.iter).expect("scan error")}#[inline]pub fn scan_vec<T>(&mut self,size:usize)->Vec<<T as IterScan>::Output>where T:IterScan{(0..size).map(|_|<T as IterScan>::scan(&mut self.iter).expect("scan error")).collect()}#[inline]pub fn iter<'b,T>(&'b mut self)->ScannerIter<'a,'b,T>where T:IterScan{ScannerIter{inner:self,_marker:std::marker::PhantomData}}}macro_rules!iter_scan_impls{($($t:ty)*)=>{$(impl IterScan for$t{type Output=Self;#[inline]fn scan<'a,I:Iterator<Item=&'a str>>(iter:&mut I)->Option<Self>{iter.next()?.parse::<$t>().ok()}})*};}iter_scan_impls!(char u8 u16 u32 u64 usize i8 i16 i32 i64 isize f32 f64 u128 i128 String);macro_rules!iter_scan_tuple_impl{(@impl$($T:ident)*)=>{impl<$($T:IterScan),*>IterScan for($($T,)*){type Output=($(<$T as IterScan>::Output,)*);#[inline]fn scan<'a,It:Iterator<Item=&'a str>>(_iter:&mut It)->Option<Self::Output>{Some(($(<$T as IterScan>::scan(_iter)?,)*))}}};(@inner$($T:ident)*,)=>{iter_scan_tuple_impl!(@impl$($T)*);};(@inner$($T:ident)*,$U:ident$($Rest:ident)*)=>{iter_scan_tuple_impl!(@impl$($T)*);iter_scan_tuple_impl!(@inner$($T)*$U,$($Rest)*);};($($T:ident)*)=>{iter_scan_tuple_impl!(@inner,$($T)*);};}iter_scan_tuple_impl!(A B C D E F G H I J K);pub struct ScannerIter<'a,'b,T>{inner:&'b mut Scanner<'a>,_marker:std::marker::PhantomData<fn()->T>}impl<'a,'b,T>Iterator for ScannerIter<'a,'b,T>where T:IterScan{type Item=<T as IterScan>::Output;#[inline]fn next(&mut self)->Option<Self::Item>{<T as IterScan>::scan(&mut self.inner.iter)}}#[doc=" - `scan_value!(scanner, ELEMENT)`"]#[doc=""]#[doc=" ELEMENT :="]#[doc=" - `$ty`: IterScan"]#[doc=" - `@$expr`: MarkedIterScan"]#[doc=" - `[ELEMENT; $expr]`: vector"]#[doc=" - `[ELEMENT]`: iterator"]#[doc=" - `($(ELEMENT)*,)`: tuple"]#[macro_export]macro_rules!scan_value{(@repeat$scanner:expr,[$($t:tt)*]$($len:expr)?)=>{::std::iter::repeat_with(||$crate::scan_value!(@inner$scanner,[]$($t)*))$(.take($len).collect::<Vec<_>>())?};(@tuple$scanner:expr,[$([$($args:tt)*])*])=>{($($($args)*,)*)};(@$tag:ident$scanner:expr,[[$($args:tt)*]])=>{$($args)*};(@$tag:ident$scanner:expr,[$($args:tt)*]@$e:expr)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$scanner.mscan($e)]])};(@$tag:ident$scanner:expr,[$($args:tt)*]@$e:expr,$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$scanner.mscan($e)]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*]($($tuple:tt)*)$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$crate::scan_value!(@tuple$scanner,[]$($tuple)*)]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*][@$e:expr;$len:expr]$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$crate::scan_value!(@repeat$scanner,[@$e]$len)]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*][[$($tt:tt)*];$len:expr]$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$crate::scan_value!(@repeat$scanner,[[$($tt)*]]$len)]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*][($($tt:tt)*);$len:expr]$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$crate::scan_value!(@repeat$scanner,[($($tt)*)]$len)]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*][$ty:ty;$len:expr]$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$crate::scan_value!(@repeat$scanner,[$ty]$len)]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*][$($tt:tt)*]$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$crate::scan_value!(@repeat$scanner,[$($tt)*])]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*]$ty:ty)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$scanner.scan::<$ty>()]])};(@$tag:ident$scanner:expr,[$($args:tt)*]$ty:ty,$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*[$scanner.scan::<$ty>()]]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*],$($t:tt)*)=>{$crate::scan_value!(@$tag$scanner,[$($args)*]$($t)*)};(@$tag:ident$scanner:expr,[$($args:tt)*])=>{::std::compile_error!(::std::stringify!($($args)*))};($scanner:expr,$($t:tt)*)=>{$crate::scan_value!(@inner$scanner,[]$($t)*)}}#[doc=" - `scan!(scanner, $($pat $(: ELEMENT)?),*)`"]#[macro_export]macro_rules!scan{(@assert$p:pat)=>{};(@assert$($p:tt)*)=>{::std::compile_error!(::std::concat!("expected pattern, found `",::std::stringify!($($p)*),"`"));};(@pat$scanner:expr,[][])=>{};(@pat$scanner:expr,[][],$($t:tt)*)=>{$crate::scan!(@pat$scanner,[][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][]$x:ident$($t:tt)*)=>{$crate::scan!(@pat$scanner,[$($p)*$x][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][]::$($t:tt)*)=>{$crate::scan!(@pat$scanner,[$($p)*::][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][]&$($t:tt)*)=>{$crate::scan!(@pat$scanner,[$($p)*&][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][]($($x:tt)*)$($t:tt)*)=>{$crate::scan!(@pat$scanner,[$($p)*($($x)*)][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][][$($x:tt)*]$($t:tt)*)=>{$crate::scan!(@pat$scanner,[$($p)*[$($x)*]][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][]{$($x:tt)*}$($t:tt)*)=>{$crate::scan!(@pat$scanner,[$($p)*{$($x)*}][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][]:$($t:tt)*)=>{$crate::scan!(@ty$scanner,[$($p)*][]$($t)*)};(@pat$scanner:expr,[$($p:tt)*][]$($t:tt)*)=>{$crate::scan!(@let$scanner,[$($p)*][usize]$($t)*)};(@ty$scanner:expr,[$($p:tt)*][$($tt:tt)*]@$e:expr)=>{$crate::scan!(@let$scanner,[$($p)*][$($tt)*@$e])};(@ty$scanner:expr,[$($p:tt)*][$($tt:tt)*]@$e:expr,$($t:tt)*)=>{$crate::scan!(@let$scanner,[$($p)*][$($tt)*@$e],$($t)*)};(@ty$scanner:expr,[$($p:tt)*][$($tt:tt)*]($($x:tt)*)$($t:tt)*)=>{$crate::scan!(@let$scanner,[$($p)*][$($tt)*($($x)*)]$($t)*)};(@ty$scanner:expr,[$($p:tt)*][$($tt:tt)*][$($x:tt)*]$($t:tt)*)=>{$crate::scan!(@let$scanner,[$($p)*][$($tt)*[$($x)*]]$($t)*)};(@ty$scanner:expr,[$($p:tt)*][$($tt:tt)*]$ty:ty)=>{$crate::scan!(@let$scanner,[$($p)*][$($tt)*$ty])};(@ty$scanner:expr,[$($p:tt)*][$($tt:tt)*]$ty:ty,$($t:tt)*)=>{$crate::scan!(@let$scanner,[$($p)*][$($tt)*$ty],$($t)*)};(@let$scanner:expr,[$($p:tt)*][$($tt:tt)*]$($t:tt)*)=>{$crate::scan!{@assert$($p)*}let$($p)* =$crate::scan_value!($scanner,$($tt)*);$crate::scan!(@pat$scanner,[][]$($t)*)};($scanner:expr,$($t:tt)*)=>{$crate::scan!(@pat$scanner,[][]$($t)*)}}#[derive(Debug,Copy,Clone)]pub enum Usize1{}impl IterScan for Usize1{type Output=usize;#[inline]fn scan<'a,I:Iterator<Item=&'a str>>(iter:&mut I)->Option<Self::Output>{<usize as IterScan>::scan(iter)?.checked_sub(1)}}#[derive(Debug,Copy,Clone)]pub struct CharWithBase(pub char);impl MarkedIterScan for CharWithBase{type Output=usize;#[inline]fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{Some((<char as IterScan>::scan(iter)?as u8-self.0 as u8)as usize)}}#[derive(Debug,Copy,Clone)]pub enum Chars{}impl IterScan for Chars{type Output=Vec<char>;#[inline]fn scan<'a,I:Iterator<Item=&'a str>>(iter:&mut I)->Option<Self::Output>{Some(iter.next()?.chars().collect())}}#[derive(Debug,Copy,Clone)]pub struct CharsWithBase(pub char);impl MarkedIterScan for CharsWithBase{type Output=Vec<usize>;#[inline]fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{Some(iter.next()?.chars().map(|c|(c as u8-self.0 as u8)as usize).collect())}}#[derive(Debug,Copy,Clone)]pub struct ByteWithBase(pub u8);impl MarkedIterScan for ByteWithBase{type Output=usize;#[inline]fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{Some((<char as IterScan>::scan(iter)?as u8-self.0)as usize)}}#[derive(Debug,Copy,Clone)]pub enum Bytes{}impl IterScan for Bytes{type Output=Vec<u8>;#[inline]fn scan<'a,I:Iterator<Item=&'a str>>(iter:&mut I)->Option<Self::Output>{Some(iter.next()?.bytes().collect())}}#[derive(Debug,Copy,Clone)]pub struct BytesWithBase(pub u8);impl MarkedIterScan for BytesWithBase{type Output=Vec<usize>;#[inline]fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{Some(iter.next()?.bytes().map(|c|(c-self.0)as usize).collect())}}#[derive(Debug,Copy,Clone)]pub struct Collect<T,B=Vec<<T as IterScan>::Output>>where T:IterScan,B:FromIterator<<T as IterScan>::Output>{size:usize,_marker:PhantomData<fn()->(T,B)>}impl<T,B>Collect<T,B>where T:IterScan,B:FromIterator<<T as IterScan>::Output>{pub fn new(size:usize)->Self{Self{size,_marker:PhantomData}}}impl<T,B>MarkedIterScan for Collect<T,B>where T:IterScan,B:FromIterator<<T as IterScan>::Output>{type Output=B;#[inline]fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{repeat_with(||<T as IterScan>::scan(iter)).take(self.size).collect()}}#[derive(Debug,Copy,Clone)]pub struct SizedCollect<T,B=Vec<<T as IterScan>::Output>>where T:IterScan,B:FromIterator<<T as IterScan>::Output>{_marker:PhantomData<fn()->(T,B)>}impl<T,B>IterScan for SizedCollect<T,B>where T:IterScan,B:FromIterator<<T as IterScan>::Output>{type Output=B;#[inline]fn scan<'a,I:Iterator<Item=&'a str>>(iter:&mut I)->Option<Self::Output>{let size=usize::scan(iter)?;repeat_with(||<T as IterScan>::scan(iter)).take(size).collect()}}#[derive(Debug,Copy,Clone)]pub struct Splitted<T,P>where T:IterScan{pat:P,_marker:PhantomData<fn()->T>}impl<T,P>Splitted<T,P>where T:IterScan{pub fn new(pat:P)->Self{Self{pat,_marker:PhantomData}}}impl<T>MarkedIterScan for Splitted<T,char>where T:IterScan{type Output=Vec<<T as IterScan>::Output>;fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{let mut iter=iter.next()?.split(self.pat);Some(from_fn(||<T as IterScan>::scan(&mut iter)).collect())}}impl<T>MarkedIterScan for Splitted<T,&str>where T:IterScan{type Output=Vec<<T as IterScan>::Output>;fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{let mut iter=iter.next()?.split(self.pat);Some(from_fn(||<T as IterScan>::scan(&mut iter)).collect())}}impl<T,F>MarkedIterScan for F where F:Fn(&str)->Option<T>{type Output=T;fn mscan<'a,I:Iterator<Item=&'a str>>(self,iter:&mut I)->Option<Self::Output>{self(iter.next()?)}}}
pub use self::binary_indexed_tree::BinaryIndexedTree;
mod binary_indexed_tree{use super::{Group,Monoid};use std::fmt::{self,Debug,Formatter};pub struct BinaryIndexedTree<M>where M:Monoid{n:usize,bit:Vec<M::T>}impl<M>Clone for BinaryIndexedTree<M>where M:Monoid{fn clone(&self)->Self{Self{n:self.n,bit:self.bit.clone()}}}impl<M>Debug for BinaryIndexedTree<M>where M:Monoid,M::T:Debug{fn fmt(&self,f:&mut Formatter<'_>)->fmt::Result{f.debug_struct("BinaryIndexedTree").field("n",&self.n).field("bit",&self.bit).finish()}}impl<M>BinaryIndexedTree<M>where M:Monoid{#[inline]pub fn new(n:usize)->Self{let bit=vec![M::unit();n+1];Self{n,bit}}#[inline]pub fn from_slice(slice:&[M::T])->Self{let n=slice.len();let mut bit=vec![M::unit();n+1];for(i,x)in slice.iter().enumerate(){let k=i+1;M::operate_assign(&mut bit[k],x);let j=k+(k&(!k+1));if j<=n{bit[j]=M::operate(&bit[j],&bit[k]);}}Self{n,bit}}#[inline]#[doc=" fold [0, k)"]pub fn accumulate0(&self,mut k:usize)->M::T{debug_assert!(k<=self.n);let mut res=M::unit();while k>0{res=M::operate(&res,&self.bit[k]);k-=k&(!k+1);}res}#[inline]#[doc=" fold [0, k]"]pub fn accumulate(&self,k:usize)->M::T{self.accumulate0(k+1)}#[inline]pub fn update(&mut self,k:usize,x:M::T){debug_assert!(k<self.n);let mut k=k+1;while k<=self.n{self.bit[k]=M::operate(&self.bit[k],&x);k+=k&(!k+1);}}}impl<G:Group>BinaryIndexedTree<G>{#[inline]pub fn fold(&self,l:usize,r:usize)->G::T{debug_assert!(l<=self.n&&r<=self.n);G::operate(&G::inverse(&self.accumulate0(l)),&self.accumulate0(r))}#[inline]pub fn get(&self,k:usize)->G::T{self.fold(k,k+1)}#[inline]pub fn set(&mut self,k:usize,x:G::T){self.update(k,G::operate(&G::inverse(&self.get(k)),&x));}}impl<M:Monoid>BinaryIndexedTree<M>where M::T:Ord{#[inline]pub fn lower_bound(&self,x:M::T)->usize{let n=self.n;let mut acc=M::unit();let mut pos=0;let mut k=n.next_power_of_two();while k>0{if k+pos<=n&&M::operate(&acc,&self.bit[k+pos])<x{pos+=k;acc=M::operate(&acc,&self.bit[pos]);}k>>=1;}pos}}}
pub use self::magma::*;
mod magma{#![doc=" algebraic traits"]#[doc=" binary operaion: $T \\circ T \\to T$"]pub trait Magma{#[doc=" type of operands: $T$"]type T:Clone;#[doc=" binary operaion: $\\circ$"]fn operate(x:&Self::T,y:&Self::T)->Self::T;#[inline]fn reverse_operate(x:&Self::T,y:&Self::T)->Self::T{Self::operate(y,x)}#[inline]fn operate_assign(x:&mut Self::T,y:&Self::T){*x=Self::operate(x,y);}}#[doc=" $\\forall a,\\forall b,\\forall c \\in T, (a \\circ b) \\circ c = a \\circ (b \\circ c)$"]pub trait Associative{}#[doc=" associative binary operation"]pub trait SemiGroup:Magma+Associative{}impl<S>SemiGroup for S where S:Magma+Associative{}#[doc=" $\\exists e \\in T, \\forall a \\in T, e \\circ a = a \\circ e = e$"]pub trait Unital:Magma{#[doc=" identity element: $e$"]fn unit()->Self::T;#[inline]fn is_unit(x:&Self::T)->bool where<Self as Magma>::T:PartialEq{x==&Self::unit()}#[inline]fn set_unit(x:&mut Self::T){*x=Self::unit();}}#[doc=" associative binary operation and an identity element"]pub trait Monoid:SemiGroup+Unital{#[doc=" binary exponentiation: $x^n = x\\circ\\ddots\\circ x$"]fn pow(mut x:Self::T,mut n:usize)->Self::T{let mut res=Self::unit();while n>0{if n&1==1{res=Self::operate(&res,&x);}x=Self::operate(&x,&x);n>>=1;}res}}impl<M>Monoid for M where M:SemiGroup+Unital{}#[doc=" $\\exists e \\in T, \\forall a \\in T, \\exists b,c \\in T, b \\circ a = a \\circ c = e$"]pub trait Invertible:Magma{#[doc=" $a$ where $a \\circ x = e$"]fn inverse(x:&Self::T)->Self::T;#[inline]fn rinv_operate(x:&Self::T,y:&Self::T)->Self::T{Self::operate(x,&Self::inverse(y))}}#[doc=" associative binary operation and an identity element and inverse elements"]pub trait Group:Monoid+Invertible{}impl<G>Group for G where G:Monoid+Invertible{}#[doc=" $\\forall a,\\forall b \\in T, a \\circ b = b \\circ a$"]pub trait Commutative{}#[doc=" commutative monoid"]pub trait AbelianMonoid:Monoid+Commutative{}impl<M>AbelianMonoid for M where M:Monoid+Commutative{}#[doc=" commutative group"]pub trait AbelianGroup:Group+Commutative{}impl<G>AbelianGroup for G where G:Group+Commutative{}#[doc=" $\\forall a \\in T, a \\circ a = a$"]pub trait Idempotent{}#[doc=" idempotent monoid"]pub trait IdempotentMonoid:Monoid+Idempotent{}impl<M>IdempotentMonoid for M where M:Monoid+Idempotent{}#[macro_export]macro_rules!monoid_fold{($m:ty)=>{<$m as Unital>::unit()};($m:ty,)=>{<$m as Unital>::unit()};($m:ty,$f:expr)=>{$f};($m:ty,$f:expr,$($ff:expr),*)=>{<$m as Magma>::operate(&($f),&monoid_fold!($m,$($ff),*))};}#[macro_export]macro_rules!define_monoid{($Name:ident,$t:ty,|$x:ident,$y:ident|$op:expr,$unit:expr)=>{struct$Name;impl Magma for$Name{type T=$t;fn operate($x:&Self::T,$y:&Self::T)->Self::T{$op}}impl Unital for$Name{fn unit()->Self::T{$unit}}impl Associative for$Name{}};}}
pub use self::additive_operation_impl::AdditiveOperation;
mod additive_operation_impl{use super::*;use std::{marker::PhantomData,ops::{Add,Neg,Sub}};#[doc=" $+$"]pub struct AdditiveOperation<T:Clone+Zero+Add<Output=T>>{_marker:PhantomData<fn()->T>}impl<T:Clone+Zero+Add<Output=T>>Magma for AdditiveOperation<T>{type T=T;#[inline]fn operate(x:&Self::T,y:&Self::T)->Self::T{x.clone()+y.clone()}}impl<T:Clone+Zero+Add<Output=T>>Unital for AdditiveOperation<T>{#[inline]fn unit()->Self::T{Zero::zero()}}impl<T:Clone+Zero+Add<Output=T>>Associative for AdditiveOperation<T>{}impl<T:Clone+Zero+Add<Output=T>>Commutative for AdditiveOperation<T>{}impl<T:Clone+Zero+Add<Output=T>+Sub<Output=T>+Neg<Output=T>>Invertible for AdditiveOperation<T>{#[inline]fn inverse(x:&Self::T)->Self::T{-x.clone()}#[inline]fn rinv_operate(x:&Self::T,y:&Self::T)->Self::T{x.clone()-y.clone()}}}
pub use self::zero_one::{One,Zero};
mod zero_one{pub trait Zero:Sized{fn zero()->Self;#[inline]fn is_zero(&self)->bool where Self:PartialEq{self==&Self::zero()}#[inline]fn set_zero(&mut self){*self=Self::zero();}}pub trait One:Sized{fn one()->Self;#[inline]fn is_one(&self)->bool where Self:PartialEq{self==&Self::one()}#[inline]fn set_one(&mut self){*self=Self::one();}}macro_rules!zero_one_impls{($({$Trait:ident$method:ident$($t:ty)*,$e:expr})*)=>{$($(impl$Trait for$t{fn$method()->Self{$e}})*)*};}zero_one_impls!({Zero zero u8 u16 u32 u64 usize i8 i16 i32 i64 isize u128 i128,0}{Zero zero f32 f64,0.}{One one u8 u16 u32 u64 usize i8 i16 i32 i64 isize u128 i128,1}{One one f32 f64,1.});}
pub use self::segment_tree::SegmentTree;
mod segment_tree{use super::{AbelianMonoid,Monoid,RangeBoundsExt};use std::{fmt::{self,Debug,Formatter},ops::RangeBounds};pub struct SegmentTree<M>where M:Monoid{n:usize,seg:Vec<M::T>}impl<M>Clone for SegmentTree<M>where M:Monoid{fn clone(&self)->Self{Self{n:self.n,seg:self.seg.clone()}}}impl<M>Debug for SegmentTree<M>where M:Monoid,M::T:Debug{fn fmt(&self,f:&mut Formatter<'_>)->fmt::Result{f.debug_struct("SegmentTree").field("n",&self.n).field("seg",&self.seg).finish()}}impl<M>SegmentTree<M>where M:Monoid{pub fn new(n:usize)->Self{let seg=vec![M::unit();2*n];Self{n,seg}}pub fn from_vec(v:Vec<M::T>)->Self{let n=v.len();let mut seg=vec![M::unit();2*n];for(i,x)in v.into_iter().enumerate(){seg[n+i]=x;}for i in(1..n).rev(){seg[i]=M::operate(&seg[2*i],&seg[2*i+1]);}Self{n,seg}}pub fn set(&mut self,k:usize,x:M::T){debug_assert!(k<self.n);let mut k=k+self.n;self.seg[k]=x;k/=2;while k>0{self.seg[k]=M::operate(&self.seg[2*k],&self.seg[2*k+1]);k/=2;}}pub fn update(&mut self,k:usize,x:M::T){debug_assert!(k<self.n);let mut k=k+self.n;self.seg[k]=M::operate(&self.seg[k],&x);k/=2;while k>0{self.seg[k]=M::operate(&self.seg[2*k],&self.seg[2*k+1]);k/=2;}}pub fn get(&self,k:usize)->M::T{debug_assert!(k<self.n);self.seg[k+self.n].clone()}pub fn fold<R>(&self,range:R)->M::T where R:RangeBounds<usize>{let range=range.to_range();debug_assert!(range.end<=self.n);let mut l=range.start+self.n;let mut r=range.end+self.n;let mut vl=M::unit();let mut vr=M::unit();while l<r{if l&1!=0{vl=M::operate(&vl,&self.seg[l]);l+=1;}if r&1!=0{r-=1;vr=M::operate(&self.seg[r],&vr);}l/=2;r/=2;}M::operate(&vl,&vr)}fn bisect_perfect<F>(&self,mut pos:usize,mut acc:M::T,f:F)->(usize,M::T)where F:Fn(&M::T)->bool{while pos<self.n{pos<<=1;let nacc=M::operate(&acc,&self.seg[pos]);if!f(&nacc){acc=nacc;pos+=1;}}(pos-self.n,acc)}fn rbisect_perfect<F>(&self,mut pos:usize,mut acc:M::T,f:F)->(usize,M::T)where F:Fn(&M::T)->bool{while pos<self.n{pos=pos*2+1;let nacc=M::operate(&self.seg[pos],&acc);if!f(&nacc){acc=nacc;pos-=1;}}(pos-self.n,acc)}#[doc=" Returns the first index that satisfies a accumlative predicate."]pub fn position_acc<R,F>(&self,range:R,f:F)->Option<usize>where R:RangeBounds<usize>,F:Fn(&M::T)->bool{let range=range.to_range();debug_assert!(range.end<=self.n);let mut l=range.start+self.n;let r=range.end+self.n;let mut k=0usize;let mut acc=M::unit();while l<r>>k{if l&1!=0{let nacc=M::operate(&acc,&self.seg[l]);if f(&nacc){return Some(self.bisect_perfect(l,acc,f).0);}acc=nacc;l+=1;}l>>=1;k+=1;}for k in(0..k).rev(){let r=r>>k;if r&1!=0{let nacc=M::operate(&acc,&self.seg[r-1]);if f(&nacc){return Some(self.bisect_perfect(r-1,acc,f).0);}acc=nacc;}}None}#[doc=" Returns the last index that satisfies a accumlative predicate."]pub fn rposition_acc<R,F>(&self,range:R,f:F)->Option<usize>where R:RangeBounds<usize>,F:Fn(&M::T)->bool{let range=range.to_range();debug_assert!(range.end<=self.n);let mut l=range.start+self.n;let mut r=range.end+self.n;let mut c=0usize;let mut k=0usize;let mut acc=M::unit();while l>>k<r{c<<=1;if l&1<<k!=0{l+=1<<k;c+=1;}if r&1!=0{r-=1;let nacc=M::operate(&self.seg[r],&acc);if f(&nacc){return Some(self.rbisect_perfect(r,acc,f).0);}acc=nacc;}r>>=1;k+=1;}for k in(0..k).rev(){if c&1!=0{l-=1<<k;let l=l>>k;let nacc=M::operate(&self.seg[l],&acc);if f(&nacc){return Some(self.rbisect_perfect(l,acc,f).0);}acc=nacc;}c>>=1;}None}pub fn as_slice(&self)->&[M::T]{&self.seg[self.n..]}}impl<M>SegmentTree<M>where M:AbelianMonoid{pub fn fold_all(&self)->M::T{self.seg[1].clone()}}}
pub use self::bounded::Bounded;
mod bounded{#[doc=" Trait for max/min bounds"]pub trait Bounded:Sized+PartialOrd{fn maximum()->Self;fn minimum()->Self;fn is_maximum(&self)->bool{self==&Self::maximum()}fn is_minimum(&self)->bool{self==&Self::minimum()}fn set_maximum(&mut self){*self=Self::maximum()}fn set_minimum(&mut self){*self=Self::minimum()}}macro_rules!bounded_num_impls{($($t:ident)*)=>{$(impl Bounded for$t{fn maximum()->Self{std::$t::MAX}fn minimum()->Self{std::$t::MIN}})*};}bounded_num_impls!(u8 u16 u32 u64 u128 usize i8 i16 i32 i64 i128 isize f32 f64);macro_rules!bounded_tuple_impls{(@impl$($T:ident)*)=>{impl<$($T:Bounded),*>Bounded for($($T,)*){fn maximum()->Self{($(<$T as Bounded>::maximum(),)*)}fn minimum()->Self{($(<$T as Bounded>::minimum(),)*)}}};(@inner$($T:ident)*,)=>{bounded_tuple_impls!(@impl$($T)*);};(@inner$($T:ident)*,$U:ident$($Rest:ident)*)=>{bounded_tuple_impls!(@impl$($T)*);bounded_tuple_impls!(@inner$($T)*$U,$($Rest)*);};($T:ident$($Rest:ident)*)=>{bounded_tuple_impls!(@inner$T,$($Rest)*);};}bounded_tuple_impls!(A B C D E F G H I J);impl Bounded for(){fn maximum()->Self{}fn minimum()->Self{}}impl Bounded for bool{fn maximum()->Self{true}fn minimum()->Self{false}}impl<T>Bounded for Option<T>where T:Bounded{fn maximum()->Self{Some(<T as Bounded>::maximum())}fn minimum()->Self{None}}impl<T>Bounded for std::cmp::Reverse<T>where T:Bounded{fn maximum()->Self{std::cmp::Reverse(<T as Bounded>::minimum())}fn minimum()->Self{std::cmp::Reverse(<T as Bounded>::maximum())}}}
pub use self::discrete_steps::{DiscreteSteps,RangeBoundsExt};
mod discrete_steps{use super::Bounded;use std::{convert::TryFrom,ops::{Bound,Range,RangeBounds,RangeInclusive}};pub trait DiscreteSteps<Delta>:Clone{fn delta()->Delta;fn steps_between(start:&Self,end:&Self)->Option<Delta>;fn forward_checked(start:Self,delta:Delta)->Option<Self>;fn backward_checked(start:Self,delta:Delta)->Option<Self>;fn forward(start:Self,delta:Delta)->Self{Self::forward_checked(start,delta).expect("overflow in `DiscreteSteps::forward`")}fn backward(start:Self,delta:Delta)->Self{Self::backward_checked(start,delta).expect("overflow in `DiscreteSteps::backward`")}fn forward_delta_checked(start:Self)->Option<Self>{Self::forward_checked(start,Self::delta())}fn backward_delta_checked(start:Self)->Option<Self>{Self::backward_checked(start,Self::delta())}fn forward_delta(start:Self)->Self{Self::forward(start,Self::delta())}fn backward_delta(start:Self)->Self{Self::backward(start,Self::delta())}}macro_rules!impl_discrete_steps_integer{(@common$u_source:ident)=>{fn delta()->$u_source{1}fn forward(start:Self,delta:$u_source)->Self{assert!(Self::forward_checked(start,delta).is_some(),"attempt to add with overflow");start.wrapping_add(delta as Self)}fn backward(start:Self,delta:$u_source)->Self{assert!(Self::backward_checked(start,delta).is_some(),"attempt to subtract with overflow");start.wrapping_sub(delta as Self)}};($u_source:ident$i_source:ident;$($u_narrower:ident$i_narrower:ident),*;$($u_wider:ident$i_wider:ident),*)=>{$(impl DiscreteSteps<$u_source>for$u_narrower{impl_discrete_steps_integer!(@common$u_source);fn steps_between(start:&Self,end:&Self)->Option<$u_source>{if*start<=*end{Some((*end-*start)as$u_source)}else{None}}fn forward_checked(start:Self,delta:$u_source)->Option<Self>{Self::try_from(delta).ok().and_then(|delta|start.checked_add(delta))}fn backward_checked(start:Self,delta:$u_source)->Option<Self>{Self::try_from(delta).ok().and_then(|delta|start.checked_sub(delta))}}impl DiscreteSteps<$u_source>for$i_narrower{impl_discrete_steps_integer!(@common$u_source);fn steps_between(start:&Self,end:&Self)->Option<$u_source>{if*start<=*end{Some((*end as$i_source).wrapping_sub(*start as$i_source)as$u_source)}else{None}}fn forward_checked(start:Self,delta:$u_source)->Option<Self>{$u_narrower::try_from(delta).ok().and_then(|delta|{let wrapped=start.wrapping_add(delta as Self);if wrapped>=start{Some(wrapped)}else{None}})}fn backward_checked(start:Self,delta:$u_source)->Option<Self>{$u_narrower::try_from(delta).ok().and_then(|delta|{let wrapped=start.wrapping_sub(delta as Self);if wrapped<=start{Some(wrapped)}else{None}})}})*$(impl DiscreteSteps<$u_source>for$u_wider{impl_discrete_steps_integer!(@common$u_source);fn steps_between(start:&Self,end:&Self)->Option<$u_source>{if*start<=*end{$u_source::try_from(*end-*start).ok()}else{None}}fn forward_checked(start:Self,delta:$u_source)->Option<Self>{start.checked_add(delta as Self)}fn backward_checked(start:Self,delta:$u_source)->Option<Self>{start.checked_sub(delta as Self)}}impl DiscreteSteps<$u_source>for$i_wider{impl_discrete_steps_integer!(@common$u_source);fn steps_between(start:&Self,end:&Self)->Option<$u_source>{if*start<=*end{end.checked_sub(*start).and_then(|result|$u_source::try_from(result).ok())}else{None}}fn forward_checked(start:Self,delta:$u_source)->Option<Self>{start.checked_add(delta as Self)}fn backward_checked(start:Self,delta:$u_source)->Option<Self>{start.checked_sub(delta as Self)}})*};}impl_discrete_steps_integer!(u16 i16;u8 i8,u16 i16,usize isize;u32 i32,u64 i64,u128 i128);impl_discrete_steps_integer!(u32 i32;u8 i8,u16 i16,u32 i32,usize isize;u64 i64,u128 i128);impl_discrete_steps_integer!(u64 i64;u8 i8,u16 i16,u32 i32,u64 i64,usize isize;u128 i128);impl_discrete_steps_integer!(u128 i128;u8 i8,u16 i16,u32 i32,u64 i64,u128 i128,usize isize;);impl_discrete_steps_integer!(usize isize;u8 i8,u16 i16,u32 i32,u64 i64,usize isize;u128 i128);pub trait RangeBoundsExt<T>{fn start_bound_included_checked(&self)->Option<T>;fn start_bound_excluded_checked(&self)->Option<T>;fn end_bound_included_checked(&self)->Option<T>;fn end_bound_excluded_checked(&self)->Option<T>;fn start_bound_included(&self)->T;fn start_bound_excluded(&self)->T;fn end_bound_included(&self)->T;fn end_bound_excluded(&self)->T;fn to_range_checked(&self)->Option<Range<T>>{match(self.start_bound_included_checked(),self.end_bound_excluded_checked()){(Some(start),Some(end))=>Some(start..end),_=>None,}}fn to_range(&self)->Range<T>{self.start_bound_included()..self.end_bound_excluded()}fn to_range_inclusive_checked(&self)->Option<RangeInclusive<T>>{match(self.start_bound_included_checked(),self.end_bound_included_checked()){(Some(start),Some(end))=>Some(start..=end),_=>None,}}fn to_range_inclusive(&self)->RangeInclusive<T>{self.start_bound_included()..=self.end_bound_included()}}macro_rules!impl_range_bounds_ext{($($source:ident=>$($target:ident)+);*$(;)?)=>{$($(impl<R>RangeBoundsExt<$target>for R where R:RangeBounds<$target>,{fn start_bound_included_checked(&self)->Option<$target>{match self.start_bound(){Bound::Included(x)=>Some(*x),Bound::Excluded(x)=>DiscreteSteps::<$source>::forward_delta_checked(*x),Bound::Unbounded=>Some(Bounded::minimum()),}}fn start_bound_excluded_checked(&self)->Option<$target>{match self.start_bound(){Bound::Included(x)=>DiscreteSteps::<$source>::backward_delta_checked(*x),Bound::Excluded(x)=>Some(*x),Bound::Unbounded=>None,}}fn end_bound_included_checked(&self)->Option<$target>{match self.end_bound(){Bound::Included(x)=>Some(*x),Bound::Excluded(x)=>DiscreteSteps::<$source>::backward_delta_checked(*x),Bound::Unbounded=>Some(Bounded::maximum()),}}fn end_bound_excluded_checked(&self)->Option<$target>{match self.end_bound(){Bound::Included(x)=>DiscreteSteps::<$source>::forward_delta_checked(*x),Bound::Excluded(x)=>Some(*x),Bound::Unbounded=>None,}}fn start_bound_included(&self)->$target{match self.start_bound(){Bound::Included(x)=>*x,Bound::Excluded(x)=>DiscreteSteps::<$source>::forward_delta(*x),Bound::Unbounded=>Bounded::minimum(),}}fn start_bound_excluded(&self)->$target{match self.start_bound(){Bound::Included(x)=>DiscreteSteps::<$source>::backward_delta(*x),Bound::Excluded(x)=>*x,Bound::Unbounded=>DiscreteSteps::<$source>::backward_delta(Bounded::minimum()),}}fn end_bound_included(&self)->$target{match self.end_bound(){Bound::Included(x)=>*x,Bound::Excluded(x)=>DiscreteSteps::<$source>::backward_delta(*x),Bound::Unbounded=>Bounded::maximum(),}}fn end_bound_excluded(&self)->$target{match self.end_bound(){Bound::Included(x)=>DiscreteSteps::<$source>::forward_delta(*x),Bound::Excluded(x)=>*x,Bound::Unbounded=>DiscreteSteps::<$source>::forward_delta(Bounded::maximum()),}}})+)*};}impl_range_bounds_ext!(u16=>u8 i8 u16 i16;u32=>u32 i32;u64=>u64 i64;u128=>u128 i128;usize=>isize usize;);}
pub use self::bitor_operation_impl::{BitOrIdentity,BitOrOperation};
mod bitor_operation_impl{use super::*;use std::{marker::PhantomData,ops::BitOr};#[doc=" |"]pub struct BitOrOperation<T:Clone+BitOrIdentity>{_marker:PhantomData<fn()->T>}pub trait BitOrIdentity:Sized+BitOr<Output=Self>{fn all_zero()->Self;}#[macro_export]macro_rules!impl_bitor_identity{([$($wh:tt)*],$t:ty,$all_zero:expr)=>{impl<$($wh)*>BitOrIdentity for$t{#[inline]fn all_zero()->Self{$all_zero}}};($t:ty,$all_zero:expr)=>{impl BitOrIdentity for$t{#[inline]fn all_zero()->Self{$all_zero}}};}impl_bitor_identity!(bool,false);impl_bitor_identity!(usize,0usize);impl_bitor_identity!(u8,0u8);impl_bitor_identity!(u16,0u16);impl_bitor_identity!(u32,0u32);impl_bitor_identity!(u64,0u64);impl_bitor_identity!(isize,0isize);impl_bitor_identity!(i8,0i8);impl_bitor_identity!(i16,0i16);impl_bitor_identity!(i32,0i32);impl_bitor_identity!(i64,0i64);impl<T:Clone+BitOrIdentity>Magma for BitOrOperation<T>{type T=T;#[inline]fn operate(x:&Self::T,y:&Self::T)->Self::T{x.clone()|y.clone()}}impl<T:Clone+BitOrIdentity>Unital for BitOrOperation<T>{#[inline]fn unit()->Self::T{BitOrIdentity::all_zero()}}impl<T:Clone+BitOrIdentity>Associative for BitOrOperation<T>{}impl<T:Clone+BitOrIdentity>Commutative for BitOrOperation<T>{}impl<T:Clone+BitOrIdentity>Idempotent for BitOrOperation<T>{}}
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