use std::collections::BTreeSet; fn main() { let mut sc = Scanner::new(); let n = sc.usize(); let m = sc.usize(); let edges = sc.edges(m); let mut in_cnt = vec![0; n]; let mut out_cnt = vec![0; n]; for &(a, b) in &edges { out_cnt[a] += 1; in_cnt[b] += 1; } // for i in 0..n { eprintln!("{} : {} {}", i, in_cnt[i], out_cnt[i]); } let mut ng = BTreeSet::new(); for i in 0..n { if in_cnt[i] == out_cnt[i] { continue } ng.insert((in_cnt[i] - out_cnt[i], i)); } // eprintln!("{:?}", ng); let mut ans = 0; while ng.len() > 2 { let (max, i) = *ng.iter().next_back().unwrap(); let (min, j) = *ng.iter().next().unwrap(); if signum(max) == signum(min) { break } let diff = max.min(-min); ng.remove(&(max, i)); ng.remove(&(min, j)); out_cnt[i] += diff; in_cnt[j] += diff; ans += diff; if max > diff { if max - diff != 0 { ng.insert((max - diff, i)); } } else { if min + diff != 0 { ng.insert((min + diff, j)); } } } // eprintln!("{:?}", ng); if ng.len() == 0 { println!("{}", ans); } else if ng.len() == 1 { let (c, _) = *ng.iter().next().unwrap(); println!("{}", ans + 1.max(c)); } else if ng.len() == 2 { let (max, _) = *ng.iter().next_back().unwrap(); let (min, _) = *ng.iter().next().unwrap(); if signum(max) == signum(min) { println!("{}", ans + max.abs() + min.abs()); } else { if max == -min { println!("{}", ans + max.abs() - 1); } else { let diff = max.min(-min); let m = max.max(-min); println!("{}", ans + diff + (m - diff)); } } } } fn signum(x: i64) -> i64 { if x == 0 { 0 } else if x > 0 { 1 } else { -1 } } struct Scanner { s : std::collections::VecDeque } #[allow(unused)] impl Scanner { fn new() -> Self { use std::io::Read; let mut s = String::new(); std::io::stdin().read_to_string(&mut s).unwrap(); Self { s : s.split_whitespace().map(|s| s.to_string()).collect() } } fn reload(&mut self) -> () { use std::io::Read; let mut s = String::new(); std::io::stdin().read_to_string(&mut s).unwrap(); self.s = s.split_whitespace().map(|s| s.to_string()).collect(); } fn usize(&mut self) -> usize { self.input() } fn usize1(&mut self) -> usize { self.input::() - 1 } fn isize(&mut self) -> isize { self.input() } fn i32(&mut self) -> i32 { self.input() } fn i64(&mut self) -> i64 { self.input() } fn i128(&mut self) -> i128 { self.input() } fn u8(&mut self) -> u8 { self.input() } fn u32(&mut self) -> u32 { self.input() } fn u64(&mut self) -> u64 { self.input() } fn u128(&mut self) -> u128 { self.input() } fn edge(&mut self) -> (usize, usize) { (self.usize1(), self.usize1()) } fn edges(&mut self, m : usize) -> Vec<(usize, usize)> { let mut e = Vec::with_capacity(m); for _ in 0..m { e.push(self.edge()); } e } fn wedge(&mut self) -> (usize, usize, T) { (self.usize1(), self.usize1(), self.input()) } fn wedges(&mut self, m : usize) -> Vec<(usize, usize, T)> { let mut e = Vec::with_capacity(m); for _ in 0..m { e.push(self.wedge()); } e } fn input(&mut self) -> T where T: std::str::FromStr { if self.s.is_empty() { self.reload(); } if let Some(head) = self.s.pop_front() { head.parse::().ok().unwrap() } else { panic!() } } fn tuple(&mut self) -> (T, U) where T: std::str::FromStr, U: std::str::FromStr { (self.input(), self.input()) } fn vec(&mut self, n: usize) -> Vec where T: std::str::FromStr { if self.s.is_empty() { self.reload(); } self.s.drain(..n).map(|s| s.parse::().ok().unwrap() ).collect::>() } fn nvec(&mut self) -> Vec where T: std::str::FromStr { let n : usize = self.input(); self.vec(n) } fn chars(&mut self) -> Vec { let s : String = self.input(); s.chars().collect() } fn bytes(&mut self) -> Vec { let s : String = self.input(); s.bytes().collect() } }