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| author | Andrew Guschin <guschin.drew@gmail.com> | 2023-04-09 18:03:28 +0400 |
|---|---|---|
| committer | Andrew Guschin <guschin.drew@gmail.com> | 2023-04-09 18:03:28 +0400 |
| commit | cf1396c9ac9a37d5f5b0821f1572be17bcca3aa7 (patch) | |
| tree | a9e6285d49dbc288d170aeb3237a78ecddeaf06f /graph-checker/src | |
| parent | 96e61039afe641e08ec524ff4cffcc911339061d (diff) | |
Changed structure of project and renamed binary
Diffstat (limited to 'graph-checker/src')
| -rw-r--r-- | graph-checker/src/main.rs | 585 |
1 files changed, 585 insertions, 0 deletions
diff --git a/graph-checker/src/main.rs b/graph-checker/src/main.rs new file mode 100644 index 0000000..e09d15f --- /dev/null +++ b/graph-checker/src/main.rs @@ -0,0 +1,585 @@ +use std::fmt; +use std::io::{self, BufRead}; +use std::time::Instant; + +struct Graph { + size: usize, + matrix: Vec<Vec<i32>>, +} + +struct Cutset { + cardinality: usize, + vertices: Vec<i32>, + graph: Graph, +} + +impl Clone for Graph { + fn clone(&self) -> Self { + let mut matrix = vec![vec![0; self.size]; self.size]; + for row in 0..self.size { + for col in 0..self.size { + matrix[row][col] = self.matrix[row][col]; + } + } + return Graph { + size: self.size, + matrix, + }; + } +} + +impl fmt::Display for Graph { + fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { + for row in 0..self.size { + for col in 0..self.size { + write!(f, "{}", self.matrix[row][col])?; + if col < self.size - 1 { + write!(f, " ")?; + } + } + if row < self.size - 1 { + write!(f, "\n")?; + } + } + return Ok(()); + } +} + +fn iterate(n: usize) -> Vec<Vec<i32>> { + let mut components = Vec::new(); + + let mut v: Vec<i32> = vec![0; n]; + loop { + let mut sum: usize = 0; + for i in &v { + sum += *i as usize; + } + + if sum == v.len() { + break; + } + + let mut k = 0; + for i in 0..v.len() { + if v[i] == 1 { + v[i] = 0; + } else { + k = i; + break; + } + } + v[k] = 1; + components.push(v.clone()); + } + + return components; +} + +impl Graph { + fn from_g6(line: &String) -> Graph { + let mut chars: Vec<u8> = Vec::new(); + for character in line.chars() { + chars.push((character as i32 - 63) as u8); + } + // TODO: spec allows multi-byte vector size + let size = chars[0] as usize; + let bytes = &chars[1..]; + + let mut matrix: Vec<Vec<i32>> = vec![vec![0; size]; size]; + let mut i = 0; + for col in 1..size { + for row in 0..col { + let bit: i32 = (bytes[i / 6] >> (5 - i % 6) & 1) as i32; + matrix[row][col] = bit; + matrix[col][row] = bit; + i += 1; + } + } + return Graph { size, matrix }; + } + + fn degree(&self, vertex: usize) -> usize { + let mut sum: usize = 0; + for i in &self.matrix[vertex] { + sum += if *i == 0 { 0 } else { 1 } as usize; + } + return sum; + } + + fn min_degree(&self) -> usize { + let mut min = self.size + 1; + for i in 0..self.size { + let d = self.degree(i); + if d < min { + min = d; + } + } + return min; + } + + fn get_closure_traced(&self, trace_steps: bool) -> Graph { + let mut step = if trace_steps { 2 } else { 1 }; + + let mut closure = self.clone(); + for _ in 0..(closure.size * closure.size) { + let mut changed = false; + for row in 0..closure.size { + for col in 0..closure.size { + if row == col || closure.matrix[row][col] != 0 { + continue; + } + let sum = closure.degree(row) + closure.degree(col); + if sum >= closure.size { + closure.matrix[row][col] = step; + if trace_steps { + step += 1; + } + changed = true; + } + } + } + if !changed { + break; + } + } + return closure; + } + + fn get_hamiltonian_cycle(&self) -> Vec<usize> { + let closure = self.get_closure_traced(true); + + let mut cycle = Vec::new(); + for i in 0..self.size - 1 { + cycle.push(i + 1); + } + cycle.push(0); + + loop { + let mut start = 0; + let mut m = 0; + + let mut end = start; + let mut new_start = start; + let mut current = start; + loop { + let next = cycle[current]; + let val = closure.matrix[current][next]; + // println!("{current} -> {next} = {val}"); + if val > m { + m = val; + end = current; + new_start = next; + } + current = next; + if current == start { + break; + } + } + if m == 1 { + break; + } + // println!("New start: {new_start}, end: {end}, m = {m}"); + start = new_start; + + let mut s = start; + let mut current = cycle[start]; + while current != end { + let next = cycle[current]; + let u1 = closure.matrix[start][next]; + let u2 = closure.matrix[end][current]; + if u1 < m && u2 < m { + s = current; + break; + } + current = next; + } + // println!("s = {s}"); + + let mut new_cycle = Vec::new(); + new_cycle.push(start); + let mut current = cycle[s]; + while current != end { + new_cycle.push(current); + current = cycle[current]; + } + new_cycle.push(end); + { + let mut tmp = Vec::new(); + let mut current = cycle[start]; + while current != s { + tmp.push(current); + current = cycle[current]; + } + tmp.push(s); + tmp.reverse(); + for i in tmp { + new_cycle.push(i); + } + } + for i in 0..self.size - 1 { + cycle[new_cycle[i]] = new_cycle[i + 1]; + } + cycle[new_cycle[self.size - 1]] = new_cycle[0]; + } + + return cycle; + } + + fn cutsets(&self) -> Vec<Cutset> { + let mut cs = Vec::new(); + for vertices in iterate(self.size) { + let mut g = self.clone(); + for vertex in 0..g.size { + for i in 0..g.size { + if vertices[vertex] == 0 { + g.matrix[vertex as usize][i as usize] = 0; + g.matrix[i as usize][vertex as usize] = 0; + } + } + } + let cardinality = vertices.iter().sum::<i32>() as usize; + cs.push(Cutset { + cardinality, + vertices: vertices.clone(), + graph: g, + }); + } + return cs; + } + + fn max_independent_cutset(&self) -> Cutset { + let mut max_cutset = None; + for cutset in self.cutsets() { + if cutset.graph.is_independent() { + match &max_cutset { + None => max_cutset = Some(cutset), + Some(m_cutset) => { + if cutset.cardinality > m_cutset.cardinality { + max_cutset = Some(cutset); + } + } + }; + } + } + return max_cutset.unwrap(); + } + + fn dfs(&self, vertex: &usize, visited: &mut Vec<usize>) { + visited[*vertex] = 1; + for i in 0..self.size { + if visited[i] == 0 && self.matrix[*vertex][i] != 0 { + self.dfs(&i, visited); + } + } + } + + fn count_components_partial(&self, included_vertices: &Vec<i32>) -> usize { + let mut visited = vec![0; self.size]; + for i in 0..included_vertices.len() { + if included_vertices[i] == 0 { + visited[i] = 1; + } + } + let mut count = 0; + while visited.iter().sum::<usize>() != visited.len() { + let mut next = 0; + for i in 0..self.size { + if visited[i] == 0 { + next = i; + break; + } + } + self.dfs(&next, &mut visited); + count += 1; + } + return count; + } + + fn count_components(&self) -> usize { + self.count_components_partial(&vec![1; self.size]) + } + + fn get_closure(&self) -> Graph { + self.get_closure_traced(false) + } + + fn check_toughness(&self, t: f64) -> bool { + for cutset in self.cutsets() { + let components_count = cutset.graph.count_components_partial(&cutset.vertices) as f64; + let cut_cardinality = (self.size - cutset.cardinality) as f64; + if components_count > 1.0 && cut_cardinality < t * components_count { + return false; + } + } + return true; + } + + fn get_toughness(&self) -> f64 { + let mut left: f64 = 0.0; + let mut right: f64 = 1024.0; // Reasonable limit + let eps: f64 = 1e-9; + + while (right - left).abs() > eps { + let mid = (left + right) / 2.0; + + if self.check_toughness(mid) == false { + right = mid; + } else { + left = mid; + } + } + + return (left * 1e7).round() / 1e7; + } + + fn is_complete(&self) -> bool { + for row in 0..self.size { + for col in 0..self.size { + if row != col && self.matrix[row][col] == 0 { + return false; + } + } + } + return true; + } + + fn is_independent(&self) -> bool { + for row in 0..self.size { + for col in 0..self.size { + if row != col && self.matrix[row][col] != 0 { + return false; + } + } + } + return true; + } +} + +struct Counters { + graphs: i32, + tough_1: i32, + tough_2: i32, + bch_hamiltonian: i32, + t15_hamiltonian: i32, + t25_hamiltonian: i32, + dirac_hamiltonian: i32, + ore_hamiltonian: i32, + posa_hamiltonian: i32, +} + +impl Counters { + fn new() -> Counters { + return Counters { + graphs: 0, + tough_1: 0, + tough_2: 0, + bch_hamiltonian: 0, + t15_hamiltonian: 0, + t25_hamiltonian: 0, + dirac_hamiltonian: 0, + ore_hamiltonian: 0, + posa_hamiltonian: 0, + }; + } +} + +fn theorem15(g: &Graph, toughness: f64, min_degree: f64) -> bool { + let max_ind_cutset_size = g.max_independent_cutset().cardinality as f64; + let third_of_size = g.size as f64 / 3.0; + let tmp = if third_of_size > max_ind_cutset_size - 1.0 { + third_of_size + } else { + max_ind_cutset_size - 1.0 + }; + + return toughness >= 1.0 && min_degree >= tmp; +} + +fn theorem25(g: &Graph, toughness: f64, min_degree: f64) -> bool { + return min_degree > g.size as f64 / (toughness + 1.0) - 1.0; +} + +fn dirac_theorem(g: &Graph) -> bool { + for vertex in 0..g.size { + if (g.degree(vertex) as f64) < g.size as f64 / 2.0 { + return false; + } + } + return true; +} + +fn ore_theorem(g: &Graph) -> bool { + for v1 in 0..g.size { + for v2 in 0..g.size { + if v1 == v2 || g.matrix[v1][v2] != 0 { + continue; + } + let d1 = g.degree(v1); + let d2 = g.degree(v2); + if d1 + d2 < g.size { + return false; + } + } + } + return true; +} + +fn posa_theorem(g: &Graph) -> bool { + let mut degrees = Vec::new(); + for v in 0..g.size { + degrees.push(g.degree(v)); + } + + let end = if g.size % 2 == 0 { + g.size / 2 + } else { + (g.size - 1) / 2 + }; + + for k in 1..end { + let mut cnt = 0; + for d in °rees { + if *d <= k { + cnt += 1; + } + } + if cnt >= k { + return false; + } + } + if g.size % 2 != 0 { + let mut cnt = 0; + for d in °rees { + if *d <= end { + cnt += 1; + } + } + if cnt > end { + return false; + } + } + return true; +} + +fn main() { + let stdin = io::stdin(); + + let mut time = 0; + let mut counters = Counters::new(); + + for line in stdin.lock().lines() { + let line = line.unwrap(); + + let g = Graph::from_g6(&line); + counters.graphs += 1; + + let start = Instant::now(); + let closure = g.get_closure(); + let is_complete = closure.is_complete(); + + let toughness = if g.is_complete() { + f64::MAX + } else { + g.get_toughness() + }; + + if toughness >= 1.0 { + counters.tough_1 += 1; + } + if toughness >= 2.0 { + counters.tough_2 += 1; + } + + let min_degree = g.min_degree() as f64; + + if theorem15(&g, toughness, min_degree) { + counters.t15_hamiltonian += 1; + println!("g6:bigalke-jung:{}", line); + } + + if theorem25(&g, toughness, min_degree) { + counters.t25_hamiltonian += 1; + println!("g6:bauer:{}", line); + } + + if dirac_theorem(&g) { + counters.dirac_hamiltonian += 1; + println!("g6:dirac:{}", line); + } + + if ore_theorem(&g) { + counters.ore_hamiltonian += 1; + println!("g6:ore:{}", line); + } + + if posa_theorem(&g) { + counters.posa_hamiltonian += 1; + println!("g6:posa:{}", line); + } + + if is_complete { + counters.bch_hamiltonian += 1; + println!("g6:bondy-chvatal:{}", line); + } + + if is_complete && false { + println!("Graph: {line}\n{g}"); + + let components_count = g.count_components(); + println!("Components count: {components_count}"); + let min_degree = g.min_degree(); + println!("Minimal degree: {min_degree}"); + + let cutset = g.max_independent_cutset(); + println!("Maximal independent cutset:\n{}", cutset.graph); + println!("Included vertices: {:?}", cutset.vertices); + println!("Cutset cardinality: {}", cutset.cardinality); + + let cycle = g.get_hamiltonian_cycle(); + print!("Hamiltonian cycle: "); + let start = 0; + let mut current = start; + loop { + print!("{}", current + 1); + print!(" -> "); + current = cycle[current]; + if current == start { + println!("{}", current + 1); + break; + } + } + } + + let elapsed = start.elapsed(); + time += elapsed.as_nanos(); + } + + println!("Total count of graphs: {}", counters.graphs); + println!("Count of 1-tough graphs: {}", counters.tough_1); + println!("Count of 2-tough graphs: {}", counters.tough_2); + println!( + "Count of Dirac's Hamiltonian graphs: {}", + counters.dirac_hamiltonian + ); + println!( + "Count of Ore's Hamiltonian graphs: {}", + counters.ore_hamiltonian + ); + println!( + "Count of Posa's Hamiltonian graphs: {}", + counters.posa_hamiltonian + ); + println!( + "Count of Bondy-Chvatal Hamiltonian graphs: {}", + counters.bch_hamiltonian + ); + println!( + "Count of Theorem 15 Hamiltonian graphs: {}", + counters.t15_hamiltonian + ); + println!( + "Count of Theorem 25 Hamiltonian graphs: {}", + counters.t25_hamiltonian + ); + println!("Time elapsed: {}s", time as f64 / 1e9); +} |