src/simple_paths.rs - third_party/github.com/petgraph/petgraph - Git at Google

 use std::{
     hash::Hash,
     iter::{from_fn, FromIterator},
 };

 use indexmap::IndexSet;

 use crate::{
     visit::{IntoNeighborsDirected, NodeCount},
     Direction::Outgoing,
 };

 /// Returns iterator that produces all simple paths from `from` node to `to`, which contains at least `min_intermediate_nodes` nodes
 /// and at most `max_intermediate_nodes`, if given, limited by graph's order otherwise
 /// Simple path is path without repetitions
 /// Algorithm is adopted from https://networkx.github.io/documentation/stable/reference/algorithms/generated/networkx.algorithms.simple_paths.all_simple_paths.html
 pub fn all_simple_paths<TargetColl, G>(
     graph: G,
     from: G::NodeId,
     to: G::NodeId,
     min_intermediate_nodes: usize,
     max_intermediate_nodes: Option<usize>,
 ) -> impl Iterator<Item = TargetColl>
 where
     G: NodeCount,
     G: IntoNeighborsDirected,
     G::NodeId: Eq + Hash,
     TargetColl: FromIterator<G::NodeId>,
 {
     // how many nodes are allowed in simple path up to target node
     // it is min/max allowed path length minus one, because it is more appropriate when implementing lookahead
     // than constantly add 1 to length of current path
     let max_length = if let Some(l) = max_intermediate_nodes {
         l + 1
     } else {
         graph.node_count() - 1
     };

     let min_length = min_intermediate_nodes + 1;

     // list of visited nodes
     let mut visited: IndexSet<G::NodeId> = IndexSet::from_iter(Some(from));
     // list of childs of currently exploring path nodes,
     // last elem is list of childs of last visited node
     let mut stack = vec![graph.neighbors_directed(from, Outgoing)];

     from_fn(move || {
         while let Some(children) = stack.last_mut() {
             if let Some(child) = children.next() {
                 if visited.len() < max_length {
                     if child == to {
                         if visited.len() >= min_length {
                             let path = visited
                                 .iter()
                                 .cloned()
                                 .chain(Some(to))
                                 .collect::<TargetColl>();
                             return Some(path);
                         }
                     } else if !visited.contains(&child) {
                         visited.insert(child);
                         stack.push(graph.neighbors_directed(child, Outgoing));
                     }
                 } else {
                     if (child == to || children.any(|v| v == to)) && visited.len() >= min_length {
                         let path = visited
                             .iter()
                             .cloned()
                             .chain(Some(to))
                             .collect::<TargetColl>();
                         return Some(path);
                     }
                     stack.pop();
                     visited.pop();
                 }
             } else {
                 stack.pop();
                 visited.pop();
             }
         }
         None
     })
 }

 #[cfg(test)]
 mod test {
     use std::{collections::HashSet, iter::FromIterator};

     use itertools::assert_equal;

     use crate::{dot::Dot, prelude::DiGraph};

     use super::all_simple_paths;

     #[test]
     fn test_all_simple_paths() {
         let graph = DiGraph::<i32, i32, _>::from_edges(&[
             (0, 1),
             (0, 2),
             (0, 3),
             (1, 2),
             (1, 3),
             (2, 3),
             (2, 4),
             (3, 2),
             (3, 4),
             (4, 2),
             (4, 5),
             (5, 2),
             (5, 3),
         ]);

         let expexted_simple_paths_0_to_5 = vec![
             vec![0usize, 1, 2, 3, 4, 5],
             vec![0, 1, 2, 4, 5],
             vec![0, 1, 3, 2, 4, 5],
             vec![0, 1, 3, 4, 5],
             vec![0, 2, 3, 4, 5],
             vec![0, 2, 4, 5],
             vec![0, 3, 2, 4, 5],
             vec![0, 3, 4, 5],
         ];

         println!("{}", Dot::new(&graph));
         let actual_simple_paths_0_to_5: HashSet<Vec<_>> =
             all_simple_paths(&graph, 0u32.into(), 5u32.into(), 0, None)
                 .map(|v: Vec<_>| v.into_iter().map(|i| i.index()).collect())
                 .collect();
         assert_eq!(actual_simple_paths_0_to_5.len(), 8);
         assert_eq!(
             HashSet::from_iter(expexted_simple_paths_0_to_5),
             actual_simple_paths_0_to_5
         );
     }

     #[test]
     fn test_one_simple_path() {
         let graph = DiGraph::<i32, i32, _>::from_edges(&[(0, 1), (2, 1)]);

         let expexted_simple_paths_0_to_1 = &[vec![0usize, 1]];
         println!("{}", Dot::new(&graph));
         let actual_simple_paths_0_to_1: Vec<Vec<_>> =
             all_simple_paths(&graph, 0u32.into(), 1u32.into(), 0, None)
                 .map(|v: Vec<_>| v.into_iter().map(|i| i.index()).collect())
                 .collect();

         assert_eq!(actual_simple_paths_0_to_1.len(), 1);
         assert_equal(expexted_simple_paths_0_to_1, &actual_simple_paths_0_to_1);
     }

     #[test]
     fn test_no_simple_paths() {
         let graph = DiGraph::<i32, i32, _>::from_edges(&[(0, 1), (2, 1)]);

         println!("{}", Dot::new(&graph));
         let actual_simple_paths_0_to_2: Vec<Vec<_>> =
             all_simple_paths(&graph, 0u32.into(), 2u32.into(), 0, None)
                 .map(|v: Vec<_>| v.into_iter().map(|i| i.index()).collect())
                 .collect();

         assert_eq!(actual_simple_paths_0_to_2.len(), 0);
     }
 }
	use std::{
	hash::Hash,
	iter::{from_fn, FromIterator},
	};

	use indexmap::IndexSet;

	use crate::{
	visit::{IntoNeighborsDirected, NodeCount},
	Direction::Outgoing,
	};

	/// Returns iterator that produces all simple paths from `from` node to `to`, which contains at least `min_intermediate_nodes` nodes
	/// and at most `max_intermediate_nodes`, if given, limited by graph's order otherwise
	/// Simple path is path without repetitions
	/// Algorithm is adopted from https://networkx.github.io/documentation/stable/reference/algorithms/generated/networkx.algorithms.simple_paths.all_simple_paths.html
	pub fn all_simple_paths<TargetColl, G>(
	graph: G,
	from: G::NodeId,
	to: G::NodeId,
	min_intermediate_nodes: usize,
	max_intermediate_nodes: Option<usize>,
	) -> impl Iterator<Item = TargetColl>
	where
	G: NodeCount,
	G: IntoNeighborsDirected,
	G::NodeId: Eq + Hash,
	TargetColl: FromIterator<G::NodeId>,
	{
	// how many nodes are allowed in simple path up to target node
	// it is min/max allowed path length minus one, because it is more appropriate when implementing lookahead
	// than constantly add 1 to length of current path
	let max_length = if let Some(l) = max_intermediate_nodes {
	l + 1
	} else {
	graph.node_count() - 1
	};

	let min_length = min_intermediate_nodes + 1;

	// list of visited nodes
	let mut visited: IndexSet<G::NodeId> = IndexSet::from_iter(Some(from));
	// list of childs of currently exploring path nodes,
	// last elem is list of childs of last visited node
	let mut stack = vec![graph.neighbors_directed(from, Outgoing)];

	from_fn(move \|\| {
	while let Some(children) = stack.last_mut() {
	if let Some(child) = children.next() {
	if visited.len() < max_length {
	if child == to {
	if visited.len() >= min_length {
	let path = visited
	.iter()
	.cloned()
	.chain(Some(to))
	.collect::<TargetColl>();
	return Some(path);
	}
	} else if !visited.contains(&child) {
	visited.insert(child);
	stack.push(graph.neighbors_directed(child, Outgoing));
	}
	} else {
	if (child == to \|\| children.any(\|v\| v == to)) && visited.len() >= min_length {
	let path = visited
	.iter()
	.cloned()
	.chain(Some(to))
	.collect::<TargetColl>();
	return Some(path);
	}
	stack.pop();
	visited.pop();
	}
	} else {
	stack.pop();
	visited.pop();
	}
	}
	None
	})
	}

	#[cfg(test)]
	mod test {
	use std::{collections::HashSet, iter::FromIterator};

	use itertools::assert_equal;

	use crate::{dot::Dot, prelude::DiGraph};

	use super::all_simple_paths;

	#[test]
	fn test_all_simple_paths() {
	let graph = DiGraph::<i32, i32, _>::from_edges(&[
	(0, 1),
	(0, 2),
	(0, 3),
	(1, 2),
	(1, 3),
	(2, 3),
	(2, 4),
	(3, 2),
	(3, 4),
	(4, 2),
	(4, 5),
	(5, 2),
	(5, 3),
	]);

	let expexted_simple_paths_0_to_5 = vec![
	vec![0usize, 1, 2, 3, 4, 5],
	vec![0, 1, 2, 4, 5],
	vec![0, 1, 3, 2, 4, 5],
	vec![0, 1, 3, 4, 5],
	vec![0, 2, 3, 4, 5],
	vec![0, 2, 4, 5],
	vec![0, 3, 2, 4, 5],
	vec![0, 3, 4, 5],
	];

	println!("{}", Dot::new(&graph));
	let actual_simple_paths_0_to_5: HashSet<Vec<_>> =
	all_simple_paths(&graph, 0u32.into(), 5u32.into(), 0, None)
	.map(\|v: Vec<_>\| v.into_iter().map(\|i\| i.index()).collect())
	.collect();
	assert_eq!(actual_simple_paths_0_to_5.len(), 8);
	assert_eq!(
	HashSet::from_iter(expexted_simple_paths_0_to_5),
	actual_simple_paths_0_to_5
	);
	}

	#[test]
	fn test_one_simple_path() {
	let graph = DiGraph::<i32, i32, _>::from_edges(&[(0, 1), (2, 1)]);

	let expexted_simple_paths_0_to_1 = &[vec![0usize, 1]];
	println!("{}", Dot::new(&graph));
	let actual_simple_paths_0_to_1: Vec<Vec<_>> =
	all_simple_paths(&graph, 0u32.into(), 1u32.into(), 0, None)
	.map(\|v: Vec<_>\| v.into_iter().map(\|i\| i.index()).collect())
	.collect();

	assert_eq!(actual_simple_paths_0_to_1.len(), 1);
	assert_equal(expexted_simple_paths_0_to_1, &actual_simple_paths_0_to_1);
	}

	#[test]
	fn test_no_simple_paths() {
	let graph = DiGraph::<i32, i32, _>::from_edges(&[(0, 1), (2, 1)]);

	println!("{}", Dot::new(&graph));
	let actual_simple_paths_0_to_2: Vec<Vec<_>> =
	all_simple_paths(&graph, 0u32.into(), 2u32.into(), 0, None)
	.map(\|v: Vec<_>\| v.into_iter().map(\|i\| i.index()).collect())
	.collect();

	assert_eq!(actual_simple_paths_0_to_2.len(), 0);
	}
	}