upstream/mercurial-mirror Files · rust/hg-core/src/dagops.rs

rust-status: refactor dispatch case for normal files...

rust-status: refactor dispatch case for normal files This should make the code easier to read and more idiomatic. Differential Revision: https://phab.mercurial-scm.org/D7300

Yuya Nishihara - - Load All Authors

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      // dagops.rs

      //

      // Copyright 2019 Georges Racinet <georges.racinet@octobus.net>

      //

      // This software may be used and distributed according to the terms of the

      // GNU General Public License version 2 or any later version.

      //! Miscellaneous DAG operations

      //!

      //! # Terminology

      //! - By *relative heads* of a collection of revision numbers (`Revision`), we

      //!   mean those revisions that have no children among the collection.

      //! - Similarly *relative roots* of a collection of `Revision`, we mean those

      //!   whose parents, if any, don't belong to the collection.

      use super::{Graph, GraphError, Revision, NULL_REVISION};

      use crate::ancestors::AncestorsIterator;

      use std::collections::{BTreeSet, HashSet};

      fn remove_parents(

          graph: &impl Graph,

          rev: Revision,

          set: &mut HashSet<Revision>,

      ) -> Result<(), GraphError> {

          for parent in graph.parents(rev)?.iter() {

              if *parent != NULL_REVISION {

                  set.remove(parent);

              }

          }

          Ok(())

      }

      /// Relative heads out of some revisions, passed as an iterator.

      ///

      /// These heads are defined as those revisions that have no children

      /// among those emitted by the iterator.

      ///

      /// # Performance notes

      /// Internally, this clones the iterator, and builds a `HashSet` out of it.

      ///

      /// This function takes an `Iterator` instead of `impl IntoIterator` to

      /// guarantee that cloning the iterator doesn't result in cloning the full

      /// construct it comes from.

      pub fn heads<'a>(

          graph: &impl Graph,

          iter_revs: impl Clone + Iterator<Item = &'a Revision>,

      ) -> Result<HashSet<Revision>, GraphError> {

          let mut heads: HashSet<Revision> = iter_revs.clone().cloned().collect();

          heads.remove(&NULL_REVISION);

          for rev in iter_revs {

              if *rev != NULL_REVISION {

                  remove_parents(graph, *rev, &mut heads)?;

              }

          }

          Ok(heads)

      }

      /// Retain in `revs` only its relative heads.

      ///

      /// This is an in-place operation, so that control of the incoming

      /// set is left to the caller.

      /// - a direct Python binding would probably need to build its own `HashSet`

      ///   from an incoming iterable, even if its sole purpose is to extract the

      ///   heads.

      /// - a Rust caller can decide whether cloning beforehand is appropriate

      ///

      /// # Performance notes

      /// Internally, this function will store a full copy of `revs` in a `Vec`.

      pub fn retain_heads(

          graph: &impl Graph,

          revs: &mut HashSet<Revision>,

      ) -> Result<(), GraphError> {

          revs.remove(&NULL_REVISION);

          // we need to construct an iterable copy of revs to avoid itering while

          // mutating

          let as_vec: Vec<Revision> = revs.iter().cloned().collect();

          for rev in as_vec {

              if rev != NULL_REVISION {

                  remove_parents(graph, rev, revs)?;

              }

          }

          Ok(())

      }

      /// Roots of `revs`, passed as a `HashSet`

      ///

      /// They are returned in arbitrary order

      pub fn roots<G: Graph>(

          graph: &G,

          revs: &HashSet<Revision>,

      ) -> Result<Vec<Revision>, GraphError> {

          let mut roots: Vec<Revision> = Vec::new();

          for rev in revs {

              if graph

                  .parents(*rev)?

                  .iter()

                  .filter(|p| **p != NULL_REVISION)

                  .all(|p| !revs.contains(p))

              {

                  roots.push(*rev);

              }

          }

          Ok(roots)

      }

      /// Compute the topological range between two collections of revisions

      ///

      /// This is equivalent to the revset `<roots>::<heads>`.

      ///

      /// Currently, the given `Graph` has to implement `Clone`, which means

      /// actually cloning just a reference-counted Python pointer if

      /// it's passed over through `rust-cpython`. This is due to the internal

      /// use of `AncestorsIterator`

      ///

      /// # Algorithmic details

      ///

      /// This is a two-pass swipe inspired from what `reachableroots2` from

      /// `mercurial.cext.parsers` does to obtain the same results.

      ///

      /// - first, we climb up the DAG from `heads` in topological order, keeping

      ///   them in the vector `heads_ancestors` vector, and adding any element of

      ///   `roots` we find among them to the resulting range.

      /// - Then, we iterate on that recorded vector so that a revision is always

      ///   emitted after its parents and add all revisions whose parents are already

      ///   in the range to the results.

      ///

      /// # Performance notes

      ///

      /// The main difference with the C implementation is that

      /// the latter uses a flat array with bit flags, instead of complex structures

      /// like `HashSet`, making it faster in most scenarios. In theory, it's

      /// possible that the present implementation could be more memory efficient

      /// for very large repositories with many branches.

      pub fn range(

          graph: &(impl Graph + Clone),

          roots: impl IntoIterator<Item = Revision>,

          heads: impl IntoIterator<Item = Revision>,

      ) -> Result<BTreeSet<Revision>, GraphError> {

          let mut range = BTreeSet::new();

          let roots: HashSet<Revision> = roots.into_iter().collect();

          let min_root: Revision = match roots.iter().cloned().min() {

              None => {

                  return Ok(range);

              }

              Some(r) => r,

          };

          // Internally, AncestorsIterator currently maintains a `HashSet`

          // of all seen revision, which is also what we record, albeit in an ordered

          // way. There's room for improvement on this duplication.

          let ait = AncestorsIterator::new(graph.clone(), heads, min_root, true)?;

          let mut heads_ancestors: Vec<Revision> = Vec::new();

          for revres in ait {

              let rev = revres?;

              if roots.contains(&rev) {

                  range.insert(rev);

              }

              heads_ancestors.push(rev);

          }

          for rev in heads_ancestors.into_iter().rev() {

              for parent in graph.parents(rev)?.iter() {

                  if *parent != NULL_REVISION && range.contains(parent) {

                      range.insert(rev);

                  }

              }

          }

          Ok(range)

      }

      #[cfg(test)]

      mod tests {

          use super::*;

          use crate::testing::SampleGraph;

          /// Apply `retain_heads()` to the given slice and return as a sorted `Vec`

          fn retain_heads_sorted(

              graph: &impl Graph,

              revs: &[Revision],

          ) -> Result<Vec<Revision>, GraphError> {

              let mut revs: HashSet<Revision> = revs.iter().cloned().collect();

              retain_heads(graph, &mut revs)?;

              let mut as_vec: Vec<Revision> = revs.iter().cloned().collect();

              as_vec.sort();

              Ok(as_vec)

          }

          #[test]

          fn test_retain_heads() -> Result<(), GraphError> {

              assert_eq!(retain_heads_sorted(&SampleGraph, &[4, 5, 6])?, vec![5, 6]);

              assert_eq!(

                  retain_heads_sorted(&SampleGraph, &[4, 1, 6, 12, 0])?,

                  vec![1, 6, 12]

              );

              assert_eq!(

                  retain_heads_sorted(&SampleGraph, &[1, 2, 3, 4, 5, 6, 7, 8, 9])?,

                  vec![3, 5, 8, 9]

              );

              Ok(())

          }

          /// Apply `heads()` to the given slice and return as a sorted `Vec`

          fn heads_sorted(

              graph: &impl Graph,

              revs: &[Revision],

          ) -> Result<Vec<Revision>, GraphError> {

              let heads = heads(graph, revs.iter())?;

              let mut as_vec: Vec<Revision> = heads.iter().cloned().collect();

              as_vec.sort();

              Ok(as_vec)

          }

          #[test]

          fn test_heads() -> Result<(), GraphError> {

              assert_eq!(heads_sorted(&SampleGraph, &[4, 5, 6])?, vec![5, 6]);

              assert_eq!(

                  heads_sorted(&SampleGraph, &[4, 1, 6, 12, 0])?,

                  vec![1, 6, 12]

              );

              assert_eq!(

                  heads_sorted(&SampleGraph, &[1, 2, 3, 4, 5, 6, 7, 8, 9])?,

                  vec![3, 5, 8, 9]

              );

              Ok(())

          }

          /// Apply `roots()` and sort the result for easier comparison

          fn roots_sorted(

              graph: &impl Graph,

              revs: &[Revision],

          ) -> Result<Vec<Revision>, GraphError> {

              let mut as_vec = roots(graph, &revs.iter().cloned().collect())?;

              as_vec.sort();

              Ok(as_vec)

          }

          #[test]

          fn test_roots() -> Result<(), GraphError> {

              assert_eq!(roots_sorted(&SampleGraph, &[4, 5, 6])?, vec![4]);

              assert_eq!(

                  roots_sorted(&SampleGraph, &[4, 1, 6, 12, 0])?,

                  vec![0, 4, 12]

              );

              assert_eq!(

                  roots_sorted(&SampleGraph, &[1, 2, 3, 4, 5, 6, 7, 8, 9])?,

                  vec![1, 8]

              );

              Ok(())

          }

          /// Apply `range()` and convert the result into a Vec for easier comparison

          fn range_vec(

              graph: impl Graph + Clone,

              roots: &[Revision],

              heads: &[Revision],

          ) -> Result<Vec<Revision>, GraphError> {

              range(&graph, roots.iter().cloned(), heads.iter().cloned())

                  .map(|bs| bs.into_iter().collect())

          }

          #[test]

          fn test_range() -> Result<(), GraphError> {

              assert_eq!(range_vec(SampleGraph, &[0], &[4])?, vec![0, 1, 2, 4]);

              assert_eq!(range_vec(SampleGraph, &[0], &[8])?, vec![]);

              assert_eq!(

                  range_vec(SampleGraph, &[5, 6], &[10, 11, 13])?,

                  vec![5, 10]

              );

              assert_eq!(

                  range_vec(SampleGraph, &[5, 6], &[10, 12])?,

                  vec![5, 6, 9, 10, 12]

              );

              Ok(())

          }

      }

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				// dagops.rs
				//
				// Copyright 2019 Georges Racinet <georges.racinet@octobus.net>
				//
				// This software may be used and distributed according to the terms of the
				// GNU General Public License version 2 or any later version.

				//! Miscellaneous DAG operations
				//!
				//! # Terminology
				//! - By relative heads of a collection of revision numbers (`Revision`), we
				//! mean those revisions that have no children among the collection.
				//! - Similarly relative roots of a collection of `Revision`, we mean those
				//! whose parents, if any, don't belong to the collection.
				use super::{Graph, GraphError, Revision, NULL_REVISION};
				use crate::ancestors::AncestorsIterator;
				use std::collections::{BTreeSet, HashSet};

				fn remove_parents(
				graph: &impl Graph,
				rev: Revision,
				set: &mut HashSet<Revision>,
				) -> Result<(), GraphError> {
				for parent in graph.parents(rev)?.iter() {
				if *parent != NULL_REVISION {
				set.remove(parent);
				}
				}
				Ok(())
				}

				/// Relative heads out of some revisions, passed as an iterator.
				///
				/// These heads are defined as those revisions that have no children
				/// among those emitted by the iterator.
				///
				/// # Performance notes
				/// Internally, this clones the iterator, and builds a `HashSet` out of it.
				///
				/// This function takes an `Iterator` instead of `impl IntoIterator` to
				/// guarantee that cloning the iterator doesn't result in cloning the full
				/// construct it comes from.
				pub fn heads<'a>(
				graph: &impl Graph,
				iter_revs: impl Clone + Iterator<Item = &'a Revision>,
				) -> Result<HashSet<Revision>, GraphError> {
				let mut heads: HashSet<Revision> = iter_revs.clone().cloned().collect();
				heads.remove(&NULL_REVISION);
				for rev in iter_revs {
				if *rev != NULL_REVISION {
				remove_parents(graph, *rev, &mut heads)?;
				}
				}
				Ok(heads)
				}

				/// Retain in `revs` only its relative heads.
				///
				/// This is an in-place operation, so that control of the incoming
				/// set is left to the caller.
				/// - a direct Python binding would probably need to build its own `HashSet`
				/// from an incoming iterable, even if its sole purpose is to extract the
				/// heads.
				/// - a Rust caller can decide whether cloning beforehand is appropriate
				///
				/// # Performance notes
				/// Internally, this function will store a full copy of `revs` in a `Vec`.
				pub fn retain_heads(
				graph: &impl Graph,
				revs: &mut HashSet<Revision>,
				) -> Result<(), GraphError> {
				revs.remove(&NULL_REVISION);
				// we need to construct an iterable copy of revs to avoid itering while
				// mutating
				let as_vec: Vec<Revision> = revs.iter().cloned().collect();
				for rev in as_vec {
				if rev != NULL_REVISION {
				remove_parents(graph, rev, revs)?;
				}
				}
				Ok(())
				}

				/// Roots of `revs`, passed as a `HashSet`
				///
				/// They are returned in arbitrary order
				pub fn roots<G: Graph>(
				graph: &G,
				revs: &HashSet<Revision>,
				) -> Result<Vec<Revision>, GraphError> {
				let mut roots: Vec<Revision> = Vec::new();
				for rev in revs {
				if graph
				.parents(*rev)?
				.iter()
				.filter(\|p\| **p != NULL_REVISION)
				.all(\|p\| !revs.contains(p))
				{
				roots.push(*rev);
				}
				}
				Ok(roots)
				}

				/// Compute the topological range between two collections of revisions
				///
				/// This is equivalent to the revset `<roots>::<heads>`.
				///
				/// Currently, the given `Graph` has to implement `Clone`, which means
				/// actually cloning just a reference-counted Python pointer if
				/// it's passed over through `rust-cpython`. This is due to the internal
				/// use of `AncestorsIterator`
				///
				/// # Algorithmic details
				///
				/// This is a two-pass swipe inspired from what `reachableroots2` from
				/// `mercurial.cext.parsers` does to obtain the same results.
				///
				/// - first, we climb up the DAG from `heads` in topological order, keeping
				/// them in the vector `heads_ancestors` vector, and adding any element of
				/// `roots` we find among them to the resulting range.
				/// - Then, we iterate on that recorded vector so that a revision is always
				/// emitted after its parents and add all revisions whose parents are already
				/// in the range to the results.
				///
				/// # Performance notes
				///
				/// The main difference with the C implementation is that
				/// the latter uses a flat array with bit flags, instead of complex structures
				/// like `HashSet`, making it faster in most scenarios. In theory, it's
				/// possible that the present implementation could be more memory efficient
				/// for very large repositories with many branches.
				pub fn range(
				graph: &(impl Graph + Clone),
				roots: impl IntoIterator<Item = Revision>,
				heads: impl IntoIterator<Item = Revision>,
				) -> Result<BTreeSet<Revision>, GraphError> {
				let mut range = BTreeSet::new();
				let roots: HashSet<Revision> = roots.into_iter().collect();
				let min_root: Revision = match roots.iter().cloned().min() {
				None => {
				return Ok(range);
				}
				Some(r) => r,
				};

				// Internally, AncestorsIterator currently maintains a `HashSet`
				// of all seen revision, which is also what we record, albeit in an ordered
				// way. There's room for improvement on this duplication.
				let ait = AncestorsIterator::new(graph.clone(), heads, min_root, true)?;
				let mut heads_ancestors: Vec<Revision> = Vec::new();
				for revres in ait {
				let rev = revres?;
				if roots.contains(&rev) {
				range.insert(rev);
				}
				heads_ancestors.push(rev);
				}

				for rev in heads_ancestors.into_iter().rev() {
				for parent in graph.parents(rev)?.iter() {
				if *parent != NULL_REVISION && range.contains(parent) {
				range.insert(rev);
				}
				}
				}
				Ok(range)
				}

				#[cfg(test)]
				mod tests {

				use super::*;
				use crate::testing::SampleGraph;

				/// Apply `retain_heads()` to the given slice and return as a sorted `Vec`
				fn retain_heads_sorted(
				graph: &impl Graph,
				revs: &[Revision],
				) -> Result<Vec<Revision>, GraphError> {
				let mut revs: HashSet<Revision> = revs.iter().cloned().collect();
				retain_heads(graph, &mut revs)?;
				let mut as_vec: Vec<Revision> = revs.iter().cloned().collect();
				as_vec.sort();
				Ok(as_vec)
				}

				#[test]
				fn test_retain_heads() -> Result<(), GraphError> {
				assert_eq!(retain_heads_sorted(&SampleGraph, &[4, 5, 6])?, vec![5, 6]);
				assert_eq!(
				retain_heads_sorted(&SampleGraph, &[4, 1, 6, 12, 0])?,
				vec![1, 6, 12]
				);
				assert_eq!(
				retain_heads_sorted(&SampleGraph, &[1, 2, 3, 4, 5, 6, 7, 8, 9])?,
				vec![3, 5, 8, 9]
				);
				Ok(())
				}

				/// Apply `heads()` to the given slice and return as a sorted `Vec`
				fn heads_sorted(
				graph: &impl Graph,
				revs: &[Revision],
				) -> Result<Vec<Revision>, GraphError> {
				let heads = heads(graph, revs.iter())?;
				let mut as_vec: Vec<Revision> = heads.iter().cloned().collect();
				as_vec.sort();
				Ok(as_vec)
				}

				#[test]
				fn test_heads() -> Result<(), GraphError> {
				assert_eq!(heads_sorted(&SampleGraph, &[4, 5, 6])?, vec![5, 6]);
				assert_eq!(
				heads_sorted(&SampleGraph, &[4, 1, 6, 12, 0])?,
				vec![1, 6, 12]
				);
				assert_eq!(
				heads_sorted(&SampleGraph, &[1, 2, 3, 4, 5, 6, 7, 8, 9])?,
				vec![3, 5, 8, 9]
				);
				Ok(())
				}

				/// Apply `roots()` and sort the result for easier comparison
				fn roots_sorted(
				graph: &impl Graph,
				revs: &[Revision],
				) -> Result<Vec<Revision>, GraphError> {
				let mut as_vec = roots(graph, &revs.iter().cloned().collect())?;
				as_vec.sort();
				Ok(as_vec)
				}

				#[test]
				fn test_roots() -> Result<(), GraphError> {
				assert_eq!(roots_sorted(&SampleGraph, &[4, 5, 6])?, vec![4]);
				assert_eq!(
				roots_sorted(&SampleGraph, &[4, 1, 6, 12, 0])?,
				vec![0, 4, 12]
				);
				assert_eq!(
				roots_sorted(&SampleGraph, &[1, 2, 3, 4, 5, 6, 7, 8, 9])?,
				vec![1, 8]
				);
				Ok(())
				}

				/// Apply `range()` and convert the result into a Vec for easier comparison
				fn range_vec(
				graph: impl Graph + Clone,
				roots: &[Revision],
				heads: &[Revision],
				) -> Result<Vec<Revision>, GraphError> {
				range(&graph, roots.iter().cloned(), heads.iter().cloned())
				.map(\|bs\| bs.into_iter().collect())
				}

				#[test]
				fn test_range() -> Result<(), GraphError> {
				assert_eq!(range_vec(SampleGraph, &[0], &[4])?, vec![0, 1, 2, 4]);
				assert_eq!(range_vec(SampleGraph, &[0], &[8])?, vec![]);
				assert_eq!(
				range_vec(SampleGraph, &[5, 6], &[10, 11, 13])?,
				vec![5, 10]
				);
				assert_eq!(
				range_vec(SampleGraph, &[5, 6], &[10, 12])?,
				vec![5, 6, 9, 10, 12]
				);
				Ok(())
				}
				}