upstream/mercurial-mirror Files · rust/hg-cpython/src/ancestors.rs

rust-dirstate: rust implementation of dirstatemap...

rust-dirstate: rust implementation of dirstatemap The `dirstatemap` is one of the last building blocks needed to get to a `dirstate.walk` Rust implementation. Disclaimer: This change is part of a big (10) series of patches, all of which started as one big changeset that took a long time to write. This `dirstatemap` implementation is a compromise in terms of complexity both for me and for the reviewers. I chose to submit this patch right now because while it is not perfect, it works and is simple enough (IMHO) to be reviewed. The Python implementation uses a lot of lazy propertycaches, breaks encapsulation and is used as an iterator in a lot of places, all of which dictated the somewhat unidiomatic patterns in this change. Like written in the comments, rewriting this struct to use the typestate pattern might be a good idea, but this is a good first step. Differential Revision: https://phab.mercurial-scm.org/D6632

Raphaël Gomès - - Load All Authors

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      // ancestors.rs

      //

      // Copyright 2018 Georges Racinet <gracinet@anybox.fr>

      //

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

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

      //! Bindings for the `hg::ancestors` module provided by the

      //! `hg-core` crate. From Python, this will be seen as `rustext.ancestor`

      //! and can be used as replacement for the the pure `ancestor` Python module.

      //!

      //! # Classes visible from Python:

      //! - [`LazyAncestors`] is the Rust implementation of

      //!   `mercurial.ancestor.lazyancestors`. The only difference is that it is

      //!   instantiated with a C `parsers.index` instance instead of a parents

      //!   function.

      //!

      //! - [`MissingAncestors`] is the Rust implementation of

      //!   `mercurial.ancestor.incrementalmissingancestors`.

      //!

      //!   API differences:

      //!    + it is instantiated with a C `parsers.index`

      //!      instance instead of a parents function.

      //!    + `MissingAncestors.bases` is a method returning a tuple instead of

      //!      a set-valued attribute. We could return a Python set easily if our

      //!      [PySet PR](https://github.com/dgrunwald/rust-cpython/pull/165)

      //!      is accepted.

      //!

      //! - [`AncestorsIterator`] is the Rust counterpart of the

      //!   `ancestor._lazyancestorsiter` Python generator. From Python, instances of

      //!   this should be mainly obtained by calling `iter()` on a [`LazyAncestors`]

      //!   instance.

      //!

      //! [`LazyAncestors`]: struct.LazyAncestors.html

      //! [`MissingAncestors`]: struct.MissingAncestors.html

      //! [`AncestorsIterator`]: struct.AncestorsIterator.html

      use crate::{

          cindex::Index,

          conversion::{py_set, rev_pyiter_collect},

          exceptions::GraphError,

      };

      use cpython::{

          ObjectProtocol, PyClone, PyDict, PyList, PyModule, PyObject, PyResult,

          Python, PythonObject, ToPyObject,

      };

      use hg::Revision;

      use hg::{

          AncestorsIterator as CoreIterator, LazyAncestors as CoreLazy,

          MissingAncestors as CoreMissing,

      };

      use std::cell::RefCell;

      use std::collections::HashSet;

      py_class!(pub class AncestorsIterator |py| {

          data inner: RefCell<Box<CoreIterator<Index>>>;

          def __next__(&self) -> PyResult<Option<Revision>> {

              match self.inner(py).borrow_mut().next() {

                  Some(Err(e)) => Err(GraphError::pynew(py, e)),

                  None => Ok(None),

                  Some(Ok(r)) => Ok(Some(r)),

              }

          }

          def __contains__(&self, rev: Revision) -> PyResult<bool> {

              self.inner(py).borrow_mut().contains(rev)

                  .map_err(|e| GraphError::pynew(py, e))

          }

          def __iter__(&self) -> PyResult<Self> {

              Ok(self.clone_ref(py))

          }

          def __new__(_cls, index: PyObject, initrevs: PyObject, stoprev: Revision,

                      inclusive: bool) -> PyResult<AncestorsIterator> {

              let initvec: Vec<Revision> = rev_pyiter_collect(py, &initrevs)?;

              let ait = CoreIterator::new(

                  Index::new(py, index)?,

                  initvec,

                  stoprev,

                  inclusive,

              )

              .map_err(|e| GraphError::pynew(py, e))?;

              AncestorsIterator::from_inner(py, ait)

          }

      });

      impl AncestorsIterator {

          pub fn from_inner(py: Python, ait: CoreIterator<Index>) -> PyResult<Self> {

              Self::create_instance(py, RefCell::new(Box::new(ait)))

          }

      }

      py_class!(pub class LazyAncestors |py| {

          data inner: RefCell<Box<CoreLazy<Index>>>;

          def __contains__(&self, rev: Revision) -> PyResult<bool> {

              self.inner(py)

                  .borrow_mut()

                  .contains(rev)

                  .map_err(|e| GraphError::pynew(py, e))

          }

          def __iter__(&self) -> PyResult<AncestorsIterator> {

              AncestorsIterator::from_inner(py, self.inner(py).borrow().iter())

          }

          def __bool__(&self) -> PyResult<bool> {

              Ok(!self.inner(py).borrow().is_empty())

          }

          def __new__(_cls, index: PyObject, initrevs: PyObject, stoprev: Revision,

                      inclusive: bool) -> PyResult<Self> {

              let initvec: Vec<Revision> = rev_pyiter_collect(py, &initrevs)?;

              let lazy =

                  CoreLazy::new(Index::new(py, index)?, initvec, stoprev, inclusive)

                      .map_err(|e| GraphError::pynew(py, e))?;

              Self::create_instance(py, RefCell::new(Box::new(lazy)))

              }

      });

      py_class!(pub class MissingAncestors |py| {

          data inner: RefCell<Box<CoreMissing<Index>>>;

          def __new__(_cls, index: PyObject, bases: PyObject) -> PyResult<MissingAncestors> {

              let bases_vec: Vec<Revision> = rev_pyiter_collect(py, &bases)?;

              let inner = CoreMissing::new(Index::new(py, index)?, bases_vec);

              MissingAncestors::create_instance(py, RefCell::new(Box::new(inner)))

          }

          def hasbases(&self) -> PyResult<bool> {

              Ok(self.inner(py).borrow().has_bases())

          }

          def addbases(&self, bases: PyObject) -> PyResult<PyObject> {

              let mut inner = self.inner(py).borrow_mut();

              let bases_vec: Vec<Revision> = rev_pyiter_collect(py, &bases)?;

              inner.add_bases(bases_vec);

              // cpython doc has examples with PyResult<()> but this gives me

              //   the trait `cpython::ToPyObject` is not implemented for `()`

              // so let's return an explicit None

              Ok(py.None())

          }

          def bases(&self) -> PyResult<PyObject> {

              py_set(py, self.inner(py).borrow().get_bases())

          }

          def basesheads(&self) -> PyResult<PyObject> {

              let inner = self.inner(py).borrow();

              py_set(py, &inner.bases_heads().map_err(|e| GraphError::pynew(py, e))?)

          }

          def removeancestorsfrom(&self, revs: PyObject) -> PyResult<PyObject> {

              let mut inner = self.inner(py).borrow_mut();

              // this is very lame: we convert to a Rust set, update it in place

              // and then convert back to Python, only to have Python remove the

              // excess (thankfully, Python is happy with a list or even an iterator)

              // Leads to improve this:

              //  - have the CoreMissing instead do something emit revisions to

              //    discard

              //  - define a trait for sets of revisions in the core and implement

              //    it for a Python set rewrapped with the GIL marker

              let mut revs_pyset: HashSet<Revision> = rev_pyiter_collect(py, &revs)?;

              inner.remove_ancestors_from(&mut revs_pyset)

                  .map_err(|e| GraphError::pynew(py, e))?;

              // convert as Python list

              let mut remaining_pyint_vec: Vec<PyObject> = Vec::with_capacity(

                  revs_pyset.len());

              for rev in revs_pyset {

                  remaining_pyint_vec.push(rev.to_py_object(py).into_object());

              }

              let remaining_pylist = PyList::new(py, remaining_pyint_vec.as_slice());

              revs.call_method(py, "intersection_update", (remaining_pylist, ), None)

          }

          def missingancestors(&self, revs: PyObject) -> PyResult<PyList> {

              let mut inner = self.inner(py).borrow_mut();

              let revs_vec: Vec<Revision> = rev_pyiter_collect(py, &revs)?;

              let missing_vec = match inner.missing_ancestors(revs_vec) {

                  Ok(missing) => missing,

                  Err(e) => {

                      return Err(GraphError::pynew(py, e));

                  }

              };

              // convert as Python list

              let mut missing_pyint_vec: Vec<PyObject> = Vec::with_capacity(

                  missing_vec.len());

              for rev in missing_vec {

                  missing_pyint_vec.push(rev.to_py_object(py).into_object());

              }

              Ok(PyList::new(py, missing_pyint_vec.as_slice()))

          }

      });

      /// Create the module, with __package__ given from parent

      pub fn init_module(py: Python, package: &str) -> PyResult<PyModule> {

          let dotted_name = &format!("{}.ancestor", package);

          let m = PyModule::new(py, dotted_name)?;

          m.add(py, "__package__", package)?;

          m.add(

              py,

              "__doc__",

              "Generic DAG ancestor algorithms - Rust implementation",

          )?;

          m.add_class::<AncestorsIterator>(py)?;

          m.add_class::<LazyAncestors>(py)?;

          m.add_class::<MissingAncestors>(py)?;

          let sys = PyModule::import(py, "sys")?;

          let sys_modules: PyDict = sys.get(py, "modules")?.extract(py)?;

          sys_modules.set_item(py, dotted_name, &m)?;

          // Example C code (see pyexpat.c and import.c) will "give away the

          // reference", but we won't because it will be consumed once the

          // Rust PyObject is dropped.

          Ok(m)

      }

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				// ancestors.rs
				//
				// Copyright 2018 Georges Racinet <gracinet@anybox.fr>
				//
				// This software may be used and distributed according to the terms of the
				// GNU General Public License version 2 or any later version.

				//! Bindings for the `hg::ancestors` module provided by the
				//! `hg-core` crate. From Python, this will be seen as `rustext.ancestor`
				//! and can be used as replacement for the the pure `ancestor` Python module.
				//!
				//! # Classes visible from Python:
				//! - [`LazyAncestors`] is the Rust implementation of
				//! `mercurial.ancestor.lazyancestors`. The only difference is that it is
				//! instantiated with a C `parsers.index` instance instead of a parents
				//! function.
				//!
				//! - [`MissingAncestors`] is the Rust implementation of
				//! `mercurial.ancestor.incrementalmissingancestors`.
				//!
				//! API differences:
				//! + it is instantiated with a C `parsers.index`
				//! instance instead of a parents function.
				//! + `MissingAncestors.bases` is a method returning a tuple instead of
				//! a set-valued attribute. We could return a Python set easily if our
				//! [PySet PR](https://github.com/dgrunwald/rust-cpython/pull/165)
				//! is accepted.
				//!
				//! - [`AncestorsIterator`] is the Rust counterpart of the
				//! `ancestor._lazyancestorsiter` Python generator. From Python, instances of
				//! this should be mainly obtained by calling `iter()` on a [`LazyAncestors`]
				//! instance.
				//!
				//! [`LazyAncestors`]: struct.LazyAncestors.html
				//! [`MissingAncestors`]: struct.MissingAncestors.html
				//! [`AncestorsIterator`]: struct.AncestorsIterator.html
				use crate::{
				cindex::Index,
				conversion::{py_set, rev_pyiter_collect},
				exceptions::GraphError,
				};
				use cpython::{
				ObjectProtocol, PyClone, PyDict, PyList, PyModule, PyObject, PyResult,
				Python, PythonObject, ToPyObject,
				};
				use hg::Revision;
				use hg::{
				AncestorsIterator as CoreIterator, LazyAncestors as CoreLazy,
				MissingAncestors as CoreMissing,
				};
				use std::cell::RefCell;
				use std::collections::HashSet;

				py_class!(pub class AncestorsIterator \|py\| {
				data inner: RefCell<Box<CoreIterator<Index>>>;

				def __next__(&self) -> PyResult<Option<Revision>> {
				match self.inner(py).borrow_mut().next() {
				Some(Err(e)) => Err(GraphError::pynew(py, e)),
				None => Ok(None),
				Some(Ok(r)) => Ok(Some(r)),
				}
				}

				def __contains__(&self, rev: Revision) -> PyResult<bool> {
				self.inner(py).borrow_mut().contains(rev)
				.map_err(\|e\| GraphError::pynew(py, e))
				}

				def __iter__(&self) -> PyResult<Self> {
				Ok(self.clone_ref(py))
				}

				def __new__(_cls, index: PyObject, initrevs: PyObject, stoprev: Revision,
				inclusive: bool) -> PyResult<AncestorsIterator> {
				let initvec: Vec<Revision> = rev_pyiter_collect(py, &initrevs)?;
				let ait = CoreIterator::new(
				Index::new(py, index)?,
				initvec,
				stoprev,
				inclusive,
				)
				.map_err(\|e\| GraphError::pynew(py, e))?;
				AncestorsIterator::from_inner(py, ait)
				}

				});

				impl AncestorsIterator {
				pub fn from_inner(py: Python, ait: CoreIterator<Index>) -> PyResult<Self> {
				Self::create_instance(py, RefCell::new(Box::new(ait)))
				}
				}

				py_class!(pub class LazyAncestors \|py\| {
				data inner: RefCell<Box<CoreLazy<Index>>>;

				def __contains__(&self, rev: Revision) -> PyResult<bool> {
				self.inner(py)
				.borrow_mut()
				.contains(rev)
				.map_err(\|e\| GraphError::pynew(py, e))
				}

				def __iter__(&self) -> PyResult<AncestorsIterator> {
				AncestorsIterator::from_inner(py, self.inner(py).borrow().iter())
				}

				def __bool__(&self) -> PyResult<bool> {
				Ok(!self.inner(py).borrow().is_empty())
				}

				def __new__(_cls, index: PyObject, initrevs: PyObject, stoprev: Revision,
				inclusive: bool) -> PyResult<Self> {
				let initvec: Vec<Revision> = rev_pyiter_collect(py, &initrevs)?;

				let lazy =
				CoreLazy::new(Index::new(py, index)?, initvec, stoprev, inclusive)
				.map_err(\|e\| GraphError::pynew(py, e))?;

				Self::create_instance(py, RefCell::new(Box::new(lazy)))
				}

				});

				py_class!(pub class MissingAncestors \|py\| {
				data inner: RefCell<Box<CoreMissing<Index>>>;

				def __new__(_cls, index: PyObject, bases: PyObject) -> PyResult<MissingAncestors> {
				let bases_vec: Vec<Revision> = rev_pyiter_collect(py, &bases)?;
				let inner = CoreMissing::new(Index::new(py, index)?, bases_vec);
				MissingAncestors::create_instance(py, RefCell::new(Box::new(inner)))
				}

				def hasbases(&self) -> PyResult<bool> {
				Ok(self.inner(py).borrow().has_bases())
				}

				def addbases(&self, bases: PyObject) -> PyResult<PyObject> {
				let mut inner = self.inner(py).borrow_mut();
				let bases_vec: Vec<Revision> = rev_pyiter_collect(py, &bases)?;
				inner.add_bases(bases_vec);
				// cpython doc has examples with PyResult<()> but this gives me
				// the trait `cpython::ToPyObject` is not implemented for `()`
				// so let's return an explicit None
				Ok(py.None())
				}

				def bases(&self) -> PyResult<PyObject> {
				py_set(py, self.inner(py).borrow().get_bases())
				}

				def basesheads(&self) -> PyResult<PyObject> {
				let inner = self.inner(py).borrow();
				py_set(py, &inner.bases_heads().map_err(\|e\| GraphError::pynew(py, e))?)
				}

				def removeancestorsfrom(&self, revs: PyObject) -> PyResult<PyObject> {
				let mut inner = self.inner(py).borrow_mut();
				// this is very lame: we convert to a Rust set, update it in place
				// and then convert back to Python, only to have Python remove the
				// excess (thankfully, Python is happy with a list or even an iterator)
				// Leads to improve this:
				// - have the CoreMissing instead do something emit revisions to
				// discard
				// - define a trait for sets of revisions in the core and implement
				// it for a Python set rewrapped with the GIL marker
				let mut revs_pyset: HashSet<Revision> = rev_pyiter_collect(py, &revs)?;
				inner.remove_ancestors_from(&mut revs_pyset)
				.map_err(\|e\| GraphError::pynew(py, e))?;

				// convert as Python list
				let mut remaining_pyint_vec: Vec<PyObject> = Vec::with_capacity(
				revs_pyset.len());
				for rev in revs_pyset {
				remaining_pyint_vec.push(rev.to_py_object(py).into_object());
				}
				let remaining_pylist = PyList::new(py, remaining_pyint_vec.as_slice());
				revs.call_method(py, "intersection_update", (remaining_pylist, ), None)
				}

				def missingancestors(&self, revs: PyObject) -> PyResult<PyList> {
				let mut inner = self.inner(py).borrow_mut();
				let revs_vec: Vec<Revision> = rev_pyiter_collect(py, &revs)?;
				let missing_vec = match inner.missing_ancestors(revs_vec) {
				Ok(missing) => missing,
				Err(e) => {
				return Err(GraphError::pynew(py, e));
				}
				};
				// convert as Python list
				let mut missing_pyint_vec: Vec<PyObject> = Vec::with_capacity(
				missing_vec.len());
				for rev in missing_vec {
				missing_pyint_vec.push(rev.to_py_object(py).into_object());
				}
				Ok(PyList::new(py, missing_pyint_vec.as_slice()))
				}
				});

				/// Create the module, with __package__ given from parent
				pub fn init_module(py: Python, package: &str) -> PyResult<PyModule> {
				let dotted_name = &format!("{}.ancestor", package);
				let m = PyModule::new(py, dotted_name)?;
				m.add(py, "__package__", package)?;
				m.add(
				py,
				"__doc__",
				"Generic DAG ancestor algorithms - Rust implementation",
				)?;
				m.add_class::<AncestorsIterator>(py)?;
				m.add_class::<LazyAncestors>(py)?;
				m.add_class::<MissingAncestors>(py)?;

				let sys = PyModule::import(py, "sys")?;
				let sys_modules: PyDict = sys.get(py, "modules")?.extract(py)?;
				sys_modules.set_item(py, dotted_name, &m)?;
				// Example C code (see pyexpat.c and import.c) will "give away the
				// reference", but we won't because it will be consumed once the
				// Rust PyObject is dropped.
				Ok(m)
				}