##// END OF EJS Templates
rust: fix unsound `OwningDirstateMap`...
rust: fix unsound `OwningDirstateMap` As per the previous patch, `OwningDirstateMap` is unsound. Self-referential structs are difficult to implement correctly in Rust since the compiler is free to move structs around as much as it wants to. They are also very rarely needed in practice, so the state-of-the-art on how they should be done within the Rust rules is still a bit new. The crate `ouroboros` is an attempt at providing a safe way (in the Rust sense) of declaring self-referential structs. It is getting a lot attention and was improved very quickly when soundness issues were found in the past: rather than relying on our own (limited) review circle, we might as well use the de-facto common crate to fix this problem. This will give us a much better chance of finding issues should any new ones be discovered as well as the benefit of fewer `unsafe` APIs of our own. I was starting to think about how I would present a safe API to the old struct but soon realized that the callback-based approach was already done in `ouroboros`, along with a lot more care towards refusing incorrect structs. In short: we don't return a mutable reference to the `DirstateMap` anymore, we expect users of its API to pass a `FnOnce` that takes the map as an argument. This allows our `OwningDirstateMap` to control the input and output lifetimes of the code that modifies it to prevent such issues. Changing to `ouroboros` meant changing every API with it, but it is relatively low churn in the end. It correctly identified the example buggy modification of `copy_map_insert` outlined in the previous patch as violating the borrow rules. Differential Revision: https://phab.mercurial-scm.org/D12429

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ancestors.rs
231 lines | 8.4 KiB | application/rls-services+xml | RustLexer
// 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::revlog::pyindex_to_graph;
use crate::{
cindex::Index, conversion::rev_pyiter_collect, exceptions::GraphError,
};
use cpython::{
ObjectProtocol, PyClone, PyDict, PyList, PyModule, PyObject, PyResult,
Python, PythonObject, ToPyObject,
};
use hg::MissingAncestors as CoreMissing;
use hg::Revision;
use std::cell::RefCell;
use std::collections::HashSet;
use vcsgraph::lazy_ancestors::{
AncestorsIterator as VCGAncestorsIterator,
LazyAncestors as VCGLazyAncestors,
};
py_class!(pub class AncestorsIterator |py| {
data inner: RefCell<Box<VCGAncestorsIterator<Index>>>;
def __next__(&self) -> PyResult<Option<Revision>> {
match self.inner(py).borrow_mut().next() {
Some(Err(e)) => Err(GraphError::pynew_from_vcsgraph(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_from_vcsgraph(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 = VCGAncestorsIterator::new(
pyindex_to_graph(py, index)?,
initvec,
stoprev,
inclusive,
)
.map_err(|e| GraphError::pynew_from_vcsgraph(py, e))?;
AncestorsIterator::from_inner(py, ait)
}
});
impl AncestorsIterator {
pub fn from_inner(
py: Python,
ait: VCGAncestorsIterator<Index>,
) -> PyResult<Self> {
Self::create_instance(py, RefCell::new(Box::new(ait)))
}
}
py_class!(pub class LazyAncestors |py| {
data inner: RefCell<Box<VCGLazyAncestors<Index>>>;
def __contains__(&self, rev: Revision) -> PyResult<bool> {
self.inner(py)
.borrow_mut()
.contains(rev)
.map_err(|e| GraphError::pynew_from_vcsgraph(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 =
VCGLazyAncestors::new(pyindex_to_graph(py, index)?,
initvec, stoprev, inclusive)
.map_err(|e| GraphError::pynew_from_vcsgraph(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(pyindex_to_graph(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<HashSet<Revision>> {
Ok(self.inner(py).borrow().get_bases().clone())
}
def basesheads(&self) -> PyResult<HashSet<Revision>> {
let inner = self.inner(py).borrow();
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)
}