use bytes_cast::BytesCast; use micro_timer::timed; use std::borrow::Cow; use std::path::PathBuf; use super::on_disk; use super::on_disk::DirstateV2ParseError; use super::owning::OwningDirstateMap; use super::path_with_basename::WithBasename; use crate::dirstate::parsers::pack_entry; use crate::dirstate::parsers::packed_entry_size; use crate::dirstate::parsers::parse_dirstate_entries; use crate::dirstate::CopyMapIter; use crate::dirstate::StateMapIter; use crate::dirstate::TruncatedTimestamp; use crate::dirstate::SIZE_FROM_OTHER_PARENT; use crate::dirstate::SIZE_NON_NORMAL; use crate::matchers::Matcher; use crate::utils::hg_path::{HgPath, HgPathBuf}; use crate::DirstateEntry; use crate::DirstateError; use crate::DirstateParents; use crate::DirstateStatus; use crate::EntryState; use crate::FastHashbrownMap as FastHashMap; use crate::PatternFileWarning; use crate::StatusError; use crate::StatusOptions; /// Append to an existing data file if the amount of unreachable data (not used /// anymore) is less than this fraction of the total amount of existing data. const ACCEPTABLE_UNREACHABLE_BYTES_RATIO: f32 = 0.5; pub struct DirstateMap<'on_disk> { /// Contents of the `.hg/dirstate` file pub(super) on_disk: &'on_disk [u8], pub(super) root: ChildNodes<'on_disk>, /// Number of nodes anywhere in the tree that have `.entry.is_some()`. pub(super) nodes_with_entry_count: u32, /// Number of nodes anywhere in the tree that have /// `.copy_source.is_some()`. pub(super) nodes_with_copy_source_count: u32, /// See on_disk::Header pub(super) ignore_patterns_hash: on_disk::IgnorePatternsHash, /// How many bytes of `on_disk` are not used anymore pub(super) unreachable_bytes: u32, } /// Using a plain `HgPathBuf` of the full path from the repository root as a /// map key would also work: all paths in a given map have the same parent /// path, so comparing full paths gives the same result as comparing base /// names. However `HashMap` would waste time always re-hashing the same /// string prefix. pub(super) type NodeKey<'on_disk> = WithBasename>; /// Similar to `&'tree Cow<'on_disk, HgPath>`, but can also be returned /// for on-disk nodes that don’t actually have a `Cow` to borrow. pub(super) enum BorrowedPath<'tree, 'on_disk> { InMemory(&'tree HgPathBuf), OnDisk(&'on_disk HgPath), } pub(super) enum ChildNodes<'on_disk> { InMemory(FastHashMap, Node<'on_disk>>), OnDisk(&'on_disk [on_disk::Node]), } pub(super) enum ChildNodesRef<'tree, 'on_disk> { InMemory(&'tree FastHashMap, Node<'on_disk>>), OnDisk(&'on_disk [on_disk::Node]), } pub(super) enum NodeRef<'tree, 'on_disk> { InMemory(&'tree NodeKey<'on_disk>, &'tree Node<'on_disk>), OnDisk(&'on_disk on_disk::Node), } impl<'tree, 'on_disk> BorrowedPath<'tree, 'on_disk> { pub fn detach_from_tree(&self) -> Cow<'on_disk, HgPath> { match *self { BorrowedPath::InMemory(in_memory) => Cow::Owned(in_memory.clone()), BorrowedPath::OnDisk(on_disk) => Cow::Borrowed(on_disk), } } } impl<'tree, 'on_disk> std::ops::Deref for BorrowedPath<'tree, 'on_disk> { type Target = HgPath; fn deref(&self) -> &HgPath { match *self { BorrowedPath::InMemory(in_memory) => in_memory, BorrowedPath::OnDisk(on_disk) => on_disk, } } } impl Default for ChildNodes<'_> { fn default() -> Self { ChildNodes::InMemory(Default::default()) } } impl<'on_disk> ChildNodes<'on_disk> { pub(super) fn as_ref<'tree>( &'tree self, ) -> ChildNodesRef<'tree, 'on_disk> { match self { ChildNodes::InMemory(nodes) => ChildNodesRef::InMemory(nodes), ChildNodes::OnDisk(nodes) => ChildNodesRef::OnDisk(nodes), } } pub(super) fn is_empty(&self) -> bool { match self { ChildNodes::InMemory(nodes) => nodes.is_empty(), ChildNodes::OnDisk(nodes) => nodes.is_empty(), } } fn make_mut( &mut self, on_disk: &'on_disk [u8], unreachable_bytes: &mut u32, ) -> Result< &mut FastHashMap, Node<'on_disk>>, DirstateV2ParseError, > { match self { ChildNodes::InMemory(nodes) => Ok(nodes), ChildNodes::OnDisk(nodes) => { *unreachable_bytes += std::mem::size_of_val::<[on_disk::Node]>(nodes) as u32; let nodes = nodes .iter() .map(|node| { Ok(( node.path(on_disk)?, node.to_in_memory_node(on_disk)?, )) }) .collect::>()?; *self = ChildNodes::InMemory(nodes); match self { ChildNodes::InMemory(nodes) => Ok(nodes), ChildNodes::OnDisk(_) => unreachable!(), } } } } } impl<'tree, 'on_disk> ChildNodesRef<'tree, 'on_disk> { pub(super) fn get( &self, base_name: &HgPath, on_disk: &'on_disk [u8], ) -> Result>, DirstateV2ParseError> { match self { ChildNodesRef::InMemory(nodes) => Ok(nodes .get_key_value(base_name) .map(|(k, v)| NodeRef::InMemory(k, v))), ChildNodesRef::OnDisk(nodes) => { let mut parse_result = Ok(()); let search_result = nodes.binary_search_by(|node| { match node.base_name(on_disk) { Ok(node_base_name) => node_base_name.cmp(base_name), Err(e) => { parse_result = Err(e); // Dummy comparison result, `search_result` won’t // be used since `parse_result` is an error std::cmp::Ordering::Equal } } }); parse_result.map(|()| { search_result.ok().map(|i| NodeRef::OnDisk(&nodes[i])) }) } } } /// Iterate in undefined order pub(super) fn iter( &self, ) -> impl Iterator> { match self { ChildNodesRef::InMemory(nodes) => itertools::Either::Left( nodes.iter().map(|(k, v)| NodeRef::InMemory(k, v)), ), ChildNodesRef::OnDisk(nodes) => { itertools::Either::Right(nodes.iter().map(NodeRef::OnDisk)) } } } /// Iterate in parallel in undefined order pub(super) fn par_iter( &self, ) -> impl rayon::iter::ParallelIterator> { use rayon::prelude::*; match self { ChildNodesRef::InMemory(nodes) => rayon::iter::Either::Left( nodes.par_iter().map(|(k, v)| NodeRef::InMemory(k, v)), ), ChildNodesRef::OnDisk(nodes) => rayon::iter::Either::Right( nodes.par_iter().map(NodeRef::OnDisk), ), } } pub(super) fn sorted(&self) -> Vec> { match self { ChildNodesRef::InMemory(nodes) => { let mut vec: Vec<_> = nodes .iter() .map(|(k, v)| NodeRef::InMemory(k, v)) .collect(); fn sort_key<'a>(node: &'a NodeRef) -> &'a HgPath { match node { NodeRef::InMemory(path, _node) => path.base_name(), NodeRef::OnDisk(_) => unreachable!(), } } // `sort_unstable_by_key` doesn’t allow keys borrowing from the // value: https://github.com/rust-lang/rust/issues/34162 vec.sort_unstable_by(|a, b| sort_key(a).cmp(sort_key(b))); vec } ChildNodesRef::OnDisk(nodes) => { // Nodes on disk are already sorted nodes.iter().map(NodeRef::OnDisk).collect() } } } } impl<'tree, 'on_disk> NodeRef<'tree, 'on_disk> { pub(super) fn full_path( &self, on_disk: &'on_disk [u8], ) -> Result<&'tree HgPath, DirstateV2ParseError> { match self { NodeRef::InMemory(path, _node) => Ok(path.full_path()), NodeRef::OnDisk(node) => node.full_path(on_disk), } } /// Returns a `BorrowedPath`, which can be turned into a `Cow<'on_disk, /// HgPath>` detached from `'tree` pub(super) fn full_path_borrowed( &self, on_disk: &'on_disk [u8], ) -> Result, DirstateV2ParseError> { match self { NodeRef::InMemory(path, _node) => match path.full_path() { Cow::Borrowed(on_disk) => Ok(BorrowedPath::OnDisk(on_disk)), Cow::Owned(in_memory) => Ok(BorrowedPath::InMemory(in_memory)), }, NodeRef::OnDisk(node) => { Ok(BorrowedPath::OnDisk(node.full_path(on_disk)?)) } } } pub(super) fn base_name( &self, on_disk: &'on_disk [u8], ) -> Result<&'tree HgPath, DirstateV2ParseError> { match self { NodeRef::InMemory(path, _node) => Ok(path.base_name()), NodeRef::OnDisk(node) => node.base_name(on_disk), } } pub(super) fn children( &self, on_disk: &'on_disk [u8], ) -> Result, DirstateV2ParseError> { match self { NodeRef::InMemory(_path, node) => Ok(node.children.as_ref()), NodeRef::OnDisk(node) => { Ok(ChildNodesRef::OnDisk(node.children(on_disk)?)) } } } pub(super) fn has_copy_source(&self) -> bool { match self { NodeRef::InMemory(_path, node) => node.copy_source.is_some(), NodeRef::OnDisk(node) => node.has_copy_source(), } } pub(super) fn copy_source( &self, on_disk: &'on_disk [u8], ) -> Result, DirstateV2ParseError> { match self { NodeRef::InMemory(_path, node) => { Ok(node.copy_source.as_ref().map(|s| &**s)) } NodeRef::OnDisk(node) => node.copy_source(on_disk), } } /// Returns a `BorrowedPath`, which can be turned into a `Cow<'on_disk, /// HgPath>` detached from `'tree` pub(super) fn copy_source_borrowed( &self, on_disk: &'on_disk [u8], ) -> Result>, DirstateV2ParseError> { Ok(match self { NodeRef::InMemory(_path, node) => { node.copy_source.as_ref().map(|source| match source { Cow::Borrowed(on_disk) => BorrowedPath::OnDisk(on_disk), Cow::Owned(in_memory) => BorrowedPath::InMemory(in_memory), }) } NodeRef::OnDisk(node) => node .copy_source(on_disk)? .map(|source| BorrowedPath::OnDisk(source)), }) } pub(super) fn entry( &self, ) -> Result, DirstateV2ParseError> { match self { NodeRef::InMemory(_path, node) => { Ok(node.data.as_entry().copied()) } NodeRef::OnDisk(node) => node.entry(), } } pub(super) fn state( &self, ) -> Result, DirstateV2ParseError> { Ok(self.entry()?.map(|e| e.state())) } pub(super) fn cached_directory_mtime( &self, ) -> Result, DirstateV2ParseError> { match self { NodeRef::InMemory(_path, node) => Ok(match node.data { NodeData::CachedDirectory { mtime } => Some(mtime), _ => None, }), NodeRef::OnDisk(node) => node.cached_directory_mtime(), } } pub(super) fn descendants_with_entry_count(&self) -> u32 { match self { NodeRef::InMemory(_path, node) => { node.descendants_with_entry_count } NodeRef::OnDisk(node) => node.descendants_with_entry_count.get(), } } pub(super) fn tracked_descendants_count(&self) -> u32 { match self { NodeRef::InMemory(_path, node) => node.tracked_descendants_count, NodeRef::OnDisk(node) => node.tracked_descendants_count.get(), } } } /// Represents a file or a directory #[derive(Default)] pub(super) struct Node<'on_disk> { pub(super) data: NodeData, pub(super) copy_source: Option>, pub(super) children: ChildNodes<'on_disk>, /// How many (non-inclusive) descendants of this node have an entry. pub(super) descendants_with_entry_count: u32, /// How many (non-inclusive) descendants of this node have an entry whose /// state is "tracked". pub(super) tracked_descendants_count: u32, } pub(super) enum NodeData { Entry(DirstateEntry), CachedDirectory { mtime: TruncatedTimestamp }, None, } impl Default for NodeData { fn default() -> Self { NodeData::None } } impl NodeData { fn has_entry(&self) -> bool { match self { NodeData::Entry(_) => true, _ => false, } } fn as_entry(&self) -> Option<&DirstateEntry> { match self { NodeData::Entry(entry) => Some(entry), _ => None, } } } impl<'on_disk> DirstateMap<'on_disk> { pub(super) fn empty(on_disk: &'on_disk [u8]) -> Self { Self { on_disk, root: ChildNodes::default(), nodes_with_entry_count: 0, nodes_with_copy_source_count: 0, ignore_patterns_hash: [0; on_disk::IGNORE_PATTERNS_HASH_LEN], unreachable_bytes: 0, } } #[timed] pub fn new_v2( on_disk: &'on_disk [u8], data_size: usize, metadata: &[u8], ) -> Result { if let Some(data) = on_disk.get(..data_size) { Ok(on_disk::read(data, metadata)?) } else { Err(DirstateV2ParseError.into()) } } #[timed] pub fn new_v1( on_disk: &'on_disk [u8], ) -> Result<(Self, Option), DirstateError> { let mut map = Self::empty(on_disk); if map.on_disk.is_empty() { return Ok((map, None)); } let parents = parse_dirstate_entries( map.on_disk, |path, entry, copy_source| { let tracked = entry.state().is_tracked(); let node = Self::get_or_insert_node( map.on_disk, &mut map.unreachable_bytes, &mut map.root, path, WithBasename::to_cow_borrowed, |ancestor| { if tracked { ancestor.tracked_descendants_count += 1 } ancestor.descendants_with_entry_count += 1 }, )?; assert!( !node.data.has_entry(), "duplicate dirstate entry in read" ); assert!( node.copy_source.is_none(), "duplicate dirstate entry in read" ); node.data = NodeData::Entry(*entry); node.copy_source = copy_source.map(Cow::Borrowed); map.nodes_with_entry_count += 1; if copy_source.is_some() { map.nodes_with_copy_source_count += 1 } Ok(()) }, )?; let parents = Some(parents.clone()); Ok((map, parents)) } /// Assuming dirstate-v2 format, returns whether the next write should /// append to the existing data file that contains `self.on_disk` (true), /// or create a new data file from scratch (false). pub(super) fn write_should_append(&self) -> bool { let ratio = self.unreachable_bytes as f32 / self.on_disk.len() as f32; ratio < ACCEPTABLE_UNREACHABLE_BYTES_RATIO } fn get_node<'tree>( &'tree self, path: &HgPath, ) -> Result>, DirstateV2ParseError> { let mut children = self.root.as_ref(); let mut components = path.components(); let mut component = components.next().expect("expected at least one components"); loop { if let Some(child) = children.get(component, self.on_disk)? { if let Some(next_component) = components.next() { component = next_component; children = child.children(self.on_disk)?; } else { return Ok(Some(child)); } } else { return Ok(None); } } } /// Returns a mutable reference to the node at `path` if it exists /// /// This takes `root` instead of `&mut self` so that callers can mutate /// other fields while the returned borrow is still valid fn get_node_mut<'tree>( on_disk: &'on_disk [u8], unreachable_bytes: &mut u32, root: &'tree mut ChildNodes<'on_disk>, path: &HgPath, ) -> Result>, DirstateV2ParseError> { let mut children = root; let mut components = path.components(); let mut component = components.next().expect("expected at least one components"); loop { if let Some(child) = children .make_mut(on_disk, unreachable_bytes)? .get_mut(component) { if let Some(next_component) = components.next() { component = next_component; children = &mut child.children; } else { return Ok(Some(child)); } } else { return Ok(None); } } } pub(super) fn get_or_insert<'tree, 'path>( &'tree mut self, path: &HgPath, ) -> Result<&'tree mut Node<'on_disk>, DirstateV2ParseError> { Self::get_or_insert_node( self.on_disk, &mut self.unreachable_bytes, &mut self.root, path, WithBasename::to_cow_owned, |_| {}, ) } fn get_or_insert_node<'tree, 'path>( on_disk: &'on_disk [u8], unreachable_bytes: &mut u32, root: &'tree mut ChildNodes<'on_disk>, path: &'path HgPath, to_cow: impl Fn( WithBasename<&'path HgPath>, ) -> WithBasename>, mut each_ancestor: impl FnMut(&mut Node), ) -> Result<&'tree mut Node<'on_disk>, DirstateV2ParseError> { let mut child_nodes = root; let mut inclusive_ancestor_paths = WithBasename::inclusive_ancestors_of(path); let mut ancestor_path = inclusive_ancestor_paths .next() .expect("expected at least one inclusive ancestor"); loop { let (_, child_node) = child_nodes .make_mut(on_disk, unreachable_bytes)? .raw_entry_mut() .from_key(ancestor_path.base_name()) .or_insert_with(|| (to_cow(ancestor_path), Node::default())); if let Some(next) = inclusive_ancestor_paths.next() { each_ancestor(child_node); ancestor_path = next; child_nodes = &mut child_node.children; } else { return Ok(child_node); } } } fn add_or_remove_file( &mut self, path: &HgPath, old_state: Option, new_entry: DirstateEntry, ) -> Result<(), DirstateV2ParseError> { let had_entry = old_state.is_some(); let was_tracked = old_state.map_or(false, |s| s.is_tracked()); let tracked_count_increment = match (was_tracked, new_entry.state().is_tracked()) { (false, true) => 1, (true, false) => -1, _ => 0, }; let node = Self::get_or_insert_node( self.on_disk, &mut self.unreachable_bytes, &mut self.root, path, WithBasename::to_cow_owned, |ancestor| { if !had_entry { ancestor.descendants_with_entry_count += 1; } // We can’t use `+= increment` because the counter is unsigned, // and we want debug builds to detect accidental underflow // through zero match tracked_count_increment { 1 => ancestor.tracked_descendants_count += 1, -1 => ancestor.tracked_descendants_count -= 1, _ => {} } }, )?; if !had_entry { self.nodes_with_entry_count += 1 } node.data = NodeData::Entry(new_entry); Ok(()) } fn iter_nodes<'tree>( &'tree self, ) -> impl Iterator< Item = Result, DirstateV2ParseError>, > + 'tree { // Depth first tree traversal. // // If we could afford internal iteration and recursion, // this would look like: // // ``` // fn traverse_children( // children: &ChildNodes, // each: &mut impl FnMut(&Node), // ) { // for child in children.values() { // traverse_children(&child.children, each); // each(child); // } // } // ``` // // However we want an external iterator and therefore can’t use the // call stack. Use an explicit stack instead: let mut stack = Vec::new(); let mut iter = self.root.as_ref().iter(); std::iter::from_fn(move || { while let Some(child_node) = iter.next() { let children = match child_node.children(self.on_disk) { Ok(children) => children, Err(error) => return Some(Err(error)), }; // Pseudo-recursion let new_iter = children.iter(); let old_iter = std::mem::replace(&mut iter, new_iter); stack.push((child_node, old_iter)); } // Found the end of a `children.iter()` iterator. if let Some((child_node, next_iter)) = stack.pop() { // "Return" from pseudo-recursion by restoring state from the // explicit stack iter = next_iter; Some(Ok(child_node)) } else { // Reached the bottom of the stack, we’re done None } }) } fn count_dropped_path(unreachable_bytes: &mut u32, path: &Cow) { if let Cow::Borrowed(path) = path { *unreachable_bytes += path.len() as u32 } } } /// Like `Iterator::filter_map`, but over a fallible iterator of `Result`s. /// /// The callback is only called for incoming `Ok` values. Errors are passed /// through as-is. In order to let it use the `?` operator the callback is /// expected to return a `Result` of `Option`, instead of an `Option` of /// `Result`. fn filter_map_results<'a, I, F, A, B, E>( iter: I, f: F, ) -> impl Iterator> + 'a where I: Iterator> + 'a, F: Fn(A) -> Result, E> + 'a, { iter.filter_map(move |result| match result { Ok(node) => f(node).transpose(), Err(e) => Some(Err(e)), }) } impl OwningDirstateMap { pub fn clear(&mut self) { let map = self.get_map_mut(); map.root = Default::default(); map.nodes_with_entry_count = 0; map.nodes_with_copy_source_count = 0; } pub fn set_entry( &mut self, filename: &HgPath, entry: DirstateEntry, ) -> Result<(), DirstateV2ParseError> { let map = self.get_map_mut(); map.get_or_insert(&filename)?.data = NodeData::Entry(entry); Ok(()) } pub fn add_file( &mut self, filename: &HgPath, entry: DirstateEntry, ) -> Result<(), DirstateError> { let old_state = self.get(filename)?.map(|e| e.state()); let map = self.get_map_mut(); Ok(map.add_or_remove_file(filename, old_state, entry)?) } pub fn remove_file( &mut self, filename: &HgPath, in_merge: bool, ) -> Result<(), DirstateError> { let old_entry_opt = self.get(filename)?; let old_state = old_entry_opt.map(|e| e.state()); let mut size = 0; if in_merge { // XXX we should not be able to have 'm' state and 'FROM_P2' if not // during a merge. So I (marmoute) am not sure we need the // conditionnal at all. Adding double checking this with assert // would be nice. if let Some(old_entry) = old_entry_opt { // backup the previous state if old_entry.state() == EntryState::Merged { size = SIZE_NON_NORMAL; } else if old_entry.state() == EntryState::Normal && old_entry.size() == SIZE_FROM_OTHER_PARENT { // other parent size = SIZE_FROM_OTHER_PARENT; } } } if size == 0 { self.copy_map_remove(filename)?; } let map = self.get_map_mut(); let entry = DirstateEntry::new_removed(size); Ok(map.add_or_remove_file(filename, old_state, entry)?) } pub fn drop_entry_and_copy_source( &mut self, filename: &HgPath, ) -> Result<(), DirstateError> { let was_tracked = self .get(filename)? .map_or(false, |e| e.state().is_tracked()); let map = self.get_map_mut(); struct Dropped { was_tracked: bool, had_entry: bool, had_copy_source: bool, } /// If this returns `Ok(Some((dropped, removed)))`, then /// /// * `dropped` is about the leaf node that was at `filename` /// * `removed` is whether this particular level of recursion just /// removed a node in `nodes`. fn recur<'on_disk>( on_disk: &'on_disk [u8], unreachable_bytes: &mut u32, nodes: &mut ChildNodes<'on_disk>, path: &HgPath, ) -> Result, DirstateV2ParseError> { let (first_path_component, rest_of_path) = path.split_first_component(); let nodes = nodes.make_mut(on_disk, unreachable_bytes)?; let node = if let Some(node) = nodes.get_mut(first_path_component) { node } else { return Ok(None); }; let dropped; if let Some(rest) = rest_of_path { if let Some((d, removed)) = recur( on_disk, unreachable_bytes, &mut node.children, rest, )? { dropped = d; if dropped.had_entry { node.descendants_with_entry_count -= 1; } if dropped.was_tracked { node.tracked_descendants_count -= 1; } // Directory caches must be invalidated when removing a // child node if removed { if let NodeData::CachedDirectory { .. } = &node.data { node.data = NodeData::None } } } else { return Ok(None); } } else { let had_entry = node.data.has_entry(); if had_entry { node.data = NodeData::None } if let Some(source) = &node.copy_source { DirstateMap::count_dropped_path(unreachable_bytes, source); node.copy_source = None } dropped = Dropped { was_tracked: node .data .as_entry() .map_or(false, |entry| entry.state().is_tracked()), had_entry, had_copy_source: node.copy_source.take().is_some(), }; } // After recursion, for both leaf (rest_of_path is None) nodes and // parent nodes, remove a node if it just became empty. let remove = !node.data.has_entry() && node.copy_source.is_none() && node.children.is_empty(); if remove { let (key, _) = nodes.remove_entry(first_path_component).unwrap(); DirstateMap::count_dropped_path( unreachable_bytes, key.full_path(), ) } Ok(Some((dropped, remove))) } if let Some((dropped, _removed)) = recur( map.on_disk, &mut map.unreachable_bytes, &mut map.root, filename, )? { if dropped.had_entry { map.nodes_with_entry_count -= 1 } if dropped.had_copy_source { map.nodes_with_copy_source_count -= 1 } } else { debug_assert!(!was_tracked); } Ok(()) } pub fn has_tracked_dir( &mut self, directory: &HgPath, ) -> Result { let map = self.get_map_mut(); if let Some(node) = map.get_node(directory)? { // A node without a `DirstateEntry` was created to hold child // nodes, and is therefore a directory. let state = node.state()?; Ok(state.is_none() && node.tracked_descendants_count() > 0) } else { Ok(false) } } pub fn has_dir( &mut self, directory: &HgPath, ) -> Result { let map = self.get_map_mut(); if let Some(node) = map.get_node(directory)? { // A node without a `DirstateEntry` was created to hold child // nodes, and is therefore a directory. let state = node.state()?; Ok(state.is_none() && node.descendants_with_entry_count() > 0) } else { Ok(false) } } #[timed] pub fn pack_v1( &self, parents: DirstateParents, ) -> Result, DirstateError> { let map = self.get_map(); // Optizimation (to be measured?): pre-compute size to avoid `Vec` // reallocations let mut size = parents.as_bytes().len(); for node in map.iter_nodes() { let node = node?; if node.entry()?.is_some() { size += packed_entry_size( node.full_path(map.on_disk)?, node.copy_source(map.on_disk)?, ); } } let mut packed = Vec::with_capacity(size); packed.extend(parents.as_bytes()); for node in map.iter_nodes() { let node = node?; if let Some(entry) = node.entry()? { pack_entry( node.full_path(map.on_disk)?, &entry, node.copy_source(map.on_disk)?, &mut packed, ); } } Ok(packed) } /// Returns new data and metadata together with whether that data should be /// appended to the existing data file whose content is at /// `map.on_disk` (true), instead of written to a new data file /// (false). #[timed] pub fn pack_v2( &self, can_append: bool, ) -> Result<(Vec, on_disk::TreeMetadata, bool), DirstateError> { let map = self.get_map(); on_disk::write(map, can_append) } pub fn status<'a>( &'a mut self, matcher: &'a (dyn Matcher + Sync), root_dir: PathBuf, ignore_files: Vec, options: StatusOptions, ) -> Result<(DirstateStatus<'a>, Vec), StatusError> { let map = self.get_map_mut(); super::status::status(map, matcher, root_dir, ignore_files, options) } pub fn copy_map_len(&self) -> usize { let map = self.get_map(); map.nodes_with_copy_source_count as usize } pub fn copy_map_iter(&self) -> CopyMapIter<'_> { let map = self.get_map(); Box::new(filter_map_results(map.iter_nodes(), move |node| { Ok(if let Some(source) = node.copy_source(map.on_disk)? { Some((node.full_path(map.on_disk)?, source)) } else { None }) })) } pub fn copy_map_contains_key( &self, key: &HgPath, ) -> Result { let map = self.get_map(); Ok(if let Some(node) = map.get_node(key)? { node.has_copy_source() } else { false }) } pub fn copy_map_get( &self, key: &HgPath, ) -> Result, DirstateV2ParseError> { let map = self.get_map(); if let Some(node) = map.get_node(key)? { if let Some(source) = node.copy_source(map.on_disk)? { return Ok(Some(source)); } } Ok(None) } pub fn copy_map_remove( &mut self, key: &HgPath, ) -> Result, DirstateV2ParseError> { let map = self.get_map_mut(); let count = &mut map.nodes_with_copy_source_count; let unreachable_bytes = &mut map.unreachable_bytes; Ok(DirstateMap::get_node_mut( map.on_disk, unreachable_bytes, &mut map.root, key, )? .and_then(|node| { if let Some(source) = &node.copy_source { *count -= 1; DirstateMap::count_dropped_path(unreachable_bytes, source); } node.copy_source.take().map(Cow::into_owned) })) } pub fn copy_map_insert( &mut self, key: HgPathBuf, value: HgPathBuf, ) -> Result, DirstateV2ParseError> { let map = self.get_map_mut(); let node = DirstateMap::get_or_insert_node( map.on_disk, &mut map.unreachable_bytes, &mut map.root, &key, WithBasename::to_cow_owned, |_ancestor| {}, )?; if node.copy_source.is_none() { map.nodes_with_copy_source_count += 1 } Ok(node.copy_source.replace(value.into()).map(Cow::into_owned)) } pub fn len(&self) -> usize { let map = self.get_map(); map.nodes_with_entry_count as usize } pub fn contains_key( &self, key: &HgPath, ) -> Result { Ok(self.get(key)?.is_some()) } pub fn get( &self, key: &HgPath, ) -> Result, DirstateV2ParseError> { let map = self.get_map(); Ok(if let Some(node) = map.get_node(key)? { node.entry()? } else { None }) } pub fn iter(&self) -> StateMapIter<'_> { let map = self.get_map(); Box::new(filter_map_results(map.iter_nodes(), move |node| { Ok(if let Some(entry) = node.entry()? { Some((node.full_path(map.on_disk)?, entry)) } else { None }) })) } pub fn iter_tracked_dirs( &mut self, ) -> Result< Box< dyn Iterator> + Send + '_, >, DirstateError, > { let map = self.get_map_mut(); let on_disk = map.on_disk; Ok(Box::new(filter_map_results( map.iter_nodes(), move |node| { Ok(if node.tracked_descendants_count() > 0 { Some(node.full_path(on_disk)?) } else { None }) }, ))) } pub fn debug_iter( &self, all: bool, ) -> Box< dyn Iterator< Item = Result< (&HgPath, (u8, i32, i32, i32)), DirstateV2ParseError, >, > + Send + '_, > { let map = self.get_map(); Box::new(filter_map_results(map.iter_nodes(), move |node| { let debug_tuple = if let Some(entry) = node.entry()? { entry.debug_tuple() } else if !all { return Ok(None); } else if let Some(mtime) = node.cached_directory_mtime()? { (b' ', 0, -1, mtime.truncated_seconds() as i32) } else { (b' ', 0, -1, -1) }; Ok(Some((node.full_path(map.on_disk)?, debug_tuple))) })) } }