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use std::borrow::Cow;
use std::path::{Path, PathBuf};
use bstr::{BStr, BString, ByteSlice};
use crate::walk::{classify, readdir, Action, Context, Delegate, Error, ForDeletionMode, Options, Outcome};
use crate::{entry, EntryRef};
/// A function to perform a git-style, unsorted, directory walk.
///
/// * `worktree_root` - the top-most root of the worktree, which must be a prefix to `root`.
/// - If [`Options::precompose_unicode`] is enabled, this path must be precomposed.
/// - The starting point of the traversal (traversal root) is calculated from by doing `worktree_root + pathspec.common_prefix()`.
/// - Note that if the traversal root leading to this directory or it itself is excluded, it will be provided to [`Delegate::emit()`]
/// without further traversal.
/// - If [`Options::precompose_unicode`] is enabled, all involved paths must be precomposed.
/// - Must be contained in `worktree_root`.
/// * `ctx` - everything needed to classify the paths seen during the traversal.
/// * `delegate` - an implementation of [`Delegate`] to control details of the traversal and receive its results.
///
/// Returns `(outcome, traversal_root)`, with the `traversal_root` actually being used for the traversal,
/// useful to transform the paths returned for the user. It's always within the `worktree_root`, or the same,
/// but is hard to guess due to additional logic affecting it.
///
/// ### Performance Notes
///
/// In theory, parallel directory traversal can be significantly faster, and what's possible for our current
/// `gix_features::fs::WalkDir` implementation is to abstract a `filter_entry()` method so it works both for
/// the iterator from the `walkdir` crate as well as from `jwalk`. However, doing so as initial version
/// has the risk of not being significantly harder if not impossible to implement as flow-control is very
/// limited.
///
/// Thus the decision was made to start out with something akin to the Git implementation, get all tests and
/// baseline comparison to pass, and see if an iterator with just `filter_entry` would be capable of dealing with
/// it. Note that `filter_entry` is the only just-in-time traversal control that `walkdir` offers, even though
/// one could consider switching to `jwalk` and just use its single-threaded implementation if a unified interface
/// is necessary to make this work - `jwalk` has a more powerful API for this to work.
///
/// If that was the case, we are talking about 0.5s for single-threaded traversal (without doing any extra work)
/// or 0.25s for optimal multi-threaded performance, all in the WebKit directory with 388k items to traverse.
/// Thus, the speedup could easily be 2x or more and thus worth investigating in due time.
pub fn walk(
worktree_root: &Path,
mut ctx: Context<'_>,
options: Options,
delegate: &mut dyn Delegate,
) -> Result<(Outcome, PathBuf), Error> {
let root = match ctx.explicit_traversal_root {
Some(root) => root.to_owned(),
None => ctx
.pathspec
.longest_common_directory()
.and_then(|candidate| {
let candidate = worktree_root.join(candidate);
candidate.is_dir().then_some(candidate)
})
.unwrap_or_else(|| worktree_root.join(ctx.pathspec.prefix_directory())),
};
let _span = gix_trace::coarse!("walk", root = ?root, worktree_root = ?worktree_root, options = ?options);
let (mut current, worktree_root_relative) = assure_no_symlink_in_root(worktree_root, &root)?;
let mut out = Outcome::default();
let mut buf = BString::default();
let (root_info, worktree_root_is_repository) = classify::root(
worktree_root,
&mut buf,
worktree_root_relative.as_ref(),
options,
&mut ctx,
)?;
let can_recurse = can_recurse(
buf.as_bstr(),
if root == worktree_root && root_info.disk_kind == Some(entry::Kind::Symlink) && current.is_dir() {
classify::Outcome {
disk_kind: Some(entry::Kind::Directory),
..root_info
}
} else {
root_info
},
options.for_deletion,
worktree_root_is_repository,
delegate,
);
if !can_recurse {
if buf.is_empty() && !root_info.disk_kind.map_or(false, |kind| kind.is_dir()) {
return Err(Error::WorktreeRootIsFile { root: root.to_owned() });
}
if options.precompose_unicode {
buf = gix_utils::str::precompose_bstr(buf.into()).into_owned();
}
let _ = emit_entry(
Cow::Borrowed(buf.as_bstr()),
root_info,
None,
options,
&mut out,
delegate,
);
return Ok((out, root.to_owned()));
}
let mut state = readdir::State::new(worktree_root, ctx.current_dir, options.for_deletion.is_some());
let may_collapse = root != worktree_root && state.may_collapse(¤t);
let (action, _) = readdir::recursive(
may_collapse,
&mut current,
&mut buf,
root_info,
&mut ctx,
options,
delegate,
&mut out,
&mut state,
)?;
if action != Action::Cancel {
state.emit_remaining(may_collapse, options, &mut out, delegate);
assert_eq!(state.on_hold.len(), 0, "BUG: after emission, on hold must be empty");
}
gix_trace::debug!(statistics = ?out);
Ok((out, root.to_owned()))
}
/// Note that we only check symlinks on the way from `worktree_root` to `root`,
/// so `worktree_root` may go through a symlink.
/// Returns `(worktree_root, normalized_worktree_relative_root)`.
fn assure_no_symlink_in_root<'root>(
worktree_root: &Path,
root: &'root Path,
) -> Result<(PathBuf, Cow<'root, Path>), Error> {
let mut current = worktree_root.to_owned();
let worktree_relative = root
.strip_prefix(worktree_root)
.expect("BUG: root was created from worktree_root + prefix");
let worktree_relative = gix_path::normalize(worktree_relative.into(), Path::new(""))
.ok_or(Error::NormalizeRoot { root: root.to_owned() })?;
for (idx, component) in worktree_relative.components().enumerate() {
current.push(component);
let meta = current.symlink_metadata().map_err(|err| Error::SymlinkMetadata {
source: err,
path: current.to_owned(),
})?;
if meta.is_symlink() {
return Err(Error::SymlinkInRoot {
root: root.to_owned(),
worktree_root: worktree_root.to_owned(),
component_index: idx,
});
}
}
Ok((current, worktree_relative))
}
pub(super) fn can_recurse(
rela_path: &BStr,
info: classify::Outcome,
for_deletion: Option<ForDeletionMode>,
worktree_root_is_repository: bool,
delegate: &mut dyn Delegate,
) -> bool {
let is_dir = info.disk_kind.map_or(false, |k| k.is_dir());
if !is_dir {
return false;
}
delegate.can_recurse(
EntryRef::from_outcome(Cow::Borrowed(rela_path), info),
for_deletion,
worktree_root_is_repository,
)
}
/// Possibly emit an entry to `for_each` in case the provided information makes that possible.
#[allow(clippy::too_many_arguments)]
pub(super) fn emit_entry(
rela_path: Cow<'_, BStr>,
info: classify::Outcome,
dir_status: Option<entry::Status>,
Options {
emit_pruned,
emit_tracked,
emit_ignored,
emit_empty_directories,
..
}: Options,
out: &mut Outcome,
delegate: &mut dyn Delegate,
) -> Action {
out.seen_entries += 1;
if (!emit_empty_directories && info.property == Some(entry::Property::EmptyDirectory)
|| !emit_tracked && info.status == entry::Status::Tracked)
|| emit_ignored.is_none() && matches!(info.status, entry::Status::Ignored(_))
|| !emit_pruned
&& (info.status.is_pruned()
|| info
.pathspec_match
.map_or(true, |m| m == entry::PathspecMatch::Excluded))
{
return Action::Continue;
}
out.returned_entries += 1;
delegate.emit(EntryRef::from_outcome(rela_path, info), dir_status)
}