Mercurial > hg
view rust/hg-core/src/revlog/manifest.rs @ 51218:0112803e6c01
rust-index: add support for `_slicechunktodensity`
author | Raphaël Gomès <rgomes@octobus.net> |
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date | Thu, 02 Nov 2023 11:40:23 +0100 |
parents | 13f58ce70299 |
children | db7dbe6f7bb2 |
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use crate::errors::HgError; use crate::revlog::{Node, NodePrefix}; use crate::revlog::{Revlog, RevlogError}; use crate::utils::hg_path::HgPath; use crate::utils::SliceExt; use crate::vfs::Vfs; use crate::{ Graph, GraphError, Revision, RevlogOpenOptions, UncheckedRevision, }; /// A specialized `Revlog` to work with `manifest` data format. pub struct Manifestlog { /// The generic `revlog` format. pub(crate) revlog: Revlog, } impl Graph for Manifestlog { fn parents(&self, rev: Revision) -> Result<[Revision; 2], GraphError> { self.revlog.parents(rev) } } impl Manifestlog { /// Open the `manifest` of a repository given by its root. pub fn open( store_vfs: &Vfs, options: RevlogOpenOptions, ) -> Result<Self, HgError> { let revlog = Revlog::open(store_vfs, "00manifest.i", None, options)?; Ok(Self { revlog }) } /// Return the `Manifest` for the given node ID. /// /// Note: this is a node ID in the manifestlog, typically found through /// `ChangelogEntry::manifest_node`. It is *not* the node ID of any /// changeset. /// /// See also `Repo::manifest_for_node` pub fn data_for_node( &self, node: NodePrefix, ) -> Result<Manifest, RevlogError> { let rev = self.revlog.rev_from_node(node)?; self.data_for_checked_rev(rev) } /// Return the `Manifest` of a given revision number. /// /// Note: this is a revision number in the manifestlog, *not* of any /// changeset. /// /// See also `Repo::manifest_for_rev` pub fn data_for_rev( &self, rev: UncheckedRevision, ) -> Result<Manifest, RevlogError> { let bytes = self.revlog.get_rev_data(rev)?.into_owned(); Ok(Manifest { bytes }) } pub fn data_for_checked_rev( &self, rev: Revision, ) -> Result<Manifest, RevlogError> { let bytes = self.revlog.get_rev_data_for_checked_rev(rev)?.into_owned(); Ok(Manifest { bytes }) } } /// `Manifestlog` entry which knows how to interpret the `manifest` data bytes. #[derive(Debug)] pub struct Manifest { /// Format for a manifest: flat sequence of variable-size entries, /// sorted by path, each as: /// /// ```text /// <path> \0 <hex_node_id> <flags> \n /// ``` /// /// The last entry is also terminated by a newline character. /// Flags is one of `b""` (the empty string), `b"x"`, `b"l"`, or `b"t"`. bytes: Vec<u8>, } impl Manifest { pub fn iter( &self, ) -> impl Iterator<Item = Result<ManifestEntry, HgError>> { self.bytes .split(|b| b == &b'\n') .filter(|line| !line.is_empty()) .map(ManifestEntry::from_raw) } /// If the given path is in this manifest, return its filelog node ID pub fn find_by_path( &self, path: &HgPath, ) -> Result<Option<ManifestEntry>, HgError> { use std::cmp::Ordering::*; let path = path.as_bytes(); // Both boundaries of this `&[u8]` slice are always at the boundary of // an entry let mut bytes = &*self.bytes; // Binary search algorithm derived from `[T]::binary_search_by` // <https://github.com/rust-lang/rust/blob/1.57.0/library/core/src/slice/mod.rs#L2221> // except we don’t have a slice of entries. Instead we jump to the // middle of the byte slice and look around for entry delimiters // (newlines). while let Some(entry_range) = Self::find_entry_near_middle_of(bytes)? { let (entry_path, rest) = ManifestEntry::split_path(&bytes[entry_range.clone()])?; let cmp = entry_path.cmp(path); if cmp == Less { let after_newline = entry_range.end + 1; bytes = &bytes[after_newline..]; } else if cmp == Greater { bytes = &bytes[..entry_range.start]; } else { return Ok(Some(ManifestEntry::from_path_and_rest( entry_path, rest, ))); } } Ok(None) } /// If there is at least one, return the byte range of an entry *excluding* /// the final newline. fn find_entry_near_middle_of( bytes: &[u8], ) -> Result<Option<std::ops::Range<usize>>, HgError> { let len = bytes.len(); if len > 0 { let middle = bytes.len() / 2; // Integer division rounds down, so `middle < len`. let (before, after) = bytes.split_at(middle); let is_newline = |&byte: &u8| byte == b'\n'; let entry_start = match before.iter().rposition(is_newline) { Some(i) => i + 1, None => 0, // We choose the first entry in `bytes` }; let entry_end = match after.iter().position(is_newline) { Some(i) => { // No `+ 1` here to exclude this newline from the range middle + i } None => { // In a well-formed manifest: // // * Since `len > 0`, `bytes` contains at least one entry // * Every entry ends with a newline // * Since `middle < len`, `after` contains at least the // newline at the end of the last entry of `bytes`. // // We didn’t find a newline, so this manifest is not // well-formed. return Err(HgError::corrupted( "manifest entry without \\n delimiter", )); } }; Ok(Some(entry_start..entry_end)) } else { // len == 0 Ok(None) } } } /// `Manifestlog` entry which knows how to interpret the `manifest` data bytes. #[derive(Debug)] pub struct ManifestEntry<'manifest> { pub path: &'manifest HgPath, pub hex_node_id: &'manifest [u8], /// `Some` values are b'x', b'l', or 't' pub flags: Option<u8>, } impl<'a> ManifestEntry<'a> { fn split_path(bytes: &[u8]) -> Result<(&[u8], &[u8]), HgError> { bytes.split_2(b'\0').ok_or_else(|| { HgError::corrupted("manifest entry without \\0 delimiter") }) } fn from_path_and_rest(path: &'a [u8], rest: &'a [u8]) -> Self { let (hex_node_id, flags) = match rest.split_last() { Some((&b'x', rest)) => (rest, Some(b'x')), Some((&b'l', rest)) => (rest, Some(b'l')), Some((&b't', rest)) => (rest, Some(b't')), _ => (rest, None), }; Self { path: HgPath::new(path), hex_node_id, flags, } } fn from_raw(bytes: &'a [u8]) -> Result<Self, HgError> { let (path, rest) = Self::split_path(bytes)?; Ok(Self::from_path_and_rest(path, rest)) } pub fn node_id(&self) -> Result<Node, HgError> { Node::from_hex_for_repo(self.hex_node_id) } }