rust: introduce Repo and Vfs types for filesystem abstraction
This is similar to the corresponding Python classes.
Repo represents a repository and knows the path to the `.hg` directory,
the `store` directory, and the working directory.
Separating these will enable supporting the share extension.
A Vfs is created from a Repo for one of these three directories.
It has filesystem access APIs that take a relative std::path::Path
as a parameter.
Differential Revision: https://phab.mercurial-scm.org/D9596
use std::borrow::Cow;
use std::io::Read;
use std::ops::Deref;
use std::path::Path;
use byteorder::{BigEndian, ByteOrder};
use crypto::digest::Digest;
use crypto::sha1::Sha1;
use flate2::read::ZlibDecoder;
use micro_timer::timed;
use zstd;
use super::index::Index;
use super::node::{NodePrefixRef, NODE_BYTES_LENGTH, NULL_NODE};
use super::nodemap;
use super::nodemap::NodeMap;
use super::nodemap_docket::NodeMapDocket;
use super::patch;
use crate::repo::Repo;
use crate::revlog::Revision;
pub enum RevlogError {
IoError(std::io::Error),
UnsuportedVersion(u16),
InvalidRevision,
/// Found more than one entry whose ID match the requested prefix
AmbiguousPrefix,
Corrupted,
UnknowDataFormat(u8),
}
/// Read only implementation of revlog.
pub struct Revlog {
/// When index and data are not interleaved: bytes of the revlog index.
/// When index and data are interleaved: bytes of the revlog index and
/// data.
index: Index,
/// When index and data are not interleaved: bytes of the revlog data
data_bytes: Option<Box<dyn Deref<Target = [u8]> + Send>>,
/// When present on disk: the persistent nodemap for this revlog
nodemap: Option<nodemap::NodeTree>,
}
impl Revlog {
/// Open a revlog index file.
///
/// It will also open the associated data file if index and data are not
/// interleaved.
#[timed]
pub fn open(
repo: &Repo,
index_path: impl AsRef<Path>,
data_path: Option<&Path>,
) -> Result<Self, RevlogError> {
let index_path = index_path.as_ref();
let index_mmap = repo
.store_vfs()
.mmap_open(&index_path)
.map_err(RevlogError::IoError)?;
let version = get_version(&index_mmap);
if version != 1 {
return Err(RevlogError::UnsuportedVersion(version));
}
let index = Index::new(Box::new(index_mmap))?;
let default_data_path = index_path.with_extension("d");
// type annotation required
// won't recognize Mmap as Deref<Target = [u8]>
let data_bytes: Option<Box<dyn Deref<Target = [u8]> + Send>> =
if index.is_inline() {
None
} else {
let data_path = data_path.unwrap_or(&default_data_path);
let data_mmap = repo
.store_vfs()
.mmap_open(data_path)
.map_err(RevlogError::IoError)?;
Some(Box::new(data_mmap))
};
let nodemap = NodeMapDocket::read_from_file(repo, index_path)?.map(
|(docket, data)| {
nodemap::NodeTree::load_bytes(
Box::new(data),
docket.data_length,
)
},
);
Ok(Revlog {
index,
data_bytes,
nodemap,
})
}
/// Return number of entries of the `Revlog`.
pub fn len(&self) -> usize {
self.index.len()
}
/// Returns `true` if the `Revlog` has zero `entries`.
pub fn is_empty(&self) -> bool {
self.index.is_empty()
}
/// Return the full data associated to a node.
#[timed]
pub fn get_node_rev(
&self,
node: NodePrefixRef,
) -> Result<Revision, RevlogError> {
if let Some(nodemap) = &self.nodemap {
return nodemap
.find_bin(&self.index, node)
// TODO: propagate details of this error:
.map_err(|_| RevlogError::Corrupted)?
.ok_or(RevlogError::InvalidRevision);
}
// Fallback to linear scan when a persistent nodemap is not present.
// This happens when the persistent-nodemap experimental feature is not
// enabled, or for small revlogs.
//
// TODO: consider building a non-persistent nodemap in memory to
// optimize these cases.
let mut found_by_prefix = None;
for rev in (0..self.len() as Revision).rev() {
let index_entry =
self.index.get_entry(rev).ok_or(RevlogError::Corrupted)?;
if node == *index_entry.hash() {
return Ok(rev);
}
if node.is_prefix_of(index_entry.hash()) {
if found_by_prefix.is_some() {
return Err(RevlogError::AmbiguousPrefix);
}
found_by_prefix = Some(rev)
}
}
found_by_prefix.ok_or(RevlogError::InvalidRevision)
}
/// Return the full data associated to a revision.
///
/// All entries required to build the final data out of deltas will be
/// retrieved as needed, and the deltas will be applied to the inital
/// snapshot to rebuild the final data.
#[timed]
pub fn get_rev_data(&self, rev: Revision) -> Result<Vec<u8>, RevlogError> {
// Todo return -> Cow
let mut entry = self.get_entry(rev)?;
let mut delta_chain = vec![];
while let Some(base_rev) = entry.base_rev {
delta_chain.push(entry);
entry =
self.get_entry(base_rev).or(Err(RevlogError::Corrupted))?;
}
// TODO do not look twice in the index
let index_entry = self
.index
.get_entry(rev)
.ok_or(RevlogError::InvalidRevision)?;
let data: Vec<u8> = if delta_chain.is_empty() {
entry.data()?.into()
} else {
Revlog::build_data_from_deltas(entry, &delta_chain)?
};
if self.check_hash(
index_entry.p1(),
index_entry.p2(),
index_entry.hash().as_bytes(),
&data,
) {
Ok(data)
} else {
Err(RevlogError::Corrupted)
}
}
/// Check the hash of some given data against the recorded hash.
pub fn check_hash(
&self,
p1: Revision,
p2: Revision,
expected: &[u8],
data: &[u8],
) -> bool {
let e1 = self.index.get_entry(p1);
let h1 = match e1 {
Some(ref entry) => entry.hash(),
None => &NULL_NODE,
};
let e2 = self.index.get_entry(p2);
let h2 = match e2 {
Some(ref entry) => entry.hash(),
None => &NULL_NODE,
};
hash(data, h1.as_bytes(), h2.as_bytes()).as_slice() == expected
}
/// Build the full data of a revision out its snapshot
/// and its deltas.
#[timed]
fn build_data_from_deltas(
snapshot: RevlogEntry,
deltas: &[RevlogEntry],
) -> Result<Vec<u8>, RevlogError> {
let snapshot = snapshot.data()?;
let deltas = deltas
.iter()
.rev()
.map(RevlogEntry::data)
.collect::<Result<Vec<Cow<'_, [u8]>>, RevlogError>>()?;
let patches: Vec<_> =
deltas.iter().map(|d| patch::PatchList::new(d)).collect();
let patch = patch::fold_patch_lists(&patches);
Ok(patch.apply(&snapshot))
}
/// Return the revlog data.
fn data(&self) -> &[u8] {
match self.data_bytes {
Some(ref data_bytes) => &data_bytes,
None => panic!(
"forgot to load the data or trying to access inline data"
),
}
}
/// Get an entry of the revlog.
fn get_entry(&self, rev: Revision) -> Result<RevlogEntry, RevlogError> {
let index_entry = self
.index
.get_entry(rev)
.ok_or(RevlogError::InvalidRevision)?;
let start = index_entry.offset();
let end = start + index_entry.compressed_len();
let data = if self.index.is_inline() {
self.index.data(start, end)
} else {
&self.data()[start..end]
};
let entry = RevlogEntry {
rev,
bytes: data,
compressed_len: index_entry.compressed_len(),
uncompressed_len: index_entry.uncompressed_len(),
base_rev: if index_entry.base_revision() == rev {
None
} else {
Some(index_entry.base_revision())
},
};
Ok(entry)
}
}
/// The revlog entry's bytes and the necessary informations to extract
/// the entry's data.
#[derive(Debug)]
pub struct RevlogEntry<'a> {
rev: Revision,
bytes: &'a [u8],
compressed_len: usize,
uncompressed_len: usize,
base_rev: Option<Revision>,
}
impl<'a> RevlogEntry<'a> {
/// Extract the data contained in the entry.
pub fn data(&self) -> Result<Cow<'_, [u8]>, RevlogError> {
if self.bytes.is_empty() {
return Ok(Cow::Borrowed(&[]));
}
match self.bytes[0] {
// Revision data is the entirety of the entry, including this
// header.
b'\0' => Ok(Cow::Borrowed(self.bytes)),
// Raw revision data follows.
b'u' => Ok(Cow::Borrowed(&self.bytes[1..])),
// zlib (RFC 1950) data.
b'x' => Ok(Cow::Owned(self.uncompressed_zlib_data()?)),
// zstd data.
b'\x28' => Ok(Cow::Owned(self.uncompressed_zstd_data()?)),
format_type => Err(RevlogError::UnknowDataFormat(format_type)),
}
}
fn uncompressed_zlib_data(&self) -> Result<Vec<u8>, RevlogError> {
let mut decoder = ZlibDecoder::new(self.bytes);
if self.is_delta() {
let mut buf = Vec::with_capacity(self.compressed_len);
decoder
.read_to_end(&mut buf)
.or(Err(RevlogError::Corrupted))?;
Ok(buf)
} else {
let mut buf = vec![0; self.uncompressed_len];
decoder
.read_exact(&mut buf)
.or(Err(RevlogError::Corrupted))?;
Ok(buf)
}
}
fn uncompressed_zstd_data(&self) -> Result<Vec<u8>, RevlogError> {
if self.is_delta() {
let mut buf = Vec::with_capacity(self.compressed_len);
zstd::stream::copy_decode(self.bytes, &mut buf)
.or(Err(RevlogError::Corrupted))?;
Ok(buf)
} else {
let mut buf = vec![0; self.uncompressed_len];
let len = zstd::block::decompress_to_buffer(self.bytes, &mut buf)
.or(Err(RevlogError::Corrupted))?;
if len != self.uncompressed_len {
Err(RevlogError::Corrupted)
} else {
Ok(buf)
}
}
}
/// Tell if the entry is a snapshot or a delta
/// (influences on decompression).
fn is_delta(&self) -> bool {
self.base_rev.is_some()
}
}
/// Format version of the revlog.
pub fn get_version(index_bytes: &[u8]) -> u16 {
BigEndian::read_u16(&index_bytes[2..=3])
}
/// Calculate the hash of a revision given its data and its parents.
fn hash(data: &[u8], p1_hash: &[u8], p2_hash: &[u8]) -> Vec<u8> {
let mut hasher = Sha1::new();
let (a, b) = (p1_hash, p2_hash);
if a > b {
hasher.input(b);
hasher.input(a);
} else {
hasher.input(a);
hasher.input(b);
}
hasher.input(data);
let mut hash = vec![0; NODE_BYTES_LENGTH];
hasher.result(&mut hash);
hash
}
#[cfg(test)]
mod tests {
use super::*;
use super::super::index::IndexEntryBuilder;
#[test]
fn version_test() {
let bytes = IndexEntryBuilder::new()
.is_first(true)
.with_version(1)
.build();
assert_eq!(get_version(&bytes), 1)
}
}