upstream/mercurial-mirror Files · rust/hg-core/src/revlog/revlog.rs

hooks: introduce a `:run-with-plain` option for hooks...

hooks: introduce a `:run-with-plain` option for hooks This option control if HGPLAIN should be set or not for the hooks. This is the first step to give user some control of the HGPLAIN setting for they hooks. Some hooks (eg: consistency checking) deserve to be run with HGPLAIN, some other (eg: user set visual helper) might need to respect the user config and setting. So both usage are valid and we need to restore the ability to run -without- HGPLAIN that got lost in Mercurial 5.7. This does not offer a way to restore the pre-5.7 behavior yet (respect whatever HGPLAIN setting from the shell), this will be dealt with in the next changeset. The option name is a bit verbose because implementing this highlighs the need for another option: `:run-if-plain`. That would make it possible for some hooks to be easily disabled if HG PLAIN is set. However such option would be a new feature, not something introduced to mitigate a behavior change introduced in 5.7, so the `:run-if-plain` option belong to the default branch and is not part of this series. Differential Revision: https://phab.mercurial-scm.org/D9981

Simon Sapin - - Load All Authors

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             revlog.rs
        
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      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)

          }

      }

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				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)
				}
				}