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

configitems: declare items in a TOML file...

configitems: declare items in a TOML file Mercurial ships with Rust code that also needs to read from the config. Having a way of presenting `configitems` to both Python and Rust is needed to prevent duplication, drift, and have the appropriate devel warnings. Abstracting away from Python means choosing a config format. No single format is perfect, and I have yet to come across a developer that doesn't hate all of them in some way. Since we have a strict no-dependencies policy for Mercurial, we either need to use whatever comes with Python, vendor a library, or implement a custom format ourselves. Python stdlib means using JSON, which doesn't support comments and isn't great for humans, or `configparser` which is an obscure, untyped format that nobody uses and doesn't have a commonplace Rust parser. Implementing a custom format is error-prone, tedious and subject to the same issues as picking an existing format. Vendoring opens us to the vast array of common config formats. The ones being picked for most modern software are YAML and TOML. YAML is older and common in the Python community, but TOML is much simpler and less error-prone. I would much rather be responsible for the <1000 lines of `tomli`, on top of TOML being the choice of the Rust community, with robust crates for reading it. The structure of `configitems.toml` is explained inline.

Raphaël Gomès - - Load All Authors

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             manifest.rs
        
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             / rust / hg-core / src / revlog / manifest.rs
          
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      use crate::errors::HgError;

      use crate::revlog::Revision;

      use crate::revlog::{Node, NodePrefix};

      use crate::revlog::{Revlog, RevlogError};

      use crate::utils::hg_path::HgPath;

      use crate::utils::SliceExt;

      use crate::vfs::Vfs;

      /// A specialized `Revlog` to work with `manifest` data format.

      pub struct Manifestlog {

          /// The generic `revlog` format.

          revlog: Revlog,

      }

      impl Manifestlog {

          /// Open the `manifest` of a repository given by its root.

          pub fn open(store_vfs: &Vfs, use_nodemap: bool) -> Result<Self, HgError> {

              let revlog =

                  Revlog::open(store_vfs, "00manifest.i", None, use_nodemap)?;

              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_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: Revision,

          ) -> Result<Manifest, RevlogError> {

              let bytes = self.revlog.get_rev_data(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)

          }

      }

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				use crate::errors::HgError;
				use crate::revlog::Revision;
				use crate::revlog::{Node, NodePrefix};
				use crate::revlog::{Revlog, RevlogError};
				use crate::utils::hg_path::HgPath;
				use crate::utils::SliceExt;
				use crate::vfs::Vfs;

				/// A specialized `Revlog` to work with `manifest` data format.
				pub struct Manifestlog {
				/// The generic `revlog` format.
				revlog: Revlog,
				}

				impl Manifestlog {
				/// Open the `manifest` of a repository given by its root.
				pub fn open(store_vfs: &Vfs, use_nodemap: bool) -> Result<Self, HgError> {
				let revlog =
				Revlog::open(store_vfs, "00manifest.i", None, use_nodemap)?;
				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_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: Revision,
				) -> Result<Manifest, RevlogError> {
				let bytes = self.revlog.get_rev_data(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)
				}
				}