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

rust-node: binary Node ID and conversion utilities...

rust-node: binary Node ID and conversion utilities The choice of type makes sure that a `Node` has the exact wanted size. We'll use a different type for prefixes. Added dependency: hexadecimal conversion relies on the `hex` crate. The fact that sooner or later Mercurial is going to need to change its hash sizes has been taken strongly in consideration: - the hash length is a constant, but that is not directly exposed to callers. Changing the value of that constant is the only thing to do to change the hash length (even in unit tests) - the code could be adapted to support several sizes of hashes, if that turned out to be useful. To that effect, only the size of a given `Node` is exposed in the public API. - callers not involved in initial computation, I/O and FFI are able to operate without a priori assumptions on the hash size. The traits `FromHex` and `ToHex` have not been directly implemented, so that the doc-comments explaining these restrictions would stay really visible in `cargo doc` Differential Revision: https://phab.mercurial-scm.org/D7788

Georges Racinet - - Load All Authors

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      // Copyright 2019-2020 Georges Racinet <georges.racinet@octobus.net>

      //

      // This software may be used and distributed according to the terms of the

      // GNU General Public License version 2 or any later version.

      //! Definitions and utilities for Revision nodes

      //!

      //! In Mercurial code base, it is customary to call "a node" the binary SHA

      //! of a revision.

      use hex::{self, FromHex, FromHexError};

      /// The length in bytes of a `Node`

      ///

      /// This constant is meant to ease refactors of this module, and

      /// are private so that calling code does not expect all nodes have

      /// the same size, should we support several formats concurrently in

      /// the future.

      const NODE_BYTES_LENGTH: usize = 20;

      /// The length in bytes of a `Node`

      ///

      /// see also `NODES_BYTES_LENGTH` about it being private.

      const NODE_NYBBLES_LENGTH: usize = 2 * NODE_BYTES_LENGTH;

      /// Private alias for readability and to ease future change

      type NodeData = [u8; NODE_BYTES_LENGTH];

      /// Binary revision SHA

      ///

      /// ## Future changes of hash size

      ///

      /// To accomodate future changes of hash size, Rust callers

      /// should use the conversion methods at the boundaries (FFI, actual

      /// computation of hashes and I/O) only, and only if required.

      ///

      /// All other callers outside of unit tests should just handle `Node` values

      /// and never make any assumption on the actual length, using [`nybbles_len`]

      /// if they need a loop boundary.

      ///

      /// All methods that create a `Node` either take a type that enforces

      /// the size or fail immediately at runtime with [`ExactLengthRequired`].

      ///

      /// [`nybbles_len`]: #method.nybbles_len

      /// [`ExactLengthRequired`]: struct.NodeError#variant.ExactLengthRequired

      #[derive(Clone, Debug, PartialEq)]

      pub struct Node {

          data: NodeData,

      }

      /// The node value for NULL_REVISION

      pub const NULL_NODE: Node = Node {

          data: [0; NODE_BYTES_LENGTH],

      };

      impl From<NodeData> for Node {

          fn from(data: NodeData) -> Node {

              Node { data }

          }

      }

      #[derive(Debug, PartialEq)]

      pub enum NodeError {

          ExactLengthRequired(usize, String),

          HexError(FromHexError, String),

      }

      /// Low level utility function, also for prefixes

      fn get_nybble(s: &[u8], i: usize) -> u8 {

          if i % 2 == 0 {

              s[i / 2] >> 4

          } else {

              s[i / 2] & 0x0f

          }

      }

      impl Node {

          /// Retrieve the `i`th half-byte of the binary data.

          ///

          /// This is also the `i`th hexadecimal digit in numeric form,

          /// also called a [nybble](https://en.wikipedia.org/wiki/Nibble).

          pub fn get_nybble(&self, i: usize) -> u8 {

              get_nybble(&self.data, i)

          }

          /// Length of the data, in nybbles

          pub fn nybbles_len(&self) -> usize {

              // public exposure as an instance method only, so that we can

              // easily support several sizes of hashes if needed in the future.

              NODE_NYBBLES_LENGTH

          }

          /// Convert from hexadecimal string representation

          ///

          /// Exact length is required.

          ///

          /// To be used in FFI and I/O only, in order to facilitate future

          /// changes of hash format.

          pub fn from_hex(hex: &str) -> Result<Node, NodeError> {

              Ok(NodeData::from_hex(hex)

                  .map_err(|e| NodeError::from((e, hex)))?

                  .into())

          }

          /// Convert to hexadecimal string representation

          ///

          /// To be used in FFI and I/O only, in order to facilitate future

          /// changes of hash format.

          pub fn encode_hex(&self) -> String {

              hex::encode(self.data)

          }

          /// Provide access to binary data

          ///

          /// This is needed by FFI layers, for instance to return expected

          /// binary values to Python.

          pub fn as_bytes(&self) -> &[u8] {

              &self.data

          }

      }

      impl From<(FromHexError, &str)> for NodeError {

          fn from(err_offender: (FromHexError, &str)) -> Self {

              let (err, offender) = err_offender;

              match err {

                  FromHexError::InvalidStringLength => {

                      NodeError::ExactLengthRequired(

                          NODE_NYBBLES_LENGTH,

                          offender.to_string(),

                      )

                  }

                  _ => NodeError::HexError(err, offender.to_string()),

              }

          }

      }

      #[cfg(test)]

      mod tests {

          use super::*;

          fn sample_node() -> Node {

              let mut data = [0; NODE_BYTES_LENGTH];

              data.copy_from_slice(&[

                  0x01, 0x23, 0x45, 0x67, 0x89, 0xab, 0xcd, 0xef, 0xfe, 0xdc, 0xba,

                  0x98, 0x76, 0x54, 0x32, 0x10, 0xde, 0xad, 0xbe, 0xef,

              ]);

              data.into()

          }

          /// Pad an hexadecimal string to reach `NODE_NYBBLES_LENGTH`

          ///

          /// The padding is made with zeros

          fn hex_pad_right(hex: &str) -> String {

              let mut res = hex.to_string();

              while res.len() < NODE_NYBBLES_LENGTH {

                  res.push('0');

              }

              res

          }

          fn sample_node_hex() -> String {

              hex_pad_right("0123456789abcdeffedcba9876543210deadbeef")

          }

          #[test]

          fn test_node_from_hex() {

              assert_eq!(Node::from_hex(&sample_node_hex()), Ok(sample_node()));

              let mut short = hex_pad_right("0123");

              short.pop();

              short.pop();

              assert_eq!(

                  Node::from_hex(&short),

                  Err(NodeError::ExactLengthRequired(NODE_NYBBLES_LENGTH, short)),

              );

              let not_hex = hex_pad_right("012... oops");

              assert_eq!(

                  Node::from_hex(&not_hex),

                  Err(NodeError::HexError(

                      FromHexError::InvalidHexCharacter { c: '.', index: 3 },

                      not_hex,

                  )),

              );

          }

          #[test]

          fn test_node_encode_hex() {

              assert_eq!(sample_node().encode_hex(), sample_node_hex());

          }

      }

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				// Copyright 2019-2020 Georges Racinet <georges.racinet@octobus.net>
				//
				// This software may be used and distributed according to the terms of the
				// GNU General Public License version 2 or any later version.

				//! Definitions and utilities for Revision nodes
				//!
				//! In Mercurial code base, it is customary to call "a node" the binary SHA
				//! of a revision.

				use hex::{self, FromHex, FromHexError};

				/// The length in bytes of a `Node`
				///
				/// This constant is meant to ease refactors of this module, and
				/// are private so that calling code does not expect all nodes have
				/// the same size, should we support several formats concurrently in
				/// the future.
				const NODE_BYTES_LENGTH: usize = 20;

				/// The length in bytes of a `Node`
				///
				/// see also `NODES_BYTES_LENGTH` about it being private.
				const NODE_NYBBLES_LENGTH: usize = 2 * NODE_BYTES_LENGTH;

				/// Private alias for readability and to ease future change
				type NodeData = [u8; NODE_BYTES_LENGTH];

				/// Binary revision SHA
				///
				/// ## Future changes of hash size
				///
				/// To accomodate future changes of hash size, Rust callers
				/// should use the conversion methods at the boundaries (FFI, actual
				/// computation of hashes and I/O) only, and only if required.
				///
				/// All other callers outside of unit tests should just handle `Node` values
				/// and never make any assumption on the actual length, using [`nybbles_len`]
				/// if they need a loop boundary.
				///
				/// All methods that create a `Node` either take a type that enforces
				/// the size or fail immediately at runtime with [`ExactLengthRequired`].
				///
				/// [`nybbles_len`]: #method.nybbles_len
				/// [`ExactLengthRequired`]: struct.NodeError#variant.ExactLengthRequired
				#[derive(Clone, Debug, PartialEq)]
				pub struct Node {
				data: NodeData,
				}

				/// The node value for NULL_REVISION
				pub const NULL_NODE: Node = Node {
				data: [0; NODE_BYTES_LENGTH],
				};

				impl From<NodeData> for Node {
				fn from(data: NodeData) -> Node {
				Node { data }
				}
				}

				#[derive(Debug, PartialEq)]
				pub enum NodeError {
				ExactLengthRequired(usize, String),
				HexError(FromHexError, String),
				}

				/// Low level utility function, also for prefixes
				fn get_nybble(s: &[u8], i: usize) -> u8 {
				if i % 2 == 0 {
				s[i / 2] >> 4
				} else {
				s[i / 2] & 0x0f
				}
				}

				impl Node {
				/// Retrieve the `i`th half-byte of the binary data.
				///
				/// This is also the `i`th hexadecimal digit in numeric form,
				/// also called a [nybble](https://en.wikipedia.org/wiki/Nibble).
				pub fn get_nybble(&self, i: usize) -> u8 {
				get_nybble(&self.data, i)
				}

				/// Length of the data, in nybbles
				pub fn nybbles_len(&self) -> usize {
				// public exposure as an instance method only, so that we can
				// easily support several sizes of hashes if needed in the future.
				NODE_NYBBLES_LENGTH
				}

				/// Convert from hexadecimal string representation
				///
				/// Exact length is required.
				///
				/// To be used in FFI and I/O only, in order to facilitate future
				/// changes of hash format.
				pub fn from_hex(hex: &str) -> Result<Node, NodeError> {
				Ok(NodeData::from_hex(hex)
				.map_err(\|e\| NodeError::from((e, hex)))?
				.into())
				}

				/// Convert to hexadecimal string representation
				///
				/// To be used in FFI and I/O only, in order to facilitate future
				/// changes of hash format.
				pub fn encode_hex(&self) -> String {
				hex::encode(self.data)
				}

				/// Provide access to binary data
				///
				/// This is needed by FFI layers, for instance to return expected
				/// binary values to Python.
				pub fn as_bytes(&self) -> &[u8] {
				&self.data
				}
				}

				impl From<(FromHexError, &str)> for NodeError {
				fn from(err_offender: (FromHexError, &str)) -> Self {
				let (err, offender) = err_offender;
				match err {
				FromHexError::InvalidStringLength => {
				NodeError::ExactLengthRequired(
				NODE_NYBBLES_LENGTH,
				offender.to_string(),
				)
				}
				_ => NodeError::HexError(err, offender.to_string()),
				}
				}
				}

				#[cfg(test)]
				mod tests {
				use super::*;

				fn sample_node() -> Node {
				let mut data = [0; NODE_BYTES_LENGTH];
				data.copy_from_slice(&[
				0x01, 0x23, 0x45, 0x67, 0x89, 0xab, 0xcd, 0xef, 0xfe, 0xdc, 0xba,
				0x98, 0x76, 0x54, 0x32, 0x10, 0xde, 0xad, 0xbe, 0xef,
				]);
				data.into()
				}

				/// Pad an hexadecimal string to reach `NODE_NYBBLES_LENGTH`
				///
				/// The padding is made with zeros
				fn hex_pad_right(hex: &str) -> String {
				let mut res = hex.to_string();
				while res.len() < NODE_NYBBLES_LENGTH {
				res.push('0');
				}
				res
				}

				fn sample_node_hex() -> String {
				hex_pad_right("0123456789abcdeffedcba9876543210deadbeef")
				}

				#[test]
				fn test_node_from_hex() {
				assert_eq!(Node::from_hex(&sample_node_hex()), Ok(sample_node()));

				let mut short = hex_pad_right("0123");
				short.pop();
				short.pop();
				assert_eq!(
				Node::from_hex(&short),
				Err(NodeError::ExactLengthRequired(NODE_NYBBLES_LENGTH, short)),
				);

				let not_hex = hex_pad_right("012... oops");
				assert_eq!(
				Node::from_hex(&not_hex),
				Err(NodeError::HexError(
				FromHexError::InvalidHexCharacter { c: '.', index: 3 },
				not_hex,
				)),
				);
				}

				#[test]
				fn test_node_encode_hex() {
				assert_eq!(sample_node().encode_hex(), sample_node_hex());
				}
				}