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rust-nodemap: NodeMap trait with simplest implementation...
rust-nodemap: NodeMap trait with simplest implementation We're defining here only a small part of the immutable methods it will have at the end. This is so we can focus in the following changesets on the needed abstractions for a mutable append-only serializable version. The first implementor exposes the actual lookup algorithm in its simplest form. It will have to be expanded to account for the missing methods, and the special cases related to NULL_NODE. Differential Revision: https://phab.mercurial-scm.org/D7791
Georges Racinet - - Load All Authors

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node.rs
367 lines | 10.6 KiB | application/rls-services+xml | RustLexer
/ rust / hg-core / src / revlog / node.rs
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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),
PrefixTooLong(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<T: AsRef<str>> From<(FromHexError, T)> for NodeError {
fn from(err_offender: (FromHexError, T)) -> Self {
let (err, offender) = err_offender;
match err {
FromHexError::InvalidStringLength => {
NodeError::ExactLengthRequired(
NODE_NYBBLES_LENGTH,
offender.as_ref().to_owned(),
)
}
_ => NodeError::HexError(err, offender.as_ref().to_owned()),
}
}
}
/// The beginning of a binary revision SHA.
///
/// Since it can potentially come from an hexadecimal representation with
/// odd length, it needs to carry around whether the last 4 bits are relevant
/// or not.
#[derive(Debug, PartialEq)]
pub struct NodePrefix {
buf: Vec<u8>,
is_odd: bool,
}
impl NodePrefix {
/// Convert from hexadecimal string representation
///
/// Similarly to `hex::decode`, can be used with Unicode string types
/// (`String`, `&str`) as well as bytes.
///
/// To be used in FFI and I/O only, in order to facilitate future
/// changes of hash format.
pub fn from_hex(hex: impl AsRef<[u8]>) -> Result<Self, NodeError> {
let hex = hex.as_ref();
let len = hex.len();
if len > NODE_NYBBLES_LENGTH {
return Err(NodeError::PrefixTooLong(
String::from_utf8_lossy(hex).to_owned().to_string(),
));
}
let is_odd = len % 2 == 1;
let even_part = if is_odd { &hex[..len - 1] } else { hex };
let mut buf: Vec<u8> = Vec::from_hex(&even_part)
.map_err(|e| (e, String::from_utf8_lossy(hex)))?;
if is_odd {
let latest_char = char::from(hex[len - 1]);
let latest_nybble = latest_char.to_digit(16).ok_or_else(|| {
(
FromHexError::InvalidHexCharacter {
c: latest_char,
index: len - 1,
},
String::from_utf8_lossy(hex),
)
})? as u8;
buf.push(latest_nybble << 4);
}
Ok(NodePrefix { buf, is_odd })
}
pub fn borrow(&self) -> NodePrefixRef {
NodePrefixRef {
buf: &self.buf,
is_odd: self.is_odd,
}
}
}
#[derive(Clone, Debug, PartialEq)]
pub struct NodePrefixRef<'a> {
buf: &'a [u8],
is_odd: bool,
}
impl<'a> NodePrefixRef<'a> {
pub fn len(&self) -> usize {
if self.is_odd {
self.buf.len() * 2 - 1
} else {
self.buf.len() * 2
}
}
pub fn is_prefix_of(&self, node: &Node) -> bool {
if self.is_odd {
let buf = self.buf;
let last_pos = buf.len() - 1;
node.data.starts_with(buf.split_at(last_pos).0)
&& node.data[last_pos] >> 4 == buf[last_pos] >> 4
} else {
node.data.starts_with(self.buf)
}
}
/// Retrieve the `i`th half-byte from the prefix.
///
/// 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.buf, i)
}
}
/// A shortcut for full `Node` references
impl<'a> From<&'a Node> for NodePrefixRef<'a> {
fn from(node: &'a Node) -> Self {
NodePrefixRef {
buf: &node.data,
is_odd: false,
}
}
}
#[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
pub 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());
}
#[test]
fn test_prefix_from_hex() -> Result<(), NodeError> {
assert_eq!(
NodePrefix::from_hex("0e1")?,
NodePrefix {
buf: vec![14, 16],
is_odd: true
}
);
assert_eq!(
NodePrefix::from_hex("0e1a")?,
NodePrefix {
buf: vec![14, 26],
is_odd: false
}
);
// checking limit case
let node_as_vec = sample_node().data.iter().cloned().collect();
assert_eq!(
NodePrefix::from_hex(sample_node_hex())?,
NodePrefix {
buf: node_as_vec,
is_odd: false
}
);
Ok(())
}
#[test]
fn test_prefix_from_hex_errors() {
assert_eq!(
NodePrefix::from_hex("testgr"),
Err(NodeError::HexError(
FromHexError::InvalidHexCharacter { c: 't', index: 0 },
"testgr".to_string()
))
);
let mut long = NULL_NODE.encode_hex();
long.push('c');
match NodePrefix::from_hex(&long)
.expect_err("should be refused as too long")
{
NodeError::PrefixTooLong(s) => assert_eq!(s, long),
err => panic!(format!("Should have been TooLong, got {:?}", err)),
}
}
#[test]
fn test_is_prefix_of() -> Result<(), NodeError> {
let mut node_data = [0; NODE_BYTES_LENGTH];
node_data[0] = 0x12;
node_data[1] = 0xca;
let node = Node::from(node_data);
assert!(NodePrefix::from_hex("12")?.borrow().is_prefix_of(&node));
assert!(!NodePrefix::from_hex("1a")?.borrow().is_prefix_of(&node));
assert!(NodePrefix::from_hex("12c")?.borrow().is_prefix_of(&node));
assert!(!NodePrefix::from_hex("12d")?.borrow().is_prefix_of(&node));
Ok(())
}
#[test]
fn test_get_nybble() -> Result<(), NodeError> {
let prefix = NodePrefix::from_hex("dead6789cafe")?;
assert_eq!(prefix.borrow().get_nybble(0), 13);
assert_eq!(prefix.borrow().get_nybble(7), 9);
Ok(())
}
}
#[cfg(test)]
pub use tests::hex_pad_right;