nodemap.rs
1118 lines
| 36.2 KiB
| application/rls-services+xml
|
RustLexer
Georges Racinet
|
r44600 | // Copyright 2018-2020 Georges Racinet <georges.racinet@octobus.net> | ||
// and Mercurial contributors | ||||
// | ||||
// This software may be used and distributed according to the terms of the | ||||
// GNU General Public License version 2 or any later version. | ||||
//! Indexing facilities for fast retrieval of `Revision` from `Node` | ||||
//! | ||||
//! This provides a variation on the 16-ary radix tree that is | ||||
//! provided as "nodetree" in revlog.c, ready for append-only persistence | ||||
//! on disk. | ||||
//! | ||||
//! Following existing implicit conventions, the "nodemap" terminology | ||||
//! is used in a more abstract context. | ||||
Georges Racinet
|
r44644 | use super::{ | ||
Georges Racinet
|
r44871 | node::NULL_NODE, Node, NodeError, NodePrefix, NodePrefixRef, Revision, | ||
RevlogIndex, NULL_REVISION, | ||||
Georges Racinet
|
r44644 | }; | ||
Georges Racinet
|
r44831 | |||
Georges Racinet
|
r44872 | use std::cmp::max; | ||
Georges Racinet
|
r44600 | use std::fmt; | ||
Georges Racinet
|
r44869 | use std::mem; | ||
Georges Racinet
|
r44644 | use std::ops::Deref; | ||
Georges Racinet
|
r44645 | use std::ops::Index; | ||
Georges Racinet
|
r44869 | use std::slice; | ||
Georges Racinet
|
r44644 | |||
#[derive(Debug, PartialEq)] | ||||
pub enum NodeMapError { | ||||
MultipleResults, | ||||
InvalidNodePrefix(NodeError), | ||||
/// A `Revision` stored in the nodemap could not be found in the index | ||||
RevisionNotInIndex(Revision), | ||||
} | ||||
impl From<NodeError> for NodeMapError { | ||||
fn from(err: NodeError) -> Self { | ||||
NodeMapError::InvalidNodePrefix(err) | ||||
} | ||||
} | ||||
/// Mapping system from Mercurial nodes to revision numbers. | ||||
/// | ||||
/// ## `RevlogIndex` and `NodeMap` | ||||
/// | ||||
/// One way to think about their relationship is that | ||||
/// the `NodeMap` is a prefix-oriented reverse index of the `Node` information | ||||
/// carried by a [`RevlogIndex`]. | ||||
/// | ||||
/// Many of the methods in this trait take a `RevlogIndex` argument | ||||
/// which is used for validation of their results. This index must naturally | ||||
/// be the one the `NodeMap` is about, and it must be consistent. | ||||
/// | ||||
/// Notably, the `NodeMap` must not store | ||||
/// information about more `Revision` values than there are in the index. | ||||
/// In these methods, an encountered `Revision` is not in the index, a | ||||
/// [`RevisionNotInIndex`] error is returned. | ||||
/// | ||||
/// In insert operations, the rule is thus that the `NodeMap` must always | ||||
/// be updated after the `RevlogIndex` | ||||
/// be updated first, and the `NodeMap` second. | ||||
/// | ||||
/// [`RevisionNotInIndex`]: enum.NodeMapError.html#variant.RevisionNotInIndex | ||||
/// [`RevlogIndex`]: ../trait.RevlogIndex.html | ||||
pub trait NodeMap { | ||||
/// Find the unique `Revision` having the given `Node` | ||||
/// | ||||
/// If no Revision matches the given `Node`, `Ok(None)` is returned. | ||||
fn find_node( | ||||
&self, | ||||
index: &impl RevlogIndex, | ||||
node: &Node, | ||||
) -> Result<Option<Revision>, NodeMapError> { | ||||
self.find_bin(index, node.into()) | ||||
} | ||||
/// Find the unique Revision whose `Node` starts with a given binary prefix | ||||
/// | ||||
/// If no Revision matches the given prefix, `Ok(None)` is returned. | ||||
/// | ||||
/// If several Revisions match the given prefix, a [`MultipleResults`] | ||||
/// error is returned. | ||||
fn find_bin<'a>( | ||||
&self, | ||||
idx: &impl RevlogIndex, | ||||
prefix: NodePrefixRef<'a>, | ||||
) -> Result<Option<Revision>, NodeMapError>; | ||||
/// Find the unique Revision whose `Node` hexadecimal string representation | ||||
/// starts with a given prefix | ||||
/// | ||||
/// If no Revision matches the given prefix, `Ok(None)` is returned. | ||||
/// | ||||
/// If several Revisions match the given prefix, a [`MultipleResults`] | ||||
/// error is returned. | ||||
fn find_hex( | ||||
&self, | ||||
idx: &impl RevlogIndex, | ||||
prefix: &str, | ||||
) -> Result<Option<Revision>, NodeMapError> { | ||||
self.find_bin(idx, NodePrefix::from_hex(prefix)?.borrow()) | ||||
} | ||||
Georges Racinet
|
r44872 | |||
/// Give the size of the shortest node prefix that determines | ||||
/// the revision uniquely. | ||||
/// | ||||
/// From a binary node prefix, if it is matched in the node map, this | ||||
/// returns the number of hexadecimal digits that would had sufficed | ||||
/// to find the revision uniquely. | ||||
/// | ||||
/// Returns `None` if no `Revision` could be found for the prefix. | ||||
/// | ||||
/// If several Revisions match the given prefix, a [`MultipleResults`] | ||||
/// error is returned. | ||||
fn unique_prefix_len_bin<'a>( | ||||
&self, | ||||
idx: &impl RevlogIndex, | ||||
node_prefix: NodePrefixRef<'a>, | ||||
) -> Result<Option<usize>, NodeMapError>; | ||||
/// Same as `unique_prefix_len_bin`, with the hexadecimal representation | ||||
/// of the prefix as input. | ||||
fn unique_prefix_len_hex( | ||||
&self, | ||||
idx: &impl RevlogIndex, | ||||
prefix: &str, | ||||
) -> Result<Option<usize>, NodeMapError> { | ||||
self.unique_prefix_len_bin(idx, NodePrefix::from_hex(prefix)?.borrow()) | ||||
} | ||||
/// Same as `unique_prefix_len_bin`, with a full `Node` as input | ||||
fn unique_prefix_len_node( | ||||
&self, | ||||
idx: &impl RevlogIndex, | ||||
node: &Node, | ||||
) -> Result<Option<usize>, NodeMapError> { | ||||
self.unique_prefix_len_bin(idx, node.into()) | ||||
} | ||||
Georges Racinet
|
r44644 | } | ||
Georges Racinet
|
r44600 | |||
Georges Racinet
|
r44831 | pub trait MutableNodeMap: NodeMap { | ||
fn insert<I: RevlogIndex>( | ||||
&mut self, | ||||
index: &I, | ||||
node: &Node, | ||||
rev: Revision, | ||||
) -> Result<(), NodeMapError>; | ||||
} | ||||
Georges Racinet
|
r44600 | /// Low level NodeTree [`Blocks`] elements | ||
/// | ||||
/// These are exactly as for instance on persistent storage. | ||||
type RawElement = i32; | ||||
/// High level representation of values in NodeTree | ||||
/// [`Blocks`](struct.Block.html) | ||||
/// | ||||
/// This is the high level representation that most algorithms should | ||||
/// use. | ||||
#[derive(Clone, Debug, Eq, PartialEq)] | ||||
enum Element { | ||||
Rev(Revision), | ||||
Block(usize), | ||||
None, | ||||
} | ||||
impl From<RawElement> for Element { | ||||
/// Conversion from low level representation, after endianness conversion. | ||||
/// | ||||
/// See [`Block`](struct.Block.html) for explanation about the encoding. | ||||
fn from(raw: RawElement) -> Element { | ||||
if raw >= 0 { | ||||
Element::Block(raw as usize) | ||||
} else if raw == -1 { | ||||
Element::None | ||||
} else { | ||||
Element::Rev(-raw - 2) | ||||
} | ||||
} | ||||
} | ||||
impl From<Element> for RawElement { | ||||
fn from(element: Element) -> RawElement { | ||||
match element { | ||||
Element::None => 0, | ||||
Element::Block(i) => i as RawElement, | ||||
Element::Rev(rev) => -rev - 2, | ||||
} | ||||
} | ||||
} | ||||
/// A logical block of the `NodeTree`, packed with a fixed size. | ||||
/// | ||||
/// These are always used in container types implementing `Index<Block>`, | ||||
/// such as `&Block` | ||||
/// | ||||
/// As an array of integers, its ith element encodes that the | ||||
/// ith potential edge from the block, representing the ith hexadecimal digit | ||||
/// (nybble) `i` is either: | ||||
/// | ||||
/// - absent (value -1) | ||||
/// - another `Block` in the same indexable container (value ≥ 0) | ||||
/// - a `Revision` leaf (value ≤ -2) | ||||
/// | ||||
/// Endianness has to be fixed for consistency on shared storage across | ||||
/// different architectures. | ||||
/// | ||||
/// A key difference with the C `nodetree` is that we need to be | ||||
/// able to represent the [`Block`] at index 0, hence -1 is the empty marker | ||||
/// rather than 0 and the `Revision` range upper limit of -2 instead of -1. | ||||
/// | ||||
/// Another related difference is that `NULL_REVISION` (-1) is not | ||||
/// represented at all, because we want an immutable empty nodetree | ||||
/// to be valid. | ||||
Georges Racinet
|
r44869 | #[derive(Copy, Clone)] | ||
pub struct Block([u8; BLOCK_SIZE]); | ||||
/// Not derivable for arrays of length >32 until const generics are stable | ||||
impl PartialEq for Block { | ||||
fn eq(&self, other: &Self) -> bool { | ||||
Raphaël Gomès
|
r45500 | self.0[..] == other.0[..] | ||
Georges Racinet
|
r44869 | } | ||
} | ||||
pub const BLOCK_SIZE: usize = 64; | ||||
Georges Racinet
|
r44600 | |||
impl Block { | ||||
fn new() -> Self { | ||||
Georges Racinet
|
r44869 | // -1 in 2's complement to create an absent node | ||
let byte: u8 = 255; | ||||
Block([byte; BLOCK_SIZE]) | ||||
Georges Racinet
|
r44600 | } | ||
fn get(&self, nybble: u8) -> Element { | ||||
Georges Racinet
|
r44869 | let index = nybble as usize * mem::size_of::<RawElement>(); | ||
Element::from(RawElement::from_be_bytes([ | ||||
self.0[index], | ||||
self.0[index + 1], | ||||
self.0[index + 2], | ||||
self.0[index + 3], | ||||
])) | ||||
Georges Racinet
|
r44600 | } | ||
fn set(&mut self, nybble: u8, element: Element) { | ||||
Georges Racinet
|
r44869 | let values = RawElement::to_be_bytes(element.into()); | ||
let index = nybble as usize * mem::size_of::<RawElement>(); | ||||
self.0[index] = values[0]; | ||||
self.0[index + 1] = values[1]; | ||||
self.0[index + 2] = values[2]; | ||||
self.0[index + 3] = values[3]; | ||||
Georges Racinet
|
r44600 | } | ||
} | ||||
impl fmt::Debug for Block { | ||||
/// sparse representation for testing and debugging purposes | ||||
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { | ||||
f.debug_map() | ||||
.entries((0..16).filter_map(|i| match self.get(i) { | ||||
Element::None => None, | ||||
element => Some((i, element)), | ||||
})) | ||||
.finish() | ||||
} | ||||
} | ||||
Georges Racinet
|
r44646 | /// A mutable 16-radix tree with the root block logically at the end | ||
/// | ||||
/// Because of the append only nature of our node trees, we need to | ||||
/// keep the original untouched and store new blocks separately. | ||||
/// | ||||
/// The mutable root `Block` is kept apart so that we don't have to rebump | ||||
/// it on each insertion. | ||||
Georges Racinet
|
r44644 | pub struct NodeTree { | ||
readonly: Box<dyn Deref<Target = [Block]> + Send>, | ||||
Georges Racinet
|
r44646 | growable: Vec<Block>, | ||
root: Block, | ||||
Georges Racinet
|
r44873 | masked_inner_blocks: usize, | ||
Georges Racinet
|
r44644 | } | ||
Georges Racinet
|
r44645 | impl Index<usize> for NodeTree { | ||
type Output = Block; | ||||
fn index(&self, i: usize) -> &Block { | ||||
Georges Racinet
|
r44646 | let ro_len = self.readonly.len(); | ||
if i < ro_len { | ||||
&self.readonly[i] | ||||
} else if i == ro_len + self.growable.len() { | ||||
&self.root | ||||
} else { | ||||
&self.growable[i - ro_len] | ||||
} | ||||
Georges Racinet
|
r44645 | } | ||
} | ||||
Georges Racinet
|
r44644 | /// Return `None` unless the `Node` for `rev` has given prefix in `index`. | ||
Georges Racinet
|
r44869 | fn has_prefix_or_none( | ||
Georges Racinet
|
r44644 | idx: &impl RevlogIndex, | ||
Georges Racinet
|
r44869 | prefix: NodePrefixRef, | ||
Georges Racinet
|
r44644 | rev: Revision, | ||
) -> Result<Option<Revision>, NodeMapError> { | ||||
idx.node(rev) | ||||
.ok_or_else(|| NodeMapError::RevisionNotInIndex(rev)) | ||||
.map(|node| { | ||||
if prefix.is_prefix_of(node) { | ||||
Some(rev) | ||||
} else { | ||||
None | ||||
} | ||||
}) | ||||
} | ||||
Georges Racinet
|
r44871 | /// validate that the candidate's node starts indeed with given prefix, | ||
/// and treat ambiguities related to `NULL_REVISION`. | ||||
/// | ||||
/// From the data in the NodeTree, one can only conclude that some | ||||
/// revision is the only one for a *subprefix* of the one being looked up. | ||||
fn validate_candidate( | ||||
idx: &impl RevlogIndex, | ||||
prefix: NodePrefixRef, | ||||
Georges Racinet
|
r44872 | candidate: (Option<Revision>, usize), | ||
) -> Result<(Option<Revision>, usize), NodeMapError> { | ||||
let (rev, steps) = candidate; | ||||
if let Some(nz_nybble) = prefix.first_different_nybble(&NULL_NODE) { | ||||
rev.map_or(Ok((None, steps)), |r| { | ||||
has_prefix_or_none(idx, prefix, r) | ||||
.map(|opt| (opt, max(steps, nz_nybble + 1))) | ||||
}) | ||||
} else { | ||||
// the prefix is only made of zeros; NULL_REVISION always matches it | ||||
Georges Racinet
|
r44871 | // and any other *valid* result is an ambiguity | ||
match rev { | ||||
Georges Racinet
|
r44872 | None => Ok((Some(NULL_REVISION), steps + 1)), | ||
Georges Racinet
|
r44871 | Some(r) => match has_prefix_or_none(idx, prefix, r)? { | ||
Georges Racinet
|
r44872 | None => Ok((Some(NULL_REVISION), steps + 1)), | ||
Georges Racinet
|
r44871 | _ => Err(NodeMapError::MultipleResults), | ||
}, | ||||
} | ||||
} | ||||
} | ||||
Georges Racinet
|
r44644 | impl NodeTree { | ||
Georges Racinet
|
r44646 | /// Initiate a NodeTree from an immutable slice-like of `Block` | ||
/// | ||||
/// We keep `readonly` and clone its root block if it isn't empty. | ||||
fn new(readonly: Box<dyn Deref<Target = [Block]> + Send>) -> Self { | ||||
Raphaël Gomès
|
r45500 | let root = readonly.last().cloned().unwrap_or_else(Block::new); | ||
Georges Racinet
|
r44646 | NodeTree { | ||
Raphaël Gomès
|
r45500 | readonly, | ||
Georges Racinet
|
r44646 | growable: Vec::new(), | ||
Raphaël Gomès
|
r45500 | root, | ||
Georges Racinet
|
r44873 | masked_inner_blocks: 0, | ||
Georges Racinet
|
r44646 | } | ||
Georges Racinet
|
r44645 | } | ||
Georges Racinet
|
r44869 | /// Create from an opaque bunch of bytes | ||
/// | ||||
/// The created `NodeTreeBytes` from `buffer`, | ||||
/// of which exactly `amount` bytes are used. | ||||
/// | ||||
/// - `buffer` could be derived from `PyBuffer` and `Mmap` objects. | ||||
/// - `offset` allows for the final file format to include fixed data | ||||
/// (generation number, behavioural flags) | ||||
/// - `amount` is expressed in bytes, and is not automatically derived from | ||||
/// `bytes`, so that a caller that manages them atomically can perform | ||||
/// temporary disk serializations and still rollback easily if needed. | ||||
/// First use-case for this would be to support Mercurial shell hooks. | ||||
/// | ||||
/// panics if `buffer` is smaller than `amount` | ||||
pub fn load_bytes( | ||||
bytes: Box<dyn Deref<Target = [u8]> + Send>, | ||||
amount: usize, | ||||
) -> Self { | ||||
NodeTree::new(Box::new(NodeTreeBytes::new(bytes, amount))) | ||||
} | ||||
/// Retrieve added `Block` and the original immutable data | ||||
pub fn into_readonly_and_added( | ||||
self, | ||||
) -> (Box<dyn Deref<Target = [Block]> + Send>, Vec<Block>) { | ||||
let mut vec = self.growable; | ||||
let readonly = self.readonly; | ||||
if readonly.last() != Some(&self.root) { | ||||
vec.push(self.root); | ||||
} | ||||
(readonly, vec) | ||||
} | ||||
/// Retrieve added `Blocks` as bytes, ready to be written to persistent | ||||
/// storage | ||||
pub fn into_readonly_and_added_bytes( | ||||
self, | ||||
) -> (Box<dyn Deref<Target = [Block]> + Send>, Vec<u8>) { | ||||
let (readonly, vec) = self.into_readonly_and_added(); | ||||
// Prevent running `v`'s destructor so we are in complete control | ||||
// of the allocation. | ||||
let vec = mem::ManuallyDrop::new(vec); | ||||
// Transmute the `Vec<Block>` to a `Vec<u8>`. Blocks are contiguous | ||||
// bytes, so this is perfectly safe. | ||||
let bytes = unsafe { | ||||
// Assert that `Block` hasn't been changed and has no padding | ||||
let _: [u8; 4 * BLOCK_SIZE] = | ||||
std::mem::transmute([Block::new(); 4]); | ||||
// /!\ Any use of `vec` after this is use-after-free. | ||||
// TODO: use `into_raw_parts` once stabilized | ||||
Vec::from_raw_parts( | ||||
vec.as_ptr() as *mut u8, | ||||
vec.len() * BLOCK_SIZE, | ||||
vec.capacity() * BLOCK_SIZE, | ||||
) | ||||
}; | ||||
(readonly, bytes) | ||||
} | ||||
Georges Racinet
|
r44646 | /// Total number of blocks | ||
fn len(&self) -> usize { | ||||
self.readonly.len() + self.growable.len() + 1 | ||||
} | ||||
/// Implemented for completeness | ||||
/// | ||||
/// A `NodeTree` always has at least the mutable root block. | ||||
#[allow(dead_code)] | ||||
Georges Racinet
|
r44645 | fn is_empty(&self) -> bool { | ||
Georges Racinet
|
r44646 | false | ||
Georges Racinet
|
r44645 | } | ||
Georges Racinet
|
r44644 | /// Main working method for `NodeTree` searches | ||
Georges Racinet
|
r44872 | /// | ||
/// The first returned value is the result of analysing `NodeTree` data | ||||
/// *alone*: whereas `None` guarantees that the given prefix is absent | ||||
/// from the `NodeTree` data (but still could match `NULL_NODE`), with | ||||
/// `Some(rev)`, it is to be understood that `rev` is the unique `Revision` | ||||
/// that could match the prefix. Actually, all that can be inferred from | ||||
/// the `NodeTree` data is that `rev` is the revision with the longest | ||||
/// common node prefix with the given prefix. | ||||
/// | ||||
/// The second returned value is the size of the smallest subprefix | ||||
/// of `prefix` that would give the same result, i.e. not the | ||||
/// `MultipleResults` error variant (again, using only the data of the | ||||
/// `NodeTree`). | ||||
fn lookup( | ||||
Georges Racinet
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r44644 | &self, | ||
Georges Racinet
|
r44872 | prefix: NodePrefixRef, | ||
) -> Result<(Option<Revision>, usize), NodeMapError> { | ||||
for (i, visit_item) in self.visit(prefix).enumerate() { | ||||
Georges Racinet
|
r44647 | if let Some(opt) = visit_item.final_revision() { | ||
Georges Racinet
|
r44872 | return Ok((opt, i + 1)); | ||
Georges Racinet
|
r44644 | } | ||
} | ||||
Err(NodeMapError::MultipleResults) | ||||
} | ||||
Georges Racinet
|
r44647 | |||
fn visit<'n, 'p>( | ||||
&'n self, | ||||
prefix: NodePrefixRef<'p>, | ||||
) -> NodeTreeVisitor<'n, 'p> { | ||||
NodeTreeVisitor { | ||||
nt: self, | ||||
Raphaël Gomès
|
r45500 | prefix, | ||
Georges Racinet
|
r44647 | visit: self.len() - 1, | ||
nybble_idx: 0, | ||||
done: false, | ||||
} | ||||
} | ||||
Georges Racinet
|
r44831 | /// Return a mutable reference for `Block` at index `idx`. | ||
/// | ||||
/// If `idx` lies in the immutable area, then the reference is to | ||||
/// a newly appended copy. | ||||
/// | ||||
/// Returns (new_idx, glen, mut_ref) where | ||||
/// | ||||
/// - `new_idx` is the index of the mutable `Block` | ||||
/// - `mut_ref` is a mutable reference to the mutable Block. | ||||
/// - `glen` is the new length of `self.growable` | ||||
/// | ||||
/// Note: the caller wouldn't be allowed to query `self.growable.len()` | ||||
/// itself because of the mutable borrow taken with the returned `Block` | ||||
fn mutable_block(&mut self, idx: usize) -> (usize, &mut Block, usize) { | ||||
let ro_blocks = &self.readonly; | ||||
let ro_len = ro_blocks.len(); | ||||
let glen = self.growable.len(); | ||||
if idx < ro_len { | ||||
Georges Racinet
|
r44873 | self.masked_inner_blocks += 1; | ||
Raphaël Gomès
|
r45500 | self.growable.push(ro_blocks[idx]); | ||
Georges Racinet
|
r44831 | (glen + ro_len, &mut self.growable[glen], glen + 1) | ||
} else if glen + ro_len == idx { | ||||
(idx, &mut self.root, glen) | ||||
} else { | ||||
(idx, &mut self.growable[idx - ro_len], glen) | ||||
} | ||||
} | ||||
/// Main insertion method | ||||
/// | ||||
/// This will dive in the node tree to find the deepest `Block` for | ||||
/// `node`, split it as much as needed and record `node` in there. | ||||
/// The method then backtracks, updating references in all the visited | ||||
/// blocks from the root. | ||||
/// | ||||
/// All the mutated `Block` are copied first to the growable part if | ||||
/// needed. That happens for those in the immutable part except the root. | ||||
pub fn insert<I: RevlogIndex>( | ||||
&mut self, | ||||
index: &I, | ||||
node: &Node, | ||||
rev: Revision, | ||||
) -> Result<(), NodeMapError> { | ||||
let ro_len = &self.readonly.len(); | ||||
let mut visit_steps: Vec<_> = self.visit(node.into()).collect(); | ||||
let read_nybbles = visit_steps.len(); | ||||
// visit_steps cannot be empty, since we always visit the root block | ||||
let deepest = visit_steps.pop().unwrap(); | ||||
let (mut block_idx, mut block, mut glen) = | ||||
self.mutable_block(deepest.block_idx); | ||||
if let Element::Rev(old_rev) = deepest.element { | ||||
let old_node = index | ||||
.node(old_rev) | ||||
.ok_or_else(|| NodeMapError::RevisionNotInIndex(old_rev))?; | ||||
if old_node == node { | ||||
return Ok(()); // avoid creating lots of useless blocks | ||||
} | ||||
// Looping over the tail of nybbles in both nodes, creating | ||||
// new blocks until we find the difference | ||||
let mut new_block_idx = ro_len + glen; | ||||
let mut nybble = deepest.nybble; | ||||
for nybble_pos in read_nybbles..node.nybbles_len() { | ||||
block.set(nybble, Element::Block(new_block_idx)); | ||||
let new_nybble = node.get_nybble(nybble_pos); | ||||
let old_nybble = old_node.get_nybble(nybble_pos); | ||||
if old_nybble == new_nybble { | ||||
self.growable.push(Block::new()); | ||||
block = &mut self.growable[glen]; | ||||
glen += 1; | ||||
new_block_idx += 1; | ||||
nybble = new_nybble; | ||||
} else { | ||||
let mut new_block = Block::new(); | ||||
new_block.set(old_nybble, Element::Rev(old_rev)); | ||||
new_block.set(new_nybble, Element::Rev(rev)); | ||||
self.growable.push(new_block); | ||||
break; | ||||
} | ||||
} | ||||
} else { | ||||
// Free slot in the deepest block: no splitting has to be done | ||||
block.set(deepest.nybble, Element::Rev(rev)); | ||||
} | ||||
// Backtrack over visit steps to update references | ||||
while let Some(visited) = visit_steps.pop() { | ||||
let to_write = Element::Block(block_idx); | ||||
if visit_steps.is_empty() { | ||||
self.root.set(visited.nybble, to_write); | ||||
break; | ||||
} | ||||
let (new_idx, block, _) = self.mutable_block(visited.block_idx); | ||||
if block.get(visited.nybble) == to_write { | ||||
break; | ||||
} | ||||
block.set(visited.nybble, to_write); | ||||
block_idx = new_idx; | ||||
} | ||||
Ok(()) | ||||
} | ||||
Georges Racinet
|
r44873 | |||
Georges Racinet
|
r44874 | /// Make the whole `NodeTree` logically empty, without touching the | ||
/// immutable part. | ||||
pub fn invalidate_all(&mut self) { | ||||
self.root = Block::new(); | ||||
self.growable = Vec::new(); | ||||
self.masked_inner_blocks = self.readonly.len(); | ||||
} | ||||
Georges Racinet
|
r44873 | /// Return the number of blocks in the readonly part that are currently | ||
/// masked in the mutable part. | ||||
/// | ||||
/// The `NodeTree` structure has no efficient way to know how many blocks | ||||
/// are already unreachable in the readonly part. | ||||
Georges Racinet
|
r44874 | /// | ||
/// After a call to `invalidate_all()`, the returned number can be actually | ||||
/// bigger than the whole readonly part, a conventional way to mean that | ||||
/// all the readonly blocks have been masked. This is what is really | ||||
/// useful to the caller and does not require to know how many were | ||||
/// actually unreachable to begin with. | ||||
Georges Racinet
|
r44873 | pub fn masked_readonly_blocks(&self) -> usize { | ||
if let Some(readonly_root) = self.readonly.last() { | ||||
if readonly_root == &self.root { | ||||
return 0; | ||||
} | ||||
} else { | ||||
return 0; | ||||
} | ||||
self.masked_inner_blocks + 1 | ||||
} | ||||
Georges Racinet
|
r44647 | } | ||
Georges Racinet
|
r44869 | pub struct NodeTreeBytes { | ||
buffer: Box<dyn Deref<Target = [u8]> + Send>, | ||||
len_in_blocks: usize, | ||||
} | ||||
impl NodeTreeBytes { | ||||
fn new( | ||||
buffer: Box<dyn Deref<Target = [u8]> + Send>, | ||||
amount: usize, | ||||
) -> Self { | ||||
assert!(buffer.len() >= amount); | ||||
let len_in_blocks = amount / BLOCK_SIZE; | ||||
NodeTreeBytes { | ||||
buffer, | ||||
len_in_blocks, | ||||
} | ||||
} | ||||
} | ||||
impl Deref for NodeTreeBytes { | ||||
type Target = [Block]; | ||||
fn deref(&self) -> &[Block] { | ||||
unsafe { | ||||
slice::from_raw_parts( | ||||
(&self.buffer).as_ptr() as *const Block, | ||||
self.len_in_blocks, | ||||
) | ||||
} | ||||
} | ||||
} | ||||
Georges Racinet
|
r44647 | struct NodeTreeVisitor<'n, 'p> { | ||
nt: &'n NodeTree, | ||||
prefix: NodePrefixRef<'p>, | ||||
visit: usize, | ||||
nybble_idx: usize, | ||||
done: bool, | ||||
} | ||||
#[derive(Debug, PartialEq, Clone)] | ||||
struct NodeTreeVisitItem { | ||||
block_idx: usize, | ||||
nybble: u8, | ||||
element: Element, | ||||
} | ||||
impl<'n, 'p> Iterator for NodeTreeVisitor<'n, 'p> { | ||||
type Item = NodeTreeVisitItem; | ||||
fn next(&mut self) -> Option<Self::Item> { | ||||
if self.done || self.nybble_idx >= self.prefix.len() { | ||||
return None; | ||||
} | ||||
let nybble = self.prefix.get_nybble(self.nybble_idx); | ||||
self.nybble_idx += 1; | ||||
let visit = self.visit; | ||||
let element = self.nt[visit].get(nybble); | ||||
if let Element::Block(idx) = element { | ||||
self.visit = idx; | ||||
} else { | ||||
self.done = true; | ||||
} | ||||
Some(NodeTreeVisitItem { | ||||
block_idx: visit, | ||||
Raphaël Gomès
|
r45500 | nybble, | ||
element, | ||||
Georges Racinet
|
r44647 | }) | ||
} | ||||
} | ||||
impl NodeTreeVisitItem { | ||||
// Return `Some(opt)` if this item is final, with `opt` being the | ||||
// `Revision` that it may represent. | ||||
// | ||||
// If the item is not terminal, return `None` | ||||
fn final_revision(&self) -> Option<Option<Revision>> { | ||||
match self.element { | ||||
Element::Block(_) => None, | ||||
Element::Rev(r) => Some(Some(r)), | ||||
Element::None => Some(None), | ||||
} | ||||
} | ||||
Georges Racinet
|
r44644 | } | ||
impl From<Vec<Block>> for NodeTree { | ||||
fn from(vec: Vec<Block>) -> Self { | ||||
Georges Racinet
|
r44646 | Self::new(Box::new(vec)) | ||
Georges Racinet
|
r44644 | } | ||
} | ||||
impl fmt::Debug for NodeTree { | ||||
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { | ||||
Georges Racinet
|
r44646 | let readonly: &[Block] = &*self.readonly; | ||
write!( | ||||
f, | ||||
"readonly: {:?}, growable: {:?}, root: {:?}", | ||||
readonly, self.growable, self.root | ||||
) | ||||
Georges Racinet
|
r44644 | } | ||
} | ||||
Georges Racinet
|
r44831 | impl Default for NodeTree { | ||
/// Create a fully mutable empty NodeTree | ||||
fn default() -> Self { | ||||
NodeTree::new(Box::new(Vec::new())) | ||||
} | ||||
} | ||||
Georges Racinet
|
r44644 | impl NodeMap for NodeTree { | ||
fn find_bin<'a>( | ||||
&self, | ||||
idx: &impl RevlogIndex, | ||||
prefix: NodePrefixRef<'a>, | ||||
) -> Result<Option<Revision>, NodeMapError> { | ||||
Georges Racinet
|
r44871 | validate_candidate(idx, prefix.clone(), self.lookup(prefix)?) | ||
Georges Racinet
|
r44872 | .map(|(opt, _shortest)| opt) | ||
} | ||||
fn unique_prefix_len_bin<'a>( | ||||
&self, | ||||
idx: &impl RevlogIndex, | ||||
prefix: NodePrefixRef<'a>, | ||||
) -> Result<Option<usize>, NodeMapError> { | ||||
validate_candidate(idx, prefix.clone(), self.lookup(prefix)?) | ||||
.map(|(opt, shortest)| opt.map(|_rev| shortest)) | ||||
Georges Racinet
|
r44644 | } | ||
} | ||||
Georges Racinet
|
r44600 | #[cfg(test)] | ||
mod tests { | ||||
Georges Racinet
|
r44644 | use super::NodeMapError::*; | ||
Georges Racinet
|
r44600 | use super::*; | ||
Georges Racinet
|
r44644 | use crate::revlog::node::{hex_pad_right, Node}; | ||
use std::collections::HashMap; | ||||
Georges Racinet
|
r44600 | |||
/// Creates a `Block` using a syntax close to the `Debug` output | ||||
macro_rules! block { | ||||
{$($nybble:tt : $variant:ident($val:tt)),*} => ( | ||||
{ | ||||
let mut block = Block::new(); | ||||
$(block.set($nybble, Element::$variant($val)));*; | ||||
block | ||||
} | ||||
) | ||||
} | ||||
#[test] | ||||
fn test_block_debug() { | ||||
let mut block = Block::new(); | ||||
block.set(1, Element::Rev(3)); | ||||
block.set(10, Element::Block(0)); | ||||
assert_eq!(format!("{:?}", block), "{1: Rev(3), 10: Block(0)}"); | ||||
} | ||||
#[test] | ||||
fn test_block_macro() { | ||||
let block = block! {5: Block(2)}; | ||||
assert_eq!(format!("{:?}", block), "{5: Block(2)}"); | ||||
let block = block! {13: Rev(15), 5: Block(2)}; | ||||
assert_eq!(format!("{:?}", block), "{5: Block(2), 13: Rev(15)}"); | ||||
} | ||||
#[test] | ||||
fn test_raw_block() { | ||||
Georges Racinet
|
r44869 | let mut raw = [255u8; 64]; | ||
let mut counter = 0; | ||||
for val in [0, 15, -2, -1, -3].iter() { | ||||
for byte in RawElement::to_be_bytes(*val).iter() { | ||||
raw[counter] = *byte; | ||||
counter += 1; | ||||
} | ||||
} | ||||
Georges Racinet
|
r44600 | let block = Block(raw); | ||
assert_eq!(block.get(0), Element::Block(0)); | ||||
assert_eq!(block.get(1), Element::Block(15)); | ||||
assert_eq!(block.get(3), Element::None); | ||||
assert_eq!(block.get(2), Element::Rev(0)); | ||||
assert_eq!(block.get(4), Element::Rev(1)); | ||||
} | ||||
Georges Racinet
|
r44644 | |||
type TestIndex = HashMap<Revision, Node>; | ||||
impl RevlogIndex for TestIndex { | ||||
fn node(&self, rev: Revision) -> Option<&Node> { | ||||
self.get(&rev) | ||||
} | ||||
fn len(&self) -> usize { | ||||
self.len() | ||||
} | ||||
} | ||||
Georges Racinet
|
r44831 | /// Pad hexadecimal Node prefix with zeros on the right | ||
Georges Racinet
|
r44644 | /// | ||
/// This avoids having to repeatedly write very long hexadecimal | ||||
/// strings for test data, and brings actual hash size independency. | ||||
Georges Racinet
|
r44831 | #[cfg(test)] | ||
fn pad_node(hex: &str) -> Node { | ||||
Node::from_hex(&hex_pad_right(hex)).unwrap() | ||||
} | ||||
/// Pad hexadecimal Node prefix with zeros on the right, then insert | ||||
Georges Racinet
|
r44644 | fn pad_insert(idx: &mut TestIndex, rev: Revision, hex: &str) { | ||
Georges Racinet
|
r44831 | idx.insert(rev, pad_node(hex)); | ||
Georges Racinet
|
r44644 | } | ||
fn sample_nodetree() -> NodeTree { | ||||
NodeTree::from(vec![ | ||||
block![0: Rev(9)], | ||||
block![0: Rev(0), 1: Rev(9)], | ||||
block![0: Block(1), 1:Rev(1)], | ||||
]) | ||||
} | ||||
#[test] | ||||
fn test_nt_debug() { | ||||
let nt = sample_nodetree(); | ||||
assert_eq!( | ||||
format!("{:?}", nt), | ||||
"readonly: \ | ||||
Georges Racinet
|
r44646 | [{0: Rev(9)}, {0: Rev(0), 1: Rev(9)}, {0: Block(1), 1: Rev(1)}], \ | ||
growable: [], \ | ||||
root: {0: Block(1), 1: Rev(1)}", | ||||
Georges Racinet
|
r44644 | ); | ||
} | ||||
#[test] | ||||
fn test_immutable_find_simplest() -> Result<(), NodeMapError> { | ||||
let mut idx: TestIndex = HashMap::new(); | ||||
pad_insert(&mut idx, 1, "1234deadcafe"); | ||||
Georges Racinet
|
r44646 | let nt = NodeTree::from(vec![block! {1: Rev(1)}]); | ||
Georges Racinet
|
r44644 | assert_eq!(nt.find_hex(&idx, "1")?, Some(1)); | ||
assert_eq!(nt.find_hex(&idx, "12")?, Some(1)); | ||||
assert_eq!(nt.find_hex(&idx, "1234de")?, Some(1)); | ||||
assert_eq!(nt.find_hex(&idx, "1a")?, None); | ||||
assert_eq!(nt.find_hex(&idx, "ab")?, None); | ||||
// and with full binary Nodes | ||||
assert_eq!(nt.find_node(&idx, idx.get(&1).unwrap())?, Some(1)); | ||||
let unknown = Node::from_hex(&hex_pad_right("3d")).unwrap(); | ||||
assert_eq!(nt.find_node(&idx, &unknown)?, None); | ||||
Ok(()) | ||||
} | ||||
#[test] | ||||
fn test_immutable_find_one_jump() { | ||||
let mut idx = TestIndex::new(); | ||||
pad_insert(&mut idx, 9, "012"); | ||||
pad_insert(&mut idx, 0, "00a"); | ||||
let nt = sample_nodetree(); | ||||
assert_eq!(nt.find_hex(&idx, "0"), Err(MultipleResults)); | ||||
assert_eq!(nt.find_hex(&idx, "01"), Ok(Some(9))); | ||||
Georges Racinet
|
r44871 | assert_eq!(nt.find_hex(&idx, "00"), Err(MultipleResults)); | ||
Georges Racinet
|
r44644 | assert_eq!(nt.find_hex(&idx, "00a"), Ok(Some(0))); | ||
Georges Racinet
|
r44872 | assert_eq!(nt.unique_prefix_len_hex(&idx, "00a"), Ok(Some(3))); | ||
Georges Racinet
|
r44871 | assert_eq!(nt.find_hex(&idx, "000"), Ok(Some(NULL_REVISION))); | ||
Georges Racinet
|
r44644 | } | ||
Georges Racinet
|
r44646 | |||
#[test] | ||||
fn test_mutated_find() -> Result<(), NodeMapError> { | ||||
let mut idx = TestIndex::new(); | ||||
pad_insert(&mut idx, 9, "012"); | ||||
pad_insert(&mut idx, 0, "00a"); | ||||
pad_insert(&mut idx, 2, "cafe"); | ||||
pad_insert(&mut idx, 3, "15"); | ||||
pad_insert(&mut idx, 1, "10"); | ||||
let nt = NodeTree { | ||||
readonly: sample_nodetree().readonly, | ||||
growable: vec![block![0: Rev(1), 5: Rev(3)]], | ||||
root: block![0: Block(1), 1:Block(3), 12: Rev(2)], | ||||
Georges Racinet
|
r44873 | masked_inner_blocks: 1, | ||
Georges Racinet
|
r44646 | }; | ||
assert_eq!(nt.find_hex(&idx, "10")?, Some(1)); | ||||
assert_eq!(nt.find_hex(&idx, "c")?, Some(2)); | ||||
Georges Racinet
|
r44872 | assert_eq!(nt.unique_prefix_len_hex(&idx, "c")?, Some(1)); | ||
Georges Racinet
|
r44871 | assert_eq!(nt.find_hex(&idx, "00"), Err(MultipleResults)); | ||
assert_eq!(nt.find_hex(&idx, "000")?, Some(NULL_REVISION)); | ||||
Georges Racinet
|
r44872 | assert_eq!(nt.unique_prefix_len_hex(&idx, "000")?, Some(3)); | ||
Georges Racinet
|
r44646 | assert_eq!(nt.find_hex(&idx, "01")?, Some(9)); | ||
Georges Racinet
|
r44873 | assert_eq!(nt.masked_readonly_blocks(), 2); | ||
Georges Racinet
|
r44646 | Ok(()) | ||
} | ||||
Georges Racinet
|
r44831 | |||
struct TestNtIndex { | ||||
index: TestIndex, | ||||
nt: NodeTree, | ||||
} | ||||
impl TestNtIndex { | ||||
fn new() -> Self { | ||||
TestNtIndex { | ||||
index: HashMap::new(), | ||||
nt: NodeTree::default(), | ||||
} | ||||
} | ||||
fn insert( | ||||
&mut self, | ||||
rev: Revision, | ||||
hex: &str, | ||||
) -> Result<(), NodeMapError> { | ||||
let node = pad_node(hex); | ||||
self.index.insert(rev, node.clone()); | ||||
self.nt.insert(&self.index, &node, rev)?; | ||||
Ok(()) | ||||
} | ||||
fn find_hex( | ||||
&self, | ||||
prefix: &str, | ||||
) -> Result<Option<Revision>, NodeMapError> { | ||||
self.nt.find_hex(&self.index, prefix) | ||||
} | ||||
Georges Racinet
|
r44872 | fn unique_prefix_len_hex( | ||
&self, | ||||
prefix: &str, | ||||
) -> Result<Option<usize>, NodeMapError> { | ||||
self.nt.unique_prefix_len_hex(&self.index, prefix) | ||||
} | ||||
Georges Racinet
|
r44831 | /// Drain `added` and restart a new one | ||
fn commit(self) -> Self { | ||||
let mut as_vec: Vec<Block> = | ||||
self.nt.readonly.iter().map(|block| block.clone()).collect(); | ||||
as_vec.extend(self.nt.growable); | ||||
as_vec.push(self.nt.root); | ||||
Self { | ||||
index: self.index, | ||||
nt: NodeTree::from(as_vec).into(), | ||||
} | ||||
} | ||||
} | ||||
#[test] | ||||
fn test_insert_full_mutable() -> Result<(), NodeMapError> { | ||||
let mut idx = TestNtIndex::new(); | ||||
idx.insert(0, "1234")?; | ||||
assert_eq!(idx.find_hex("1")?, Some(0)); | ||||
assert_eq!(idx.find_hex("12")?, Some(0)); | ||||
// let's trigger a simple split | ||||
idx.insert(1, "1a34")?; | ||||
assert_eq!(idx.nt.growable.len(), 1); | ||||
assert_eq!(idx.find_hex("12")?, Some(0)); | ||||
assert_eq!(idx.find_hex("1a")?, Some(1)); | ||||
// reinserting is a no_op | ||||
idx.insert(1, "1a34")?; | ||||
assert_eq!(idx.nt.growable.len(), 1); | ||||
assert_eq!(idx.find_hex("12")?, Some(0)); | ||||
assert_eq!(idx.find_hex("1a")?, Some(1)); | ||||
idx.insert(2, "1a01")?; | ||||
assert_eq!(idx.nt.growable.len(), 2); | ||||
assert_eq!(idx.find_hex("1a"), Err(NodeMapError::MultipleResults)); | ||||
assert_eq!(idx.find_hex("12")?, Some(0)); | ||||
assert_eq!(idx.find_hex("1a3")?, Some(1)); | ||||
assert_eq!(idx.find_hex("1a0")?, Some(2)); | ||||
assert_eq!(idx.find_hex("1a12")?, None); | ||||
// now let's make it split and create more than one additional block | ||||
idx.insert(3, "1a345")?; | ||||
assert_eq!(idx.nt.growable.len(), 4); | ||||
assert_eq!(idx.find_hex("1a340")?, Some(1)); | ||||
assert_eq!(idx.find_hex("1a345")?, Some(3)); | ||||
assert_eq!(idx.find_hex("1a341")?, None); | ||||
Georges Racinet
|
r44873 | // there's no readonly block to mask | ||
assert_eq!(idx.nt.masked_readonly_blocks(), 0); | ||||
Georges Racinet
|
r44831 | Ok(()) | ||
} | ||||
#[test] | ||||
Georges Racinet
|
r44872 | fn test_unique_prefix_len_zero_prefix() { | ||
let mut idx = TestNtIndex::new(); | ||||
idx.insert(0, "00000abcd").unwrap(); | ||||
assert_eq!(idx.find_hex("000"), Err(NodeMapError::MultipleResults)); | ||||
// in the nodetree proper, this will be found at the first nybble | ||||
// yet the correct answer for unique_prefix_len is not 1, nor 1+1, | ||||
// but the first difference with `NULL_NODE` | ||||
assert_eq!(idx.unique_prefix_len_hex("00000a"), Ok(Some(6))); | ||||
assert_eq!(idx.unique_prefix_len_hex("00000ab"), Ok(Some(6))); | ||||
// same with odd result | ||||
idx.insert(1, "00123").unwrap(); | ||||
assert_eq!(idx.unique_prefix_len_hex("001"), Ok(Some(3))); | ||||
assert_eq!(idx.unique_prefix_len_hex("0012"), Ok(Some(3))); | ||||
// these are unchanged of course | ||||
assert_eq!(idx.unique_prefix_len_hex("00000a"), Ok(Some(6))); | ||||
assert_eq!(idx.unique_prefix_len_hex("00000ab"), Ok(Some(6))); | ||||
} | ||||
#[test] | ||||
Georges Racinet
|
r44831 | fn test_insert_extreme_splitting() -> Result<(), NodeMapError> { | ||
// check that the splitting loop is long enough | ||||
let mut nt_idx = TestNtIndex::new(); | ||||
let nt = &mut nt_idx.nt; | ||||
let idx = &mut nt_idx.index; | ||||
let node0_hex = hex_pad_right("444444"); | ||||
let mut node1_hex = hex_pad_right("444444").clone(); | ||||
node1_hex.pop(); | ||||
node1_hex.push('5'); | ||||
let node0 = Node::from_hex(&node0_hex).unwrap(); | ||||
let node1 = Node::from_hex(&node1_hex).unwrap(); | ||||
idx.insert(0, node0.clone()); | ||||
nt.insert(idx, &node0, 0)?; | ||||
idx.insert(1, node1.clone()); | ||||
nt.insert(idx, &node1, 1)?; | ||||
assert_eq!(nt.find_bin(idx, (&node0).into())?, Some(0)); | ||||
assert_eq!(nt.find_bin(idx, (&node1).into())?, Some(1)); | ||||
Ok(()) | ||||
} | ||||
#[test] | ||||
fn test_insert_partly_immutable() -> Result<(), NodeMapError> { | ||||
let mut idx = TestNtIndex::new(); | ||||
idx.insert(0, "1234")?; | ||||
idx.insert(1, "1235")?; | ||||
idx.insert(2, "131")?; | ||||
idx.insert(3, "cafe")?; | ||||
let mut idx = idx.commit(); | ||||
assert_eq!(idx.find_hex("1234")?, Some(0)); | ||||
assert_eq!(idx.find_hex("1235")?, Some(1)); | ||||
assert_eq!(idx.find_hex("131")?, Some(2)); | ||||
assert_eq!(idx.find_hex("cafe")?, Some(3)); | ||||
Georges Racinet
|
r44873 | // we did not add anything since init from readonly | ||
assert_eq!(idx.nt.masked_readonly_blocks(), 0); | ||||
Georges Racinet
|
r44831 | |||
idx.insert(4, "123A")?; | ||||
assert_eq!(idx.find_hex("1234")?, Some(0)); | ||||
assert_eq!(idx.find_hex("1235")?, Some(1)); | ||||
assert_eq!(idx.find_hex("131")?, Some(2)); | ||||
assert_eq!(idx.find_hex("cafe")?, Some(3)); | ||||
assert_eq!(idx.find_hex("123A")?, Some(4)); | ||||
Georges Racinet
|
r44873 | // we masked blocks for all prefixes of "123", including the root | ||
assert_eq!(idx.nt.masked_readonly_blocks(), 4); | ||||
Georges Racinet
|
r44831 | |||
Georges Racinet
|
r44873 | eprintln!("{:?}", idx.nt); | ||
Georges Racinet
|
r44831 | idx.insert(5, "c0")?; | ||
assert_eq!(idx.find_hex("cafe")?, Some(3)); | ||||
assert_eq!(idx.find_hex("c0")?, Some(5)); | ||||
assert_eq!(idx.find_hex("c1")?, None); | ||||
assert_eq!(idx.find_hex("1234")?, Some(0)); | ||||
Georges Racinet
|
r44873 | // inserting "c0" is just splitting the 'c' slot of the mutable root, | ||
// it doesn't mask anything | ||||
assert_eq!(idx.nt.masked_readonly_blocks(), 4); | ||||
Georges Racinet
|
r44831 | |||
Ok(()) | ||||
} | ||||
Georges Racinet
|
r44869 | |||
#[test] | ||||
Georges Racinet
|
r44874 | fn test_invalidate_all() -> Result<(), NodeMapError> { | ||
let mut idx = TestNtIndex::new(); | ||||
idx.insert(0, "1234")?; | ||||
idx.insert(1, "1235")?; | ||||
idx.insert(2, "131")?; | ||||
idx.insert(3, "cafe")?; | ||||
let mut idx = idx.commit(); | ||||
idx.nt.invalidate_all(); | ||||
assert_eq!(idx.find_hex("1234")?, None); | ||||
assert_eq!(idx.find_hex("1235")?, None); | ||||
assert_eq!(idx.find_hex("131")?, None); | ||||
assert_eq!(idx.find_hex("cafe")?, None); | ||||
// all the readonly blocks have been masked, this is the | ||||
// conventional expected response | ||||
assert_eq!(idx.nt.masked_readonly_blocks(), idx.nt.readonly.len() + 1); | ||||
Ok(()) | ||||
} | ||||
#[test] | ||||
Georges Racinet
|
r44869 | fn test_into_added_empty() { | ||
assert!(sample_nodetree().into_readonly_and_added().1.is_empty()); | ||||
assert!(sample_nodetree() | ||||
.into_readonly_and_added_bytes() | ||||
.1 | ||||
.is_empty()); | ||||
} | ||||
#[test] | ||||
fn test_into_added_bytes() -> Result<(), NodeMapError> { | ||||
let mut idx = TestNtIndex::new(); | ||||
idx.insert(0, "1234")?; | ||||
let mut idx = idx.commit(); | ||||
idx.insert(4, "cafe")?; | ||||
let (_, bytes) = idx.nt.into_readonly_and_added_bytes(); | ||||
// only the root block has been changed | ||||
assert_eq!(bytes.len(), BLOCK_SIZE); | ||||
// big endian for -2 | ||||
assert_eq!(&bytes[4..2 * 4], [255, 255, 255, 254]); | ||||
// big endian for -6 | ||||
assert_eq!(&bytes[12 * 4..13 * 4], [255, 255, 255, 250]); | ||||
Ok(()) | ||||
} | ||||
Georges Racinet
|
r44600 | } | ||