Implementation of Unicode Standard Annex #31 for determining which
char
values are valid in programming language identifiers.
This crate is a better optimized implementation of the older unicode-xid
crate. This crate uses less static storage, and is able to classify both
ASCII and non-ASCII codepoints with better performance, 2–10×
faster than unicode-xid
.
The following table shows a comparison between five Unicode identifier implementations.
unicode-ident
is this crate;unicode-xid
is a widely used crate run by the “unicode-rs” org;ucd-trie
and fst
are two data structures supported by the
ucd-generate
tool;roaring
is a Rust implementation of Roaring bitmap.The static storage column shows the total size of static
tables that the
crate bakes into your binary, measured in 1000s of bytes.
The remaining columns show the cost per call to evaluate whether a
single char
has the XID_Start or XID_Continue Unicode property,
comparing across different ratios of ASCII to non-ASCII codepoints in the
input data.
static storage | 0% nonascii | 1% | 10% | 100% nonascii | |
---|---|---|---|---|---|
unicode-ident | 10.1 K | 0.96 ns | 0.95 ns | 1.09 ns | 1.55 ns |
unicode-xid | 11.5 K | 1.88 ns | 2.14 ns | 3.48 ns | 15.63 ns |
ucd-trie | 10.2 K | 1.29 ns | 1.28 ns | 1.36 ns | 2.15 ns |
fst | 139 K | 55.1 ns | 54.9 ns | 53.2 ns | 28.5 ns |
roaring | 66.1 K | 2.78 ns | 3.09 ns | 3.37 ns | 4.70 ns |
Source code for the benchmark is provided in the bench directory of this
repo and may be repeated by running cargo criterion
.
They use a sorted array of character ranges, and do a binary search to look up whether a given character lands inside one of those ranges.
static XID_Continue_table: [(char, char); 763] = [
('\u{30}', '\u{39}'), // 0-9
('\u{41}', '\u{5a}'), // A-Z
…
('\u{e0100}', '\u{e01ef}'),
];
The static storage used by this data structure scales with the number of
contiguous ranges of identifier codepoints in Unicode. Every table entry
consumes 8 bytes, because it consists of a pair of 32-bit char
values.
In some ranges of the Unicode codepoint space, this is quite a sparse
representation – there are some ranges where tens of thousands of
adjacent codepoints are all valid identifier characters. In other places,
the representation is quite inefficient. A characater like µ
(U+00B5)
which is surrounded by non-identifier codepoints consumes 64 bits in the
table, while it would be just 1 bit in a dense bitmap.
On a system with 64-byte cache lines, binary searching the table touches 7 cache lines on average. Each cache line fits only 8 table entries. Additionally, the branching performed during the binary search is probably mostly unpredictable to the branch predictor.
Overall, the crate ends up being about 10× slower on non-ASCII input compared to the fastest crate.
A potential improvement would be to pack the table entries more compactly.
Rust’s char
type is a 21-bit integer padded to 32 bits, which means every
table entry is holding 22 bits of wasted space, adding up to 3.9 K. They
could instead fit every table entry into 6 bytes, leaving out some of the
padding, for a 25% improvement in space used. With some cleverness it may be
possible to fit in 5 bytes or even 4 bytes by storing a low char and an
extent, instead of low char and high char. I don’t expect that performance
would improve much but this could be the most efficient for space across all
the libraries, needing only about 7 K to store.
Their data structure is a compressed trie set specifically tailored for Unicode codepoints. The design is credited to Raph Levien in rust-lang/rust#33098.
pub struct TrieSet {
tree1_level1: &'static [u64; 32],
tree2_level1: &'static [u8; 992],
tree2_level2: &'static [u64],
tree3_level1: &'static [u8; 256],
tree3_level2: &'static [u8],
tree3_level3: &'static [u64],
}
It represents codepoint sets using a trie to achieve prefix compression. The final states of the trie are embedded in leaves or “chunks”, where each chunk is a 64-bit integer. Each bit position of the integer corresponds to whether a particular codepoint is in the set or not. These chunks are not just a compact representation of the final states of the trie, but are also a form of suffix compression. In particular, if multiple ranges of 64 contiguous codepoints have the same Unicode properties, then they all map to the same chunk in the final level of the trie.
Being tailored for Unicode codepoints, this trie is partitioned into three disjoint sets: tree1, tree2, tree3. The first set corresponds to codepoints [0, 0x800), the second [0x800, 0x10000) and the third [0x10000, 0x110000). These partitions conveniently correspond to the space of 1 or 2 byte UTF-8 encoded codepoints, 3 byte UTF-8 encoded codepoints and 4 byte UTF-8 encoded codepoints, respectively.
Lookups in this data structure are significantly more efficient than binary search. A lookup touches either 1, 2, or 3 cache lines based on which of the trie partitions is being accessed.
One possible performance improvement would be for this crate to expose a way
to query based on a UTF-8 encoded string, returning the Unicode property
corresponding to the first character in the string. Without such an API, the
caller is required to tokenize their UTF-8 encoded input data into char
,
hand the char
into ucd-trie
, only for ucd-trie
to undo that work by
converting back into the variable-length representation for trie traversal.
Uses a finite state transducer. This representation is built into
ucd-generate but I am not aware of any advantage over the ucd-trie
representation. In particular ucd-trie
is optimized for storing Unicode
properties while fst
is not.
As far as I can tell, the main thing that causes fst
to have large size
and slow lookups for this use case relative to ucd-trie
is that it does
not specialize for the fact that only 21 of the 32 bits in a char
are
meaningful. There are some dense arrays in the structure with large ranges
that could never possibly be used.
This crate is a pure-Rust implementation of Roaring Bitmap, a data structure designed for storing sets of 32-bit unsigned integers.
Roaring bitmaps are compressed bitmaps which tend to outperform conventional compressed bitmaps such as WAH, EWAH or Concise. In some instances, they can be hundreds of times faster and they often offer significantly better compression.
In this use case the performance was reasonably competitive but still substantially slower than the Unicode-optimized crates. Meanwhile the compression was significantly worse, requiring 6× as much storage for the data structure.
I also benchmarked the croaring
crate which is an FFI wrapper around the
C reference implementation of Roaring Bitmap. This crate was consistently
about 15% slower than pure-Rust roaring
, which could just be FFI overhead.
I did not investigate further.
This crate is most similar to the ucd-trie
library, in that it’s based on
bitmaps stored in the leafs of a trie representation, achieving both prefix
compression and suffix compression.
The key differences are:
The following diagram show the XID_Start and XID_Continue Unicode boolean properties in uncompressed form, in row-major order:
XID_Start | XID_Continue |
---|---|
Uncompressed, these would take 140 K to store, which is beyond what would be reasonable. However, as you can see there is a large degree of similarity between the two bitmaps and across the rows, which lends well to compression.
This crate stores one 512-bit “row” of the above bitmaps in the leaf level of a trie, and a single additional level to index into the leafs. It turns out there are 124 unique 512-bit chunks across the two bitmaps so 7 bits are sufficient to index them.
The chunk size of 512 bits is selected as the size that minimizes the total size of the data structure. A smaller chunk, like 256 or 128 bits, would achieve better deduplication but require a larger index. A larger chunk would increase redundancy in the leaf bitmaps. 512 bit chunks are the optimum for total size of the index plus leaf bitmaps.
In fact since there are only 124 unique chunks, we can use an 8-bit index with a spare bit to index at the half-chunk level. This achieves an additional 8.5% compression by eliminating redundancies between the second half of any chunk and the first half of any other chunk. Note that this is not the same as using chunks which are half the size, because it does not necessitate raising the size of the trie’s first level.
In contrast to binary search or the ucd-trie
crate, performing lookups in
this data structure is straight-line code with no need for branching.