Crates.io | ustr-fxhash |
lib.rs | ustr-fxhash |
version | 1.0.0 |
source | src |
created_at | 2024-01-30 06:35:07.717061 |
updated_at | 2024-01-30 06:35:07.717061 |
description | Fast, FFI-friendly string interning. |
homepage | |
repository | https://github.com/Boshen/ustr-fxhash |
max_upload_size | |
id | 1119923 |
size | 720,504 |
ustr
Fast, FFI-friendly string interning.
[!NOTE] This is a fork of
ustr
withahash
replaced withfxhash
for consistent hashing.
A Ustr
(Unique str) is a lightweight handle representing a static,
immutable entry in a global string cache, allowing for:
Extremely fast string assignment and comparisons.
Efficient storage. Only one copy of the string is held in memory, and getting access to it is just a pointer indirection.
Fast hashing ‒ the precomputed hash is stored with the string.
Fast FFI ‒ the string is stored with a terminating null byte so can be
passed to C directly without doing the CString
dance.
The downside is no strings are ever freed, so if you're creating lots and lots of strings, you might run out of memory. On the other hand, War and Peace is only 3MB, so it's probably fine.
This crate is based on OpenImageIO's
(OIIO) ustring
but it is not binary-compatible (yet). The underlying hash map implementation
is directy ported from OIIO.
use ustr::{Ustr, ustr};
// Creation is quick and easy using either `Ustr::from` or the `ustr` short
// function and only one copy of any string is stored
let h1 = Ustr::from("hello");
let h2 = ustr("hello");
// Comparisons and copies are extremely cheap
let h3 = h1;
assert_eq!(h2, h3);
// You can pass straight to FFI
let len = unsafe {
libc::strlen(h1.as_char_ptr())
};
assert_eq!(len, 5);
// For best performance when using Ustr as key for a HashMap or HashSet,
// you'll want to use the precomputed hash. To make this easier, just use
// the UstrMap and UstrSet exports:
use ustr::UstrMap;
// Key type is always Ustr
let mut map: UstrMap<usize> = UstrMap::default();
map.insert(u1, 17);
assert_eq!(*map.get(&u1).unwrap(), 17);
By enabling the "serde"
feature you can serialize individual Ustr
s or
the whole cache with serde.
use ustr::{Ustr, ustr};
let u_ser = ustr("serialization is fun!");
let json = serde_json::to_string(&u_ser).unwrap();
let u_de : Ustr = serde_json::from_str(&json).unwrap();
assert_eq!(u_ser, u_de);
Since the cache is global, use the ustr::DeserializedCache
dummy object to
drive the deserialization.
ustr("Send me to JSON and back");
let json = serde_json::to_string(ustr::cache()).unwrap();
// ... some time later ...
let _: ustr::DeserializedCache = serde_json::from_str(&json).unwrap();
assert_eq!(ustr::num_entries(), 1);
assert_eq!(ustr::string_cache_iter().collect::<Vec<_>>(), vec!["Send me to JSON and back"]);
If you are writing a library that uses ustr and want users to be able to create
Ustr
s to pass to your API from C, add ustr_extern.rs
to your crate and use
include/ustr.h
or include/ustr.hpp
for function declarations.
Ustr
from working on wasm32-unknown-unknown
(contributed by bouk)and thanks to virtualritz:
Ustr::get_cache()
was renamed
to cache()
All dependencies were bumped to latest versions
All features were removed (there are good defaults) except for
serialization
The serialization
feature was renamed
to serde
ustr
now uses Rust 2021
Add existing_ustr
function (contributed by macprog-guy)
The idea behind this is to allow the creation of a Ustr
only when that
Ustr
already exists. This is particularly useful when Ustr
s are being
created using untrusted user input (say from a web server or API). In that
case, by providing different values at each call we consume more and more
memory eventually running out (DoS).
Add implementation for Ord
(contributed by zigazeljko)
Inlined a bunch of simple functions (contributed by g-plane)
Fixed tests to lock rather than relying on RUST_TEST_THREADS=1
(contributed
by kornelski)
Fixed tests to handle serialization feature properly when enabled (contributed by kornelski)
Added a check for a potential allocation failure in the allocator (contributed by kornelski)
Added FromStr
impl (contributed by martinmr)
Add rustfmt.toml
to repo
Update dependencies
The versions of parking_lot
and ahash
have been updated.
Space optimization with NonNull
The internal pointer is now a NonNull
to take advanatge of layout
optimizations in Option
etc.
Add as_cstr()
method
Added as_cstr(&self) -> std::ffi::CStr
to make it easier to interface with
APIs that rely on CStr
.
Derive Ord for Ustr
So now you can sort a Vec
of Ustr
s lexicographically.
Added From<Ustr>
for &str
This impl
makes it easier to pass a Ustr
to methods expecting an
Into<&str>
.
32-bit support added
Removed the restriction to 64-bit systems and fixed a bug relating to pointer maths. Thanks to agaussman for bringing it up.
Miri leak checks re-enabled
Thanks to RalfJung for pointing out that Miri now ignores "leaks" from statics.
PartialOrd
is now lexicographic
Thanks to macprog-guy for the PR implementing PartialOrd by deferring to
&str
. This will be slower than the previous derived implementation which
just did a pointer comparison, but is much less surprising.
Added Miri to CI tests
Miri sanity-checks the unsafe parts of the code to guard against some types of UB.
Switched to ahash as the default hasher
Ahash is a fast, non-cryptographic pure Rust hasher. Pure Rust is important
to be able to run Miri and ahash benchmarks the fastest I could find. The old
fasthash
/cityhash
is available by enabling --features=hashcity
Serde support
Ustr
can now be serialized with Serde when enabling
--features=serialization
. The global string cache can also be serialized if
you really want to.
Switched to parking_lot::Mutex
as default synchronization
Spinlocks have been getting a bad rap recently so the string cache now uses
parking_lot::Mutex
as the default synchronization primitive. spin::Mutex
is still available behind the --features=spinlock
feature gate if you
really want that extra 5% speed.
Cleaned up unsafe
Did a better job of documenting the invariants for the unsafe blocks and replaced some blind additions with checked_add() and friends to avoid potential (but very unlikely) overflow.
Compared to string-cache
string-cache provides a global cache
that can be created at compile time as well as at run time. Dynamic strings
in the cache appear to be reference-counted so will be freed when they are no
longer used, while Ustr
s are never deleted.
Creating a string_cache::DefaultAtom
is much slower than creating a Ustr
,
especially in a multi-threaded context. On the other hand if you can just
bake all your Atom
s into your binary at compile-time this wouldn't be an
issue.
Compared to string-interner
string-interner gives you
individual Interner
objects to work with rather than a global cache, which
could be more flexible. It's faster to create than string-cache but still
significantly slower than Ustr
.
Ustr
s are significantly faster to create than string-interner
or
string-cache
. Creating 100,000 cycled copies of ~20,000 path strings of the
form:
/cgi-bin/images/admin
/modules/templates/cache
/libraries/themes/wp-includes
... etc.
It is common in certain types of applications to use strings as identifiers,
but not really do any processing with them. To paraphrase from OIIO's ustring
documentation:
Compared to standard strings, Ustr
s have several advantages:
Each individual Ustr
is very small -- in fact, we guarantee that a Ustr
is the same size and memory layout as an ordinary *u8.
Storage is frugal, since there is only one allocated copy of each unique character sequence, throughout the lifetime of the program.
Assignment from one Ustr
to another is just copy of the pointer; no
allocation, no character copying, no reference counting.
Equality testing (do the strings contain the same characters) is a single operation, the comparison of the pointer.
Memory allocation only occurs when a new Ustr
is constructed from raw
characters the first time ‒ subsequent constructions of the same string
just finds it in the canonial string set, but doesn't need to allocate new
storage. Destruction of a Ustr
is trivial, there is no de-allocation
because the canonical version stays in the set. Also, therefore, no user
code mistake can lead to memory leaks.
But there are some problems, too. Canonical strings are never freed from the
table. So in some sense all the strings "leak", but they only leak one copy
for each unique string that the program ever comes across. Creating a Ustr
is slower than String::from()
on a single thread, and performance will be
worse if trying to create many Ustr
s in tight loops from multiple threads
due to lock contention for the global cache.
On the whole, Ustr
s are a really great string representation
if you tend to have (relatively) few unique strings, but many copies of those strings;
if you tend to make the same strings over and over again, and if it's relatively rare that a single unique character sequence is used only once in the entire lifetime of the program; ‒ if your most common string operations are assignment and equality testing and you want them to be as fast as possible;
if you are doing relatively little character-by-character assembly of strings, string concatenation, or other "string manipulation" (other than equality testing).
Ustr
s are not so hot:
if your program tends to have very few copies of each character sequence over the entire lifetime of the program;
if your program tends to generate a huge variety of unique strings over its lifetime, each of which is used only a short time and then discarded, never to be needed again;
if you don't need to do a lot of string assignment or equality testing, but lots of more complex string manipulation.
This crate contains a significant amount of unsafe but usage has been checked and is well-documented. It is also run through Miri as part of the CI process.
I use it regularly on 64-bit systems, and it has passed Miri on a 32-bit system as well, bit 32-bit is not checked regularly. If you want to use it on 32-bit, please make sure to run Miri and open and issue if you find any problems.
BSD+ License
Copyright © 2019—2020 Anders Langlands
Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:
Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.
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Contains code ported from OpenImageIO, BSD 3-clause licence.
Contains a copy of Max Woolf's Big List of Naughty Strings, MIT licence.
Contains some strings from SecLists, MIT licence.