From a990de90fe41456a23e58bd087d2f107d321f3a1 Mon Sep 17 00:00:00 2001 From: Valentin Popov Date: Fri, 19 Jul 2024 16:37:58 +0400 Subject: Deleted vendor folder --- vendor/memchr/src/lib.rs | 221 ----------------------------------------------- 1 file changed, 221 deletions(-) delete mode 100644 vendor/memchr/src/lib.rs (limited to 'vendor/memchr/src/lib.rs') diff --git a/vendor/memchr/src/lib.rs b/vendor/memchr/src/lib.rs deleted file mode 100644 index de366fb..0000000 --- a/vendor/memchr/src/lib.rs +++ /dev/null @@ -1,221 +0,0 @@ -/*! -This library provides heavily optimized routines for string search primitives. - -# Overview - -This section gives a brief high level overview of what this crate offers. - -* The top-level module provides routines for searching for 1, 2 or 3 bytes - in the forward or reverse direction. When searching for more than one byte, - positions are considered a match if the byte at that position matches any - of the bytes. -* The [`memmem`] sub-module provides forward and reverse substring search - routines. - -In all such cases, routines operate on `&[u8]` without regard to encoding. This -is exactly what you want when searching either UTF-8 or arbitrary bytes. - -# Example: using `memchr` - -This example shows how to use `memchr` to find the first occurrence of `z` in -a haystack: - -``` -use memchr::memchr; - -let haystack = b"foo bar baz quuz"; -assert_eq!(Some(10), memchr(b'z', haystack)); -``` - -# Example: matching one of three possible bytes - -This examples shows how to use `memrchr3` to find occurrences of `a`, `b` or -`c`, starting at the end of the haystack. - -``` -use memchr::memchr3_iter; - -let haystack = b"xyzaxyzbxyzc"; - -let mut it = memchr3_iter(b'a', b'b', b'c', haystack).rev(); -assert_eq!(Some(11), it.next()); -assert_eq!(Some(7), it.next()); -assert_eq!(Some(3), it.next()); -assert_eq!(None, it.next()); -``` - -# Example: iterating over substring matches - -This example shows how to use the [`memmem`] sub-module to find occurrences of -a substring in a haystack. - -``` -use memchr::memmem; - -let haystack = b"foo bar foo baz foo"; - -let mut it = memmem::find_iter(haystack, "foo"); -assert_eq!(Some(0), it.next()); -assert_eq!(Some(8), it.next()); -assert_eq!(Some(16), it.next()); -assert_eq!(None, it.next()); -``` - -# Example: repeating a search for the same needle - -It may be possible for the overhead of constructing a substring searcher to be -measurable in some workloads. In cases where the same needle is used to search -many haystacks, it is possible to do construction once and thus to avoid it for -subsequent searches. This can be done with a [`memmem::Finder`]: - -``` -use memchr::memmem; - -let finder = memmem::Finder::new("foo"); - -assert_eq!(Some(4), finder.find(b"baz foo quux")); -assert_eq!(None, finder.find(b"quux baz bar")); -``` - -# Why use this crate? - -At first glance, the APIs provided by this crate might seem weird. Why provide -a dedicated routine like `memchr` for something that could be implemented -clearly and trivially in one line: - -``` -fn memchr(needle: u8, haystack: &[u8]) -> Option { - haystack.iter().position(|&b| b == needle) -} -``` - -Or similarly, why does this crate provide substring search routines when Rust's -core library already provides them? - -``` -fn search(haystack: &str, needle: &str) -> Option { - haystack.find(needle) -} -``` - -The primary reason for both of them to exist is performance. When it comes to -performance, at a high level at least, there are two primary ways to look at -it: - -* **Throughput**: For this, think about it as, "given some very large haystack - and a byte that never occurs in that haystack, how long does it take to - search through it and determine that it, in fact, does not occur?" -* **Latency**: For this, think about it as, "given a tiny haystack---just a - few bytes---how long does it take to determine if a byte is in it?" - -The `memchr` routine in this crate has _slightly_ worse latency than the -solution presented above, however, its throughput can easily be over an -order of magnitude faster. This is a good general purpose trade off to make. -You rarely lose, but often gain big. - -**NOTE:** The name `memchr` comes from the corresponding routine in `libc`. A -key advantage of using this library is that its performance is not tied to its -quality of implementation in the `libc` you happen to be using, which can vary -greatly from platform to platform. - -But what about substring search? This one is a bit more complicated. The -primary reason for its existence is still indeed performance, but it's also -useful because Rust's core library doesn't actually expose any substring -search routine on arbitrary bytes. The only substring search routine that -exists works exclusively on valid UTF-8. - -So if you have valid UTF-8, is there a reason to use this over the standard -library substring search routine? Yes. This routine is faster on almost every -metric, including latency. The natural question then, is why isn't this -implementation in the standard library, even if only for searching on UTF-8? -The reason is that the implementation details for using SIMD in the standard -library haven't quite been worked out yet. - -**NOTE:** Currently, only `x86_64`, `wasm32` and `aarch64` targets have vector -accelerated implementations of `memchr` (and friends) and `memmem`. - -# Crate features - -* **std** - When enabled (the default), this will permit features specific to -the standard library. Currently, the only thing used from the standard library -is runtime SIMD CPU feature detection. This means that this feature must be -enabled to get AVX2 accelerated routines on `x86_64` targets without enabling -the `avx2` feature at compile time, for example. When `std` is not enabled, -this crate will still attempt to use SSE2 accelerated routines on `x86_64`. It -will also use AVX2 accelerated routines when the `avx2` feature is enabled at -compile time. In general, enable this feature if you can. -* **alloc** - When enabled (the default), APIs in this crate requiring some -kind of allocation will become available. For example, the -[`memmem::Finder::into_owned`](crate::memmem::Finder::into_owned) API and the -[`arch::all::shiftor`](crate::arch::all::shiftor) substring search -implementation. Otherwise, this crate is designed from the ground up to be -usable in core-only contexts, so the `alloc` feature doesn't add much -currently. Notably, disabling `std` but enabling `alloc` will **not** result -in the use of AVX2 on `x86_64` targets unless the `avx2` feature is enabled -at compile time. (With `std` enabled, AVX2 can be used even without the `avx2` -feature enabled at compile time by way of runtime CPU feature detection.) -* **logging** - When enabled (disabled by default), the `log` crate is used -to emit log messages about what kinds of `memchr` and `memmem` algorithms -are used. Namely, both `memchr` and `memmem` have a number of different -implementation choices depending on the target and CPU, and the log messages -can help show what specific implementations are being used. Generally, this is -useful for debugging performance issues. -* **libc** - **DEPRECATED**. Previously, this enabled the use of the target's -`memchr` function from whatever `libc` was linked into the program. This -feature is now a no-op because this crate's implementation of `memchr` should -now be sufficiently fast on a number of platforms that `libc` should no longer -be needed. (This feature is somewhat of a holdover from this crate's origins. -Originally, this crate was literally just a safe wrapper function around the -`memchr` function from `libc`.) -*/ - -#![deny(missing_docs)] -#![no_std] -// It's just not worth trying to squash all dead code warnings. Pretty -// unfortunate IMO. Not really sure how to fix this other than to either -// live with it or sprinkle a whole mess of `cfg` annotations everywhere. -#![cfg_attr( - not(any( - all(target_arch = "x86_64", target_feature = "sse2"), - target_arch = "wasm32", - target_arch = "aarch64", - )), - allow(dead_code) -)] -// Same deal for miri. -#![cfg_attr(miri, allow(dead_code, unused_macros))] - -// Supporting 8-bit (or others) would be fine. If you need it, please submit a -// bug report at https://github.com/BurntSushi/memchr -#[cfg(not(any( - target_pointer_width = "16", - target_pointer_width = "32", - target_pointer_width = "64" -)))] -compile_error!("memchr currently not supported on non-{16,32,64}"); - -#[cfg(any(test, feature = "std"))] -extern crate std; - -#[cfg(any(test, feature = "alloc"))] -extern crate alloc; - -pub use crate::memchr::{ - memchr, memchr2, memchr2_iter, memchr3, memchr3_iter, memchr_iter, - memrchr, memrchr2, memrchr2_iter, memrchr3, memrchr3_iter, memrchr_iter, - Memchr, Memchr2, Memchr3, -}; - -#[macro_use] -mod macros; - -#[cfg(test)] -#[macro_use] -mod tests; - -pub mod arch; -mod cow; -mod ext; -mod memchr; -pub mod memmem; -mod vector; -- cgit v1.2.3