README.md - platform/external/rust/crates/memchr - Git at Google

 memchr
 ======
 This library provides heavily optimized routines for string search primitives.

 [![Build status](https://github.com/BurntSushi/memchr/workflows/ci/badge.svg)](https://github.com/BurntSushi/memchr/actions)
 [![Crates.io](https://img.shields.io/crates/v/memchr.svg)](https://crates.io/crates/memchr)

 Dual-licensed under MIT or the [UNLICENSE](https://unlicense.org/).


 ### Documentation

 [https://docs.rs/memchr](https://docs.rs/memchr)


 ### Overview

 * 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.

 ### Compiling without the standard library

 memchr links to the standard library by default, but you can disable the
 `std` feature if you want to use it in a `#![no_std]` crate:

 ```toml
 [dependencies]
 memchr = { version = "2", default-features = false }
 ```

 On `x86_64` platforms, when the `std` feature is disabled, the SSE2 accelerated
 implementations will be used. When `std` is enabled, AVX2 accelerated
 implementations will be used if the CPU is determined to support it at runtime.

 SIMD accelerated routines are also available on the `wasm32` and `aarch64`
 targets. The `std` feature is not required to use them.

 When a SIMD version is not available, then this crate falls back to
 [SWAR](https://en.wikipedia.org/wiki/SWAR) techniques.

 ### Minimum Rust version policy

 This crate's minimum supported `rustc` version is `1.61.0`.

 The current policy is that the minimum Rust version required to use this crate
 can be increased in minor version updates. For example, if `crate 1.0` requires
 Rust 1.20.0, then `crate 1.0.z` for all values of `z` will also require Rust
 1.20.0 or newer. However, `crate 1.y` for `y > 0` may require a newer minimum
 version of Rust.

 In general, this crate will be conservative with respect to the minimum
 supported version of Rust.


 ### Testing strategy

 Given the complexity of the code in this crate, along with the pervasive use
 of `unsafe`, this crate has an extensive testing strategy. It combines multiple
 approaches:

 * Hand-written tests.
 * Exhaustive-style testing meant to exercise all possible branching and offset
   calculations.
 * Property based testing through [`quickcheck`](https://github.com/BurntSushi/quickcheck).
 * Fuzz testing through [`cargo fuzz`](https://github.com/rust-fuzz/cargo-fuzz).
 * A huge suite of benchmarks that are also run as tests. Benchmarks always
   confirm that the expected result occurs.

 Improvements to the testing infrastructure are very welcome.


 ### Algorithms used

 At time of writing, this crate's implementation of substring search actually
 has a few different algorithms to choose from depending on the situation.

 * For very small haystacks,
   [Rabin-Karp](https://en.wikipedia.org/wiki/Rabin%E2%80%93Karp_algorithm)
   is used to reduce latency. Rabin-Karp has very small overhead and can often
   complete before other searchers have even been constructed.
 * For small needles, a variant of the
   ["Generic SIMD"](http://0x80.pl/articles/simd-strfind.html#algorithm-1-generic-simd)
   algorithm is used. Instead of using the first and last bytes, a heuristic is
   used to select bytes based on a background distribution of byte frequencies.
 * In all other cases,
   [Two-Way](https://en.wikipedia.org/wiki/Two-way_string-matching_algorithm)
   is used. If possible, a prefilter based on the "Generic SIMD" algorithm
   linked above is used to find candidates quickly. A dynamic heuristic is used
   to detect if the prefilter is ineffective, and if so, disables it.


 ### Why is the standard library's substring search so much slower?

 We'll start by establishing what the difference in performance actually
 is. There are two relevant benchmark classes to consider: `prebuilt` and
 `oneshot`. The `prebuilt` benchmarks are designed to measure---to the extent
 possible---search time only. That is, the benchmark first starts by building a
 searcher and then only tracking the time for _using_ the searcher:

 ```
 $ rebar rank benchmarks/record/x86_64/2023-08-26.csv --intersection -e memchr/memmem/prebuilt -e std/memmem/prebuilt
 Engine                       Version                   Geometric mean of speed ratios  Benchmark count
 ------                       -------                   ------------------------------  ---------------
 rust/memchr/memmem/prebuilt  2.5.0                     1.03                            53
 rust/std/memmem/prebuilt     1.73.0-nightly 180dffba1  6.50                            53
 ```

 Conversely, the `oneshot` benchmark class measures the time it takes to both
 build the searcher _and_ use it:

 ```
 $ rebar rank benchmarks/record/x86_64/2023-08-26.csv --intersection -e memchr/memmem/oneshot -e std/memmem/oneshot
 Engine                      Version                   Geometric mean of speed ratios  Benchmark count
 ------                      -------                   ------------------------------  ---------------
 rust/memchr/memmem/oneshot  2.5.0                     1.04                            53
 rust/std/memmem/oneshot     1.73.0-nightly 180dffba1  5.26                            53
 ```

 **NOTE:** Replace `rebar rank` with `rebar cmp` in the above commands to
 explore the specific benchmarks and their differences.

 So in both cases, this crate is quite a bit faster over a broad sampling of
 benchmarks regardless of whether you measure only search time or search time
 plus construction time. The difference is a little smaller when you include
 construction time in your measurements.

 These two different types of benchmark classes make for a nice segue into
 one reason why the standard library's substring search can be slower: API
 design. In the standard library, the only APIs available to you require
 one to re-construct the searcher for every search. While you can benefit
 from building a searcher once and iterating over all matches in a single
 string, you cannot reuse that searcher to search other strings. This might
 come up when, for example, searching a file one line at a time. You'll need
 to re-build the searcher for every line searched, and this can [really
 matter][burntsushi-bstr-blog].

 **NOTE:** The `prebuilt` benchmark for the standard library can't actually
 avoid measuring searcher construction at some level, because there is no API
 for it. Instead, the benchmark consists of building the searcher once and then
 finding all matches in a single string via an iterator. This tends to
 approximate a benchmark where searcher construction isn't measured, but it
 isn't perfect. While this means the comparison is not strictly
 apples-to-apples, it does reflect what is maximally possible with the standard
 library, and thus reflects the best that one could do in a real world scenario.

 While there is more to the story than just API design here, it's important to
 point out that even if the standard library's substring search were a precise
 clone of this crate internally, it would still be at a disadvantage in some
 workloads because of its API. (The same also applies to C's standard library
 `memmem` function. There is no way to amortize construction of the searcher.
 You need to pay for it on every call.)

 The other reason for the difference in performance is that
 the standard library has trouble using SIMD. In particular, substring search
 is implemented in the `core` library, where platform specific code generally
 can't exist. That's an issue because in order to utilize SIMD beyond SSE2
 while maintaining portable binaries, one needs to use [dynamic CPU feature
 detection][dynamic-cpu], and that in turn requires platform specific code.
 While there is [an RFC for enabling target feature detection in
 `core`][core-feature], it doesn't yet exist.

 The bottom line here is that `core`'s substring search implementation is
 limited to making use of SSE2, but not AVX.

 Still though, this crate does accelerate substring search even when only SSE2
 is available. The standard library could therefore adopt the techniques in this
 crate just for SSE2. The reason why that hasn't happened yet isn't totally
 clear to me. It likely needs a champion to push it through. The standard
 library tends to be more conservative in these things. With that said, the
 standard library does use some [SSE2 acceleration on `x86-64`][std-sse2] added
 in [this PR][std-sse2-pr]. However, at the time of writing, it is only used
 for short needles and doesn't use the frequency based heuristics found in this
 crate.

 **NOTE:** Another thing worth mentioning is that the standard library's
 substring search routine requires that both the needle and haystack have type
 `&str`. Unless you can assume that your data is valid UTF-8, building a `&str`
 will come with the overhead of UTF-8 validation. This may in turn result in
 overall slower searching depending on your workload. In contrast, the `memchr`
 crate permits both the needle and the haystack to have type `&[u8]`, where
 `&[u8]` can be created from a `&str` with zero cost. Therefore, the substring
 search in this crate is strictly more flexible than what the standard library
 provides.

 [burntsushi-bstr-blog]: https://blog.burntsushi.net/bstr/#motivation-based-on-performance
 [dynamic-cpu]: https://doc.rust-lang.org/std/arch/index.html#dynamic-cpu-feature-detection
 [core-feature]: https://github.com/rust-lang/rfcs/pull/3469
 [std-sse2]: https://github.com/rust-lang/rust/blob/bf9229a2e366b4c311f059014a4aa08af16de5d8/library/core/src/str/pattern.rs#L1719-L1857
 [std-sse2-pr]: https://github.com/rust-lang/rust/pull/103779
	memchr
	======
	This library provides heavily optimized routines for string search primitives.

	[![Build status](https://github.com/BurntSushi/memchr/workflows/ci/badge.svg)](https://github.com/BurntSushi/memchr/actions)
	[![Crates.io](https://img.shields.io/crates/v/memchr.svg)](https://crates.io/crates/memchr)

	Dual-licensed under MIT or the [UNLICENSE](https://unlicense.org/).


	### Documentation

	[https://docs.rs/memchr](https://docs.rs/memchr)


	### Overview

	* 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.

	### Compiling without the standard library

	memchr links to the standard library by default, but you can disable the
	`std` feature if you want to use it in a `#![no_std]` crate:

	```toml
	[dependencies]
	memchr = { version = "2", default-features = false }
	```

	On `x86_64` platforms, when the `std` feature is disabled, the SSE2 accelerated
	implementations will be used. When `std` is enabled, AVX2 accelerated
	implementations will be used if the CPU is determined to support it at runtime.

	SIMD accelerated routines are also available on the `wasm32` and `aarch64`
	targets. The `std` feature is not required to use them.

	When a SIMD version is not available, then this crate falls back to
	[SWAR](https://en.wikipedia.org/wiki/SWAR) techniques.

	### Minimum Rust version policy

	This crate's minimum supported `rustc` version is `1.61.0`.

	The current policy is that the minimum Rust version required to use this crate
	can be increased in minor version updates. For example, if `crate 1.0` requires
	Rust 1.20.0, then `crate 1.0.z` for all values of `z` will also require Rust
	1.20.0 or newer. However, `crate 1.y` for `y > 0` may require a newer minimum
	version of Rust.

	In general, this crate will be conservative with respect to the minimum
	supported version of Rust.


	### Testing strategy

	Given the complexity of the code in this crate, along with the pervasive use
	of `unsafe`, this crate has an extensive testing strategy. It combines multiple
	approaches:

	* Hand-written tests.
	* Exhaustive-style testing meant to exercise all possible branching and offset
	calculations.
	* Property based testing through [`quickcheck`](https://github.com/BurntSushi/quickcheck).
	* Fuzz testing through [`cargo fuzz`](https://github.com/rust-fuzz/cargo-fuzz).
	* A huge suite of benchmarks that are also run as tests. Benchmarks always
	confirm that the expected result occurs.

	Improvements to the testing infrastructure are very welcome.


	### Algorithms used

	At time of writing, this crate's implementation of substring search actually
	has a few different algorithms to choose from depending on the situation.

	* For very small haystacks,
	[Rabin-Karp](https://en.wikipedia.org/wiki/Rabin%E2%80%93Karp_algorithm)
	is used to reduce latency. Rabin-Karp has very small overhead and can often
	complete before other searchers have even been constructed.
	* For small needles, a variant of the
	["Generic SIMD"](http://0x80.pl/articles/simd-strfind.html#algorithm-1-generic-simd)
	algorithm is used. Instead of using the first and last bytes, a heuristic is
	used to select bytes based on a background distribution of byte frequencies.
	* In all other cases,
	[Two-Way](https://en.wikipedia.org/wiki/Two-way_string-matching_algorithm)
	is used. If possible, a prefilter based on the "Generic SIMD" algorithm
	linked above is used to find candidates quickly. A dynamic heuristic is used
	to detect if the prefilter is ineffective, and if so, disables it.


	### Why is the standard library's substring search so much slower?

	We'll start by establishing what the difference in performance actually
	is. There are two relevant benchmark classes to consider: `prebuilt` and
	`oneshot`. The `prebuilt` benchmarks are designed to measure---to the extent
	possible---search time only. That is, the benchmark first starts by building a
	searcher and then only tracking the time for _using_ the searcher:

	```
	$ rebar rank benchmarks/record/x86_64/2023-08-26.csv --intersection -e memchr/memmem/prebuilt -e std/memmem/prebuilt
	Engine Version Geometric mean of speed ratios Benchmark count
	------ ------- ------------------------------ ---------------
	rust/memchr/memmem/prebuilt 2.5.0 1.03 53
	rust/std/memmem/prebuilt 1.73.0-nightly 180dffba1 6.50 53
	```

	Conversely, the `oneshot` benchmark class measures the time it takes to both
	build the searcher _and_ use it:

	```
	$ rebar rank benchmarks/record/x86_64/2023-08-26.csv --intersection -e memchr/memmem/oneshot -e std/memmem/oneshot
	Engine Version Geometric mean of speed ratios Benchmark count
	------ ------- ------------------------------ ---------------
	rust/memchr/memmem/oneshot 2.5.0 1.04 53
	rust/std/memmem/oneshot 1.73.0-nightly 180dffba1 5.26 53
	```

	NOTE: Replace `rebar rank` with `rebar cmp` in the above commands to
	explore the specific benchmarks and their differences.

	So in both cases, this crate is quite a bit faster over a broad sampling of
	benchmarks regardless of whether you measure only search time or search time
	plus construction time. The difference is a little smaller when you include
	construction time in your measurements.

	These two different types of benchmark classes make for a nice segue into
	one reason why the standard library's substring search can be slower: API
	design. In the standard library, the only APIs available to you require
	one to re-construct the searcher for every search. While you can benefit
	from building a searcher once and iterating over all matches in a single
	string, you cannot reuse that searcher to search other strings. This might
	come up when, for example, searching a file one line at a time. You'll need
	to re-build the searcher for every line searched, and this can [really
	matter][burntsushi-bstr-blog].

	NOTE: The `prebuilt` benchmark for the standard library can't actually
	avoid measuring searcher construction at some level, because there is no API
	for it. Instead, the benchmark consists of building the searcher once and then
	finding all matches in a single string via an iterator. This tends to
	approximate a benchmark where searcher construction isn't measured, but it
	isn't perfect. While this means the comparison is not strictly
	apples-to-apples, it does reflect what is maximally possible with the standard
	library, and thus reflects the best that one could do in a real world scenario.

	While there is more to the story than just API design here, it's important to
	point out that even if the standard library's substring search were a precise
	clone of this crate internally, it would still be at a disadvantage in some
	workloads because of its API. (The same also applies to C's standard library
	`memmem` function. There is no way to amortize construction of the searcher.
	You need to pay for it on every call.)

	The other reason for the difference in performance is that
	the standard library has trouble using SIMD. In particular, substring search
	is implemented in the `core` library, where platform specific code generally
	can't exist. That's an issue because in order to utilize SIMD beyond SSE2
	while maintaining portable binaries, one needs to use [dynamic CPU feature
	detection][dynamic-cpu], and that in turn requires platform specific code.
	While there is [an RFC for enabling target feature detection in
	`core`][core-feature], it doesn't yet exist.

	The bottom line here is that `core`'s substring search implementation is
	limited to making use of SSE2, but not AVX.

	Still though, this crate does accelerate substring search even when only SSE2
	is available. The standard library could therefore adopt the techniques in this
	crate just for SSE2. The reason why that hasn't happened yet isn't totally
	clear to me. It likely needs a champion to push it through. The standard
	library tends to be more conservative in these things. With that said, the
	standard library does use some [SSE2 acceleration on `x86-64`][std-sse2] added
	in [this PR][std-sse2-pr]. However, at the time of writing, it is only used
	for short needles and doesn't use the frequency based heuristics found in this
	crate.

	NOTE: Another thing worth mentioning is that the standard library's
	substring search routine requires that both the needle and haystack have type
	`&str`. Unless you can assume that your data is valid UTF-8, building a `&str`
	will come with the overhead of UTF-8 validation. This may in turn result in
	overall slower searching depending on your workload. In contrast, the `memchr`
	crate permits both the needle and the haystack to have type `&[u8]`, where
	`&[u8]` can be created from a `&str` with zero cost. Therefore, the substring
	search in this crate is strictly more flexible than what the standard library
	provides.

	[burntsushi-bstr-blog]: https://blog.burntsushi.net/bstr/#motivation-based-on-performance
	[dynamic-cpu]: https://doc.rust-lang.org/std/arch/index.html#dynamic-cpu-feature-detection
	[core-feature]: https://github.com/rust-lang/rfcs/pull/3469
	[std-sse2]: https://github.com/rust-lang/rust/blob/bf9229a2e366b4c311f059014a4aa08af16de5d8/library/core/src/str/pattern.rs#L1719-L1857
	[std-sse2-pr]: https://github.com/rust-lang/rust/pull/103779