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+use core::iter::Rev;
+
+use crate::arch::generic::memchr as generic;
+
+/// Search for the first occurrence of a byte in a slice.
+///
+/// This returns the index corresponding to the first occurrence of `needle` in
+/// `haystack`, or `None` if one is not found. If an index is returned, it is
+/// guaranteed to be less than `haystack.len()`.
+///
+/// While this is semantically the same as something like
+/// `haystack.iter().position(|&b| b == needle)`, this routine will attempt to
+/// use highly optimized vector operations that can be an order of magnitude
+/// faster (or more).
+///
+/// # Example
+///
+/// This shows how to find the first position of a byte in a byte string.
+///
+/// ```
+/// use memchr::memchr;
+///
+/// let haystack = b"the quick brown fox";
+/// assert_eq!(memchr(b'k', haystack), Some(8));
+/// ```
+#[inline]
+pub fn memchr(needle: u8, haystack: &[u8]) -> Option<usize> {
+ // SAFETY: memchr_raw, when a match is found, always returns a valid
+ // pointer between start and end.
+ unsafe {
+ generic::search_slice_with_raw(haystack, |start, end| {
+ memchr_raw(needle, start, end)
+ })
+ }
+}
+
+/// Search for the last occurrence of a byte in a slice.
+///
+/// This returns the index corresponding to the last occurrence of `needle` in
+/// `haystack`, or `None` if one is not found. If an index is returned, it is
+/// guaranteed to be less than `haystack.len()`.
+///
+/// While this is semantically the same as something like
+/// `haystack.iter().rposition(|&b| b == needle)`, this routine will attempt to
+/// use highly optimized vector operations that can be an order of magnitude
+/// faster (or more).
+///
+/// # Example
+///
+/// This shows how to find the last position of a byte in a byte string.
+///
+/// ```
+/// use memchr::memrchr;
+///
+/// let haystack = b"the quick brown fox";
+/// assert_eq!(memrchr(b'o', haystack), Some(17));
+/// ```
+#[inline]
+pub fn memrchr(needle: u8, haystack: &[u8]) -> Option<usize> {
+ // SAFETY: memrchr_raw, when a match is found, always returns a valid
+ // pointer between start and end.
+ unsafe {
+ generic::search_slice_with_raw(haystack, |start, end| {
+ memrchr_raw(needle, start, end)
+ })
+ }
+}
+
+/// Search for the first occurrence of two possible bytes in a haystack.
+///
+/// This returns the index corresponding to the first occurrence of one of the
+/// needle bytes in `haystack`, or `None` if one is not found. If an index is
+/// returned, it is guaranteed to be less than `haystack.len()`.
+///
+/// While this is semantically the same as something like
+/// `haystack.iter().position(|&b| b == needle1 || b == needle2)`, this routine
+/// will attempt to use highly optimized vector operations that can be an order
+/// of magnitude faster (or more).
+///
+/// # Example
+///
+/// This shows how to find the first position of one of two possible bytes in a
+/// haystack.
+///
+/// ```
+/// use memchr::memchr2;
+///
+/// let haystack = b"the quick brown fox";
+/// assert_eq!(memchr2(b'k', b'q', haystack), Some(4));
+/// ```
+#[inline]
+pub fn memchr2(needle1: u8, needle2: u8, haystack: &[u8]) -> Option<usize> {
+ // SAFETY: memchr2_raw, when a match is found, always returns a valid
+ // pointer between start and end.
+ unsafe {
+ generic::search_slice_with_raw(haystack, |start, end| {
+ memchr2_raw(needle1, needle2, start, end)
+ })
+ }
+}
+
+/// Search for the last occurrence of two possible bytes in a haystack.
+///
+/// This returns the index corresponding to the last occurrence of one of the
+/// needle bytes in `haystack`, or `None` if one is not found. If an index is
+/// returned, it is guaranteed to be less than `haystack.len()`.
+///
+/// While this is semantically the same as something like
+/// `haystack.iter().rposition(|&b| b == needle1 || b == needle2)`, this
+/// routine will attempt to use highly optimized vector operations that can be
+/// an order of magnitude faster (or more).
+///
+/// # Example
+///
+/// This shows how to find the last position of one of two possible bytes in a
+/// haystack.
+///
+/// ```
+/// use memchr::memrchr2;
+///
+/// let haystack = b"the quick brown fox";
+/// assert_eq!(memrchr2(b'k', b'o', haystack), Some(17));
+/// ```
+#[inline]
+pub fn memrchr2(needle1: u8, needle2: u8, haystack: &[u8]) -> Option<usize> {
+ // SAFETY: memrchr2_raw, when a match is found, always returns a valid
+ // pointer between start and end.
+ unsafe {
+ generic::search_slice_with_raw(haystack, |start, end| {
+ memrchr2_raw(needle1, needle2, start, end)
+ })
+ }
+}
+
+/// Search for the first occurrence of three possible bytes in a haystack.
+///
+/// This returns the index corresponding to the first occurrence of one of the
+/// needle bytes in `haystack`, or `None` if one is not found. If an index is
+/// returned, it is guaranteed to be less than `haystack.len()`.
+///
+/// While this is semantically the same as something like
+/// `haystack.iter().position(|&b| b == needle1 || b == needle2 || b == needle3)`,
+/// this routine will attempt to use highly optimized vector operations that
+/// can be an order of magnitude faster (or more).
+///
+/// # Example
+///
+/// This shows how to find the first position of one of three possible bytes in
+/// a haystack.
+///
+/// ```
+/// use memchr::memchr3;
+///
+/// let haystack = b"the quick brown fox";
+/// assert_eq!(memchr3(b'k', b'q', b'u', haystack), Some(4));
+/// ```
+#[inline]
+pub fn memchr3(
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ haystack: &[u8],
+) -> Option<usize> {
+ // SAFETY: memchr3_raw, when a match is found, always returns a valid
+ // pointer between start and end.
+ unsafe {
+ generic::search_slice_with_raw(haystack, |start, end| {
+ memchr3_raw(needle1, needle2, needle3, start, end)
+ })
+ }
+}
+
+/// Search for the last occurrence of three possible bytes in a haystack.
+///
+/// This returns the index corresponding to the last occurrence of one of the
+/// needle bytes in `haystack`, or `None` if one is not found. If an index is
+/// returned, it is guaranteed to be less than `haystack.len()`.
+///
+/// While this is semantically the same as something like
+/// `haystack.iter().rposition(|&b| b == needle1 || b == needle2 || b == needle3)`,
+/// this routine will attempt to use highly optimized vector operations that
+/// can be an order of magnitude faster (or more).
+///
+/// # Example
+///
+/// This shows how to find the last position of one of three possible bytes in
+/// a haystack.
+///
+/// ```
+/// use memchr::memrchr3;
+///
+/// let haystack = b"the quick brown fox";
+/// assert_eq!(memrchr3(b'k', b'o', b'n', haystack), Some(17));
+/// ```
+#[inline]
+pub fn memrchr3(
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ haystack: &[u8],
+) -> Option<usize> {
+ // SAFETY: memrchr3_raw, when a match is found, always returns a valid
+ // pointer between start and end.
+ unsafe {
+ generic::search_slice_with_raw(haystack, |start, end| {
+ memrchr3_raw(needle1, needle2, needle3, start, end)
+ })
+ }
+}
+
+/// Returns an iterator over all occurrences of the needle in a haystack.
+///
+/// The iterator returned implements `DoubleEndedIterator`. This means it
+/// can also be used to find occurrences in reverse order.
+#[inline]
+pub fn memchr_iter<'h>(needle: u8, haystack: &'h [u8]) -> Memchr<'h> {
+ Memchr::new(needle, haystack)
+}
+
+/// Returns an iterator over all occurrences of the needle in a haystack, in
+/// reverse.
+#[inline]
+pub fn memrchr_iter(needle: u8, haystack: &[u8]) -> Rev<Memchr<'_>> {
+ Memchr::new(needle, haystack).rev()
+}
+
+/// Returns an iterator over all occurrences of the needles in a haystack.
+///
+/// The iterator returned implements `DoubleEndedIterator`. This means it
+/// can also be used to find occurrences in reverse order.
+#[inline]
+pub fn memchr2_iter<'h>(
+ needle1: u8,
+ needle2: u8,
+ haystack: &'h [u8],
+) -> Memchr2<'h> {
+ Memchr2::new(needle1, needle2, haystack)
+}
+
+/// Returns an iterator over all occurrences of the needles in a haystack, in
+/// reverse.
+#[inline]
+pub fn memrchr2_iter(
+ needle1: u8,
+ needle2: u8,
+ haystack: &[u8],
+) -> Rev<Memchr2<'_>> {
+ Memchr2::new(needle1, needle2, haystack).rev()
+}
+
+/// Returns an iterator over all occurrences of the needles in a haystack.
+///
+/// The iterator returned implements `DoubleEndedIterator`. This means it
+/// can also be used to find occurrences in reverse order.
+#[inline]
+pub fn memchr3_iter<'h>(
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ haystack: &'h [u8],
+) -> Memchr3<'h> {
+ Memchr3::new(needle1, needle2, needle3, haystack)
+}
+
+/// Returns an iterator over all occurrences of the needles in a haystack, in
+/// reverse.
+#[inline]
+pub fn memrchr3_iter(
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ haystack: &[u8],
+) -> Rev<Memchr3<'_>> {
+ Memchr3::new(needle1, needle2, needle3, haystack).rev()
+}
+
+/// An iterator over all occurrences of a single byte in a haystack.
+///
+/// This iterator implements `DoubleEndedIterator`, which means it can also be
+/// used to find occurrences in reverse order.
+///
+/// This iterator is created by the [`memchr_iter`] or `[memrchr_iter`]
+/// functions. It can also be created with the [`Memchr::new`] method.
+///
+/// The lifetime parameter `'h` refers to the lifetime of the haystack being
+/// searched.
+#[derive(Clone, Debug)]
+pub struct Memchr<'h> {
+ needle1: u8,
+ it: crate::arch::generic::memchr::Iter<'h>,
+}
+
+impl<'h> Memchr<'h> {
+ /// Returns an iterator over all occurrences of the needle byte in the
+ /// given haystack.
+ ///
+ /// The iterator returned implements `DoubleEndedIterator`. This means it
+ /// can also be used to find occurrences in reverse order.
+ #[inline]
+ pub fn new(needle1: u8, haystack: &'h [u8]) -> Memchr<'h> {
+ Memchr {
+ needle1,
+ it: crate::arch::generic::memchr::Iter::new(haystack),
+ }
+ }
+}
+
+impl<'h> Iterator for Memchr<'h> {
+ type Item = usize;
+
+ #[inline]
+ fn next(&mut self) -> Option<usize> {
+ // SAFETY: All of our implementations of memchr ensure that any
+ // pointers returns will fall within the start and end bounds, and this
+ // upholds the safety contract of `self.it.next`.
+ unsafe {
+ // NOTE: I attempted to define an enum of previously created
+ // searchers and then switch on those here instead of just
+ // calling `memchr_raw` (or `One::new(..).find_raw(..)`). But
+ // that turned out to have a fair bit of extra overhead when
+ // searching very small haystacks.
+ self.it.next(|s, e| memchr_raw(self.needle1, s, e))
+ }
+ }
+
+ #[inline]
+ fn count(self) -> usize {
+ self.it.count(|s, e| {
+ // SAFETY: We rely on our generic iterator to return valid start
+ // and end pointers.
+ unsafe { count_raw(self.needle1, s, e) }
+ })
+ }
+
+ #[inline]
+ fn size_hint(&self) -> (usize, Option<usize>) {
+ self.it.size_hint()
+ }
+}
+
+impl<'h> DoubleEndedIterator for Memchr<'h> {
+ #[inline]
+ fn next_back(&mut self) -> Option<usize> {
+ // SAFETY: All of our implementations of memchr ensure that any
+ // pointers returns will fall within the start and end bounds, and this
+ // upholds the safety contract of `self.it.next_back`.
+ unsafe { self.it.next_back(|s, e| memrchr_raw(self.needle1, s, e)) }
+ }
+}
+
+impl<'h> core::iter::FusedIterator for Memchr<'h> {}
+
+/// An iterator over all occurrences of two possible bytes in a haystack.
+///
+/// This iterator implements `DoubleEndedIterator`, which means it can also be
+/// used to find occurrences in reverse order.
+///
+/// This iterator is created by the [`memchr2_iter`] or `[memrchr2_iter`]
+/// functions. It can also be created with the [`Memchr2::new`] method.
+///
+/// The lifetime parameter `'h` refers to the lifetime of the haystack being
+/// searched.
+#[derive(Clone, Debug)]
+pub struct Memchr2<'h> {
+ needle1: u8,
+ needle2: u8,
+ it: crate::arch::generic::memchr::Iter<'h>,
+}
+
+impl<'h> Memchr2<'h> {
+ /// Returns an iterator over all occurrences of the needle bytes in the
+ /// given haystack.
+ ///
+ /// The iterator returned implements `DoubleEndedIterator`. This means it
+ /// can also be used to find occurrences in reverse order.
+ #[inline]
+ pub fn new(needle1: u8, needle2: u8, haystack: &'h [u8]) -> Memchr2<'h> {
+ Memchr2 {
+ needle1,
+ needle2,
+ it: crate::arch::generic::memchr::Iter::new(haystack),
+ }
+ }
+}
+
+impl<'h> Iterator for Memchr2<'h> {
+ type Item = usize;
+
+ #[inline]
+ fn next(&mut self) -> Option<usize> {
+ // SAFETY: All of our implementations of memchr ensure that any
+ // pointers returns will fall within the start and end bounds, and this
+ // upholds the safety contract of `self.it.next`.
+ unsafe {
+ self.it.next(|s, e| memchr2_raw(self.needle1, self.needle2, s, e))
+ }
+ }
+
+ #[inline]
+ fn size_hint(&self) -> (usize, Option<usize>) {
+ self.it.size_hint()
+ }
+}
+
+impl<'h> DoubleEndedIterator for Memchr2<'h> {
+ #[inline]
+ fn next_back(&mut self) -> Option<usize> {
+ // SAFETY: All of our implementations of memchr ensure that any
+ // pointers returns will fall within the start and end bounds, and this
+ // upholds the safety contract of `self.it.next_back`.
+ unsafe {
+ self.it.next_back(|s, e| {
+ memrchr2_raw(self.needle1, self.needle2, s, e)
+ })
+ }
+ }
+}
+
+impl<'h> core::iter::FusedIterator for Memchr2<'h> {}
+
+/// An iterator over all occurrences of three possible bytes in a haystack.
+///
+/// This iterator implements `DoubleEndedIterator`, which means it can also be
+/// used to find occurrences in reverse order.
+///
+/// This iterator is created by the [`memchr2_iter`] or `[memrchr2_iter`]
+/// functions. It can also be created with the [`Memchr3::new`] method.
+///
+/// The lifetime parameter `'h` refers to the lifetime of the haystack being
+/// searched.
+#[derive(Clone, Debug)]
+pub struct Memchr3<'h> {
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ it: crate::arch::generic::memchr::Iter<'h>,
+}
+
+impl<'h> Memchr3<'h> {
+ /// Returns an iterator over all occurrences of the needle bytes in the
+ /// given haystack.
+ ///
+ /// The iterator returned implements `DoubleEndedIterator`. This means it
+ /// can also be used to find occurrences in reverse order.
+ #[inline]
+ pub fn new(
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ haystack: &'h [u8],
+ ) -> Memchr3<'h> {
+ Memchr3 {
+ needle1,
+ needle2,
+ needle3,
+ it: crate::arch::generic::memchr::Iter::new(haystack),
+ }
+ }
+}
+
+impl<'h> Iterator for Memchr3<'h> {
+ type Item = usize;
+
+ #[inline]
+ fn next(&mut self) -> Option<usize> {
+ // SAFETY: All of our implementations of memchr ensure that any
+ // pointers returns will fall within the start and end bounds, and this
+ // upholds the safety contract of `self.it.next`.
+ unsafe {
+ self.it.next(|s, e| {
+ memchr3_raw(self.needle1, self.needle2, self.needle3, s, e)
+ })
+ }
+ }
+
+ #[inline]
+ fn size_hint(&self) -> (usize, Option<usize>) {
+ self.it.size_hint()
+ }
+}
+
+impl<'h> DoubleEndedIterator for Memchr3<'h> {
+ #[inline]
+ fn next_back(&mut self) -> Option<usize> {
+ // SAFETY: All of our implementations of memchr ensure that any
+ // pointers returns will fall within the start and end bounds, and this
+ // upholds the safety contract of `self.it.next_back`.
+ unsafe {
+ self.it.next_back(|s, e| {
+ memrchr3_raw(self.needle1, self.needle2, self.needle3, s, e)
+ })
+ }
+ }
+}
+
+impl<'h> core::iter::FusedIterator for Memchr3<'h> {}
+
+/// memchr, but using raw pointers to represent the haystack.
+///
+/// # Safety
+///
+/// Pointers must be valid. See `One::find_raw`.
+#[inline]
+unsafe fn memchr_raw(
+ needle: u8,
+ start: *const u8,
+ end: *const u8,
+) -> Option<*const u8> {
+ #[cfg(target_arch = "x86_64")]
+ {
+ // x86_64 does CPU feature detection at runtime in order to use AVX2
+ // instructions even when the `avx2` feature isn't enabled at compile
+ // time. This function also handles using a fallback if neither AVX2
+ // nor SSE2 (unusual) are available.
+ crate::arch::x86_64::memchr::memchr_raw(needle, start, end)
+ }
+ #[cfg(target_arch = "wasm32")]
+ {
+ crate::arch::wasm32::memchr::memchr_raw(needle, start, end)
+ }
+ #[cfg(target_arch = "aarch64")]
+ {
+ crate::arch::aarch64::memchr::memchr_raw(needle, start, end)
+ }
+ #[cfg(not(any(
+ target_arch = "x86_64",
+ target_arch = "wasm32",
+ target_arch = "aarch64"
+ )))]
+ {
+ crate::arch::all::memchr::One::new(needle).find_raw(start, end)
+ }
+}
+
+/// memrchr, but using raw pointers to represent the haystack.
+///
+/// # Safety
+///
+/// Pointers must be valid. See `One::rfind_raw`.
+#[inline]
+unsafe fn memrchr_raw(
+ needle: u8,
+ start: *const u8,
+ end: *const u8,
+) -> Option<*const u8> {
+ #[cfg(target_arch = "x86_64")]
+ {
+ crate::arch::x86_64::memchr::memrchr_raw(needle, start, end)
+ }
+ #[cfg(target_arch = "wasm32")]
+ {
+ crate::arch::wasm32::memchr::memrchr_raw(needle, start, end)
+ }
+ #[cfg(target_arch = "aarch64")]
+ {
+ crate::arch::aarch64::memchr::memrchr_raw(needle, start, end)
+ }
+ #[cfg(not(any(
+ target_arch = "x86_64",
+ target_arch = "wasm32",
+ target_arch = "aarch64"
+ )))]
+ {
+ crate::arch::all::memchr::One::new(needle).rfind_raw(start, end)
+ }
+}
+
+/// memchr2, but using raw pointers to represent the haystack.
+///
+/// # Safety
+///
+/// Pointers must be valid. See `Two::find_raw`.
+#[inline]
+unsafe fn memchr2_raw(
+ needle1: u8,
+ needle2: u8,
+ start: *const u8,
+ end: *const u8,
+) -> Option<*const u8> {
+ #[cfg(target_arch = "x86_64")]
+ {
+ crate::arch::x86_64::memchr::memchr2_raw(needle1, needle2, start, end)
+ }
+ #[cfg(target_arch = "wasm32")]
+ {
+ crate::arch::wasm32::memchr::memchr2_raw(needle1, needle2, start, end)
+ }
+ #[cfg(target_arch = "aarch64")]
+ {
+ crate::arch::aarch64::memchr::memchr2_raw(needle1, needle2, start, end)
+ }
+ #[cfg(not(any(
+ target_arch = "x86_64",
+ target_arch = "wasm32",
+ target_arch = "aarch64"
+ )))]
+ {
+ crate::arch::all::memchr::Two::new(needle1, needle2)
+ .find_raw(start, end)
+ }
+}
+
+/// memrchr2, but using raw pointers to represent the haystack.
+///
+/// # Safety
+///
+/// Pointers must be valid. See `Two::rfind_raw`.
+#[inline]
+unsafe fn memrchr2_raw(
+ needle1: u8,
+ needle2: u8,
+ start: *const u8,
+ end: *const u8,
+) -> Option<*const u8> {
+ #[cfg(target_arch = "x86_64")]
+ {
+ crate::arch::x86_64::memchr::memrchr2_raw(needle1, needle2, start, end)
+ }
+ #[cfg(target_arch = "wasm32")]
+ {
+ crate::arch::wasm32::memchr::memrchr2_raw(needle1, needle2, start, end)
+ }
+ #[cfg(target_arch = "aarch64")]
+ {
+ crate::arch::aarch64::memchr::memrchr2_raw(
+ needle1, needle2, start, end,
+ )
+ }
+ #[cfg(not(any(
+ target_arch = "x86_64",
+ target_arch = "wasm32",
+ target_arch = "aarch64"
+ )))]
+ {
+ crate::arch::all::memchr::Two::new(needle1, needle2)
+ .rfind_raw(start, end)
+ }
+}
+
+/// memchr3, but using raw pointers to represent the haystack.
+///
+/// # Safety
+///
+/// Pointers must be valid. See `Three::find_raw`.
+#[inline]
+unsafe fn memchr3_raw(
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ start: *const u8,
+ end: *const u8,
+) -> Option<*const u8> {
+ #[cfg(target_arch = "x86_64")]
+ {
+ crate::arch::x86_64::memchr::memchr3_raw(
+ needle1, needle2, needle3, start, end,
+ )
+ }
+ #[cfg(target_arch = "wasm32")]
+ {
+ crate::arch::wasm32::memchr::memchr3_raw(
+ needle1, needle2, needle3, start, end,
+ )
+ }
+ #[cfg(target_arch = "aarch64")]
+ {
+ crate::arch::aarch64::memchr::memchr3_raw(
+ needle1, needle2, needle3, start, end,
+ )
+ }
+ #[cfg(not(any(
+ target_arch = "x86_64",
+ target_arch = "wasm32",
+ target_arch = "aarch64"
+ )))]
+ {
+ crate::arch::all::memchr::Three::new(needle1, needle2, needle3)
+ .find_raw(start, end)
+ }
+}
+
+/// memrchr3, but using raw pointers to represent the haystack.
+///
+/// # Safety
+///
+/// Pointers must be valid. See `Three::rfind_raw`.
+#[inline]
+unsafe fn memrchr3_raw(
+ needle1: u8,
+ needle2: u8,
+ needle3: u8,
+ start: *const u8,
+ end: *const u8,
+) -> Option<*const u8> {
+ #[cfg(target_arch = "x86_64")]
+ {
+ crate::arch::x86_64::memchr::memrchr3_raw(
+ needle1, needle2, needle3, start, end,
+ )
+ }
+ #[cfg(target_arch = "wasm32")]
+ {
+ crate::arch::wasm32::memchr::memrchr3_raw(
+ needle1, needle2, needle3, start, end,
+ )
+ }
+ #[cfg(target_arch = "aarch64")]
+ {
+ crate::arch::aarch64::memchr::memrchr3_raw(
+ needle1, needle2, needle3, start, end,
+ )
+ }
+ #[cfg(not(any(
+ target_arch = "x86_64",
+ target_arch = "wasm32",
+ target_arch = "aarch64"
+ )))]
+ {
+ crate::arch::all::memchr::Three::new(needle1, needle2, needle3)
+ .rfind_raw(start, end)
+ }
+}
+
+/// Count all matching bytes, but using raw pointers to represent the haystack.
+///
+/// # Safety
+///
+/// Pointers must be valid. See `One::count_raw`.
+#[inline]
+unsafe fn count_raw(needle: u8, start: *const u8, end: *const u8) -> usize {
+ #[cfg(target_arch = "x86_64")]
+ {
+ crate::arch::x86_64::memchr::count_raw(needle, start, end)
+ }
+ #[cfg(target_arch = "wasm32")]
+ {
+ crate::arch::wasm32::memchr::count_raw(needle, start, end)
+ }
+ #[cfg(target_arch = "aarch64")]
+ {
+ crate::arch::aarch64::memchr::count_raw(needle, start, end)
+ }
+ #[cfg(not(any(
+ target_arch = "x86_64",
+ target_arch = "wasm32",
+ target_arch = "aarch64"
+ )))]
+ {
+ crate::arch::all::memchr::One::new(needle).count_raw(start, end)
+ }
+}
+
+#[cfg(test)]
+mod tests {
+ use super::*;
+
+ #[test]
+ fn forward1_iter() {
+ crate::tests::memchr::Runner::new(1).forward_iter(
+ |haystack, needles| {
+ Some(memchr_iter(needles[0], haystack).collect())
+ },
+ )
+ }
+
+ #[test]
+ fn forward1_oneshot() {
+ crate::tests::memchr::Runner::new(1).forward_oneshot(
+ |haystack, needles| Some(memchr(needles[0], haystack)),
+ )
+ }
+
+ #[test]
+ fn reverse1_iter() {
+ crate::tests::memchr::Runner::new(1).reverse_iter(
+ |haystack, needles| {
+ Some(memrchr_iter(needles[0], haystack).collect())
+ },
+ )
+ }
+
+ #[test]
+ fn reverse1_oneshot() {
+ crate::tests::memchr::Runner::new(1).reverse_oneshot(
+ |haystack, needles| Some(memrchr(needles[0], haystack)),
+ )
+ }
+
+ #[test]
+ fn count1_iter() {
+ crate::tests::memchr::Runner::new(1).count_iter(|haystack, needles| {
+ Some(memchr_iter(needles[0], haystack).count())
+ })
+ }
+
+ #[test]
+ fn forward2_iter() {
+ crate::tests::memchr::Runner::new(2).forward_iter(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ Some(memchr2_iter(n1, n2, haystack).collect())
+ },
+ )
+ }
+
+ #[test]
+ fn forward2_oneshot() {
+ crate::tests::memchr::Runner::new(2).forward_oneshot(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ Some(memchr2(n1, n2, haystack))
+ },
+ )
+ }
+
+ #[test]
+ fn reverse2_iter() {
+ crate::tests::memchr::Runner::new(2).reverse_iter(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ Some(memrchr2_iter(n1, n2, haystack).collect())
+ },
+ )
+ }
+
+ #[test]
+ fn reverse2_oneshot() {
+ crate::tests::memchr::Runner::new(2).reverse_oneshot(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ Some(memrchr2(n1, n2, haystack))
+ },
+ )
+ }
+
+ #[test]
+ fn forward3_iter() {
+ crate::tests::memchr::Runner::new(3).forward_iter(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ let n3 = needles.get(2).copied()?;
+ Some(memchr3_iter(n1, n2, n3, haystack).collect())
+ },
+ )
+ }
+
+ #[test]
+ fn forward3_oneshot() {
+ crate::tests::memchr::Runner::new(3).forward_oneshot(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ let n3 = needles.get(2).copied()?;
+ Some(memchr3(n1, n2, n3, haystack))
+ },
+ )
+ }
+
+ #[test]
+ fn reverse3_iter() {
+ crate::tests::memchr::Runner::new(3).reverse_iter(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ let n3 = needles.get(2).copied()?;
+ Some(memrchr3_iter(n1, n2, n3, haystack).collect())
+ },
+ )
+ }
+
+ #[test]
+ fn reverse3_oneshot() {
+ crate::tests::memchr::Runner::new(3).reverse_oneshot(
+ |haystack, needles| {
+ let n1 = needles.get(0).copied()?;
+ let n2 = needles.get(1).copied()?;
+ let n3 = needles.get(2).copied()?;
+ Some(memrchr3(n1, n2, n3, haystack))
+ },
+ )
+ }
+
+ // Prior to memchr 2.6, the memchr iterators both implemented Send and
+ // Sync. But in memchr 2.6, the iterator changed to use raw pointers
+ // internally and I didn't add explicit Send/Sync impls. This ended up
+ // regressing the API. This test ensures we don't do that again.
+ //
+ // See: https://github.com/BurntSushi/memchr/issues/133
+ #[test]
+ fn sync_regression() {
+ use core::panic::{RefUnwindSafe, UnwindSafe};
+
+ fn assert_send_sync<T: Send + Sync + UnwindSafe + RefUnwindSafe>() {}
+ assert_send_sync::<Memchr>();
+ assert_send_sync::<Memchr2>();
+ assert_send_sync::<Memchr3>()
+ }
+}