// This module defines some core types for dealing with accelerated DFA states. // Briefly, a DFA state can be "accelerated" if all of its transitions except // for a few loop back to itself. This directly implies that the only way out // of such a state is if a byte corresponding to one of those non-loopback // transitions is found. Such states are often found in simple repetitions in // non-Unicode regexes. For example, consider '(?-u)[^a]+a'. We can look at its // DFA with regex-cli: // // $ regex-cli debug dfa dense '(?-u)[^a]+a' -BbC // dense::DFA( // D 000000: // Q 000001: // *000002: // A 000003: \x00-` => 3, a => 5, b-\xFF => 3 // >000004: \x00-` => 3, a => 4, b-\xFF => 3 // 000005: \x00-\xFF => 2, EOI => 2 // ) // // In particular, state 3 is accelerated (shown via the 'A' indicator) since // the only way to leave that state once entered is to see an 'a' byte. If // there is a long run of non-'a' bytes, then using something like 'memchr' // to find the next 'a' byte can be significantly faster than just using the // standard byte-at-a-time state machine. // // Unfortunately, this optimization rarely applies when Unicode is enabled. // For example, patterns like '[^a]' don't actually match any byte that isn't // 'a', but rather, any UTF-8 encoding of a Unicode scalar value that isn't // 'a'. This makes the state machine much more complex---far beyond a single // state---and removes the ability to easily accelerate it. (Because if the // machine sees a non-UTF-8 sequence, then the machine won't match through it.) // // In practice, we only consider accelerating states that have 3 or fewer // non-loop transitions. At a certain point, you get diminishing returns, but // also because that's what the memchr crate supports. The structures below // hard-code this assumption and provide (de)serialization APIs for use inside // a DFA. // // And finally, note that there is some trickery involved in making it very // fast to not only check whether a state is accelerated at search time, but // also to access the bytes to search for to implement the acceleration itself. // dfa/special.rs provides more detail, but the short story is that all // accelerated states appear contiguously in a DFA. This means we can represent // the ID space of all accelerated DFA states with a single range. So given // a state ID, we can determine whether it's accelerated via // // min_accel_id <= id <= max_accel_id // // And find its corresponding accelerator with: // // accels.get((id - min_accel_id) / dfa_stride) #[cfg(feature = "dfa-build")] use alloc::{vec, vec::Vec}; use crate::util::{ int::Pointer, memchr, wire::{self, DeserializeError, Endian, SerializeError}, }; /// The base type used to represent a collection of accelerators. /// /// While an `Accel` is represented as a fixed size array of bytes, a /// *collection* of `Accel`s (called `Accels`) is represented internally as a /// slice of u32. While it's a bit unnatural to do this and costs us a bit of /// fairly low-risk not-safe code, it lets us remove the need for a second type /// parameter in the definition of dense::DFA. (Which really wants everything /// to be a slice of u32.) type AccelTy = u32; /// The size of the unit of representation for accelerators. /// /// ACCEL_CAP *must* be a multiple of this size. const ACCEL_TY_SIZE: usize = core::mem::size_of::(); /// The maximum length in bytes that a single Accel can be. This is distinct /// from the capacity of an accelerator in that the length represents only the /// bytes that should be read. const ACCEL_LEN: usize = 4; /// The capacity of each accelerator, in bytes. We set this to 8 since it's a /// multiple of 4 (our ID size) and because it gives us a little wiggle room /// if we want to support more accel bytes in the future without a breaking /// change. /// /// This MUST be a multiple of ACCEL_TY_SIZE. const ACCEL_CAP: usize = 8; /// Search for between 1 and 3 needle bytes in the given haystack, starting the /// search at the given position. If `needles` has a length other than 1-3, /// then this panics. #[cfg_attr(feature = "perf-inline", inline(always))] pub(crate) fn find_fwd( needles: &[u8], haystack: &[u8], at: usize, ) -> Option { let bs = needles; let i = match needles.len() { 1 => memchr::memchr(bs[0], &haystack[at..])?, 2 => memchr::memchr2(bs[0], bs[1], &haystack[at..])?, 3 => memchr::memchr3(bs[0], bs[1], bs[2], &haystack[at..])?, 0 => panic!("cannot find with empty needles"), n => panic!("invalid needles length: {}", n), }; Some(at + i) } /// Search for between 1 and 3 needle bytes in the given haystack in reverse, /// starting the search at the given position. If `needles` has a length other /// than 1-3, then this panics. #[cfg_attr(feature = "perf-inline", inline(always))] pub(crate) fn find_rev( needles: &[u8], haystack: &[u8], at: usize, ) -> Option { let bs = needles; match needles.len() { 1 => memchr::memrchr(bs[0], &haystack[..at]), 2 => memchr::memrchr2(bs[0], bs[1], &haystack[..at]), 3 => memchr::memrchr3(bs[0], bs[1], bs[2], &haystack[..at]), 0 => panic!("cannot find with empty needles"), n => panic!("invalid needles length: {}", n), } } /// Represents the accelerators for all accelerated states in a dense DFA. /// /// The `A` type parameter represents the type of the underlying bytes. /// Generally, this is either `&[AccelTy]` or `Vec`. #[derive(Clone)] pub(crate) struct Accels { /// A length prefixed slice of contiguous accelerators. See the top comment /// in this module for more details on how we can jump from a DFA's state /// ID to an accelerator in this list. /// /// The first 4 bytes always correspond to the number of accelerators /// that follow. accels: A, } #[cfg(feature = "dfa-build")] impl Accels> { /// Create an empty sequence of accelerators for a DFA. pub fn empty() -> Accels> { Accels { accels: vec![0] } } /// Add an accelerator to this sequence. /// /// This adds to the accelerator to the end of the sequence and therefore /// should be done in correspondence with its state in the DFA. /// /// This panics if this results in more accelerators than AccelTy::MAX. pub fn add(&mut self, accel: Accel) { self.accels.extend_from_slice(&accel.as_accel_tys()); let len = self.len(); self.set_len(len + 1); } /// Set the number of accelerators in this sequence, which is encoded in /// the first 4 bytes of the underlying bytes. fn set_len(&mut self, new_len: usize) { // The only way an accelerator gets added is if a state exists for // it, and if a state exists, then its index is guaranteed to be // representable by a AccelTy by virtue of the guarantees provided by // StateID. let new_len = AccelTy::try_from(new_len).unwrap(); self.accels[0] = new_len; } } impl<'a> Accels<&'a [AccelTy]> { /// Deserialize a sequence of accelerators from the given bytes. If there /// was a problem deserializing, then an error is returned. /// /// This is guaranteed to run in constant time. This does not guarantee /// that every accelerator in the returned collection is valid. Thus, /// accessing one may panic, or not-safe code that relies on accelerators /// being correct my result in UB. /// /// Callers may check the validity of every accelerator with the `validate` /// method. pub fn from_bytes_unchecked( mut slice: &'a [u8], ) -> Result<(Accels<&'a [AccelTy]>, usize), DeserializeError> { let slice_start = slice.as_ptr().as_usize(); let (accel_len, _) = wire::try_read_u32_as_usize(slice, "accelerators length")?; // The accelerator length is part of the accel_tys slice that // we deserialize. This is perhaps a bit idiosyncratic. It would // probably be better to split out the length into a real field. let accel_tys_len = wire::add( wire::mul(accel_len, 2, "total number of accelerator accel_tys")?, 1, "total number of accel_tys", )?; let accel_tys_bytes_len = wire::mul( ACCEL_TY_SIZE, accel_tys_len, "total number of bytes in accelerators", )?; wire::check_slice_len(slice, accel_tys_bytes_len, "accelerators")?; wire::check_alignment::(slice)?; let accel_tys = &slice[..accel_tys_bytes_len]; slice = &slice[accel_tys_bytes_len..]; // SAFETY: We've checked the length and alignment above, and since // slice is just bytes and AccelTy is just a u32, we can safely cast to // a slice of &[AccelTy]. let accels = unsafe { core::slice::from_raw_parts( accel_tys.as_ptr().cast::(), accel_tys_len, ) }; Ok((Accels { accels }, slice.as_ptr().as_usize() - slice_start)) } } impl> Accels { /// Return an owned version of the accelerators. #[cfg(feature = "alloc")] pub fn to_owned(&self) -> Accels> { Accels { accels: self.accels.as_ref().to_vec() } } /// Return a borrowed version of the accelerators. pub fn as_ref(&self) -> Accels<&[AccelTy]> { Accels { accels: self.accels.as_ref() } } /// Return the bytes representing the serialization of the accelerators. pub fn as_bytes(&self) -> &[u8] { let accels = self.accels.as_ref(); // SAFETY: This is safe because accels is a just a slice of AccelTy, // and u8 always has a smaller alignment. unsafe { core::slice::from_raw_parts( accels.as_ptr().cast::(), accels.len() * ACCEL_TY_SIZE, ) } } /// Returns the memory usage, in bytes, of these accelerators. /// /// The memory usage is computed based on the number of bytes used to /// represent all of the accelerators. /// /// This does **not** include the stack size used by this value. pub fn memory_usage(&self) -> usize { self.as_bytes().len() } /// Return the bytes to search for corresponding to the accelerator in this /// sequence at index `i`. If no such accelerator exists, then this panics. /// /// The significance of the index is that it should be in correspondence /// with the index of the corresponding DFA. That is, accelerated DFA /// states are stored contiguously in the DFA and have an ordering implied /// by their respective state IDs. The state's index in that sequence /// corresponds to the index of its corresponding accelerator. #[cfg_attr(feature = "perf-inline", inline(always))] pub fn needles(&self, i: usize) -> &[u8] { if i >= self.len() { panic!("invalid accelerator index {}", i); } let bytes = self.as_bytes(); let offset = ACCEL_TY_SIZE + i * ACCEL_CAP; let len = usize::from(bytes[offset]); &bytes[offset + 1..offset + 1 + len] } /// Return the total number of accelerators in this sequence. pub fn len(&self) -> usize { // This should never panic since deserialization checks that the // length can fit into a usize. usize::try_from(self.accels.as_ref()[0]).unwrap() } /// Return the accelerator in this sequence at index `i`. If no such /// accelerator exists, then this returns None. /// /// See the docs for `needles` on the significance of the index. fn get(&self, i: usize) -> Option { if i >= self.len() { return None; } let offset = ACCEL_TY_SIZE + i * ACCEL_CAP; let accel = Accel::from_slice(&self.as_bytes()[offset..]) .expect("Accels must contain valid accelerators"); Some(accel) } /// Returns an iterator of accelerators in this sequence. fn iter(&self) -> IterAccels<'_, A> { IterAccels { accels: self, i: 0 } } /// Writes these accelerators to the given byte buffer using the indicated /// endianness. If the given buffer is too small, then an error is /// returned. Upon success, the total number of bytes written is returned. /// The number of bytes written is guaranteed to be a multiple of 8. pub fn write_to( &self, dst: &mut [u8], ) -> Result { let nwrite = self.write_to_len(); assert_eq!( nwrite % ACCEL_TY_SIZE, 0, "expected accelerator bytes written to be a multiple of {}", ACCEL_TY_SIZE, ); if dst.len() < nwrite { return Err(SerializeError::buffer_too_small("accelerators")); } // The number of accelerators can never exceed AccelTy::MAX. E::write_u32(AccelTy::try_from(self.len()).unwrap(), dst); // The actual accelerators are just raw bytes and thus their endianness // is irrelevant. So we can copy them as bytes. dst[ACCEL_TY_SIZE..nwrite] .copy_from_slice(&self.as_bytes()[ACCEL_TY_SIZE..nwrite]); Ok(nwrite) } /// Validates that every accelerator in this collection can be successfully /// deserialized as a valid accelerator. pub fn validate(&self) -> Result<(), DeserializeError> { for chunk in self.as_bytes()[ACCEL_TY_SIZE..].chunks(ACCEL_CAP) { let _ = Accel::from_slice(chunk)?; } Ok(()) } /// Returns the total number of bytes written by `write_to`. pub fn write_to_len(&self) -> usize { self.as_bytes().len() } } impl> core::fmt::Debug for Accels { fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { write!(f, "Accels(")?; let mut list = f.debug_list(); for a in self.iter() { list.entry(&a); } list.finish()?; write!(f, ")") } } #[derive(Debug)] struct IterAccels<'a, A: AsRef<[AccelTy]>> { accels: &'a Accels, i: usize, } impl<'a, A: AsRef<[AccelTy]>> Iterator for IterAccels<'a, A> { type Item = Accel; fn next(&mut self) -> Option { let accel = self.accels.get(self.i)?; self.i += 1; Some(accel) } } /// Accel represents a structure for determining how to "accelerate" a DFA /// state. /// /// Namely, it contains zero or more bytes that must be seen in order for the /// DFA to leave the state it is associated with. In practice, the actual range /// is 1 to 3 bytes. /// /// The purpose of acceleration is to identify states whose vast majority /// of transitions are just loops back to the same state. For example, /// in the regex `(?-u)^[^a]+b`, the corresponding DFA will have a state /// (corresponding to `[^a]+`) where all transitions *except* for `a` and /// `b` loop back to itself. Thus, this state can be "accelerated" by simply /// looking for the next occurrence of either `a` or `b` instead of explicitly /// following transitions. (In this case, `b` transitions to the next state /// where as `a` would transition to the dead state.) #[derive(Clone)] pub(crate) struct Accel { /// The first byte is the length. Subsequent bytes are the accelerated /// bytes. /// /// Note that we make every accelerator 8 bytes as a slightly wasteful /// way of making sure alignment is always correct for state ID sizes of /// 1, 2, 4 and 8. This should be okay since accelerated states aren't /// particularly common, especially when Unicode is enabled. bytes: [u8; ACCEL_CAP], } impl Accel { /// Returns an empty accel, where no bytes are accelerated. #[cfg(feature = "dfa-build")] pub fn new() -> Accel { Accel { bytes: [0; ACCEL_CAP] } } /// Returns a verified accelerator derived from the beginning of the given /// slice. /// /// If the slice is not long enough or contains invalid bytes for an /// accelerator, then this returns an error. pub fn from_slice(mut slice: &[u8]) -> Result { slice = &slice[..core::cmp::min(ACCEL_LEN, slice.len())]; let bytes = slice .try_into() .map_err(|_| DeserializeError::buffer_too_small("accelerator"))?; Accel::from_bytes(bytes) } /// Returns a verified accelerator derived from raw bytes. /// /// If the given bytes are invalid, then this returns an error. fn from_bytes(bytes: [u8; 4]) -> Result { if usize::from(bytes[0]) >= ACCEL_LEN { return Err(DeserializeError::generic( "accelerator bytes cannot have length more than 3", )); } Ok(Accel::from_bytes_unchecked(bytes)) } /// Returns an accelerator derived from raw bytes. /// /// This does not check whether the given bytes are valid. Invalid bytes /// cannot sacrifice memory safety, but may result in panics or silent /// logic bugs. fn from_bytes_unchecked(bytes: [u8; 4]) -> Accel { Accel { bytes: [bytes[0], bytes[1], bytes[2], bytes[3], 0, 0, 0, 0] } } /// Attempts to add the given byte to this accelerator. If the accelerator /// is already full or thinks the byte is a poor accelerator, then this /// returns false. Otherwise, returns true. /// /// If the given byte is already in this accelerator, then it panics. #[cfg(feature = "dfa-build")] pub fn add(&mut self, byte: u8) -> bool { if self.len() >= 3 { return false; } // As a special case, we totally reject trying to accelerate a state // with an ASCII space. In most cases, it occurs very frequently, and // tends to result in worse overall performance. if byte == b' ' { return false; } assert!( !self.contains(byte), "accelerator already contains {:?}", crate::util::escape::DebugByte(byte) ); self.bytes[self.len() + 1] = byte; self.bytes[0] += 1; true } /// Return the number of bytes in this accelerator. pub fn len(&self) -> usize { usize::from(self.bytes[0]) } /// Returns true if and only if there are no bytes in this accelerator. #[cfg(feature = "dfa-build")] pub fn is_empty(&self) -> bool { self.len() == 0 } /// Returns the slice of bytes to accelerate. /// /// If this accelerator is empty, then this returns an empty slice. fn needles(&self) -> &[u8] { &self.bytes[1..1 + self.len()] } /// Returns true if and only if this accelerator will accelerate the given /// byte. #[cfg(feature = "dfa-build")] fn contains(&self, byte: u8) -> bool { self.needles().iter().position(|&b| b == byte).is_some() } /// Returns the accelerator bytes as an array of AccelTys. #[cfg(feature = "dfa-build")] fn as_accel_tys(&self) -> [AccelTy; 2] { assert_eq!(ACCEL_CAP, 8); // These unwraps are OK since ACCEL_CAP is set to 8. let first = AccelTy::from_ne_bytes(self.bytes[0..4].try_into().unwrap()); let second = AccelTy::from_ne_bytes(self.bytes[4..8].try_into().unwrap()); [first, second] } } impl core::fmt::Debug for Accel { fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { write!(f, "Accel(")?; let mut set = f.debug_set(); for &b in self.needles() { set.entry(&crate::util::escape::DebugByte(b)); } set.finish()?; write!(f, ")") } }