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android / toolchain / rustc / 54272acac043c1dedfb7db7420545b31ec1ac51f / . / compiler / rustc_middle / src / mir / interpret / allocation.rs
blob: bbf792edcded9ee27cade96ed363776996ec9cb3 [file] [log] [blame]
//! The virtual memory representation of the MIR interpreter.
use std::borrow::Cow;
use std::convert::TryFrom;
use std::iter;
use std::ops::{Deref, Range};
use std::ptr;
use rustc_ast::Mutability;
use rustc_data_structures::sorted_map::SortedMap;
use rustc_span::DUMMY_SP;
use rustc_target::abi::{Align, HasDataLayout, Size};
use super::{
read_target_uint, write_target_uint, AllocId, InterpError, InterpResult, Pointer,
ResourceExhaustionInfo, Scalar, ScalarMaybeUninit, UndefinedBehaviorInfo, UninitBytesAccess,
UnsupportedOpInfo,
};
use crate::ty;
/// This type represents an Allocation in the Miri/CTFE core engine.
///
/// Its public API is rather low-level, working directly with allocation offsets and a custom error
/// type to account for the lack of an AllocId on this level. The Miri/CTFE core engine `memory`
/// module provides higher-level access.
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Hash, TyEncodable, TyDecodable)]
#[derive(HashStable)]
pub struct Allocation<Tag = AllocId, Extra = ()> {
/// The actual bytes of the allocation.
/// Note that the bytes of a pointer represent the offset of the pointer.
bytes: Vec<u8>,
/// Maps from byte addresses to extra data for each pointer.
/// Only the first byte of a pointer is inserted into the map; i.e.,
/// every entry in this map applies to `pointer_size` consecutive bytes starting
/// at the given offset.
relocations: Relocations<Tag>,
/// Denotes which part of this allocation is initialized.
init_mask: InitMask,
/// The alignment of the allocation to detect unaligned reads.
/// (`Align` guarantees that this is a power of two.)
pub align: Align,
/// `true` if the allocation is mutable.
/// Also used by codegen to determine if a static should be put into mutable memory,
/// which happens for `static mut` and `static` with interior mutability.
pub mutability: Mutability,
/// Extra state for the machine.
pub extra: Extra,
}
/// We have our own error type that does not know about the `AllocId`; that information
/// is added when converting to `InterpError`.
#[derive(Debug)]
pub enum AllocError {
/// Encountered a pointer where we needed raw bytes.
ReadPointerAsBytes,
/// Using uninitialized data where it is not allowed.
InvalidUninitBytes(Option<UninitBytesAccess>),
}
pub type AllocResult<T = ()> = Result<T, AllocError>;
impl AllocError {
pub fn to_interp_error<'tcx>(self, alloc_id: AllocId) -> InterpError<'tcx> {
match self {
AllocError::ReadPointerAsBytes => {
InterpError::Unsupported(UnsupportedOpInfo::ReadPointerAsBytes)
}
AllocError::InvalidUninitBytes(info) => InterpError::UndefinedBehavior(
UndefinedBehaviorInfo::InvalidUninitBytes(info.map(|b| (alloc_id, b))),
),
}
}
}
/// The information that makes up a memory access: offset and size.
#[derive(Copy, Clone, Debug)]
pub struct AllocRange {
pub start: Size,
pub size: Size,
}
/// Free-starting constructor for less syntactic overhead.
#[inline(always)]
pub fn alloc_range(start: Size, size: Size) -> AllocRange {
AllocRange { start, size }
}
impl AllocRange {
#[inline(always)]
pub fn end(self) -> Size {
self.start + self.size // This does overflow checking.
}
/// Returns the `subrange` within this range; panics if it is not a subrange.
#[inline]
pub fn subrange(self, subrange: AllocRange) -> AllocRange {
let sub_start = self.start + subrange.start;
let range = alloc_range(sub_start, subrange.size);
assert!(range.end() <= self.end(), "access outside the bounds for given AllocRange");
range
}
}
// The constructors are all without extra; the extra gets added by a machine hook later.
impl<Tag> Allocation<Tag> {
/// Creates an allocation initialized by the given bytes
pub fn from_bytes<'a>(
slice: impl Into<Cow<'a, [u8]>>,
align: Align,
mutability: Mutability,
) -> Self {
let bytes = slice.into().into_owned();
let size = Size::from_bytes(bytes.len());
Self {
bytes,
relocations: Relocations::new(),
init_mask: InitMask::new(size, true),
align,
mutability,
extra: (),
}
}
pub fn from_bytes_byte_aligned_immutable<'a>(slice: impl Into<Cow<'a, [u8]>>) -> Self {
Allocation::from_bytes(slice, Align::ONE, Mutability::Not)
}
/// Try to create an Allocation of `size` bytes, failing if there is not enough memory
/// available to the compiler to do so.
pub fn uninit(size: Size, align: Align, panic_on_fail: bool) -> InterpResult<'static, Self> {
let mut bytes = Vec::new();
bytes.try_reserve(size.bytes_usize()).map_err(|_| {
// This results in an error that can happen non-deterministically, since the memory
// available to the compiler can change between runs. Normally queries are always
// deterministic. However, we can be non-determinstic here because all uses of const
// evaluation (including ConstProp!) will make compilation fail (via hard error
// or ICE) upon encountering a `MemoryExhausted` error.
if panic_on_fail {
panic!("Allocation::uninit called with panic_on_fail had allocation failure")
}
ty::tls::with(|tcx| {
tcx.sess.delay_span_bug(DUMMY_SP, "exhausted memory during interpreation")
});
InterpError::ResourceExhaustion(ResourceExhaustionInfo::MemoryExhausted)
})?;
bytes.resize(size.bytes_usize(), 0);
Ok(Allocation {
bytes,
relocations: Relocations::new(),
init_mask: InitMask::new(size, false),
align,
mutability: Mutability::Mut,
extra: (),
})
}
}
impl Allocation {
/// Convert Tag and add Extra fields
pub fn convert_tag_add_extra<Tag, Extra>(
self,
cx: &impl HasDataLayout,
extra: Extra,
mut tagger: impl FnMut(Pointer<AllocId>) -> Pointer<Tag>,
) -> Allocation<Tag, Extra> {
// Compute new pointer tags, which also adjusts the bytes.
let mut bytes = self.bytes;
let mut new_relocations = Vec::with_capacity(self.relocations.0.len());
let ptr_size = cx.data_layout().pointer_size.bytes_usize();
let endian = cx.data_layout().endian;
for &(offset, alloc_id) in self.relocations.iter() {
let idx = offset.bytes_usize();
let ptr_bytes = &mut bytes[idx..idx + ptr_size];
let bits = read_target_uint(endian, ptr_bytes).unwrap();
let (ptr_tag, ptr_offset) =
tagger(Pointer::new(alloc_id, Size::from_bytes(bits))).into_parts();
write_target_uint(endian, ptr_bytes, ptr_offset.bytes().into()).unwrap();
new_relocations.push((offset, ptr_tag));
}
// Create allocation.
Allocation {
bytes,
relocations: Relocations::from_presorted(new_relocations),
init_mask: self.init_mask,
align: self.align,
mutability: self.mutability,
extra,
}
}
}
/// Raw accessors. Provide access to otherwise private bytes.
impl<Tag, Extra> Allocation<Tag, Extra> {
pub fn len(&self) -> usize {
self.bytes.len()
}
pub fn size(&self) -> Size {
Size::from_bytes(self.len())
}
/// Looks at a slice which may describe uninitialized bytes or describe a relocation. This differs
/// from `get_bytes_with_uninit_and_ptr` in that it does no relocation checks (even on the
/// edges) at all.
/// This must not be used for reads affecting the interpreter execution.
pub fn inspect_with_uninit_and_ptr_outside_interpreter(&self, range: Range<usize>) -> &[u8] {
&self.bytes[range]
}
/// Returns the mask indicating which bytes are initialized.
pub fn init_mask(&self) -> &InitMask {
&self.init_mask
}
/// Returns the relocation list.
pub fn relocations(&self) -> &Relocations<Tag> {
&self.relocations
}
}
/// Byte accessors.
impl<Tag: Copy, Extra> Allocation<Tag, Extra> {
/// The last argument controls whether we error out when there are uninitialized
/// or pointer bytes. You should never call this, call `get_bytes` or
/// `get_bytes_with_uninit_and_ptr` instead,
///
/// This function also guarantees that the resulting pointer will remain stable
/// even when new allocations are pushed to the `HashMap`. `copy_repeatedly` relies
/// on that.
///
/// It is the caller's responsibility to check bounds and alignment beforehand.
fn get_bytes_internal(
&self,
cx: &impl HasDataLayout,
range: AllocRange,
check_init_and_ptr: bool,
) -> AllocResult<&[u8]> {
if check_init_and_ptr {
self.check_init(range)?;
self.check_relocations(cx, range)?;
} else {
// We still don't want relocations on the *edges*.
self.check_relocation_edges(cx, range)?;
}
Ok(&self.bytes[range.start.bytes_usize()..range.end().bytes_usize()])
}
/// Checks that these bytes are initialized and not pointer bytes, and then return them
/// as a slice.
///
/// It is the caller's responsibility to check bounds and alignment beforehand.
/// Most likely, you want to use the `PlaceTy` and `OperandTy`-based methods
/// on `InterpCx` instead.
#[inline]
pub fn get_bytes(&self, cx: &impl HasDataLayout, range: AllocRange) -> AllocResult<&[u8]> {
self.get_bytes_internal(cx, range, true)
}
/// It is the caller's responsibility to handle uninitialized and pointer bytes.
/// However, this still checks that there are no relocations on the *edges*.
///
/// It is the caller's responsibility to check bounds and alignment beforehand.
#[inline]
pub fn get_bytes_with_uninit_and_ptr(
&self,
cx: &impl HasDataLayout,
range: AllocRange,
) -> AllocResult<&[u8]> {
self.get_bytes_internal(cx, range, false)
}
/// Just calling this already marks everything as defined and removes relocations,
/// so be sure to actually put data there!
///
/// It is the caller's responsibility to check bounds and alignment beforehand.
/// Most likely, you want to use the `PlaceTy` and `OperandTy`-based methods
/// on `InterpCx` instead.
pub fn get_bytes_mut(&mut self, cx: &impl HasDataLayout, range: AllocRange) -> &mut [u8] {
self.mark_init(range, true);
self.clear_relocations(cx, range);
&mut self.bytes[range.start.bytes_usize()..range.end().bytes_usize()]
}
/// A raw pointer variant of `get_bytes_mut` that avoids invalidating existing aliases into this memory.
pub fn get_bytes_mut_ptr(&mut self, cx: &impl HasDataLayout, range: AllocRange) -> *mut [u8] {
self.mark_init(range, true);
// This also clears relocations that just overlap with the written range. So writing to some
// byte can de-initialize its neighbors! See
// <https://github.com/rust-lang/rust/issues/87184> for details.
self.clear_relocations(cx, range);
assert!(range.end().bytes_usize() <= self.bytes.len()); // need to do our own bounds-check
let begin_ptr = self.bytes.as_mut_ptr().wrapping_add(range.start.bytes_usize());
let len = range.end().bytes_usize() - range.start.bytes_usize();
ptr::slice_from_raw_parts_mut(begin_ptr, len)
}
}
/// Reading and writing.
impl<Tag: Copy, Extra> Allocation<Tag, Extra> {
/// Validates that `ptr.offset` and `ptr.offset + size` do not point to the middle of a
/// relocation. If `allow_uninit_and_ptr` is `false`, also enforces that the memory in the
/// given range contains neither relocations nor uninitialized bytes.
pub fn check_bytes(
&self,
cx: &impl HasDataLayout,
range: AllocRange,
allow_uninit_and_ptr: bool,
) -> AllocResult {
// Check bounds and relocations on the edges.
self.get_bytes_with_uninit_and_ptr(cx, range)?;
// Check uninit and ptr.
if !allow_uninit_and_ptr {
self.check_init(range)?;
self.check_relocations(cx, range)?;
}
Ok(())
}
/// Reads a *non-ZST* scalar.
///
/// ZSTs can't be read because in order to obtain a `Pointer`, we need to check
/// for ZSTness anyway due to integer pointers being valid for ZSTs.
///
/// It is the caller's responsibility to check bounds and alignment beforehand.
/// Most likely, you want to call `InterpCx::read_scalar` instead of this method.
pub fn read_scalar(
&self,
cx: &impl HasDataLayout,
range: AllocRange,
) -> AllocResult<ScalarMaybeUninit<Tag>> {
// `get_bytes_with_uninit_and_ptr` tests relocation edges.
// We deliberately error when loading data that partially has provenance, or partially
// initialized data (that's the check below), into a scalar. The LLVM semantics of this are
// unclear so we are conservative. See <https://github.com/rust-lang/rust/issues/69488> for
// further discussion.
let bytes = self.get_bytes_with_uninit_and_ptr(cx, range)?;
// Uninit check happens *after* we established that the alignment is correct.
// We must not return `Ok()` for unaligned pointers!
if self.is_init(range).is_err() {
// This inflates uninitialized bytes to the entire scalar, even if only a few
// bytes are uninitialized.
return Ok(ScalarMaybeUninit::Uninit);
}
// Now we do the actual reading.
let bits = read_target_uint(cx.data_layout().endian, bytes).unwrap();
// See if we got a pointer.
if range.size != cx.data_layout().pointer_size {
// Not a pointer.
// *Now*, we better make sure that the inside is free of relocations too.
self.check_relocations(cx, range)?;
} else {
// Maybe a pointer.
if let Some(&prov) = self.relocations.get(&range.start) {
let ptr = Pointer::new(prov, Size::from_bytes(bits));
return Ok(ScalarMaybeUninit::from_pointer(ptr, cx));
}
}
// We don't. Just return the bits.
Ok(ScalarMaybeUninit::Scalar(Scalar::from_uint(bits, range.size)))
}
/// Writes a *non-ZST* scalar.
///
/// ZSTs can't be read because in order to obtain a `Pointer`, we need to check
/// for ZSTness anyway due to integer pointers being valid for ZSTs.
///
/// It is the caller's responsibility to check bounds and alignment beforehand.
/// Most likely, you want to call `InterpCx::write_scalar` instead of this method.
pub fn write_scalar(
&mut self,
cx: &impl HasDataLayout,
range: AllocRange,
val: ScalarMaybeUninit<Tag>,
) -> AllocResult {
assert!(self.mutability == Mutability::Mut);
let val = match val {
ScalarMaybeUninit::Scalar(scalar) => scalar,
ScalarMaybeUninit::Uninit => {
self.mark_init(range, false);
return Ok(());
}
};
// `to_bits_or_ptr_internal` is the right method because we just want to store this data
// as-is into memory.
let (bytes, provenance) = match val.to_bits_or_ptr_internal(range.size) {
Err(val) => {
let (provenance, offset) = val.into_parts();
(u128::from(offset.bytes()), Some(provenance))
}
Ok(data) => (data, None),
};
let endian = cx.data_layout().endian;
let dst = self.get_bytes_mut(cx, range);
write_target_uint(endian, dst, bytes).unwrap();
// See if we have to also write a relocation.
if let Some(provenance) = provenance {
self.relocations.0.insert(range.start, provenance);
}
Ok(())
}
}
/// Relocations.
impl<Tag: Copy, Extra> Allocation<Tag, Extra> {
/// Returns all relocations overlapping with the given pointer-offset pair.
pub fn get_relocations(&self, cx: &impl HasDataLayout, range: AllocRange) -> &[(Size, Tag)] {
// We have to go back `pointer_size - 1` bytes, as that one would still overlap with
// the beginning of this range.
let start = range.start.bytes().saturating_sub(cx.data_layout().pointer_size.bytes() - 1);
self.relocations.range(Size::from_bytes(start)..range.end())
}
/// Checks that there are no relocations overlapping with the given range.
#[inline(always)]
fn check_relocations(&self, cx: &impl HasDataLayout, range: AllocRange) -> AllocResult {
if self.get_relocations(cx, range).is_empty() {
Ok(())
} else {
Err(AllocError::ReadPointerAsBytes)
}
}
/// Removes all relocations inside the given range.
/// If there are relocations overlapping with the edges, they
/// are removed as well *and* the bytes they cover are marked as
/// uninitialized. This is a somewhat odd "spooky action at a distance",
/// but it allows strictly more code to run than if we would just error
/// immediately in that case.
fn clear_relocations(&mut self, cx: &impl HasDataLayout, range: AllocRange) {
// Find the start and end of the given range and its outermost relocations.
let (first, last) = {
// Find all relocations overlapping the given range.
let relocations = self.get_relocations(cx, range);
if relocations.is_empty() {
return;
}
(
relocations.first().unwrap().0,
relocations.last().unwrap().0 + cx.data_layout().pointer_size,
)
};
let start = range.start;
let end = range.end();
// Mark parts of the outermost relocations as uninitialized if they partially fall outside the
// given range.
if first < start {
self.init_mask.set_range(first, start, false);
}
if last > end {
self.init_mask.set_range(end, last, false);
}
// Forget all the relocations.
self.relocations.0.remove_range(first..last);
}
/// Errors if there are relocations overlapping with the edges of the
/// given memory range.
#[inline]
fn check_relocation_edges(&self, cx: &impl HasDataLayout, range: AllocRange) -> AllocResult {
self.check_relocations(cx, alloc_range(range.start, Size::ZERO))?;
self.check_relocations(cx, alloc_range(range.end(), Size::ZERO))?;
Ok(())
}
}
/// Uninitialized bytes.
impl<Tag: Copy, Extra> Allocation<Tag, Extra> {
/// Checks whether the given range is entirely initialized.
///
/// Returns `Ok(())` if it's initialized. Otherwise returns the range of byte
/// indexes of the first contiguous uninitialized access.
fn is_init(&self, range: AllocRange) -> Result<(), Range<Size>> {
self.init_mask.is_range_initialized(range.start, range.end()) // `Size` addition
}
/// Checks that a range of bytes is initialized. If not, returns the `InvalidUninitBytes`
/// error which will report the first range of bytes which is uninitialized.
fn check_init(&self, range: AllocRange) -> AllocResult {
self.is_init(range).or_else(|idx_range| {
Err(AllocError::InvalidUninitBytes(Some(UninitBytesAccess {
access_offset: range.start,
access_size: range.size,
uninit_offset: idx_range.start,
uninit_size: idx_range.end - idx_range.start, // `Size` subtraction
})))
})
}
pub fn mark_init(&mut self, range: AllocRange, is_init: bool) {
if range.size.bytes() == 0 {
return;
}
assert!(self.mutability == Mutability::Mut);
self.init_mask.set_range(range.start, range.end(), is_init);
}
}
/// Run-length encoding of the uninit mask.
/// Used to copy parts of a mask multiple times to another allocation.
pub struct InitMaskCompressed {
/// Whether the first range is initialized.
initial: bool,
/// The lengths of ranges that are run-length encoded.
/// The initialization state of the ranges alternate starting with `initial`.
ranges: smallvec::SmallVec<[u64; 1]>,
}
impl InitMaskCompressed {
pub fn no_bytes_init(&self) -> bool {
// The `ranges` are run-length encoded and of alternating initialization state.
// So if `ranges.len() > 1` then the second block is an initialized range.
!self.initial && self.ranges.len() == 1
}
}
/// Transferring the initialization mask to other allocations.
impl<Tag, Extra> Allocation<Tag, Extra> {
/// Creates a run-length encoding of the initialization mask.
pub fn compress_uninit_range(&self, range: AllocRange) -> InitMaskCompressed {
// Since we are copying `size` bytes from `src` to `dest + i * size` (`for i in 0..repeat`),
// a naive initialization mask copying algorithm would repeatedly have to read the initialization mask from
// the source and write it to the destination. Even if we optimized the memory accesses,
// we'd be doing all of this `repeat` times.
// Therefore we precompute a compressed version of the initialization mask of the source value and
// then write it back `repeat` times without computing any more information from the source.
// A precomputed cache for ranges of initialized / uninitialized bits
// 0000010010001110 will become
// `[5, 1, 2, 1, 3, 3, 1]`,
// where each element toggles the state.
let mut ranges = smallvec::SmallVec::<[u64; 1]>::new();
let initial = self.init_mask.get(range.start);
let mut cur_len = 1;
let mut cur = initial;
for i in 1..range.size.bytes() {
// FIXME: optimize to bitshift the current uninitialized block's bits and read the top bit.
if self.init_mask.get(range.start + Size::from_bytes(i)) == cur {
cur_len += 1;
} else {
ranges.push(cur_len);
cur_len = 1;
cur = !cur;
}
}
ranges.push(cur_len);
InitMaskCompressed { ranges, initial }
}
/// Applies multiple instances of the run-length encoding to the initialization mask.
pub fn mark_compressed_init_range(
&mut self,
defined: &InitMaskCompressed,
range: AllocRange,
repeat: u64,
) {
// An optimization where we can just overwrite an entire range of initialization
// bits if they are going to be uniformly `1` or `0`.
if defined.ranges.len() <= 1 {
self.init_mask.set_range_inbounds(
range.start,
range.start + range.size * repeat, // `Size` operations
defined.initial,
);
return;
}
for mut j in 0..repeat {
j *= range.size.bytes();
j += range.start.bytes();
let mut cur = defined.initial;
for range in &defined.ranges {
let old_j = j;
j += range;
self.init_mask.set_range_inbounds(
Size::from_bytes(old_j),
Size::from_bytes(j),
cur,
);
cur = !cur;
}
}
}
}
/// "Relocations" stores the provenance information of pointers stored in memory.
#[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Hash, Debug, TyEncodable, TyDecodable)]
pub struct Relocations<Tag = AllocId>(SortedMap<Size, Tag>);
impl<Tag> Relocations<Tag> {
pub fn new() -> Self {
Relocations(SortedMap::new())
}
// The caller must guarantee that the given relocations are already sorted
// by address and contain no duplicates.
pub fn from_presorted(r: Vec<(Size, Tag)>) -> Self {
Relocations(SortedMap::from_presorted_elements(r))
}
}
impl<Tag> Deref for Relocations<Tag> {
type Target = SortedMap<Size, Tag>;
fn deref(&self) -> &Self::Target {
&self.0
}
}
/// A partial, owned list of relocations to transfer into another allocation.
pub struct AllocationRelocations<Tag> {
relative_relocations: Vec<(Size, Tag)>,
}
impl<Tag: Copy, Extra> Allocation<Tag, Extra> {
pub fn prepare_relocation_copy(
&self,
cx: &impl HasDataLayout,
src: AllocRange,
dest: Size,
count: u64,
) -> AllocationRelocations<Tag> {
let relocations = self.get_relocations(cx, src);
if relocations.is_empty() {
return AllocationRelocations { relative_relocations: Vec::new() };
}
let size = src.size;
let mut new_relocations = Vec::with_capacity(relocations.len() * (count as usize));
for i in 0..count {
new_relocations.extend(relocations.iter().map(|&(offset, reloc)| {
// compute offset for current repetition
let dest_offset = dest + size * i; // `Size` operations
(
// shift offsets from source allocation to destination allocation
(offset + dest_offset) - src.start, // `Size` operations
reloc,
)
}));
}
AllocationRelocations { relative_relocations: new_relocations }
}
/// Applies a relocation copy.
/// The affected range, as defined in the parameters to `prepare_relocation_copy` is expected
/// to be clear of relocations.
pub fn mark_relocation_range(&mut self, relocations: AllocationRelocations<Tag>) {
self.relocations.0.insert_presorted(relocations.relative_relocations);
}
}
////////////////////////////////////////////////////////////////////////////////
// Uninitialized byte tracking
////////////////////////////////////////////////////////////////////////////////
type Block = u64;
/// A bitmask where each bit refers to the byte with the same index. If the bit is `true`, the byte
/// is initialized. If it is `false` the byte is uninitialized.
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Hash, TyEncodable, TyDecodable)]
#[derive(HashStable)]
pub struct InitMask {
blocks: Vec<Block>,
len: Size,
}
impl InitMask {
pub const BLOCK_SIZE: u64 = 64;
pub fn new(size: Size, state: bool) -> Self {
let mut m = InitMask { blocks: vec![], len: Size::ZERO };
m.grow(size, state);
m
}
/// Checks whether the range `start..end` (end-exclusive) is entirely initialized.
///
/// Returns `Ok(())` if it's initialized. Otherwise returns a range of byte
/// indexes for the first contiguous span of the uninitialized access.
#[inline]
pub fn is_range_initialized(&self, start: Size, end: Size) -> Result<(), Range<Size>> {
if end > self.len {
return Err(self.len..end);
}
// FIXME(oli-obk): optimize this for allocations larger than a block.
let idx = (start.bytes()..end.bytes()).map(Size::from_bytes).find(|&i| !self.get(i));
match idx {
Some(idx) => {
let uninit_end = (idx.bytes()..end.bytes())
.map(Size::from_bytes)
.find(|&i| self.get(i))
.unwrap_or(end);
Err(idx..uninit_end)
}
None => Ok(()),
}
}
pub fn set_range(&mut self, start: Size, end: Size, new_state: bool) {
let len = self.len;
if end > len {
self.grow(end - len, new_state);
}
self.set_range_inbounds(start, end, new_state);
}
pub fn set_range_inbounds(&mut self, start: Size, end: Size, new_state: bool) {
let (blocka, bita) = bit_index(start);
let (blockb, bitb) = bit_index(end);
if blocka == blockb {
// First set all bits except the first `bita`,
// then unset the last `64 - bitb` bits.
let range = if bitb == 0 {
u64::MAX << bita
} else {
(u64::MAX << bita) & (u64::MAX >> (64 - bitb))
};
if new_state {
self.blocks[blocka] |= range;
} else {
self.blocks[blocka] &= !range;
}
return;
}
// across block boundaries
if new_state {
// Set `bita..64` to `1`.
self.blocks[blocka] |= u64::MAX << bita;
// Set `0..bitb` to `1`.
if bitb != 0 {
self.blocks[blockb] |= u64::MAX >> (64 - bitb);
}
// Fill in all the other blocks (much faster than one bit at a time).
for block in (blocka + 1)..blockb {
self.blocks[block] = u64::MAX;
}
} else {
// Set `bita..64` to `0`.
self.blocks[blocka] &= !(u64::MAX << bita);
// Set `0..bitb` to `0`.
if bitb != 0 {
self.blocks[blockb] &= !(u64::MAX >> (64 - bitb));
}
// Fill in all the other blocks (much faster than one bit at a time).
for block in (blocka + 1)..blockb {
self.blocks[block] = 0;
}
}
}
#[inline]
pub fn get(&self, i: Size) -> bool {
let (block, bit) = bit_index(i);
(self.blocks[block] & (1 << bit)) != 0
}
#[inline]
pub fn set(&mut self, i: Size, new_state: bool) {
let (block, bit) = bit_index(i);
self.set_bit(block, bit, new_state);
}
#[inline]
fn set_bit(&mut self, block: usize, bit: usize, new_state: bool) {
if new_state {
self.blocks[block] |= 1 << bit;
} else {
self.blocks[block] &= !(1 << bit);
}
}
pub fn grow(&mut self, amount: Size, new_state: bool) {
if amount.bytes() == 0 {
return;
}
let unused_trailing_bits =
u64::try_from(self.blocks.len()).unwrap() * Self::BLOCK_SIZE - self.len.bytes();
if amount.bytes() > unused_trailing_bits {
let additional_blocks = amount.bytes() / Self::BLOCK_SIZE + 1;
self.blocks.extend(
// FIXME(oli-obk): optimize this by repeating `new_state as Block`.
iter::repeat(0).take(usize::try_from(additional_blocks).unwrap()),
);
}
let start = self.len;
self.len += amount;
self.set_range_inbounds(start, start + amount, new_state); // `Size` operation
}
}
#[inline]
fn bit_index(bits: Size) -> (usize, usize) {
let bits = bits.bytes();
let a = bits / InitMask::BLOCK_SIZE;
let b = bits % InitMask::BLOCK_SIZE;
(usize::try_from(a).unwrap(), usize::try_from(b).unwrap())
}