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//! Store the provenance for each byte in the range, with a more efficient
//! representation for the common case where PTR_SIZE consecutive bytes have the same provenance.
use std::cmp;
use rustc_data_structures::sorted_map::SortedMap;
use rustc_target::abi::{HasDataLayout, Size};
use super::{alloc_range, AllocError, AllocRange, AllocResult, CtfeProvenance, Provenance};
use rustc_serialize::{Decodable, Decoder, Encodable, Encoder};
/// Stores the provenance information of pointers stored in memory.
#[derive(Clone, PartialEq, Eq, Hash, Debug)]
#[derive(HashStable)]
pub struct ProvenanceMap<Prov = CtfeProvenance> {
/// `Provenance` in this map applies from the given offset for an entire pointer-size worth of
/// bytes. Two entries in this map are always at least a pointer size apart.
ptrs: SortedMap<Size, Prov>,
/// Provenance in this map only applies to the given single byte.
/// This map is disjoint from the previous. It will always be empty when
/// `Prov::OFFSET_IS_ADDR` is false.
bytes: Option<Box<SortedMap<Size, Prov>>>,
}
// These impls are generic over `Prov` since `CtfeProvenance` is only decodable/encodable
// for some particular `D`/`S`.
impl<D: Decoder, Prov: Provenance + Decodable<D>> Decodable<D> for ProvenanceMap<Prov> {
fn decode(d: &mut D) -> Self {
assert!(!Prov::OFFSET_IS_ADDR); // only `CtfeProvenance` is ever serialized
Self { ptrs: Decodable::decode(d), bytes: None }
}
}
impl<S: Encoder, Prov: Provenance + Encodable<S>> Encodable<S> for ProvenanceMap<Prov> {
fn encode(&self, s: &mut S) {
let Self { ptrs, bytes } = self;
assert!(!Prov::OFFSET_IS_ADDR); // only `CtfeProvenance` is ever serialized
debug_assert!(bytes.is_none()); // without `OFFSET_IS_ADDR`, this is always empty
ptrs.encode(s)
}
}
impl<Prov> ProvenanceMap<Prov> {
pub fn new() -> Self {
ProvenanceMap { ptrs: SortedMap::new(), bytes: None }
}
/// The caller must guarantee that the given provenance list is already sorted
/// by address and contain no duplicates.
pub fn from_presorted_ptrs(r: Vec<(Size, Prov)>) -> Self {
ProvenanceMap { ptrs: SortedMap::from_presorted_elements(r), bytes: None }
}
}
impl ProvenanceMap {
/// Give access to the ptr-sized provenances (which can also be thought of as relocations, and
/// indeed that is how codegen treats them).
///
/// Only exposed with `CtfeProvenance` provenance, since it panics if there is bytewise provenance.
#[inline]
pub fn ptrs(&self) -> &SortedMap<Size, CtfeProvenance> {
debug_assert!(self.bytes.is_none()); // `CtfeProvenance::OFFSET_IS_ADDR` is false so this cannot fail
&self.ptrs
}
}
impl<Prov: Provenance> ProvenanceMap<Prov> {
/// Returns all ptr-sized provenance in the given range.
/// If the range has length 0, returns provenance that crosses the edge between `start-1` and
/// `start`.
pub(super) fn range_get_ptrs(
&self,
range: AllocRange,
cx: &impl HasDataLayout,
) -> &[(Size, Prov)] {
// We have to go back `pointer_size - 1` bytes, as that one would still overlap with
// the beginning of this range.
let adjusted_start = Size::from_bytes(
range.start.bytes().saturating_sub(cx.data_layout().pointer_size.bytes() - 1),
);
self.ptrs.range(adjusted_start..range.end())
}
/// Returns all byte-wise provenance in the given range.
fn range_get_bytes(&self, range: AllocRange) -> &[(Size, Prov)] {
if let Some(bytes) = self.bytes.as_ref() {
bytes.range(range.start..range.end())
} else {
&[]
}
}
/// Get the provenance of a single byte.
pub fn get(&self, offset: Size, cx: &impl HasDataLayout) -> Option<Prov> {
let prov = self.range_get_ptrs(alloc_range(offset, Size::from_bytes(1)), cx);
debug_assert!(prov.len() <= 1);
if let Some(entry) = prov.first() {
// If it overlaps with this byte, it is on this byte.
debug_assert!(self.bytes.as_ref().map_or(true, |b| b.get(&offset).is_none()));
Some(entry.1)
} else {
// Look up per-byte provenance.
self.bytes.as_ref().and_then(|b| b.get(&offset).copied())
}
}
/// Check if here is ptr-sized provenance at the given index.
/// Does not mean anything for bytewise provenance! But can be useful as an optimization.
pub fn get_ptr(&self, offset: Size) -> Option<Prov> {
self.ptrs.get(&offset).copied()
}
/// Returns whether this allocation has provenance overlapping with the given range.
///
/// Note: this function exists to allow `range_get_provenance` to be private, in order to somewhat
/// limit access to provenance outside of the `Allocation` abstraction.
///
pub fn range_empty(&self, range: AllocRange, cx: &impl HasDataLayout) -> bool {
self.range_get_ptrs(range, cx).is_empty() && self.range_get_bytes(range).is_empty()
}
/// Yields all the provenances stored in this map.
pub fn provenances(&self) -> impl Iterator<Item = Prov> + '_ {
let bytes = self.bytes.iter().flat_map(|b| b.values());
self.ptrs.values().chain(bytes).copied()
}
pub fn insert_ptr(&mut self, offset: Size, prov: Prov, cx: &impl HasDataLayout) {
debug_assert!(self.range_empty(alloc_range(offset, cx.data_layout().pointer_size), cx));
self.ptrs.insert(offset, prov);
}
/// Removes all provenance inside the given range.
/// If there is provenance overlapping with the edges, might result in an error.
pub fn clear(&mut self, range: AllocRange, cx: &impl HasDataLayout) -> AllocResult {
let start = range.start;
let end = range.end();
// Clear the bytewise part -- this is easy.
if Prov::OFFSET_IS_ADDR {
if let Some(bytes) = self.bytes.as_mut() {
bytes.remove_range(start..end);
}
} else {
debug_assert!(self.bytes.is_none());
}
// For the ptr-sized part, find the first (inclusive) and last (exclusive) byte of
// provenance that overlaps with the given range.
let (first, last) = {
// Find all provenance overlapping the given range.
let provenance = self.range_get_ptrs(range, cx);
if provenance.is_empty() {
// No provenance in this range, we are done.
return Ok(());
}
(
provenance.first().unwrap().0,
provenance.last().unwrap().0 + cx.data_layout().pointer_size,
)
};
// We need to handle clearing the provenance from parts of a pointer.
if first < start {
if !Prov::OFFSET_IS_ADDR {
// We can't split up the provenance into less than a pointer.
return Err(AllocError::OverwritePartialPointer(first));
}
// Insert the remaining part in the bytewise provenance.
let prov = self.ptrs[&first];
let bytes = self.bytes.get_or_insert_with(Box::default);
for offset in first..start {
bytes.insert(offset, prov);
}
}
if last > end {
let begin_of_last = last - cx.data_layout().pointer_size;
if !Prov::OFFSET_IS_ADDR {
// We can't split up the provenance into less than a pointer.
return Err(AllocError::OverwritePartialPointer(begin_of_last));
}
// Insert the remaining part in the bytewise provenance.
let prov = self.ptrs[&begin_of_last];
let bytes = self.bytes.get_or_insert_with(Box::default);
for offset in end..last {
bytes.insert(offset, prov);
}
}
// Forget all the provenance.
// Since provenance do not overlap, we know that removing until `last` (exclusive) is fine,
// i.e., this will not remove any other provenance just after the ones we care about.
self.ptrs.remove_range(first..last);
Ok(())
}
}
/// A partial, owned list of provenance to transfer into another allocation.
///
/// Offsets are already adjusted to the destination allocation.
pub struct ProvenanceCopy<Prov> {
dest_ptrs: Option<Box<[(Size, Prov)]>>,
dest_bytes: Option<Box<[(Size, Prov)]>>,
}
impl<Prov: Provenance> ProvenanceMap<Prov> {
pub fn prepare_copy(
&self,
src: AllocRange,
dest: Size,
count: u64,
cx: &impl HasDataLayout,
) -> AllocResult<ProvenanceCopy<Prov>> {
let shift_offset = move |idx, offset| {
// compute offset for current repetition
let dest_offset = dest + src.size * idx; // `Size` operations
// shift offsets from source allocation to destination allocation
(offset - src.start) + dest_offset // `Size` operations
};
let ptr_size = cx.data_layout().pointer_size;
// # Pointer-sized provenances
// Get the provenances that are entirely within this range.
// (Different from `range_get_ptrs` which asks if they overlap the range.)
// Only makes sense if we are copying at least one pointer worth of bytes.
let mut dest_ptrs_box = None;
if src.size >= ptr_size {
let adjusted_end = Size::from_bytes(src.end().bytes() - (ptr_size.bytes() - 1));
let ptrs = self.ptrs.range(src.start..adjusted_end);
// If `count` is large, this is rather wasteful -- we are allocating a big array here, which
// is mostly filled with redundant information since it's just N copies of the same `Prov`s
// at slightly adjusted offsets. The reason we do this is so that in `mark_provenance_range`
// we can use `insert_presorted`. That wouldn't work with an `Iterator` that just produces
// the right sequence of provenance for all N copies.
// Basically, this large array would have to be created anyway in the target allocation.
let mut dest_ptrs = Vec::with_capacity(ptrs.len() * (count as usize));
for i in 0..count {
dest_ptrs
.extend(ptrs.iter().map(|&(offset, reloc)| (shift_offset(i, offset), reloc)));
}
debug_assert_eq!(dest_ptrs.len(), dest_ptrs.capacity());
dest_ptrs_box = Some(dest_ptrs.into_boxed_slice());
};
// # Byte-sized provenances
// This includes the existing bytewise provenance in the range, and ptr provenance
// that overlaps with the begin/end of the range.
let mut dest_bytes_box = None;
let begin_overlap = self.range_get_ptrs(alloc_range(src.start, Size::ZERO), cx).first();
let end_overlap = self.range_get_ptrs(alloc_range(src.end(), Size::ZERO), cx).first();
if !Prov::OFFSET_IS_ADDR {
// There can't be any bytewise provenance, and we cannot split up the begin/end overlap.
if let Some(entry) = begin_overlap {
return Err(AllocError::ReadPartialPointer(entry.0));
}
if let Some(entry) = end_overlap {
return Err(AllocError::ReadPartialPointer(entry.0));
}
debug_assert!(self.bytes.is_none());
} else {
let mut bytes = Vec::new();
// First, if there is a part of a pointer at the start, add that.
if let Some(entry) = begin_overlap {
trace!("start overlapping entry: {entry:?}");
// For really small copies, make sure we don't run off the end of the `src` range.
let entry_end = cmp::min(entry.0 + ptr_size, src.end());
for offset in src.start..entry_end {
bytes.push((offset, entry.1));
}
} else {
trace!("no start overlapping entry");
}
// Then the main part, bytewise provenance from `self.bytes`.
if let Some(all_bytes) = self.bytes.as_ref() {
bytes.extend(all_bytes.range(src.start..src.end()));
}
// And finally possibly parts of a pointer at the end.
if let Some(entry) = end_overlap {
trace!("end overlapping entry: {entry:?}");
// For really small copies, make sure we don't start before `src` does.
let entry_start = cmp::max(entry.0, src.start);
for offset in entry_start..src.end() {
if bytes.last().map_or(true, |bytes_entry| bytes_entry.0 < offset) {
// The last entry, if it exists, has a lower offset than us.
bytes.push((offset, entry.1));
} else {
// There already is an entry for this offset in there! This can happen when the
// start and end range checks actually end up hitting the same pointer, so we
// already added this in the "pointer at the start" part above.
assert!(entry.0 <= src.start);
}
}
} else {
trace!("no end overlapping entry");
}
trace!("byte provenances: {bytes:?}");
// And again a buffer for the new list on the target side.
let mut dest_bytes = Vec::with_capacity(bytes.len() * (count as usize));
for i in 0..count {
dest_bytes
.extend(bytes.iter().map(|&(offset, reloc)| (shift_offset(i, offset), reloc)));
}
debug_assert_eq!(dest_bytes.len(), dest_bytes.capacity());
dest_bytes_box = Some(dest_bytes.into_boxed_slice());
}
Ok(ProvenanceCopy { dest_ptrs: dest_ptrs_box, dest_bytes: dest_bytes_box })
}
/// Applies a provenance copy.
/// The affected range, as defined in the parameters to `prepare_copy` is expected
/// to be clear of provenance.
pub fn apply_copy(&mut self, copy: ProvenanceCopy<Prov>) {
if let Some(dest_ptrs) = copy.dest_ptrs {
self.ptrs.insert_presorted(dest_ptrs.into());
}
if Prov::OFFSET_IS_ADDR {
if let Some(dest_bytes) = copy.dest_bytes
&& !dest_bytes.is_empty()
{
self.bytes.get_or_insert_with(Box::default).insert_presorted(dest_bytes.into());
}
} else {
debug_assert!(copy.dest_bytes.is_none());
}
}
}