From 1376c5a617be5c25655d0d7cb63e3beaa5a6e026 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Wed, 17 Apr 2024 14:20:39 +0200 Subject: Merging upstream version 1.70.0+dfsg1. Signed-off-by: Daniel Baumann --- .../src/mir/interpret/allocation/init_mask.rs | 330 ++++++++++++++++----- .../mir/interpret/allocation/init_mask/tests.rs | 195 ++++++++++++ .../src/mir/interpret/allocation/provenance_map.rs | 2 +- .../src/mir/interpret/allocation/tests.rs | 19 -- 4 files changed, 446 insertions(+), 100 deletions(-) create mode 100644 compiler/rustc_middle/src/mir/interpret/allocation/init_mask/tests.rs delete mode 100644 compiler/rustc_middle/src/mir/interpret/allocation/tests.rs (limited to 'compiler/rustc_middle/src/mir/interpret/allocation') diff --git a/compiler/rustc_middle/src/mir/interpret/allocation/init_mask.rs b/compiler/rustc_middle/src/mir/interpret/allocation/init_mask.rs index 82e9a961a..dcb56a175 100644 --- a/compiler/rustc_middle/src/mir/interpret/allocation/init_mask.rs +++ b/compiler/rustc_middle/src/mir/interpret/allocation/init_mask.rs @@ -1,3 +1,6 @@ +#[cfg(test)] +mod tests; + use std::hash; use std::iter; use std::ops::Range; @@ -10,20 +13,185 @@ 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. -// Note: for performance reasons when interning, some of the `InitMask` fields can be partially -// hashed. (see the `Hash` impl below for more details), so the impl is not derived. -#[derive(Clone, Debug, Eq, PartialEq, TyEncodable, TyDecodable)] -#[derive(HashStable)] +/// The actual bits are only materialized when needed, and we try to keep this data lazy as long as +/// possible. Currently, if all the blocks have the same value, then the mask represents either a +/// fully initialized or fully uninitialized const allocation, so we can only store that single +/// value. +#[derive(Clone, Debug, Eq, PartialEq, TyEncodable, TyDecodable, Hash, HashStable)] pub struct InitMask { - blocks: Vec, + blocks: InitMaskBlocks, len: Size, } +#[derive(Clone, Debug, Eq, PartialEq, TyEncodable, TyDecodable, Hash, HashStable)] +enum InitMaskBlocks { + Lazy { + /// Whether the lazy init mask is fully initialized or uninitialized. + state: bool, + }, + Materialized(InitMaskMaterialized), +} + +impl InitMask { + pub fn new(size: Size, state: bool) -> Self { + // Blocks start lazily allocated, until we have to materialize them. + let blocks = InitMaskBlocks::Lazy { state }; + InitMask { len: size, blocks } + } + + /// Checks whether the `range` 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, range: AllocRange) -> Result<(), AllocRange> { + let end = range.end(); + if end > self.len { + return Err(AllocRange::from(self.len..end)); + } + + match self.blocks { + InitMaskBlocks::Lazy { state } => { + // Lazily allocated blocks represent the full mask, and cover the requested range by + // definition. + if state { Ok(()) } else { Err(range) } + } + InitMaskBlocks::Materialized(ref blocks) => { + blocks.is_range_initialized(range.start, end) + } + } + } + + /// Sets a specified range to a value. If the range is out-of-bounds, the mask will grow to + /// accommodate it entirely. + pub fn set_range(&mut self, range: AllocRange, new_state: bool) { + let start = range.start; + let end = range.end(); + + let is_full_overwrite = start == Size::ZERO && end >= self.len; + + // Optimize the cases of a full init/uninit state, while handling growth if needed. + match self.blocks { + InitMaskBlocks::Lazy { ref mut state } if is_full_overwrite => { + // This is fully overwriting the mask, and we'll still have a single initialization + // state: the blocks can stay lazy. + *state = new_state; + self.len = end; + } + InitMaskBlocks::Materialized(_) if is_full_overwrite => { + // This is also fully overwriting materialized blocks with a single initialization + // state: we'll have no need for these blocks anymore and can make them lazy. + self.blocks = InitMaskBlocks::Lazy { state: new_state }; + self.len = end; + } + InitMaskBlocks::Lazy { state } if state == new_state => { + // Here we're partially overwriting the mask but the initialization state doesn't + // change: the blocks can stay lazy. + if end > self.len { + self.len = end; + } + } + _ => { + // Otherwise, we have a partial overwrite that can result in a mix of initialization + // states, so we'll need materialized blocks. + let len = self.len; + let blocks = self.materialize_blocks(); + + // There are 3 cases of interest here, if we have: + // + // [--------] + // ^ ^ + // 0 len + // + // 1) the range to set can be in-bounds: + // + // xxxx = [start, end] + // [--------] + // ^ ^ + // 0 len + // + // Here, we'll simply set the single `start` to `end` range. + // + // 2) the range to set can be partially out-of-bounds: + // + // xxxx = [start, end] + // [--------] + // ^ ^ + // 0 len + // + // We have 2 subranges to handle: + // - we'll set the existing `start` to `len` range. + // - we'll grow and set the `len` to `end` range. + // + // 3) the range to set can be fully out-of-bounds: + // + // ---xxxx = [start, end] + // [--------] + // ^ ^ + // 0 len + // + // Since we're growing the mask to a single `new_state` value, we consider the gap + // from `len` to `start` to be part of the range, and have a single subrange to + // handle: we'll grow and set the `len` to `end` range. + // + // Note that we have to materialize, set blocks, and grow the mask. We could + // therefore slightly optimize things in situations where these writes overlap. + // However, as of writing this, growing the mask doesn't happen in practice yet, so + // we don't do this micro-optimization. + + if end <= len { + // Handle case 1. + blocks.set_range_inbounds(start, end, new_state); + } else { + if start < len { + // Handle the first subrange of case 2. + blocks.set_range_inbounds(start, len, new_state); + } + + // Handle the second subrange of case 2, and case 3. + blocks.grow(len, end - len, new_state); // `Size` operation + self.len = end; + } + } + } + } + + /// Materializes this mask's blocks when the mask is lazy. + #[inline] + fn materialize_blocks(&mut self) -> &mut InitMaskMaterialized { + if let InitMaskBlocks::Lazy { state } = self.blocks { + self.blocks = InitMaskBlocks::Materialized(InitMaskMaterialized::new(self.len, state)); + } + + let InitMaskBlocks::Materialized(ref mut blocks) = self.blocks else { + bug!("initmask blocks must be materialized here") + }; + blocks + } + + /// Returns the initialization state at the specified in-bounds index. + #[inline] + pub fn get(&self, idx: Size) -> bool { + match self.blocks { + InitMaskBlocks::Lazy { state } => state, + InitMaskBlocks::Materialized(ref blocks) => blocks.get(idx), + } + } +} + +/// The actual materialized blocks of the bitmask, when we can't keep the `InitMask` lazy. +// Note: for performance reasons when interning, some of the fields can be partially +// hashed. (see the `Hash` impl below for more details), so the impl is not derived. +#[derive(Clone, Debug, Eq, PartialEq, TyEncodable, TyDecodable, HashStable)] +struct InitMaskMaterialized { + blocks: Vec, +} + // Const allocations are only hashed for interning. However, they can be large, making the hashing // expensive especially since it uses `FxHash`: it's better suited to short keys, not potentially // big buffers like the allocation's init mask. We can partially hash some fields when they're // large. -impl hash::Hash for InitMask { +impl hash::Hash for InitMaskMaterialized { fn hash(&self, state: &mut H) { const MAX_BLOCKS_TO_HASH: usize = super::MAX_BYTES_TO_HASH / std::mem::size_of::(); const MAX_BLOCKS_LEN: usize = super::MAX_HASHED_BUFFER_LEN / std::mem::size_of::(); @@ -41,18 +209,15 @@ impl hash::Hash for InitMask { } else { self.blocks.hash(state); } - - // Hash the other fields as usual. - self.len.hash(state); } } -impl InitMask { +impl InitMaskMaterialized { 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); + fn new(size: Size, state: bool) -> Self { + let mut m = InitMaskMaterialized { blocks: vec![] }; + m.grow(Size::ZERO, size, state); m } @@ -62,8 +227,8 @@ impl InitMask { // Each bit in a `Block` represents the initialization state of one byte of an allocation, // so we use `.bytes()` here. let bits = bits.bytes(); - let a = bits / InitMask::BLOCK_SIZE; - let b = bits % InitMask::BLOCK_SIZE; + let a = bits / Self::BLOCK_SIZE; + let b = bits % Self::BLOCK_SIZE; (usize::try_from(a).unwrap(), usize::try_from(b).unwrap()) } @@ -71,7 +236,7 @@ impl InitMask { fn size_from_bit_index(block: impl TryInto, bit: impl TryInto) -> Size { let block = block.try_into().ok().unwrap(); let bit = bit.try_into().ok().unwrap(); - Size::from_bytes(block * InitMask::BLOCK_SIZE + bit) + Size::from_bytes(block * Self::BLOCK_SIZE + bit) } /// Checks whether the `range` is entirely initialized. @@ -79,13 +244,8 @@ impl InitMask { /// 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, range: AllocRange) -> Result<(), AllocRange> { - let end = range.end(); - if end > self.len { - return Err(AllocRange::from(self.len..end)); - } - - let uninit_start = self.find_bit(range.start, end, false); + fn is_range_initialized(&self, start: Size, end: Size) -> Result<(), AllocRange> { + let uninit_start = self.find_bit(start, end, false); match uninit_start { Some(uninit_start) => { @@ -96,81 +256,80 @@ impl InitMask { } } - pub fn set_range(&mut self, range: AllocRange, new_state: bool) { - let end = range.end(); - let len = self.len; - if end > len { - self.grow(end - len, new_state); - } - self.set_range_inbounds(range.start, end, new_state); - } - fn set_range_inbounds(&mut self, start: Size, end: Size, new_state: bool) { - let (blocka, bita) = Self::bit_index(start); - let (blockb, bitb) = Self::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 + let (block_a, bit_a) = Self::bit_index(start); + let (block_b, bit_b) = Self::bit_index(end); + if block_a == block_b { + // First set all bits except the first `bit_a`, + // then unset the last `64 - bit_b` bits. + let range = if bit_b == 0 { + u64::MAX << bit_a } else { - (u64::MAX << bita) & (u64::MAX >> (64 - bitb)) + (u64::MAX << bit_a) & (u64::MAX >> (64 - bit_b)) }; if new_state { - self.blocks[blocka] |= range; + self.blocks[block_a] |= range; } else { - self.blocks[blocka] &= !range; + self.blocks[block_a] &= !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); + // Set `bit_a..64` to `1`. + self.blocks[block_a] |= u64::MAX << bit_a; + // Set `0..bit_b` to `1`. + if bit_b != 0 { + self.blocks[block_b] |= u64::MAX >> (64 - bit_b); } // Fill in all the other blocks (much faster than one bit at a time). - for block in (blocka + 1)..blockb { + for block in (block_a + 1)..block_b { 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)); + // Set `bit_a..64` to `0`. + self.blocks[block_a] &= !(u64::MAX << bit_a); + // Set `0..bit_b` to `0`. + if bit_b != 0 { + self.blocks[block_b] &= !(u64::MAX >> (64 - bit_b)); } // Fill in all the other blocks (much faster than one bit at a time). - for block in (blocka + 1)..blockb { + for block in (block_a + 1)..block_b { self.blocks[block] = 0; } } } #[inline] - pub fn get(&self, i: Size) -> bool { + fn get(&self, i: Size) -> bool { let (block, bit) = Self::bit_index(i); (self.blocks[block] & (1 << bit)) != 0 } - fn grow(&mut self, amount: Size, new_state: bool) { + fn grow(&mut self, len: Size, 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(); + u64::try_from(self.blocks.len()).unwrap() * Self::BLOCK_SIZE - len.bytes(); + + // If there's not enough capacity in the currently allocated blocks, allocate some more. 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()), - ); + + // We allocate the blocks to the correct value for the requested init state, so we won't + // have to manually set them with another write. + let block = if new_state { u64::MAX } else { 0 }; + self.blocks + .extend(iter::repeat(block).take(usize::try_from(additional_blocks).unwrap())); + } + + // New blocks have already been set here, so we only need to set the unused trailing bits, + // if any. + if unused_trailing_bits > 0 { + let in_bounds_tail = Size::from_bytes(unused_trailing_bits); + self.set_range_inbounds(len, len + in_bounds_tail, new_state); // `Size` operation } - let start = self.len; - self.len += amount; - self.set_range_inbounds(start, start + amount, new_state); // `Size` operation } /// Returns the index of the first bit in `start..end` (end-exclusive) that is equal to is_init. @@ -188,7 +347,7 @@ impl InitMask { /// ``` /// Also, if not stated, assume that `is_init = true`, that is, we are searching for the first 1 bit. fn find_bit_fast( - init_mask: &InitMask, + init_mask: &InitMaskMaterialized, start: Size, end: Size, is_init: bool, @@ -223,7 +382,7 @@ impl InitMask { None } else { let bit = bits.trailing_zeros(); - Some(InitMask::size_from_bit_index(block, bit)) + Some(InitMaskMaterialized::size_from_bit_index(block, bit)) } } @@ -253,9 +412,9 @@ impl InitMask { // This provides the desired behavior of searching blocks 0 and 1 for (a), // and searching only block 0 for (b). // There is no concern of overflows since we checked for `start >= end` above. - let (start_block, start_bit) = InitMask::bit_index(start); + let (start_block, start_bit) = InitMaskMaterialized::bit_index(start); let end_inclusive = Size::from_bytes(end.bytes() - 1); - let (end_block_inclusive, _) = InitMask::bit_index(end_inclusive); + let (end_block_inclusive, _) = InitMaskMaterialized::bit_index(end_inclusive); // Handle first block: need to skip `start_bit` bits. // @@ -340,7 +499,7 @@ impl InitMask { #[cfg_attr(not(debug_assertions), allow(dead_code))] fn find_bit_slow( - init_mask: &InitMask, + init_mask: &InitMaskMaterialized, start: Size, end: Size, is_init: bool, @@ -436,10 +595,19 @@ impl<'a> Iterator for InitChunkIter<'a> { return None; } - let end_of_chunk = - self.init_mask.find_bit(self.start, self.end, !self.is_init).unwrap_or(self.end); + let end_of_chunk = match self.init_mask.blocks { + InitMaskBlocks::Lazy { .. } => { + // If we're iterating over the chunks of lazy blocks, we just emit a single + // full-size chunk. + self.end + } + InitMaskBlocks::Materialized(ref blocks) => { + let end_of_chunk = + blocks.find_bit(self.start, self.end, !self.is_init).unwrap_or(self.end); + end_of_chunk + } + }; let range = self.start..end_of_chunk; - let ret = Some(if self.is_init { InitChunk::Init(range) } else { InitChunk::Uninit(range) }); @@ -504,17 +672,19 @@ impl InitMask { /// Applies multiple instances of the run-length encoding to the initialization mask. pub fn apply_copy(&mut self, defined: InitCopy, 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`. + // An optimization where we can just overwrite an entire range of initialization bits if + // they are going to be uniformly `1` or `0`. If this happens to be a full-range overwrite, + // we won't need materialized blocks either. if defined.ranges.len() <= 1 { - self.set_range_inbounds( - range.start, - range.start + range.size * repeat, // `Size` operations - defined.initial, - ); + let start = range.start; + let end = range.start + range.size * repeat; // `Size` operations + self.set_range(AllocRange::from(start..end), defined.initial); return; } + // We're about to do one or more partial writes, so we ensure the blocks are materialized. + let blocks = self.materialize_blocks(); + for mut j in 0..repeat { j *= range.size.bytes(); j += range.start.bytes(); @@ -522,7 +692,7 @@ impl InitMask { for range in &defined.ranges { let old_j = j; j += range; - self.set_range_inbounds(Size::from_bytes(old_j), Size::from_bytes(j), cur); + blocks.set_range_inbounds(Size::from_bytes(old_j), Size::from_bytes(j), cur); cur = !cur; } } diff --git a/compiler/rustc_middle/src/mir/interpret/allocation/init_mask/tests.rs b/compiler/rustc_middle/src/mir/interpret/allocation/init_mask/tests.rs new file mode 100644 index 000000000..1a7934bc2 --- /dev/null +++ b/compiler/rustc_middle/src/mir/interpret/allocation/init_mask/tests.rs @@ -0,0 +1,195 @@ +use super::*; +use crate::mir::interpret::alloc_range; + +#[test] +fn uninit_mask() { + let mut mask = InitMask::new(Size::from_bytes(500), false); + assert!(!mask.get(Size::from_bytes(499))); + mask.set_range(alloc_range(Size::from_bytes(499), Size::from_bytes(1)), true); + assert!(mask.get(Size::from_bytes(499))); + mask.set_range((100..256).into(), true); + for i in 0..100 { + assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); + } + for i in 100..256 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + for i in 256..499 { + assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); + } +} + +/// Returns the number of materialized blocks for this mask. +fn materialized_block_count(mask: &InitMask) -> usize { + match mask.blocks { + InitMaskBlocks::Lazy { .. } => 0, + InitMaskBlocks::Materialized(ref blocks) => blocks.blocks.len(), + } +} + +#[test] +fn materialize_mask_within_range() { + // To have spare bits, we use a mask size smaller than its block size of 64. + let mut mask = InitMask::new(Size::from_bytes(16), false); + assert_eq!(materialized_block_count(&mask), 0); + + // Forces materialization, but doesn't require growth. This is case #1 documented in the + // `set_range` method. + mask.set_range((8..16).into(), true); + assert_eq!(materialized_block_count(&mask), 1); + + for i in 0..8 { + assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); + } + for i in 8..16 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } +} + +#[test] +fn grow_within_unused_bits_with_full_overwrite() { + // To have spare bits, we use a mask size smaller than its block size of 64. + let mut mask = InitMask::new(Size::from_bytes(16), true); + for i in 0..16 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + + // Grow without requiring an additional block. Full overwrite. + // This can be fully handled without materialization. + let range = (0..32).into(); + mask.set_range(range, true); + + for i in 0..32 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + + assert_eq!(materialized_block_count(&mask), 0); +} + +// This test checks that an initmask's spare capacity is correctly used when growing within block +// capacity. This can be fully handled without materialization. +#[test] +fn grow_same_state_within_unused_bits() { + // To have spare bits, we use a mask size smaller than its block size of 64. + let mut mask = InitMask::new(Size::from_bytes(16), true); + for i in 0..16 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + + // Grow without requiring an additional block. The gap between the current length and the + // range's beginning should be set to the same value as the range. + let range = (24..32).into(); + mask.set_range(range, true); + + // We want to make sure the unused bits in the first block are correct + for i in 16..24 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + + for i in 24..32 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + + assert_eq!(1, mask.range_as_init_chunks((0..32).into()).count()); + assert_eq!(materialized_block_count(&mask), 0); +} + +// This is the same test as `grow_same_state_within_unused_bits` but with both init and uninit +// states: this forces materialization; otherwise the mask could stay lazy even when needing to +// grow. +#[test] +fn grow_mixed_state_within_unused_bits() { + // To have spare bits, we use a mask size smaller than its block size of 64. + let mut mask = InitMask::new(Size::from_bytes(16), true); + for i in 0..16 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + + // Grow without requiring an additional block. The gap between the current length and the + // range's beginning should be set to the same value as the range. Note: since this is fully + // out-of-bounds of the current mask, this is case #3 described in the `set_range` method. + let range = (24..32).into(); + mask.set_range(range, false); + + // We want to make sure the unused bits in the first block are correct + for i in 16..24 { + assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); + } + + for i in 24..32 { + assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); + } + + assert_eq!(1, mask.range_as_init_chunks((0..16).into()).count()); + assert_eq!(2, mask.range_as_init_chunks((0..32).into()).count()); + assert_eq!(materialized_block_count(&mask), 1); +} + +// This is similar to `grow_mixed_state_within_unused_bits` to force materialization, but the range +// to set partially overlaps the mask, so this requires a different growth + write pattern in the +// mask. +#[test] +fn grow_within_unused_bits_with_overlap() { + // To have spare bits, we use a mask size smaller than its block size of 64. + let mut mask = InitMask::new(Size::from_bytes(16), true); + for i in 0..16 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + + // Grow without requiring an additional block, but leave no gap after the current len. Note: + // since this is partially out-of-bounds of the current mask, this is case #2 described in the + // `set_range` method. + let range = (8..24).into(); + mask.set_range(range, false); + + // We want to make sure the unused bits in the first block are correct + for i in 8..24 { + assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); + } + + assert_eq!(1, mask.range_as_init_chunks((0..8).into()).count()); + assert_eq!(2, mask.range_as_init_chunks((0..24).into()).count()); + assert_eq!(materialized_block_count(&mask), 1); +} + +// Force materialization before a full overwrite: the mask can now become lazy. +#[test] +fn grow_mixed_state_within_unused_bits_and_full_overwrite() { + // To have spare bits, we use a mask size smaller than its block size of 64. + let mut mask = InitMask::new(Size::from_bytes(16), true); + let range = (0..16).into(); + assert!(mask.is_range_initialized(range).is_ok()); + + // Force materialization. + let range = (8..24).into(); + mask.set_range(range, false); + assert!(mask.is_range_initialized(range).is_err()); + assert_eq!(materialized_block_count(&mask), 1); + + // Full overwrite, lazy blocks would be enough from now on. + let range = (0..32).into(); + mask.set_range(range, true); + assert!(mask.is_range_initialized(range).is_ok()); + + assert_eq!(1, mask.range_as_init_chunks((0..32).into()).count()); + assert_eq!(materialized_block_count(&mask), 0); +} + +// Check that growth outside the current capacity can still be lazy: if the init state doesn't +// change, we don't need materialized blocks. +#[test] +fn grow_same_state_outside_capacity() { + // To have spare bits, we use a mask size smaller than its block size of 64. + let mut mask = InitMask::new(Size::from_bytes(16), true); + for i in 0..16 { + assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); + } + assert_eq!(materialized_block_count(&mask), 0); + + // Grow to 10 blocks with the same init state. + let range = (24..640).into(); + mask.set_range(range, true); + + assert_eq!(1, mask.range_as_init_chunks((0..640).into()).count()); + assert_eq!(materialized_block_count(&mask), 0); +} diff --git a/compiler/rustc_middle/src/mir/interpret/allocation/provenance_map.rs b/compiler/rustc_middle/src/mir/interpret/allocation/provenance_map.rs index ddd3f3943..318f93e12 100644 --- a/compiler/rustc_middle/src/mir/interpret/allocation/provenance_map.rs +++ b/compiler/rustc_middle/src/mir/interpret/allocation/provenance_map.rs @@ -14,7 +14,7 @@ use rustc_serialize::{Decodable, Decoder, Encodable, Encoder}; #[derive(HashStable)] pub struct ProvenanceMap { /// Provenance in this map applies from the given offset for an entire pointer-size worth of - /// bytes. Two entires in this map are always at least a pointer size apart. + /// bytes. Two entries in this map are always at least a pointer size apart. ptrs: SortedMap, /// Provenance in this map only applies to the given single byte. /// This map is disjoint from the previous. It will always be empty when diff --git a/compiler/rustc_middle/src/mir/interpret/allocation/tests.rs b/compiler/rustc_middle/src/mir/interpret/allocation/tests.rs deleted file mode 100644 index c9c3c50c5..000000000 --- a/compiler/rustc_middle/src/mir/interpret/allocation/tests.rs +++ /dev/null @@ -1,19 +0,0 @@ -use super::*; - -#[test] -fn uninit_mask() { - let mut mask = InitMask::new(Size::from_bytes(500), false); - assert!(!mask.get(Size::from_bytes(499))); - mask.set_range(alloc_range(Size::from_bytes(499), Size::from_bytes(1)), true); - assert!(mask.get(Size::from_bytes(499))); - mask.set_range((100..256).into(), true); - for i in 0..100 { - assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); - } - for i in 100..256 { - assert!(mask.get(Size::from_bytes(i)), "{i} should be set"); - } - for i in 256..499 { - assert!(!mask.get(Size::from_bytes(i)), "{i} should not be set"); - } -} -- cgit v1.2.3