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freeing_bump.rs
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freeing_bump.rs
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// This file is part of Substrate.
// Copyright (C) Parity Technologies (UK) Ltd.
// SPDX-License-Identifier: Apache-2.0
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! This module implements a freeing-bump allocator.
//!
//! The heap is a continuous linear memory and chunks are allocated using a bump allocator.
//!
//! ```ignore
//! +-------------+-------------------------------------------------+
//! | <allocated> | <unallocated> |
//! +-------------+-------------------------------------------------+
//! ^
//! |_ bumper
//! ```
//!
//! Only allocations with sizes of power of two can be allocated. If the incoming request has a non
//! power of two size it is increased to the nearest power of two. The power of two of size is
//! referred as **an order**.
//!
//! Each allocation has a header immediately preceding to it. The header is always 8 bytes and can
//! be of two types: free and occupied.
//!
//! For implementing freeing we maintain a linked lists for each order. The maximum supported
//! allocation size is capped, therefore the number of orders and thus the linked lists is as well
//! limited. Currently, the maximum size of an allocation is 32 MiB.
//!
//! When the allocator serves an allocation request it first checks the linked list for the
//! respective order. If it doesn't have any free chunks, the allocator requests memory from the
//! bump allocator. In any case the order is stored in the header of the allocation.
//!
//! Upon deallocation we get the order of the allocation from its header and then add that
//! allocation to the linked list for the respective order.
//!
//! # Caveats
//!
//! This is a fast allocator but it is also dumb. There are specifically two main shortcomings
//! that the user should keep in mind:
//!
//! - Once the bump allocator space is exhausted, there is no way to reclaim the memory. This means
//! that it's possible to end up in a situation where there are no live allocations yet a new
//! allocation will fail.
//!
//! Let's look into an example. Given a heap of 32 MiB. The user makes a 32 MiB allocation that we
//! call `X` . Now the heap is full. Then user deallocates `X`. Since all the space in the bump
//! allocator was consumed by the 32 MiB allocation, allocations of all sizes except 32 MiB will
//! fail.
//!
//! - Sizes of allocations are rounded up to the nearest order. That is, an allocation of 2,00001
//! MiB will be put into the bucket of 4 MiB. Therefore, any allocation of size `(N, 2N]` will
//! take up to `2N`, thus assuming a uniform distribution of allocation sizes, the average amount
//! in use of a `2N` space on the heap will be `(3N + ε) / 2`. So average utilization is going to
//! be around 75% (`(3N + ε) / 2 / 2N`) meaning that around 25% of the space in allocation will be
//! wasted. This is more pronounced (in terms of absolute heap amounts) with larger allocation
//! sizes.
use crate::{Error, Memory, MAX_WASM_PAGES, PAGE_SIZE};
pub use sp_core::MAX_POSSIBLE_ALLOCATION;
use sp_wasm_interface::{Pointer, WordSize};
use std::{
cmp::{max, min},
mem,
ops::{Index, IndexMut, Range},
};
/// The minimal alignment guaranteed by this allocator.
///
/// The alignment of 8 is chosen because it is the maximum size of a primitive type supported by the
/// target version of wasm32: i64's natural alignment is 8.
const ALIGNMENT: u32 = 8;
// Each pointer is prefixed with 8 bytes, which identify the list index
// to which it belongs.
const HEADER_SIZE: u32 = 8;
/// Create an allocator error.
fn error(msg: &'static str) -> Error {
Error::Other(msg)
}
const LOG_TARGET: &str = "wasm-heap";
// The minimum possible allocation size is chosen to be 8 bytes because in that case we would have
// easier time to provide the guaranteed alignment of 8.
//
// The maximum possible allocation size is set in the primitives to 32MiB.
//
// N_ORDERS - represents the number of orders supported.
//
// This number corresponds to the number of powers between the minimum possible allocation and
// maximum possible allocation, or: 2^3...2^25 (both ends inclusive, hence 23).
const N_ORDERS: usize = 23;
const MIN_POSSIBLE_ALLOCATION: u32 = 8; // 2^3 bytes, 8 bytes
/// The exponent for the power of two sized block adjusted to the minimum size.
///
/// This way, if `MIN_POSSIBLE_ALLOCATION == 8`, we would get:
///
/// power_of_two_size | order
/// 8 | 0
/// 16 | 1
/// 32 | 2
/// 64 | 3
/// ...
/// 16777216 | 21
/// 33554432 | 22
///
/// and so on.
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
struct Order(u32);
impl Order {
/// Create `Order` object from a raw order.
///
/// Returns `Err` if it is greater than the maximum supported order.
fn from_raw(order: u32) -> Result<Self, Error> {
if order < N_ORDERS as u32 {
Ok(Self(order))
} else {
Err(error("invalid order"))
}
}
/// Compute the order by the given size
///
/// The size is clamped, so that the following holds:
///
/// `MIN_POSSIBLE_ALLOCATION <= size <= MAX_POSSIBLE_ALLOCATION`
fn from_size(size: u32) -> Result<Self, Error> {
let clamped_size = if size > MAX_POSSIBLE_ALLOCATION {
log::warn!(target: LOG_TARGET, "going to fail due to allocating {:?}", size);
return Err(Error::RequestedAllocationTooLarge)
} else if size < MIN_POSSIBLE_ALLOCATION {
MIN_POSSIBLE_ALLOCATION
} else {
size
};
// Round the clamped size to the next power of two.
//
// It returns the unchanged value if the value is already a power of two.
let power_of_two_size = clamped_size.next_power_of_two();
// Compute the number of trailing zeroes to get the order. We adjust it by the number of
// trailing zeroes in the minimum possible allocation.
let order = power_of_two_size.trailing_zeros() - MIN_POSSIBLE_ALLOCATION.trailing_zeros();
Ok(Self(order))
}
/// Returns the corresponding size in bytes for this order.
///
/// Note that it is always a power of two.
fn size(&self) -> u32 {
MIN_POSSIBLE_ALLOCATION << self.0
}
/// Extract the order as `u32`.
fn into_raw(self) -> u32 {
self.0
}
}
/// A special magic value for a pointer in a link that denotes the end of the linked list.
const NIL_MARKER: u32 = u32::MAX;
/// A link between headers in the free list.
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
enum Link {
/// Nil, denotes that there is no next element.
Nil,
/// Link to the next element represented as a pointer to the a header.
Ptr(u32),
}
impl Link {
/// Creates a link from raw value.
fn from_raw(raw: u32) -> Self {
if raw != NIL_MARKER {
Self::Ptr(raw)
} else {
Self::Nil
}
}
/// Converts this link into a raw u32.
fn into_raw(self) -> u32 {
match self {
Self::Nil => NIL_MARKER,
Self::Ptr(ptr) => ptr,
}
}
}
/// A header of an allocation.
///
/// The header is encoded in memory as follows.
///
/// ## Free header
///
/// ```ignore
/// 64 32 0
// +--------------+-------------------+
/// | 0 | next element link |
/// +--------------+-------------------+
/// ```
/// ## Occupied header
/// ```ignore
/// 64 32 0
// +--------------+-------------------+
/// | 1 | order |
/// +--------------+-------------------+
/// ```
#[derive(Clone, Debug, PartialEq, Eq)]
enum Header {
/// A free header contains a link to the next element to form a free linked list.
Free(Link),
/// An occupied header has attached order to know in which free list we should put the
/// allocation upon deallocation.
Occupied(Order),
}
impl Header {
/// Reads a header from memory.
///
/// Returns an error if the `header_ptr` is out of bounds of the linear memory or if the read
/// header is corrupted (e.g. the order is incorrect).
fn read_from(memory: &impl Memory, header_ptr: u32) -> Result<Self, Error> {
let raw_header = memory.read_le_u64(header_ptr)?;
// Check if the header represents an occupied or free allocation and extract the header data
// by trimming (and discarding) the high bits.
let occupied = raw_header & 0x00000001_00000000 != 0;
let header_data = raw_header as u32;
Ok(if occupied {
Self::Occupied(Order::from_raw(header_data)?)
} else {
Self::Free(Link::from_raw(header_data))
})
}
/// Write out this header to memory.
///
/// Returns an error if the `header_ptr` is out of bounds of the linear memory.
fn write_into(&self, memory: &mut impl Memory, header_ptr: u32) -> Result<(), Error> {
let (header_data, occupied_mask) = match *self {
Self::Occupied(order) => (order.into_raw(), 0x00000001_00000000),
Self::Free(link) => (link.into_raw(), 0x00000000_00000000),
};
let raw_header = header_data as u64 | occupied_mask;
memory.write_le_u64(header_ptr, raw_header)?;
Ok(())
}
/// Returns the order of the allocation if this is an occupied header.
fn into_occupied(self) -> Option<Order> {
match self {
Self::Occupied(order) => Some(order),
_ => None,
}
}
/// Returns the link to the next element in the free list if this is a free header.
fn into_free(self) -> Option<Link> {
match self {
Self::Free(link) => Some(link),
_ => None,
}
}
}
/// This struct represents a collection of intrusive linked lists for each order.
struct FreeLists {
heads: [Link; N_ORDERS],
}
impl FreeLists {
/// Creates the free empty lists.
fn new() -> Self {
Self { heads: [Link::Nil; N_ORDERS] }
}
/// Replaces a given link for the specified order and returns the old one.
fn replace(&mut self, order: Order, new: Link) -> Link {
let prev = self[order];
self[order] = new;
prev
}
}
impl Index<Order> for FreeLists {
type Output = Link;
fn index(&self, index: Order) -> &Link {
&self.heads[index.0 as usize]
}
}
impl IndexMut<Order> for FreeLists {
fn index_mut(&mut self, index: Order) -> &mut Link {
&mut self.heads[index.0 as usize]
}
}
/// Memory allocation stats gathered during the lifetime of the allocator.
#[derive(Clone, Debug, Default)]
#[non_exhaustive]
pub struct AllocationStats {
/// The current number of bytes allocated.
///
/// This represents how many bytes are allocated *right now*.
pub bytes_allocated: u32,
/// The peak number of bytes ever allocated.
///
/// This is the maximum the `bytes_allocated` ever reached.
pub bytes_allocated_peak: u32,
/// The sum of every allocation ever made.
///
/// This increases every time a new allocation is made.
pub bytes_allocated_sum: u128,
/// The amount of address space (in bytes) used by the allocator.
///
/// This is calculated as the difference between the allocator's bumper
/// and the heap base.
///
/// Currently the bumper's only ever incremented, so this is simultaneously
/// the current value as well as the peak value.
pub address_space_used: u32,
}
/// Convert the given `size` in bytes into the number of pages.
///
/// The returned number of pages is ensured to be big enough to hold memory with the given `size`.
///
/// Returns `None` if the number of pages to not fit into `u32`.
fn pages_from_size(size: u64) -> Option<u32> {
u32::try_from((size + PAGE_SIZE as u64 - 1) / PAGE_SIZE as u64).ok()
}
/// An implementation of freeing bump allocator.
///
/// Refer to the module-level documentation for further details.
pub struct FreeingBumpHeapAllocator {
original_heap_base: u32,
bumper: u32,
free_lists: FreeLists,
poisoned: bool,
last_observed_memory_size: u64,
stats: AllocationStats,
}
impl Drop for FreeingBumpHeapAllocator {
fn drop(&mut self) {
log::debug!(target: LOG_TARGET, "allocator dropped: {:?}", self.stats)
}
}
impl FreeingBumpHeapAllocator {
/// Creates a new allocation heap which follows a freeing-bump strategy.
///
/// # Arguments
///
/// - `heap_base` - the offset from the beginning of the linear memory where the heap starts.
pub fn new(heap_base: u32) -> Self {
let aligned_heap_base = (heap_base + ALIGNMENT - 1) / ALIGNMENT * ALIGNMENT;
FreeingBumpHeapAllocator {
original_heap_base: aligned_heap_base,
bumper: aligned_heap_base,
free_lists: FreeLists::new(),
poisoned: false,
last_observed_memory_size: 0,
stats: AllocationStats::default(),
}
}
/// Gets requested number of bytes to allocate and returns a pointer.
/// The maximum size which can be allocated at once is 32 MiB.
/// There is no minimum size, but whatever size is passed into
/// this function is rounded to the next power of two. If the requested
/// size is below 8 bytes it will be rounded up to 8 bytes.
///
/// The identity or the type of the passed memory object does not matter. However, the size of
/// memory cannot shrink compared to the memory passed in previous invocations.
///
/// NOTE: Once the allocator has returned an error all subsequent requests will return an error.
///
/// # Arguments
///
/// - `mem` - a slice representing the linear memory on which this allocator operates.
/// - `size` - size in bytes of the allocation request
pub fn allocate(
&mut self,
mem: &mut impl Memory,
size: WordSize,
) -> Result<Pointer<u8>, Error> {
if self.poisoned {
return Err(error("the allocator has been poisoned"))
}
let bomb = PoisonBomb { poisoned: &mut self.poisoned };
Self::observe_memory_size(&mut self.last_observed_memory_size, mem)?;
let order = Order::from_size(size)?;
let header_ptr: u32 = match self.free_lists[order] {
Link::Ptr(header_ptr) => {
if (u64::from(header_ptr) + u64::from(order.size()) + u64::from(HEADER_SIZE)) >
mem.size()
{
return Err(error("Invalid header pointer detected"))
}
// Remove this header from the free list.
let next_free = Header::read_from(mem, header_ptr)?
.into_free()
.ok_or_else(|| error("free list points to a occupied header"))?;
self.free_lists[order] = next_free;
header_ptr
},
Link::Nil => {
// Corresponding free list is empty. Allocate a new item.
Self::bump(&mut self.bumper, order.size() + HEADER_SIZE, mem)?
},
};
// Write the order in the occupied header.
Header::Occupied(order).write_into(mem, header_ptr)?;
self.stats.bytes_allocated += order.size() + HEADER_SIZE;
self.stats.bytes_allocated_sum += u128::from(order.size() + HEADER_SIZE);
self.stats.bytes_allocated_peak =
max(self.stats.bytes_allocated_peak, self.stats.bytes_allocated);
self.stats.address_space_used = self.bumper - self.original_heap_base;
log::trace!(target: LOG_TARGET, "after allocation: {:?}", self.stats);
bomb.disarm();
Ok(Pointer::new(header_ptr + HEADER_SIZE))
}
/// Deallocates the space which was allocated for a pointer.
///
/// The identity or the type of the passed memory object does not matter. However, the size of
/// memory cannot shrink compared to the memory passed in previous invocations.
///
/// NOTE: Once the allocator has returned an error all subsequent requests will return an error.
///
/// # Arguments
///
/// - `mem` - a slice representing the linear memory on which this allocator operates.
/// - `ptr` - pointer to the allocated chunk
pub fn deallocate(&mut self, mem: &mut impl Memory, ptr: Pointer<u8>) -> Result<(), Error> {
if self.poisoned {
return Err(error("the allocator has been poisoned"))
}
let bomb = PoisonBomb { poisoned: &mut self.poisoned };
Self::observe_memory_size(&mut self.last_observed_memory_size, mem)?;
let header_ptr = u32::from(ptr)
.checked_sub(HEADER_SIZE)
.ok_or_else(|| error("Invalid pointer for deallocation"))?;
let order = Header::read_from(mem, header_ptr)?
.into_occupied()
.ok_or_else(|| error("the allocation points to an empty header"))?;
// Update the just freed header and knit it back to the free list.
let prev_head = self.free_lists.replace(order, Link::Ptr(header_ptr));
Header::Free(prev_head).write_into(mem, header_ptr)?;
self.stats.bytes_allocated = self
.stats
.bytes_allocated
.checked_sub(order.size() + HEADER_SIZE)
.ok_or_else(|| error("underflow of the currently allocated bytes count"))?;
log::trace!("after deallocation: {:?}", self.stats);
bomb.disarm();
Ok(())
}
/// Returns the allocation stats for this allocator.
pub fn stats(&self) -> AllocationStats {
self.stats.clone()
}
/// Increases the `bumper` by `size`.
///
/// Returns the `bumper` from before the increase. Returns an `Error::AllocatorOutOfSpace` if
/// the operation would exhaust the heap.
fn bump(bumper: &mut u32, size: u32, memory: &mut impl Memory) -> Result<u32, Error> {
let required_size = u64::from(*bumper) + u64::from(size);
if required_size > memory.size() {
let required_pages =
pages_from_size(required_size).ok_or_else(|| Error::AllocatorOutOfSpace)?;
let current_pages = memory.pages();
let max_pages = memory.max_pages().unwrap_or(MAX_WASM_PAGES);
debug_assert!(
current_pages < required_pages,
"current pages {current_pages} < required pages {required_pages}"
);
if current_pages >= max_pages {
log::debug!(
target: LOG_TARGET,
"Wasm pages ({current_pages}) are already at the maximum.",
);
return Err(Error::AllocatorOutOfSpace)
} else if required_pages > max_pages {
log::debug!(
target: LOG_TARGET,
"Failed to grow memory from {current_pages} pages to at least {required_pages}\
pages due to the maximum limit of {max_pages} pages",
);
return Err(Error::AllocatorOutOfSpace)
}
// Ideally we want to double our current number of pages,
// as long as it's less than the absolute maximum we can have.
let next_pages = min(current_pages * 2, max_pages);
// ...but if even more pages are required then try to allocate that many.
let next_pages = max(next_pages, required_pages);
if memory.grow(next_pages - current_pages).is_err() {
log::error!(
target: LOG_TARGET,
"Failed to grow memory from {current_pages} pages to {next_pages} pages",
);
return Err(Error::AllocatorOutOfSpace)
}
debug_assert_eq!(memory.pages(), next_pages, "Number of pages should have increased!");
}
let res = *bumper;
*bumper += size;
Ok(res)
}
fn observe_memory_size(
last_observed_memory_size: &mut u64,
mem: &mut impl Memory,
) -> Result<(), Error> {
if mem.size() < *last_observed_memory_size {
return Err(Error::MemoryShrinked)
}
*last_observed_memory_size = mem.size();
Ok(())
}
}
/// A trait for abstraction of accesses to a wasm linear memory. Used to read or modify the
/// allocation prefixes.
///
/// A wasm linear memory behaves similarly to a vector. The address space doesn't have holes and is
/// accessible up to the reported size.
///
/// The linear memory can grow in size with the wasm page granularity (64KiB), but it cannot shrink.
trait MemoryExt: Memory {
/// Read a u64 from the heap in LE form. Returns an error if any of the bytes read are out of
/// bounds.
fn read_le_u64(&self, ptr: u32) -> Result<u64, Error> {
self.with_access(|memory| {
let range =
heap_range(ptr, 8, memory.len()).ok_or_else(|| error("read out of heap bounds"))?;
let bytes = memory[range]
.try_into()
.expect("[u8] slice of length 8 must be convertible to [u8; 8]");
Ok(u64::from_le_bytes(bytes))
})
}
/// Write a u64 to the heap in LE form. Returns an error if any of the bytes written are out of
/// bounds.
fn write_le_u64(&mut self, ptr: u32, val: u64) -> Result<(), Error> {
self.with_access_mut(|memory| {
let range = heap_range(ptr, 8, memory.len())
.ok_or_else(|| error("write out of heap bounds"))?;
let bytes = val.to_le_bytes();
memory[range].copy_from_slice(&bytes[..]);
Ok(())
})
}
/// Returns the full size of the memory in bytes.
fn size(&self) -> u64 {
debug_assert!(self.pages() <= MAX_WASM_PAGES);
self.pages() as u64 * PAGE_SIZE as u64
}
}
impl<T: Memory> MemoryExt for T {}
fn heap_range(offset: u32, length: u32, heap_len: usize) -> Option<Range<usize>> {
let start = offset as usize;
let end = offset.checked_add(length)? as usize;
if end <= heap_len {
Some(start..end)
} else {
None
}
}
/// A guard that will raise the poisoned flag on drop unless disarmed.
struct PoisonBomb<'a> {
poisoned: &'a mut bool,
}
impl<'a> PoisonBomb<'a> {
fn disarm(self) {
mem::forget(self)
}
}
impl<'a> Drop for PoisonBomb<'a> {
fn drop(&mut self) {
*self.poisoned = true;
}
}
#[cfg(test)]
mod tests {
use super::*;
/// Makes a pointer out of the given address.
fn to_pointer(address: u32) -> Pointer<u8> {
Pointer::new(address)
}
#[derive(Debug)]
struct MemoryInstance {
data: Vec<u8>,
max_wasm_pages: u32,
}
impl MemoryInstance {
fn with_pages(pages: u32) -> Self {
Self { data: vec![0; (pages * PAGE_SIZE) as usize], max_wasm_pages: MAX_WASM_PAGES }
}
fn set_max_wasm_pages(&mut self, max_pages: u32) {
self.max_wasm_pages = max_pages;
}
}
impl Memory for MemoryInstance {
fn with_access<R>(&self, run: impl FnOnce(&[u8]) -> R) -> R {
run(&self.data)
}
fn with_access_mut<R>(&mut self, run: impl FnOnce(&mut [u8]) -> R) -> R {
run(&mut self.data)
}
fn pages(&self) -> u32 {
pages_from_size(self.data.len() as u64).unwrap()
}
fn max_pages(&self) -> Option<u32> {
Some(self.max_wasm_pages)
}
fn grow(&mut self, pages: u32) -> Result<(), ()> {
if self.pages() + pages > self.max_wasm_pages {
Err(())
} else {
self.data.resize(((self.pages() + pages) * PAGE_SIZE) as usize, 0);
Ok(())
}
}
}
#[test]
fn test_pages_from_size() {
assert_eq!(pages_from_size(0).unwrap(), 0);
assert_eq!(pages_from_size(1).unwrap(), 1);
assert_eq!(pages_from_size(65536).unwrap(), 1);
assert_eq!(pages_from_size(65536 + 1).unwrap(), 2);
assert_eq!(pages_from_size(2 * 65536).unwrap(), 2);
assert_eq!(pages_from_size(2 * 65536 + 1).unwrap(), 3);
}
#[test]
fn should_allocate_properly() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
// when
let ptr = heap.allocate(&mut mem, 1).unwrap();
// then
// returned pointer must start right after `HEADER_SIZE`
assert_eq!(ptr, to_pointer(HEADER_SIZE));
}
#[test]
fn should_always_align_pointers_to_multiples_of_8() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(13);
// when
let ptr = heap.allocate(&mut mem, 1).unwrap();
// then
// the pointer must start at the next multiple of 8 from 13
// + the prefix of 8 bytes.
assert_eq!(ptr, to_pointer(24));
}
#[test]
fn should_increment_pointers_properly() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
// when
let ptr1 = heap.allocate(&mut mem, 1).unwrap();
let ptr2 = heap.allocate(&mut mem, 9).unwrap();
let ptr3 = heap.allocate(&mut mem, 1).unwrap();
// then
// a prefix of 8 bytes is prepended to each pointer
assert_eq!(ptr1, to_pointer(HEADER_SIZE));
// the prefix of 8 bytes + the content of ptr1 padded to the lowest possible
// item size of 8 bytes + the prefix of ptr1
assert_eq!(ptr2, to_pointer(24));
// ptr2 + its content of 16 bytes + the prefix of 8 bytes
assert_eq!(ptr3, to_pointer(24 + 16 + HEADER_SIZE));
}
#[test]
fn should_free_properly() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
let ptr1 = heap.allocate(&mut mem, 1).unwrap();
// the prefix of 8 bytes is prepended to the pointer
assert_eq!(ptr1, to_pointer(HEADER_SIZE));
let ptr2 = heap.allocate(&mut mem, 1).unwrap();
// the prefix of 8 bytes + the content of ptr 1 is prepended to the pointer
assert_eq!(ptr2, to_pointer(24));
// when
heap.deallocate(&mut mem, ptr2).unwrap();
// then
// then the heads table should contain a pointer to the
// prefix of ptr2 in the leftmost entry
assert_eq!(heap.free_lists.heads[0], Link::Ptr(u32::from(ptr2) - HEADER_SIZE));
}
#[test]
fn should_deallocate_and_reallocate_properly() {
// given
let mut mem = MemoryInstance::with_pages(1);
let padded_offset = 16;
let mut heap = FreeingBumpHeapAllocator::new(13);
let ptr1 = heap.allocate(&mut mem, 1).unwrap();
// the prefix of 8 bytes is prepended to the pointer
assert_eq!(ptr1, to_pointer(padded_offset + HEADER_SIZE));
let ptr2 = heap.allocate(&mut mem, 9).unwrap();
// the padded_offset + the previously allocated ptr (8 bytes prefix +
// 8 bytes content) + the prefix of 8 bytes which is prepended to the
// current pointer
assert_eq!(ptr2, to_pointer(padded_offset + 16 + HEADER_SIZE));
// when
heap.deallocate(&mut mem, ptr2).unwrap();
let ptr3 = heap.allocate(&mut mem, 9).unwrap();
// then
// should have re-allocated
assert_eq!(ptr3, to_pointer(padded_offset + 16 + HEADER_SIZE));
assert_eq!(heap.free_lists.heads, [Link::Nil; N_ORDERS]);
}
#[test]
fn should_build_linked_list_of_free_areas_properly() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
let ptr1 = heap.allocate(&mut mem, 8).unwrap();
let ptr2 = heap.allocate(&mut mem, 8).unwrap();
let ptr3 = heap.allocate(&mut mem, 8).unwrap();
// when
heap.deallocate(&mut mem, ptr1).unwrap();
heap.deallocate(&mut mem, ptr2).unwrap();
heap.deallocate(&mut mem, ptr3).unwrap();
// then
assert_eq!(heap.free_lists.heads[0], Link::Ptr(u32::from(ptr3) - HEADER_SIZE));
let ptr4 = heap.allocate(&mut mem, 8).unwrap();
assert_eq!(ptr4, ptr3);
assert_eq!(heap.free_lists.heads[0], Link::Ptr(u32::from(ptr2) - HEADER_SIZE));
}
#[test]
fn should_not_allocate_if_too_large() {
// given
let mut mem = MemoryInstance::with_pages(1);
mem.set_max_wasm_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(13);
// when
let ptr = heap.allocate(&mut mem, PAGE_SIZE - 13);
// then
assert_eq!(Error::AllocatorOutOfSpace, ptr.unwrap_err());
}
#[test]
fn should_not_allocate_if_full() {
// given
let mut mem = MemoryInstance::with_pages(1);
mem.set_max_wasm_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
let ptr1 = heap.allocate(&mut mem, (PAGE_SIZE / 2) - HEADER_SIZE).unwrap();
assert_eq!(ptr1, to_pointer(HEADER_SIZE));
// when
let ptr2 = heap.allocate(&mut mem, PAGE_SIZE / 2);
// then
// there is no room for another half page incl. its 8 byte prefix
match ptr2.unwrap_err() {
Error::AllocatorOutOfSpace => {},
e => panic!("Expected allocator out of space error, got: {:?}", e),
}
}
#[test]
fn should_allocate_max_possible_allocation_size() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
// when
let ptr = heap.allocate(&mut mem, MAX_POSSIBLE_ALLOCATION).unwrap();
// then
assert_eq!(ptr, to_pointer(HEADER_SIZE));
}
#[test]
fn should_not_allocate_if_requested_size_too_large() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
// when
let ptr = heap.allocate(&mut mem, MAX_POSSIBLE_ALLOCATION + 1);
// then
assert_eq!(Error::RequestedAllocationTooLarge, ptr.unwrap_err());
}
#[test]
fn should_return_error_when_bumper_greater_than_heap_size() {
// given
let mut mem = MemoryInstance::with_pages(1);
mem.set_max_wasm_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(0);
let mut ptrs = Vec::new();
for _ in 0..(PAGE_SIZE as usize / 40) {
ptrs.push(heap.allocate(&mut mem, 32).expect("Allocate 32 byte"));
}
assert_eq!(heap.stats.bytes_allocated, PAGE_SIZE - 16);
assert_eq!(heap.bumper, PAGE_SIZE - 16);
ptrs.into_iter()
.for_each(|ptr| heap.deallocate(&mut mem, ptr).expect("Deallocate 32 byte"));
assert_eq!(heap.stats.bytes_allocated, 0);
assert_eq!(heap.stats.bytes_allocated_peak, PAGE_SIZE - 16);
assert_eq!(heap.bumper, PAGE_SIZE - 16);
// Allocate another 8 byte to use the full heap.
heap.allocate(&mut mem, 8).expect("Allocate 8 byte");
// when
// the `bumper` value is equal to `size` here and any
// further allocation which would increment the bumper must fail.
// we try to allocate 8 bytes here, which will increment the
// bumper since no 8 byte item has been freed before.
assert_eq!(heap.bumper as u64, mem.size());
let ptr = heap.allocate(&mut mem, 8);
// then
assert_eq!(Error::AllocatorOutOfSpace, ptr.unwrap_err());
}
#[test]
fn should_include_prefixes_in_total_heap_size() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(1);
// when
// an item size of 16 must be used then
heap.allocate(&mut mem, 9).unwrap();
// then
assert_eq!(heap.stats.bytes_allocated, HEADER_SIZE + 16);
}
#[test]
fn should_calculate_total_heap_size_to_zero() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(13);
// when
let ptr = heap.allocate(&mut mem, 42).unwrap();
assert_eq!(ptr, to_pointer(16 + HEADER_SIZE));
heap.deallocate(&mut mem, ptr).unwrap();
// then
assert_eq!(heap.stats.bytes_allocated, 0);
}
#[test]
fn should_calculate_total_size_of_zero() {
// given
let mut mem = MemoryInstance::with_pages(1);
let mut heap = FreeingBumpHeapAllocator::new(19);
// when
for _ in 1..10 {
let ptr = heap.allocate(&mut mem, 42).unwrap();
heap.deallocate(&mut mem, ptr).unwrap();
}
// then
assert_eq!(heap.stats.bytes_allocated, 0);
}
#[test]
fn should_read_and_write_u64_correctly() {
// given
let mut mem = MemoryInstance::with_pages(1);
// when
mem.write_le_u64(40, 4480113).unwrap();
// then
let value = MemoryExt::read_le_u64(&mut mem, 40).unwrap();
assert_eq!(value, 4480113);
}
#[test]
fn should_get_item_size_from_order() {
// given
let raw_order = 0;
// when
let item_size = Order::from_raw(raw_order).unwrap().size();
// then
assert_eq!(item_size, 8);
}