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|
use async_trait::async_trait;
use std::collections::BinaryHeap;
use std::future::Future;
#[repr(u8)]
enum WALRingType {
#[allow(dead_code)]
Null = 0x0,
Full,
First,
Middle,
Last,
}
#[repr(packed)]
struct WALRingBlob {
crc32: u32,
rsize: u32,
rtype: WALRingType,
// payload follows
}
pub type WALBytes = Box<[u8]>;
pub type WALFileId = u64;
pub type WALPos = u64;
#[derive(Eq, PartialEq, Copy, Clone, Debug, Hash)]
pub struct WALRingId {
start: WALPos,
end: WALPos,
}
impl WALRingId {
pub fn empty_id() -> Self {
WALRingId { start: 0, end: 0 }
}
pub fn get_start(&self) -> WALPos {
self.start
}
pub fn get_end(&self) -> WALPos {
self.end
}
}
impl Ord for WALRingId {
fn cmp(&self, other: &WALRingId) -> std::cmp::Ordering {
other
.start
.cmp(&self.start)
.then_with(|| other.end.cmp(&self.end))
}
}
impl PartialOrd for WALRingId {
fn partial_cmp(&self, other: &WALRingId) -> Option<std::cmp::Ordering> {
Some(self.cmp(other))
}
}
/// the state for a WAL writer
struct WALState {
/// the first file id of WAL
first_fid: WALFileId,
/// the next position for a record, addressed in the entire WAL space
next: WALPos,
/// number of bits for a file
file_nbit: u64,
}
#[async_trait(?Send)]
pub trait WALFile {
/// Initialize the file space in [offset, offset + length) to zero.
async fn allocate(&self, offset: WALPos, length: usize) -> Result<(), ()>;
/// Truncate a file to a specified length.
fn truncate(&self, length: usize) -> Result<(), ()>;
/// Write data with offset. We assume the actual writes on the storage medium are _strictly
/// ordered_ the same way as this callback is invoked. We also assume all previous
/// `allocate/truncate` invocation should be visible if ordered earlier (should be guaranteed
/// by most OS). Additionally, the final write caused by each invocation of this function
/// should be _atomic_ (the entire single write should be all or nothing).
async fn write(&self, offset: WALPos, data: WALBytes) -> Result<(), ()>;
/// Read data with offset. Return Ok(None) when it reaches EOF.
fn read(
&self,
offset: WALPos,
length: usize,
) -> Result<Option<WALBytes>, ()>;
}
pub trait WALStore {
type FileNameIter: Iterator<Item = String>;
/// Open a file given the filename, create the file if not exists when `touch` is `true`.
fn open_file(
&mut self,
filename: &str,
touch: bool,
) -> Result<Box<dyn WALFile>, ()>;
/// Unlink a file given the filename.
fn remove_file(&mut self, filename: &str) -> Result<(), ()>;
/// Enumerate all WAL filenames. It should include all WAL files that are previously opened
/// (created) but not removed. The list could be unordered.
fn enumerate_files(&self) -> Result<Self::FileNameIter, ()>;
/// Apply the payload during recovery. An invocation of the callback waits the application for
/// redoing the given operation to ensure its state is consistent. We assume the necessary
/// changes by the payload has already been persistent when the callback returns.
fn apply_payload(
&mut self,
payload: WALBytes,
ringid: WALRingId,
) -> Result<(), ()>;
}
/// The middle layer that manages WAL file handles and invokes public trait functions to actually
/// manipulate files and their contents.
struct WALFilePool<F: WALStore> {
store: F,
handles: lru::LruCache<WALFileId, Box<dyn WALFile>>,
file_nbit: u64,
file_size: u64,
block_nbit: u64,
}
impl<F: WALStore> WALFilePool<F> {
fn new(store: F, file_nbit: u8, block_nbit: u8, cache_size: usize) -> Self {
let file_nbit = file_nbit as u64;
let block_nbit = block_nbit as u64;
WALFilePool {
store,
handles: lru::LruCache::new(cache_size),
file_nbit,
file_size: 1 << (file_nbit as u64),
block_nbit,
}
}
fn get_fname(fid: WALFileId) -> String {
format!("{:08x}.log", fid)
}
fn get_file(
&mut self,
fid: u64,
touch: bool,
) -> Result<&'static dyn WALFile, ()> {
let h = match self.handles.get(&fid) {
Some(h) => &**h,
None => {
self.handles.put(
fid,
self.store.open_file(&Self::get_fname(fid), touch)?,
);
&**self.handles.get(&fid).unwrap()
}
};
Ok(unsafe { &*(h as *const dyn WALFile) })
}
fn get_fid(&mut self, fname: &str) -> WALFileId {
scan_fmt!(fname, "{x}.log", [hex WALFileId]).unwrap()
}
// TODO: evict stale handles
async fn write(&mut self, writes: Vec<(WALPos, WALBytes)>) -> Result<(), ()> {
// pre-allocate the file space
let mut fid = writes[0].0 >> self.file_nbit;
let mut alloc_start = writes[0].0 & (self.file_size - 1);
let mut alloc_end = alloc_start + writes[0].1.len() as u64;
let files = writes
.iter()
.map(|(off, _)| self.get_file((*off) >> self.file_nbit, true))
.collect::<Result<Vec<&dyn WALFile>, ()>>()?;
// prepare file handles
let mut last_h = files[0];
for ((off, w), h) in writes[1..].iter().zip(files[1..].iter()) {
let next_fid = off >> self.file_nbit;
if next_fid != fid {
last_h.allocate(
alloc_start,
(alloc_end - alloc_start) as usize,
).await?;
last_h = *h;
alloc_start = 0;
alloc_end = alloc_start + w.len() as u64;
fid = next_fid;
} else {
alloc_end += w.len() as u64;
}
}
last_h.allocate(alloc_start, (alloc_end - alloc_start) as usize).await?;
for (off, w) in writes.into_iter() {
self.get_file(off >> self.file_nbit, true)?
.write(off & (self.file_size - 1), w).await?;
}
Ok(())
}
fn remove_file(&mut self, fid: u64) -> Result<(), ()> {
self.store.remove_file(&Self::get_fname(fid))
}
fn reset(&mut self) {
self.handles.clear()
}
}
pub struct WALWriter<F: WALStore> {
state: WALState,
file_pool: WALFilePool<F>,
block_buffer: WALBytes,
block_size: u32,
next_complete: WALPos,
io_complete: BinaryHeap<WALRingId>,
msize: usize,
}
impl<F: WALStore> WALWriter<F> {
fn new(state: WALState, file_pool: WALFilePool<F>) -> Self {
let mut b = Vec::new();
let block_size = 1 << file_pool.block_nbit as u32;
let msize = std::mem::size_of::<WALRingBlob>();
b.resize(block_size as usize, 0);
WALWriter {
state,
file_pool,
block_buffer: b.into_boxed_slice(),
block_size,
next_complete: 0,
io_complete: BinaryHeap::new(),
msize,
}
}
/// Submit a sequence of records to WAL; WALStore/WALFile callbacks are invoked before the
/// function returns. The caller then has the knowledge of WAL writes so it should defer
/// actual data writes after WAL writes.
pub fn grow<'a, T: AsRef<[WALBytes]>>(
&'a mut self,
records: T,
) -> (Box<[WALRingId]>, impl Future<Output = Result<(), ()>> + 'a) {
let mut res = Vec::new();
let mut writes = Vec::new();
let msize = self.msize as u32;
// the global offest of the begining of the block
// the start of the unwritten data
let mut bbuff_start = self.state.next as u32 & (self.block_size - 1);
// the end of the unwritten data
let mut bbuff_cur = bbuff_start;
for _rec in records.as_ref() {
let mut rec = &_rec[..];
let mut rsize = rec.len() as u32;
let mut ring_start = None;
while rsize > 0 {
let remain = self.block_size - bbuff_cur;
if remain > msize {
let d = remain - msize;
let rs0 =
self.state.next + (bbuff_cur - bbuff_start) as u64;
let blob = unsafe {
std::mem::transmute::<*mut u8, &mut WALRingBlob>(
(&mut self.block_buffer[bbuff_cur as usize..])
.as_mut_ptr(),
)
};
bbuff_cur += msize;
if d >= rsize {
// the remaining rec fits in the block
let payload = rec;
blob.crc32 = crc::crc32::checksum_ieee(payload);
blob.rsize = rsize;
let (rs, rt) = if let Some(rs) = ring_start.take() {
(rs, WALRingType::Last)
} else {
(rs0, WALRingType::Full)
};
blob.rtype = rt;
&mut self.block_buffer[bbuff_cur as usize..
bbuff_cur as usize + payload.len()]
.copy_from_slice(payload);
bbuff_cur += rsize;
rsize = 0;
let end =
self.state.next + (bbuff_cur - bbuff_start) as u64;
res.push(WALRingId { start: rs, end });
} else {
// the remaining block can only accommodate partial rec
let payload = &rec[..d as usize];
blob.crc32 = crc::crc32::checksum_ieee(payload);
blob.rsize = d;
blob.rtype = if ring_start.is_some() {
WALRingType::Middle
} else {
ring_start = Some(rs0);
WALRingType::First
};
&mut self.block_buffer[bbuff_cur as usize..
bbuff_cur as usize + payload.len()]
.copy_from_slice(payload);
bbuff_cur += d;
rsize -= d;
rec = &rec[d as usize..];
}
} else {
// add padding space by moving the point to the end of the block
bbuff_cur = self.block_size;
}
if bbuff_cur == self.block_size {
writes.push((
self.state.next,
self.block_buffer[bbuff_start as usize..]
.to_vec()
.into_boxed_slice(),
));
self.state.next += (self.block_size - bbuff_start) as u64;
bbuff_start = 0;
bbuff_cur = 0;
}
}
}
if bbuff_cur > bbuff_start {
writes.push((
self.state.next,
self.block_buffer[bbuff_start as usize..bbuff_cur as usize]
.to_vec()
.into_boxed_slice(),
));
self.state.next += (bbuff_cur - bbuff_start) as u64;
}
(res.into_boxed_slice(), self.file_pool.write(writes))
}
/// Inform the WALWriter that data writes (specified by a slice of (offset, length) tuples) are
/// complete so that it could automatically remove obsolete WAL files.
pub fn peel<T: AsRef<[WALRingId]>>(
&mut self,
records: T,
) -> Result<(), ()> {
let msize = self.msize as u64;
let block_size = self.block_size as u64;
for rec in records.as_ref() {
self.io_complete.push(*rec);
}
let orig_fid = self.state.first_fid;
while let Some(s) = self.io_complete.peek().and_then(|&e| Some(e.start))
{
if s != self.next_complete {
break;
}
let mut m = self.io_complete.pop().unwrap();
let block_remain = block_size - (m.end & (block_size - 1));
if block_remain <= msize as u64 {
m.end += block_remain
}
self.next_complete = m.end
}
let next_fid = self.next_complete >> self.state.file_nbit;
for fid in orig_fid..next_fid {
self.file_pool.remove_file(fid)?;
}
self.state.first_fid = next_fid;
Ok(())
}
}
pub struct WALLoader {
file_nbit: u8,
block_nbit: u8,
cache_size: usize,
msize: usize,
filename_fmt: regex::Regex,
}
impl WALLoader {
pub fn new(file_nbit: u8, block_nbit: u8, cache_size: usize) -> Self {
let msize = std::mem::size_of::<WALRingBlob>();
assert!(file_nbit > block_nbit);
assert!(msize < 1 << block_nbit);
let filename_fmt = regex::Regex::new(r"[0-9a-f]+\.log").unwrap();
WALLoader {
file_nbit,
block_nbit,
cache_size,
msize,
filename_fmt,
}
}
/// Recover by reading the WAL log files.
pub fn recover<F: WALStore>(self, store: F) -> Result<WALWriter<F>, ()> {
let mut file_pool = WALFilePool::new(
store,
self.file_nbit,
self.block_nbit,
self.cache_size,
);
let block_size = 1 << file_pool.block_nbit;
let msize = self.msize as u32;
let mut logfiles: Vec<String> = file_pool
.store
.enumerate_files()?
.filter(|f| self.filename_fmt.is_match(f))
.collect();
// TODO: check for missing logfiles
logfiles.sort();
let mut chunks = None;
for fname in logfiles.iter() {
let fid = file_pool.get_fid(fname);
let f = file_pool.get_file(fid, false)?;
let mut off = 0;
while let Some(header_raw) = f.read(off, msize as usize)? {
let ringid_start = (fid << file_pool.file_nbit) + off;
off += msize as u64;
let header = unsafe {
std::mem::transmute::<*const u8, &WALRingBlob>(
header_raw.as_ptr(),
)
};
let rsize = header.rsize;
match header.rtype {
WALRingType::Full => {
assert!(chunks.is_none());
let payload = f.read(off, rsize as usize)?.ok_or(())?;
off += rsize as u64;
file_pool.store.apply_payload(
payload,
WALRingId {
start: ringid_start,
end: (fid << file_pool.file_nbit) + off,
},
)?;
}
WALRingType::First => {
assert!(chunks.is_none());
chunks = Some((
vec![f.read(off, rsize as usize)?.ok_or(())?],
ringid_start,
));
off += rsize as u64;
}
WALRingType::Middle => {
if let Some((chunks, _)) = &mut chunks {
chunks
.push(f.read(off, rsize as usize)?.ok_or(())?);
} // otherwise ignore the leftover
off += rsize as u64;
}
WALRingType::Last => {
if let Some((mut chunks, ringid_start)) = chunks.take()
{
chunks
.push(f.read(off, rsize as usize)?.ok_or(())?);
off += rsize as u64;
let mut payload = Vec::new();
payload.resize(
chunks.iter().fold(0, |acc, v| acc + v.len()),
0,
);
let mut ps = &mut payload[..];
for c in chunks {
ps[..c.len()].copy_from_slice(&*c);
ps = &mut ps[c.len()..];
}
file_pool.store.apply_payload(
payload.into_boxed_slice(),
WALRingId {
start: ringid_start,
end: (fid << file_pool.file_nbit) + off,
},
)?;
}
// otherwise ignore the leftover
else {
off += rsize as u64;
}
}
WALRingType::Null => break,
}
let block_remain = block_size - (off & (block_size - 1));
if block_remain <= msize as u64 {
off += block_remain;
}
}
f.truncate(0)?;
file_pool.remove_file(fid)?;
}
file_pool.reset();
Ok(WALWriter::new(
WALState {
first_fid: 0,
next: 0,
file_nbit: file_pool.file_nbit,
},
file_pool,
))
}
}
|