moonfire-nvr/server/db/dir/reader.rs

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// This file is part of Moonfire NVR, a security camera network video recorder.
// Copyright (C) 2021 The Moonfire NVR Authors; see AUTHORS and LICENSE.txt.
// SPDX-License-Identifier: GPL-v3.0-or-later WITH GPL-3.0-linking-exception
//! Reads sample files in a dedicated thread.
//!
//! Typically sample files are on spinning disk where IO operations take
//! ~10 ms on success. When disks fail, operations can stall for arbitrarily
//! long. POSIX doesn't have good support for asynchronous disk IO,
//! so it's desirable to do this from a dedicated thread for each disk rather
//! than stalling the tokio IO threads or (as when using `tokio::fs`) creating
//! unbounded numbers of workers.
//!
//! This also has some minor theoretical efficiency advantages over
//! `tokio::fs::File`:
//! * it uses `mmap`, which means fewer system calls and a somewhat faster
//! userspace `memcpy` implementation (see [Why mmap is faster than system
//! calls](https://sasha-f.medium.com/why-mmap-is-faster-than-system-calls-24718e75ab37).)
//! * it has fewer thread handoffs because it batches operations on open
//! (open, fstat, mmap, madvise, close, memcpy first chunk) and close
//! (memcpy last chunk, munmap).
use std::convert::TryFrom;
use std::future::Future;
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use std::os::unix::prelude::AsRawFd;
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use std::path::Path;
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use std::{
ops::Range,
pin::Pin,
sync::Arc,
task::{Context, Poll},
};
use base::bail_t;
use base::clock::{RealClocks, TimerGuard};
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use base::{format_err_t, Error, ErrorKind, ResultExt};
use nix::{fcntl::OFlag, sys::stat::Mode};
use crate::CompositeId;
/// Handle for a reader thread, used to send it commands.
///
/// The reader will shut down after the last handle is closed.
#[derive(Clone, Debug)]
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pub(super) struct Reader(tokio::sync::mpsc::UnboundedSender<ReaderCommand>);
impl Reader {
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pub(super) fn spawn(path: &Path, dir: Arc<super::Fd>) -> Self {
let (tx, rx) = tokio::sync::mpsc::unbounded_channel();
let page_size = usize::try_from(
nix::unistd::sysconf(nix::unistd::SysconfVar::PAGE_SIZE)
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.expect("PAGE_SIZE fetch must succeed")
.expect("PAGE_SIZE must be defined"),
)
.expect("PAGE_SIZE fits in usize");
assert_eq!(page_size.count_ones(), 1, "invalid page size {}", page_size);
std::thread::Builder::new()
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.name(format!("r-{}", path.display()))
.spawn(move || ReaderInt { dir, page_size }.run(rx))
.expect("unable to create reader thread");
Self(tx)
}
pub(super) fn open_file(&self, composite_id: CompositeId, range: Range<u64>) -> FileStream {
if range.is_empty() {
return FileStream {
state: FileStreamState::Invalid,
reader: Reader(self.0.clone()),
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};
}
let (tx, rx) = tokio::sync::oneshot::channel();
self.send(ReaderCommand::OpenFile {
composite_id,
range,
tx,
});
FileStream {
state: FileStreamState::Reading(rx),
reader: Reader(self.0.clone()),
}
}
fn send(&self, cmd: ReaderCommand) {
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self.0
.send(cmd)
.map_err(|_| ())
.expect("reader thread panicked; see logs.");
}
}
pub struct FileStream {
state: FileStreamState,
reader: Reader,
}
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type ReadReceiver = tokio::sync::oneshot::Receiver<Result<SuccessfulRead, Error>>;
enum FileStreamState {
Idle(OpenFile),
Reading(ReadReceiver),
Invalid,
}
impl FileStream {
/// Helper for reading during `poll_next`.
fn read(
mut self: Pin<&mut Self>,
cx: &mut Context<'_>,
mut rx: ReadReceiver,
) -> Poll<Option<Result<Vec<u8>, Error>>> {
match Pin::new(&mut rx).poll(cx) {
Poll::Ready(Err(_)) => {
self.state = FileStreamState::Invalid;
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Poll::Ready(Some(Err(format_err_t!(
Internal,
"reader thread panicked; see logs"
))))
}
Poll::Ready(Ok(Err(e))) => {
self.state = FileStreamState::Invalid;
Poll::Ready(Some(Err(e)))
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}
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Poll::Ready(Ok(Ok(SuccessfulRead {
chunk,
file: Some(file),
}))) => {
self.state = FileStreamState::Idle(file);
Poll::Ready(Some(Ok(chunk)))
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}
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Poll::Ready(Ok(Ok(SuccessfulRead { chunk, file: None }))) => {
self.state = FileStreamState::Invalid;
Poll::Ready(Some(Ok(chunk)))
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}
Poll::Pending => {
self.state = FileStreamState::Reading(rx);
Poll::Pending
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}
}
}
}
impl futures::stream::Stream for FileStream {
type Item = Result<Vec<u8>, Error>;
fn poll_next(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
match std::mem::replace(&mut self.state, FileStreamState::Invalid) {
FileStreamState::Idle(file) => {
let (tx, rx) = tokio::sync::oneshot::channel();
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self.reader.send(ReaderCommand::ReadNextChunk { file, tx });
// Try reading right away. It probably will return pending, but Receiver
// needs to see the waker.
self.read(cx, rx)
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}
FileStreamState::Reading(rx) => self.read(cx, rx),
FileStreamState::Invalid => Poll::Ready(None),
}
}
}
impl Drop for FileStream {
fn drop(&mut self) {
use FileStreamState::{Idle, Invalid};
if let Idle(file) = std::mem::replace(&mut self.state, Invalid) {
// This will succeed unless reader has panicked. If that happened,
// the logfiles will be loud anyway; no need to add additional
// error messages.
let _ = self.reader.0.send(ReaderCommand::CloseFile(file));
}
}
}
/// An open, `mmap()`ed file.
///
/// This is only actually used by the reader thread, but ownership is passed
/// around between it and the [FileStream] to avoid maintaining extra data
/// structures.
struct OpenFile {
composite_id: CompositeId,
/// The memory-mapped region backed by the file. Valid up to length `map_len`.
map_ptr: *mut libc::c_void,
/// The position within the memory mapping. Invariant: `map_pos < map_len`.
map_pos: usize,
/// The length of the memory mapping. This may be less than the length of
/// the file.
map_len: usize,
}
// Rust makes us manually state these because of the `*mut` ptr above.
unsafe impl Send for OpenFile {}
unsafe impl Sync for OpenFile {}
impl Drop for OpenFile {
fn drop(&mut self) {
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if let Err(e) =
unsafe { nix::sys::mman::munmap(self.map_ptr as *mut std::ffi::c_void, self.map_len) }
{
// This should never happen.
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log::error!(
"unable to munmap {}, {:?} len {}: {}",
self.composite_id,
self.map_ptr,
self.map_len,
e
);
}
}
}
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struct SuccessfulRead {
chunk: Vec<u8>,
/// If this is not the final requested chunk, the `OpenFile` for next time.
file: Option<OpenFile>,
}
enum ReaderCommand {
/// Opens a file and reads the first chunk.
OpenFile {
composite_id: CompositeId,
range: std::ops::Range<u64>,
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tx: tokio::sync::oneshot::Sender<Result<SuccessfulRead, Error>>,
},
/// Reads the next chunk of the file.
ReadNextChunk {
file: OpenFile,
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tx: tokio::sync::oneshot::Sender<Result<SuccessfulRead, Error>>,
},
/// Closes the file early, as when the [FileStream] is dropped before completing.
CloseFile(OpenFile),
}
struct ReaderInt {
/// File descriptor of the sample file directory.
dir: Arc<super::Fd>,
/// The page size as returned by `sysconf`; guaranteed to be a power of two.
page_size: usize,
}
impl ReaderInt {
fn run(self, mut rx: tokio::sync::mpsc::UnboundedReceiver<ReaderCommand>) {
while let Some(cmd) = rx.blocking_recv() {
// OpenFile's Drop implementation takes care of closing the file on error paths and
// the CloseFile operation.
match cmd {
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ReaderCommand::OpenFile {
composite_id,
range,
tx,
} => {
if tx.is_closed() {
// avoid spending effort on expired commands
continue;
}
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let _guard =
TimerGuard::new(&RealClocks {}, || format!("open {}", composite_id));
let _ = tx.send(self.open(composite_id, range));
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}
ReaderCommand::ReadNextChunk { file, tx } => {
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if tx.is_closed() {
// avoid spending effort on expired commands
continue;
}
let composite_id = file.composite_id;
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let _guard =
TimerGuard::new(&RealClocks {}, || format!("read from {}", composite_id));
let _ = tx.send(Ok(self.chunk(file)));
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}
ReaderCommand::CloseFile(_) => {}
}
}
}
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fn open(&self, composite_id: CompositeId, range: Range<u64>) -> Result<SuccessfulRead, Error> {
let p = super::CompositeIdPath::from(composite_id);
// Reader::open_file checks for an empty range, but check again right
// before the unsafe block to make it easier to audit the safety constraints.
assert!(range.start < range.end);
// mmap offsets must be aligned to page size boundaries.
let unaligned = (range.start as usize) & (self.page_size - 1);
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let offset = libc::off_t::try_from(range.start).expect("range.start fits in off_t")
- libc::off_t::try_from(unaligned).expect("usize fits in off_t");
// Recordings from very high bitrate streams could theoretically exceed exhaust a 32-bit
// machine's address space, causing either this usize::MAX error or mmap
// failure. If that happens in practice, we'll have to stop mmap()ing
// the whole range.
let map_len = usize::try_from(
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range.end - range.start + u64::try_from(unaligned).expect("usize fits in u64"),
)
.map_err(|_| {
format_err_t!(
OutOfRange,
"file {}'s range {:?} len exceeds usize::MAX",
composite_id,
range
)
})?;
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let map_len = std::num::NonZeroUsize::new(map_len).expect("range is non-empty");
let file = crate::fs::openat(self.dir.0, &p, OFlag::O_RDONLY, Mode::empty())
.err_kind(ErrorKind::Unknown)?;
// Check the actual on-disk file length. It's an error (a bug or filesystem corruption)
// for it to be less than the requested read. Check for this now rather than crashing
// with a SIGBUS or reading bad data at the end of the last page later.
let metadata = file.metadata().err_kind(ErrorKind::Unknown)?;
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if metadata.len() < u64::try_from(offset).unwrap() + u64::try_from(map_len.get()).unwrap() {
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bail_t!(
Internal,
"file {}, range {:?}, len {}",
composite_id,
range,
metadata.len()
);
}
let map_ptr = unsafe {
nix::sys::mman::mmap(
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None,
map_len,
nix::sys::mman::ProtFlags::PROT_READ,
nix::sys::mman::MapFlags::MAP_SHARED,
file.as_raw_fd(),
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offset,
)
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}
.map_err(|e| {
format_err_t!(
Internal,
"mmap failed for {} off={} len={}: {}",
composite_id,
offset,
map_len,
e
)
})?;
if let Err(e) = unsafe {
nix::sys::mman::madvise(
map_ptr as *mut libc::c_void,
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map_len.get(),
nix::sys::mman::MmapAdvise::MADV_SEQUENTIAL,
)
} {
// This shouldn't happen but is "just" a performance problem.
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log::warn!(
"madvise(MADV_SEQUENTIAL) failed for {} off={} len={}: {}",
composite_id,
offset,
map_len,
e
);
}
Ok(self.chunk(OpenFile {
composite_id,
map_ptr,
map_pos: unaligned,
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map_len: map_len.get(),
}))
}
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fn chunk(&self, mut file: OpenFile) -> SuccessfulRead {
// Read a chunk that's large enough to minimize thread handoffs but
// short enough to keep memory usage under control. It's hopefully
// unnecessary to worry about disk seeks; the madvise call should cause
// the kernel to read ahead.
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let end = std::cmp::min(file.map_len, file.map_pos.saturating_add(1 << 16));
let mut chunk = Vec::new();
let len = end.checked_sub(file.map_pos).unwrap();
chunk.reserve_exact(len);
// SAFETY: [map_pos, map_pos + len) is verified to be within map_ptr.
//
// If the read is out of bounds of the file, we'll get a SIGBUS.
// That's not a safety violation. It also shouldn't happen because the
// length was set properly at open time, Moonfire NVR is a closed
// system (nothing else ever touches its files), and sample files are
// never truncated (only appended to or unlinked).
unsafe {
std::ptr::copy_nonoverlapping(
file.map_ptr.add(file.map_pos) as *const u8,
chunk.as_mut_ptr(),
len,
);
chunk.set_len(len);
}
let file = if end == file.map_len {
None
} else {
file.map_pos = end;
Some(file)
};
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SuccessfulRead { chunk, file }
}
}
#[cfg(test)]
mod tests {
use futures::TryStreamExt;
#[tokio::test]
async fn basic() {
crate::testutil::init();
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let tmpdir = tempfile::Builder::new()
.prefix("moonfire-db-test-reader")
.tempdir()
.unwrap();
let fd = std::sync::Arc::new(super::super::Fd::open(tmpdir.path(), false).unwrap());
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let reader = super::Reader::spawn(tmpdir.path(), fd);
std::fs::write(tmpdir.path().join("0123456789abcdef"), b"blah blah").unwrap();
let f = reader.open_file(crate::CompositeId(0x01234567_89abcdef), 1..8);
assert_eq!(f.try_concat().await.unwrap(), b"lah bla");
}
}