##// END OF EJS Templates
revlog: add a mechanism to verify expected file position before appending...
revlog: add a mechanism to verify expected file position before appending If someone uses `hg debuglocks`, or some non-hg process writes to the .hg directory without respecting the locks, or if the repo's on a networked filesystem, it's possible for the revlog code to write out corrupted data. The form of this corruption can vary depending on what data was written and how that happened. We are in the "networked filesystem" case (though I've had users also do this to themselves with the "`hg debuglocks`" scenario), and most often see this with the changelog. What ends up happening is we produce two items (let's call them rev1 and rev2) in the .i file that have the same linkrev, baserev, and offset into the .d file, while the data in the .d file is appended properly. rev2's compressed_size is accurate for rev2, but when we go to decompress the data in the .d file, we use the offset that's recorded in the index file, which is the same as rev1, and attempt to decompress rev2.compressed_size bytes of rev1's data. This usually does not succeed. :) When using inline data, this also fails, though I haven't investigated why too closely. This shows up as a "patch decode" error. I believe what's happening there is that we're basically ignoring the offset field, getting the data properly, but since baserev != rev, it thinks this is a delta based on rev (instead of a full text) and can't actually apply it as such. For now, I'm going to make this an optional component and default it to entirely off. I may increase the default severity of this in the future, once I've enabled it for my users and we gain more experience with it. Luckily, most of my users have a versioned filesystem and can roll back to before the corruption has been written, it's just a hassle to do so and not everyone knows how (so it's a support burden). Users on other filesystems will not have that luxury, and this can cause them to have a corrupted repository that they are unlikely to know how to resolve, and they'll see this as a data-loss event. Refusing to create the corruption is a much better user experience. This mechanism is not perfect. There may be false-negatives (racy writes that are not detected). There should not be any false-positives (non-racy writes that are detected as such). This is not a mechanism that makes putting a repo on a networked filesystem "safe" or "supported", just *less* likely to cause corruption. Differential Revision: https://phab.mercurial-scm.org/D9952

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logging.rs
101 lines | 3.6 KiB | application/rls-services+xml | RustLexer
use crate::errors::{HgError, HgResultExt, IoErrorContext, IoResultExt};
use crate::repo::Vfs;
use std::io::Write;
/// An utility to append to a log file with the given name, and optionally
/// rotate it after it reaches a certain maximum size.
///
/// Rotation works by renaming "example.log" to "example.log.1", after renaming
/// "example.log.1" to "example.log.2" etc up to the given maximum number of
/// files.
pub struct LogFile<'a> {
vfs: Vfs<'a>,
name: &'a str,
max_size: Option<u64>,
max_files: u32,
}
impl<'a> LogFile<'a> {
pub fn new(vfs: Vfs<'a>, name: &'a str) -> Self {
Self {
vfs,
name,
max_size: None,
max_files: 0,
}
}
/// Rotate before writing to a log file that was already larger than the
/// given size, in bytes. `None` disables rotation.
pub fn max_size(mut self, value: Option<u64>) -> Self {
self.max_size = value;
self
}
/// Keep this many rotated files `{name}.1` up to `{name}.{max}`, in
/// addition to the original `{name}` file.
pub fn max_files(mut self, value: u32) -> Self {
self.max_files = value;
self
}
/// Append the given `bytes` as-is to the log file, after rotating if
/// needed.
///
/// No trailing newline is added. Make sure to include one in `bytes` if
/// desired.
pub fn write(&self, bytes: &[u8]) -> Result<(), HgError> {
let path = self.vfs.join(self.name);
let context = || IoErrorContext::WritingFile(path.clone());
let open = || {
std::fs::OpenOptions::new()
.create(true)
.append(true)
.open(&path)
.with_context(context)
};
let mut file = open()?;
if let Some(max_size) = self.max_size {
if file.metadata().with_context(context)?.len() >= max_size {
// For example with `max_files == 5`, the first iteration of
// this loop has `i == 4` and renames `{name}.4` to `{name}.5`.
// The last iteration renames `{name}.1` to
// `{name}.2`
for i in (1..self.max_files).rev() {
self.vfs
.rename(
format!("{}.{}", self.name, i),
format!("{}.{}", self.name, i + 1),
)
.io_not_found_as_none()?;
}
// Then rename `{name}` to `{name}.1`. This is the
// previously-opened `file`.
self.vfs
.rename(self.name, format!("{}.1", self.name))
.io_not_found_as_none()?;
// Finally, create a new `{name}` file and replace our `file`
// handle.
file = open()?;
}
}
file.write_all(bytes).with_context(context)?;
file.sync_all().with_context(context)
}
}
#[test]
fn test_rotation() {
let temp = tempfile::tempdir().unwrap();
let vfs = Vfs { base: temp.path() };
let logger = LogFile::new(vfs, "log").max_size(Some(3)).max_files(2);
logger.write(b"one\n").unwrap();
logger.write(b"two\n").unwrap();
logger.write(b"3\n").unwrap();
logger.write(b"four\n").unwrap();
logger.write(b"five\n").unwrap();
assert_eq!(vfs.read("log").unwrap(), b"five\n");
assert_eq!(vfs.read("log.1").unwrap(), b"3\nfour\n");
assert_eq!(vfs.read("log.2").unwrap(), b"two\n");
assert!(vfs.read("log.3").io_not_found_as_none().unwrap().is_none());
}