bkt
bkt
(pronounced "bucket") is a subprocess caching utility written in Rust,
inspired by bash-cache.
Wrapping expensive process invocations with bkt
allows callers to reuse recent
invocations without complicating their application logic. This can be useful in
shell prompts, interactive applications such as fzf
, and long-running
programs that poll other processes.
bkt
is available as a standalone binary as well as a
Rust library. See https://docs.rs/bkt/ for
library documentation. This README covers the bkt
binary.
Run cargo install bkt
to compile and install bkt
locally. You will need to
install cargo
if it's not already on your system.
Pre-compiled binaries for common platforms are attached to each release (starting with 0.5). Please open an issue or send a PR if you would like releases to include binaries for additional platforms.
Package manager support is being tracked here; volunteers are welcome.
bkt --ttl=DURATION [--stale=DURATION] [--cwd] [--env=ENV ...] [--modtime=FILE ...] [--scope=SCOPE] [--discard-failures] [--warm|--force] -- <command>...
bkt
is easy to start using - simply prefix the command you intend to cache
with bkt --ttl=[some duration] --
, for example:
# Execute and cache an invocation of 'date +%s.%N'
$ bkt --ttl=1m -- date +%s.%N
1631992417.080884000
# A subsequent invocation reuses the same cached output
$ bkt --ttl=1m -- date +%s.%N
1631992417.080884000
When bkt
is passed a command it hasn't seen before (or recently) it executes
the command synchronously and caches its stdout, stderr, and exit code. Calling
bkt
again with the same command reads the data from the cache and outputs it
as if the command had been run again.
Two flags, --ttl
and --stale
, configure how long cached data is preserved.
The TTL (Time to Live) specifies how long cached data will be used. Once the
TTL expires the cached data will be discarded and the backing command re-run.
A TTL can also be configured by setting a BKT_TTL
environment variable.
When the data expires bkt
has to re-execute the command synchronously, which
can introduce unexpected slowness. To avoid this, pass --stale
with a shorter
duration than the TTL. When the cached data is older than the stale threshold
this causes bkt
to refresh the cache in the background while still promptly
returning the cached data.
Both flags (and BKT_TTL
) accept duration strings such as 10s
or
1hour 30min
. The exact syntax is defined in the
humantime
library.
Some commands' behavior depends on more than just the command line arguments.
It's possible to adjust how bkt
caches such commands so that unrelated
invocations are cached separately.
For example, attempting to cache pwd
will not work as expected by default:
$ $ bkt --ttl=1m -- pwd
/tmp/foo
$ cd ../bar
# Cached output for 'pwd' is reused even though the directory has changed
$ bkt --ttl=1m -- pwd
/tmp/foo
To have bkt
key off the current working directory in addition to the command
line arguments pass --cwd
:
$ bkt --cwd --ttl=1m -- pwd
/tmp/foo
$ cd ../bar
$ bkt --cwd --ttl=1m -- pwd
/tmp/bar
Similarly, to specify one or more environment variables as relevant for the
command being cached use --env
, such as --env=LANG
. This flag can be
provided multiple times to key off additional variables. Invocations with
different values for any of the given variables will be cached separately.
bkt
can also check the last-modified time of one or more files and include
this in the cache key using --modtime
. For instance passing
--modtime=/etc/passwd
would cause the backing command to be re-executed any
time /etc/passwd
is modified even if the TTL has not expired.
It's also possible to trigger refreshes manually using --force
or --warm
.
The former behaves exactly as if the cached data was not found, executing the
process and caching the result. This is useful if you know the cached data
is no longer up-to-date, e.g. because something external changed.
Alternatively, it can be useful to refresh the cache asynchronously, which
--warm
provides. This triggers a refresh in the background but immediately
ends the current process with no output. This is useful if you expect
additional invocations in the near future and want to ensure they get a cache
hit. Note that until the warming process completes concurrent calls may still
see a cache miss and trigger their own invocation.
Cached data is persisted to disk (but see below), and is
available to any process that invokes bkt
. Generally this is desirable, but
certain usages may want to isolate their invocations from other potential
concurrent calls.
To do so pass --scope=...
with a sufficiently unique argument, such as a fixed
label for the calling program, the current process ID, or a timestamp.
$ bkt --ttl=1m -- date +%s.%N
1631992417.080884000
# Changing the scope causes the command to be cached separately
$ bkt --scope=foo --ttl=1m -- date +%s.%N
1631992418.010562000
Alternatively, define a BKT_SCOPE
environment variable to configure a
consistent scope across invocations. This can be useful within a script to
ensure all commands share a scope.
#!/bin/bash
# Set a unique scope for this script invocation using the PID and current time
export BKT_SCOPE="my_script_$$_$(date -Ins)"
By default, all invocations are cached regardless of their output or exit code.
In situations where failures should not be cached pass --discard-failures
to
only persist successful invocations (those that return a 0
exit code).
WARNING: Passing this flag can cause the backing command to be invoked more
frequently than the --ttl
would suggest, which in turn can create unexpected
load. If the backing command is failing due to an outage or bug (such as an
overloaded website) triggering additional calls can exacerbate the issue and
effectively DDoS the hampered system. It is generally safer not to set this
flag and instead make the client robust to occasional failures.
By default, cached data is stored under your system's temporary directory
(typically /tmp
on Linux).
You may want to use a different location for certain commands, for instance to
be able to easily delete the cached data as soon as it's no longer needed. You
can specify a custom cache directory via the --cache-dir
flag or by defining
a BKT_CACHE_DIR
environment variable.
Note that the choice of directory can affect bkt
's performance: if the cache
directory is on a tmpfs
or solid-state
partition it will be significantly faster than one using a spinning disk.
If your system's temporary directory is not a good choice for the default cache
location (e.g. it is not a tmpfs
) you can specify a different location by
defining a BKT_TMPDIR
environment variable (for example in your .bashrc
).
These two environment variables, BKT_TMPDIR
and BKT_CACHE_DIR
, have similar
effects but BKT_TMPDIR
should be used to configure the system-wide default,
and --cache-dir
/BKT_CACHE_DIR
used to override it.
bkt
periodically prunes stale data from its cache, but it also assumes the
operating system will empty its temporary storage from time to time (for /tmp
this typically happens on reboot). If you opt to use a directory that the
system does not maintain, such as ~/.cache
, you may want to manually delete
the cache directory on occasion, such as when upgrading bkt
.
The default cache directory is potentially world-readable. On Unix the cache
directory is created with 700
permissions, meaning only the current user can
access it, but this is not foolproof.
You can customize the cache directory (see above) to a location
you trust such as ~/.cache
, but note that your home directory may be slower than
the temporary directory selected by default.
In general, if you are not the only user of your system it's wise to configure
your TMPDIR
to a location only you can access. If that is not possible use
BKT_TMPDIR
to configure a custom temporary directory specifically for bkt
.
Please share how you're using bkt
on the
Discussion Board!
fzf
and other preview toolsbkt
works well with interactive tools like
fzf
that execute other commands. Because
fzf
executes the --preview
command every time an element is selected it can
be slow and tedious to browse when the command takes a long time to run. Using
bkt
allows each selection's preview to be cached. Compare:
$ printf '%s\n' 1 0.2 3 0.1 5 | \
fzf --preview="bash -c 'sleep {}; echo {}'"
$ printf '%s\n' 1 0.2 3 0.1 5 | \
fzf --preview="bkt --ttl=10m --stale=10s -- bash -c 'sleep {}; echo {}'"
You'll generally want to use a long TTL and a short stale duration so that
even if you leave fzf
running for a while the cache remains warm and is
refreshed in the background. You may also want to set a --scope
if it's
important to invalidate the cache on subsequent invocations.
See this discussion for a more
complete example of using bkt
with fzf
, including warming the commands before
the user starts navigating the selector.
bkt
only if installedYou may want to distribute shell scripts that utilize bkt
without requiring
every user also install bkt
. By wrapping bkt
in a shell function your script
can cleanly invoke bkt
if available without complicating your users' workflow.
Of course if they choose to install bkt
they'll get a faster script as a
result!
# Cache commands using bkt if installed
if command -v bkt >&/dev/null; then
bkt() { command bkt "$@"; }
else
# If bkt isn't installed skip its arguments and just execute directly.
# Optionally write a msg to stderr suggesting users install bkt.
bkt() {
while [[ "$1" == --* ]]; do shift; done
"$@"
}
fi
# Now you can call bkt (the function) just like you'd call bkt (the binary):
bkt --ttl=1m -- expensive_cmd ...
bkt
in shell scriptsIt is sometimes helpful to cache all invocations of a command in a shell script or in your shell environment. You can use a decorator function pattern similar to what bash-cache does to enable caching transparently, like so:
# This is Bash syntax, but other shells support similar syntax
expensive_cmd() {
bkt [bkt args ...] -- expensive_cmd "$@"
}
Calls to expensive_cmd
in your shell will now go through bkt
behind the
scenes. This can be useful for brevity and consistency but obviously changing
behavior like this is a double-edged-sword, so use with caution. Should you
need to bypass the cache for a single invocation Bash provides the
command
builtin,
so command expensive_cmd ...
will invoke expensive_cmd
directly. Other
shells provide similar features.