Awesome
zsh-bench
Benchmark for interactive zsh.
Summary
zsh-bench
measures user-visible latency of interactive zsh: input lag, command lag, etc. You can use it to benchmark your own shell.human-bench
measures human perception of latency when using interactive zsh. You can use it to check how it feels to use zsh with specific latencies or to test whether you can tell a difference between 5ms and 0ms lag.- I've used
human-bench
to conduct a blind study on myself to find the maximum values of latencies that are indistinguishable from zero. For example, command lag below 10ms feels just like 0ms but anything above this value starts feeling sluggish. - I've used these threshold values to normalize benchmark results to see what is fast and what is slow.
- Armed with this set of tools I've optimized two of my zsh projects: powerlevel10k and zsh4humans. They used to be fairly fast but now they are literally indistinguishable from instantaneous as far as human perception goes.
- I've benchmarked many zsh techniques, plugins, frameworks and plugin managers and have shared my observations in this document together with a brief conclusion.
Install
Clone the repo:
git clone https://github.com/romkatv/zsh-bench ~/zsh-bench
Usage
usage: zsh-bench [OPTION].. [CONFIG]..
OPTIONS
-h,--help
-i,--iters <NUM> [default=16]
-l,--login <yes|no> [default=yes]
-g,--git <yes|no|empty> [default=yes]
-c,--config-dir <directory> [default=<zsh-bench-dir>/configs]
-d,--scratch-dir <directory>
-I,--isolation <docker|user>
-s,--standalone
-r,--raw
Benchmark zsh on your machine
~/zsh-bench/zsh-bench
This requires zsh >= 5.8 and it must be your login shell.
If your zsh startup files start tmux
, the benchmark may hang unless your tmux
has this fix
for this bug.
If your zsh startup files enable history but don't set histignorespace
, you might find random
commands in your history after running zsh-bench
.
Benchmark predefined zsh configs
~/zsh-bench/zsh-bench --isolation docker -- <name> [name]..
This requires docker
. Names of predefined zsh configs are directories under
configs.
With --isolation user
benchmarking is done as user zsh-bench
on the host.
How it works
zsh-bench
creates a virtual TTY and starts a login shell in it. It then sends keystrokes to the
TTY and measures how long it takes for the shell to react. For example, zsh-bench
can send
echo hello
and echo goodbye
to the TTY twice in quick succession and measure how long it takes
for the words "hello" and "goodbye" to be printed.
What it measures
Sample output of zsh-bench
:
creates_tty=1
has_compsys=1
has_syntax_highlighting=1
has_autosuggestions=1
has_git_prompt=1
first_prompt_lag_ms=14.331
first_command_lag_ms=56.500
command_lag_ms=2.518
input_lag_ms=5.195
exit_time_ms=5.886
The first few fields list detected shell capabilities; the rest are measured latencies.
Shell capabilities (0 or 1):
name | meaning |
---|---|
creates tty | the shell creates its own TTY by invoking tmux or screen |
has compsys | the shell initializes compsys βthe "new" completion systemβby invoking compinit |
has syntax highlighting | user input (the command line) is highlighted by zsh-syntax-highlighting |
has autosuggestions | suggestions for command completions are offered automatically by zsh-autosuggestions |
has git prompt | git branch is displayed in prompt |
Latencies (in milliseconds):
name | what time it measures | if too high |
---|---|---|
first prompt lag (ms) | from the start of the shell to the moment prompt appears on the screen | you get to stare at an empty screen for some time whenever you open a terminal |
first command lag (ms) | from the start of the shell to the moment the first interactive command starts executing | you get to wait for the output of ls if you type it really fast after opening a terminal |
command lag (ms) | from pressing <kbd>Enter</kbd> on an empty command line to the moment the next prompt appears; the same as zsh-prompt-benchmark (my project) | all commands appear to take longer to execute; the slowdown may happen after you press <kbd>Enter</kbd> and before the command starts executing, or after the command finishes executing and before the next prompt appears |
input lag (ms) | from pressing a regular key to the moment the corresponding character appears on the command line; this test is performed when the current command line is already fairly long | keyboard input feels sluggish, as if you are working over an SSH connection with high latency |
exit time (ms) | how long it takes to execute zsh -lic "exit" ; this value is meaningless as far as measuring interactive shell latencies goes | there is no baseline value for this latency, so it cannot be "too high" |
How fast is fast
Is input lag of 5ms a lot? What about first prompt lag of 100ms? How good/bad would it
be if these latencies were halved/doubled? I've written human-bench
to answer questions like this.
It's a small tool that can simulate zsh with latencies of your choice.
usage: human-bench [OPTION]..
OPTIONS
-h,--help
-s,--shell-command <STR> [default="zsh"]
-f,--first-prompt-lag-ms <NUM> [default=0]
-c,--first-command-lag-ms <NUM> [default=0]
-p,--command-lag-ms <NUM> [default=0]
-i,--input-lag-ms <NUM> [default=0]
It turns out that first prompt lag of 100ms causes the first prompt to appear with a noticeable
delay when starting zsh but input lag of 5ms is barely perceptible. Or is it imperceptible?
When I invoke human-bench --input-lag-ms 5
I expect input to lag and this might affect what I'm
seeing. To rule out this bias I've extended human-bench
to accept several values of the same
latency:
human-bench --input-lag-ms 0 --input-lag-ms 5
human-bench
picks one of these latencies at random before starting zsh. However, it doesn't
reveal the choice until I exit the playground. With this tool in hand I conducted a blind study on
myself and found out that I cannot distinguish between these two latencies. As far as my senses are
concerned, input lag of 5ms is as good as zero.
I used this blinding method to find the threshold values of all latencies in my use of zsh. Any value below the threshold isβto meβindistinguishable from zero. I can distinguish values above the threshold from zero with better than 50% accuracy.
latency (ms) | the maximum value indistinguishable from zero |
---|---|
first prompt lag | 50 |
first command lag | 150 |
command lag | 10 |
input lag | 20 |
The first two latencies are related to zsh startup time. I don't start zsh by literally typing zsh
within an existing shell. I either open a terminal, create a new tab, or split an existing tab. The
latter is the most common, so I rigged human-bench
to split a tab for the purpose of testing
startup latencies. For the other two latencies I typed and executed simple commands.
Keep in mind that these thresholds may have different values for different people, machines, terminals, etc. I believe the ballpark should be the same though.
Benchmark results
I implemented zsh-bench
in order to optimize powerlevel10k
and zsh4humans. In the process I benchmarked many zsh
techniques, plugins, frameworks and plugin managers. I'm sharing some of my findings here.
I recommend reading this section top-to-bottom without jumping back and forth. You can also skip right to conclusions.
All benchmark results in this section have been normalized by the threshold values. first prompt lag of 25ms becomes 50% and 100ms becomes 200%. Latencies up to 50%, 100% and 200% are be marked with π’, π‘ and π , respectively. Latencies above 200% get π΄. Note that π‘ is actually really good. It means the latency is indistinguishable from zero. A zsh config with all latencies marked green or yellow performs as if there were no latencies at all. I'm reserving π’ for latencies under half of this ambitious threshold because it's nice to have a bit of headroom. I might add extra stuff to my zsh configs or maybe I'll run zsh on a slower machine. I wouldn't want this to push my latencies outside of the imperceptible range. So, green latencies aren't just imperceptible but also leave enough unused latency budget.
Basics
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
no-rcs | β | β | β | β | β | 3%<br>π’ | 1%<br>π’ | 1%<br>π’ | 1%<br>π’ |
tmux | βοΈ | β | β | β | β | 8%<br>π’ | 3%<br>π’ | 1%<br>π’ | 1%<br>π’ |
compsys | β | βοΈ | β | β | β | 37%<br>π’ | 12%<br>π’ | 1%<br>π’ | 1%<br>π’ |
zsh-syntax-highlighting | β | β | βοΈ | β | β | 23%<br>π’ | 14%<br>π’ | 6%<br>π’ | 57%<br>π‘ |
zsh-autosuggestions | β | β | β | βοΈ | β | 32%<br>π’ | 13%<br>π’ | 96%<br>π‘ | 3%<br>π’ |
git-branch | β | β | β | β | βοΈ | 32%<br>π’ | 11%<br>π’ | 50%<br>π’ | 1%<br>π’ |
no-rcs is zsh in its pure form, without any rc files. It's really fast! Even if it was 10 times slower, I wouldn't be able to tell a difference.
The rest of the entries here are the simplest configs capable of providing each capability. For
example, here's .zshrc
from zsh-autosuggestions:
source ~/zsh-autosuggestions/zsh-autosuggestions.zsh
Just one line. Plain and simple. ~/zsh-autosuggestions
is supposed to be created manually, outside
of zsh rc files. In the benchmark it's done by a setup
script like this:
git clone -q --depth=1 https://github.com/zsh-users/zsh-autosuggestions.git ~/zsh-autosuggestions
These basic building blocks are composable. We can easily create a config by combining any number of them. Later we'll be doing just that. The latencies of a combination are the sums of latencies of all its constituents. For example, first prompt lag of tmux+compsys is first prompt lag of tmux plus first prompt lag of compsys. You can probably already see that adding everything together will push some latencies over the threshold. Our goal is to avoid that while still getting all the goodies. git-branch gives us git prompt for the price of 48% of our command lag budget. Let's see if we can do better.
Prompt
I've benchmarked several different git prompts.
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
git-branch | β | β | β | β | βοΈ | 32%<br>π’ | 11%<br>π’ | 50%<br>π’ | 1%<br>π’ |
agnoster | β | β | β | β | βοΈ | 65%<br>π‘ | 22%<br>π’ | 244%<br>π΄ | 1%<br>π’ |
starship | β | β | β | β | βοΈ | 82%<br>π‘ | 28%<br>π’ | 354%<br>π΄ | 1%<br>π’ |
powerlevel10k | β | β | β | β | βοΈ | 4%<br>π’ | 14%<br>π’ | 19%<br>π’ | 1%<br>π’ |
The git repo used by the benchmark has 1,000 directories and 10,000 files in it. Not too few,
not too many. All benchmarks ran with untracked cache enabled. Wall time of git status
stood at
16ms.
git-branch only shows the name of the current branch and has the same latency regardless of the repository size.
agnoster config uses the classic agnoster zsh theme. It scans the whole repo to see if there are untracked files, unstaged changes, etc. We can see that this causes lag on every command pushing latency into the red. The lag is linear in the number of files and directories in the git repo. You wouldn't want to use this theme in a truly large git repo with hundreds of thousands or millions of files.
starship config uses the cross-shell starship prompt. It suffers from the same performance problems as agnoster plus some. Starship is implemented as an external binary, so it has to pay the price of at least one additional fork+exec on every command compared to native zsh prompts. One fork+exec cannot account for the high lag starship exhibits, so what gives? Under the benchmark conditions starship clones 158 times! That's costly.
powerlevel10k config uses powerlevel10k zsh theme
that I've developed. It scans the git repo just like agnoster and starship but it does not invoke
git
to do that. Instead, it uses gitstatus -- another of
my projects. This gives powerlevel10k a nice speedup on repositories large and small. In addition,
powerlevel10k doesn't block zsh prompt while gitstatus is scanning the repo, so command lag stays
constant even in giant repositories. Powerlevel10k has a few other interesting performance-related
properties that we'll explore when we start building real zsh configs.
Premade configs
Let's see what some of the popular premade zsh configs offer out of the box.
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
prezto | β | βοΈ | β | β | β | 97%<br>π‘ | 35%<br>π’ | 13%<br>π’ | 1%<br>π’ |
ohmyzsh | β | βοΈ | β | β | βοΈ | 187%<br>π | 64%<br>π‘ | 366%<br>π΄ | 2%<br>π’ |
zim | β | βοΈ | βοΈ | βοΈ | βοΈ | 122%<br>π | 53%<br>π‘ | 191%<br>π | 64%<br>π‘ |
zsh4humans | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 19%<br>π’ | 36%<br>π’ | 27%<br>π’ | 25%<br>π’ |
The names of these configs match the respective public projects from which they were copied: ohmyzsh, prezto, zim and zsh4humans. The latter is my project. All configs were used unmodified.
prezto is fast but doesn't provide much out of the box. No syntax highlighting, autosuggestions or git prompt. Users who need these featuresβmost doβshould enable them explicitly.
ohmyzsh and zim by default use a theme with similar performance characteristics of agnoster, so they have high command lag in larger git repositories. zim is the only config among these that doesn't detect untracked files. This appears to have been a conscious decision by zim developers for performance reasons. We can see that it helps: zim has approximately half the command lag of ohmyzsh.
zim enables syntax highlight and autosuggestions by default, so it naturally has higher input lag than projects that don't. Fast zsh startup is a major explicit goal of zim and we can see that it beats ohmyzsh on first prompt lag and first command lag.
zsh4humans ticks all capability checkboxes and has all latencies comfortably in the green zone.
This shouldn't be surprising. In the game of optimization, measuring is half the work. I had access
to zsh-bench
, so I was able to optimize zsh4humans to score well on it. Prior to creating
zsh-bench
I knew that input lag and first command lag in zsh4humans were sometimes noticeable
but it was difficult to evaluate the effectiveness of potential optimizations when I not only
couldn't measure these latencies but didn't even have clear concepts for them.
Note that all these projects have extra features that aren't reflected in the capabilities shown in the table. They all enable persistent history, define aliases, set shell options, etc.
Do it yourself
Let's leave premade configs alone for some time and try to build a zsh config from scratch. Given the availability of high-quality building blocks, this shouldn't be very difficult.
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
diy | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 118%<br>π | 47%<br>π’ | 155%<br>π | 61%<br>π‘ |
diy+ | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 51%<br>π‘ | 24%<br>π’ | 63%<br>π‘ |
diy++ | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 42%<br>π’ | 24%<br>π’ | 64%<br>π‘ |
diy is the simplest config that provides all capabilities. I've made it by concatenating configs
of the basic building blocks. Here's the whole .zshrc
:
# If not in tmux, start tmux.
if [[ -z ${TMUX+X}${ZSH_SCRIPT+X}${ZSH_EXECUTION_STRING+X} ]]; then
exec tmux
fi
# Enable the "new" completion system (compsys).
autoload -Uz compinit && compinit
# Configure prompt to show the current working directory and git branch.
autoload -Uz vcs_info add-zsh-hook
add-zsh-hook precmd vcs_info
PS1='%~ $vcs_info_msg_0_'
setopt prompt_subst
# Enable syntax highlighting.
source ~/zsh-syntax-highlighting/zsh-syntax-highlighting.zsh
# Enable autosuggestions.
source ~/zsh-autosuggestions/zsh-autosuggestions.zsh
Two latencies are over the threshold, so some lag can be noticeable. However, before using this config you'll want to add more stuff to it -- key bindings, environment variables, aliases, completions options, etc. All these things will make zsh slower. If you aren't careful, a lot slower.
diy+ improves on diy by replacing its prompt with powerlevel10k. This has
dramatic positive effect on first prompt lag and command lag. Moreover, first prompt lag
is now constant and won't increase if more stuff is added to the config. This means you'll never
have to stare at an empty screen when opening terminal -- prompt will be there right from the start.
The additional initialization code will only affect first command lag, which has the highest
threshold of all latencies and has the least impact on the perception of zsh performance. I've also
made .zshrc
in this config self-bootstrapping to obviate the need to maintain a separate install
or setup
script for the cloning of zsh plugin repositories. This is primarily to make comparisons
with plugin managers in the future sections easier.
diy++ adds one more optimization -- it compiles large zsh files to wordcode. This reduces first command lag a little bit. This config performs well and is still relatively simple.
Cutting corners
There are several optimizations that speed up zsh startup but can easily backfire. diy++unsafe adds three such optimizations on top of diy++ to reduce first command lag by 5% of the budget. I don't recommend them.
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
diy++unsafe | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 9%<br>π’ | 37%<br>π’ | 24%<br>π’ | 63%<br>π‘ |
The first optimization is to compile to wordcode .zshrc
itself. This will cause you a lot of grief
if you do something like this:
% cp ~/.zshrc ~/.zshrc.bak # backup .zshrc before messing with it
% vi ~/.zshrc # change stuff
% exec zsh # restart zsh to try the new changes
% mv ~/.zshrc.bak ~/.zshrc # revert changes
% exec zsh # restart zsh
At this point you'll be surprised to find that the last command seemingly had no effect. Zsh is
still using .zshrc
that you modified in vi
. This happens because mv
preserves file
modification time and zsh looks at it to figure out whether the wordcode matches the source code.
Compiling .zshrc
to wordcode will also prevent you from using aliases in .zshrc
if they were
defined in the same file. For example:
alias ll='ls -l'
lll() { ll "$@" | less; }
If you put this code in .zshrc
, you'll notice that lll
doesn't work if .zshrc
is compiled.
Another dangerous optimization is to invoke compinit
with -C
. If you do that and install a new
tool using your favorite package manager, completions for this tool may not appear in zsh even after
restart. You'll have to manually delete a cache file. Saving a few milliseconds on zsh startup is
not worth it if later you'll have to spend an hour trying to figure out why completions don't work.
The last over-eager optimization is to print the first prompt before checking whether plugins need to be installed. The section on Instant Prompt explains why this is a bad idea.
Powerlevel10k
Before going further let's look at powerlevel10k more closely. This theme can display a lot of
information in prompt: disk usage, public IP address, VPN status, current kubernetes context,
taskwarrior task count, etc. The configuration of powerlevel10k affects its latency. All benchmarked
configs that use powerlevel10k employ the same small config that only shows the current working
directory and git status in prompt. In addition to this I've also measured (and optimized -- this
was the whole point of working on zsh-bench
) the performance of powerlevel10k with everything
turned on.
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
powerlevel10k | β | β | β | β | βοΈ | 4%<br>π’ | 14%<br>π’ | 19%<br>π’ | 1%<br>π’ |
powerlevel10k-full | β | β | β | β | βοΈ | 8%<br>π’ | 27%<br>π’ | 64%<br>π‘ | 6%<br>π’ |
powerlevel10k-full has substantially higher command lag but it's still under 100%, meaning that prompt is still indistinguishable from instantaneous. However, there is not much command lag budget left for doing extra things on every command. So you would need to be careful with your zsh config if you were to use powerlevel10k with everything turned on. In practice, no sane person would enable everything. Here's a ridiculously overwrought prompt:
It has 18 segments. The full config enables 64!
powerlevel10k-full increases input lag by 1.2ms compared to the smaller config. Powerlevel10k can dynamically update prompt depending on the current command you are typing. Here's an example from powerlevel10k docs where the current kubernetes context and gcloud credentials are shown only when they are relevant to the current command.
<details> <summary>Powerlevel10k Show On Command</summary> </details>This feature requires parsing the command line as it changes, hence extra input lag. The impact on latency is small, so it shouldn't cause any problems.
Instant prompt
I mentioned earlier that powerlevel10k makes first prompt lag small and, importantly, independent from anything else you have in zsh startup files. This feature is called Instant Prompt in powerlevel10k docs (a more appropriate name would have been Instant First Prompt) and it's worth looking at how it works.
When you open the homepage of Google in a web browser, it appears to load almost instantly even though there is a lot of fancy functionality built into it. If we look under the hood, the whole page takes a long time to load but most of this loading happens after the UI has been rendered. It doesn't take much time to render an input box for the query and the search button, so it looks instantaneous. The initial UI may look like the real thing but it's only a stub. If you enter a query and click the button quickly enough, search results won't appear. The button doesn't have the necessary logic yet, so it'll just remember that it was clicked. The query will go through once the page loads.
This trick works really well because you can start typing right away. Typing is very slow by machine standards, so by the time you are finished the page has almost always been fully loaded and you don't notice any delay when clicking the button.
Powerlevel10k uses the same trick, only in case of zsh the UI you see on startup is the prompt. As soon as you open a terminal, powerlevel10k prints prompt. This first prompt only has information that can be computed quickly (the current working directory, username, hostname, current time, python virtual environment, etc.) but nothing that can require a lot of time, so no git status. While you are typing the first command, zsh continues to initialize -- loading plugins, setting up completions, defining aliases, enabling key bindings, retrieving git status, etc. Once zsh is fully initialized, the original limited prompt is replaced with the full prompt and whatever you have typed is replayed in Zsh Line Editor (zle). If you've enabled syntax highlighting, at this point the command line gets highlighted. Here's how it looks:
<details> <summary>Powerlevel10k Instant Prompt</summary> </details>If you press <kbd>Enter</kbd> before zsh is fully initialized, the command won't execute. It cannot execute because execution relies on aliases, environment variables and whatnot, but those things haven't been defined yet. The command will execute once zsh finishes initializing. Until then it'll look like lag, as if the command takes a long time to start. You'll notice the same "lag" if you use a key binding such as <kbd>Tab</kbd> for a completion or <kbd>Ctrl+R</kbd> for interactive history search.
Initializing zsh while you are typing the first command poses a problem. What if some part of
.zshrc
prints to the terminal? The output will appear smack in the middle of what you perceive as
the command line. That wouldn't be pretty at all. And what if .zshrc
asks you a question?
Disk usage seems kinda high. Delete your home directory? [y/N]
The buffered input that was intended to go to Zsh Line Editor will be read by the disk cleaner. If the first command you are typing starts with "y", say goodbye to your files.
To avoid these issues, for the duration of zsh initialization powerlevel10k redirects standard input
to /dev/null
and standard output with standard error to a temporary file. Once zsh is fully
initialized, standard file descriptors are restored and the content of the temporary file is printed
out. This content appears above the first prompt. This is much better than letting the output
interleave with the command line but it's still not pretty.
For best results, when using Instant Prompt, .zshrc
should be structured like so:
- The first section is for commands that either:
- read from standard input or the TTY
- write to standard output, standard error or the TTY
- occasionally (but rarely) may take unpredictably long time to execute
# If not in tmux, start tmux: reads from and writes to the TTY. if [[ -z ${TMUX+X}${ZSH_SCRIPT+X}${ZSH_EXECUTION_STRING+X} ]]; then exec tmux fi # Clone git repos that don't exist: prints and may take unpredictably long time to execute. if [[ ! -e ~/zsh-autosuggestions ]]; then print -r -- 'installing zsh-autosuggestions ...' git clone --depth=1 https://github.com/zsh-users/zsh-autosuggestions.git ~/zsh-autosuggestions fi # Prints. print -Pr -- 'Hello, %n. Today is %D{%A}.' # ... and so on
- Activate Instant Prompt. This must be done with this exact command.
# Print the first prompt and redirect standard file descriptors. if [[ -r "${XDG_CACHE_HOME:-$HOME/.cache}/p10k-instant-prompt-${(%):-%n}.zsh" ]]; then source "${XDG_CACHE_HOME:-$HOME/.cache}/p10k-instant-prompt-${(%):-%n}.zsh" fi
- The last section is for the bulk of initialization. These commands must not:
- read from standard input or the TTY
- write to standard output, standard error or the TTY
- take unpredictably long time to execute
autoload -Uz compinit && compinit source ~/zsh-autosuggestions/zsh-autosuggestions.zsh # ... and so on
Commands in the first section must be very fast to avoid delaying the first prompt.
It's OK for commands in the last section to print in case of errors. The assumption is that you'll fix these errors, so in normal operation there won't be any output.
If you need to use the TTY in the last section, there is $TTY
for you. Just make sure you aren't
reading anything from it and only writing "invisible" things that don't appear on the screen. This
is OK:
# Let gpg know what our TTY is.
export GPG_TTY=$TTY
# Change the cursor shape to "beam".
print -n '\e[5 q' >$TTY
# Display the current working directory in the terminal title.
printf '\e]0;%s\a' ${(V)${(%):-%1~}} >$TTY
Plugin managers
diy++ is a solid base for a zsh config that gives us full control over the initialization process. By using a plugin manager we can give up some of this control for convenience. I've benchmarked several plugin managers and frameworks. All configs here have all core capabilities.
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
diy++ | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 42%<br>π’ | 24%<br>π’ | 64%<br>π‘ |
diy++unsafe | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 9%<br>π’ | 37%<br>π’ | 24%<br>π’ | 63%<br>π‘ |
zcomet | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 44%<br>π’ | 25%<br>π’ | 64%<br>π‘ |
zinit | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 78%<br>π‘ | 24%<br>π’ | 64%<br>π‘ |
zplug | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 108%<br>π | 100%<br>π‘ | 24%<br>π’ | 64%<br>π‘ |
ohmyzsh+ | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 56%<br>π‘ | 29%<br>π’ | 64%<br>π‘ |
prezto+ | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 47%<br>π’ | 34%<br>π’ | 68%<br>π‘ |
zim+ | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 10%<br>π’ | 38%<br>π’ | 24%<br>π’ | 64%<br>π‘ |
zsh4humans | βοΈ | βοΈ | βοΈ | βοΈ | βοΈ | 19%<br>π’ | 36%<br>π’ | 27%<br>π’ | 25%<br>π’ |
diy++ and diy++unsafe are listed here to serve as baseline for comparing latency.
The next three configs use "pure" plugin managers: zcomet, zinit and zplug. These allow you to install and load plugins but don't configure zsh on their own in any way.
Configs ohmyzsh+, prezto+ and zim+ are based on the respective standard configs. I've enabled only the plugins that are required to tick off all capabilities and disabled the rest.
zsh4humans can install and load arbitrary plugins but the default config already enables everything we care about. So I'm benchmarking the stock config with no changes here.
Most configs in this list treat compinit
, zsh-syntax-highlighting,
zsh-autosuggestions
and powerlevel10k as black
boxes. They cannot beat diy++unsafe on benchmarks.
zplug, ohmyzsh and prezto trade usability for performance by invoking compinit
with
-C
. This is not a good choice in my opinion. The small speedup isn't worth it. zsh4humans and
zim go the opposite way -- they perform more checks than the regular compinit
in order to
improve usability of the completion system. For example, if you add a completion function to an
existing file with a #compdef
directive, none of the configs except for zsh4humans and zim will
pick up this change until you manually delete .zcompdump
. Restarting zsh or even rebooting the
machine won't help. zsh4humans manages to achieve first command lag lower than any other
config despite the additional quality of life improvements. This shows that cutting corners isn't
necessary for achieving low latency goals.
All configs have very low first prompt lag thanks to powerlevel10k. The only exception is zplug. zplug provides a nice API that plays well with Instant Prompt. It has one function to install plugins and another to load them. Installation of plugins can print status messages and perform network I/O, so it should be done before the first prompt is printed. Unfortunately, this function in zplug is rather slow, hence high first prompt lag. zcomet, and zinit dodge this bullet by not providing this kind of API in the first place, so these configs are cutting corners. It's not that zcomet and zinit are acting recklessly here but rather their limitations don't allow me to cleanly use Instant Prompt. When using these plugin managers you either have to give up Instant Prompt and have first prompt lag over the threshold or cut corners and get subpar UX.
zsh4humans has lower first command lag and input lag than anything else. It achieves this by implementing tight integration between the core shell features: prompt, syntax highlighting and autosuggestions. You can enable extra plugins in zsh4humans but the core comes as a single unit.
zsh4humans has first prompt lag 9% (4.7ms in absolute terms) higher than diy++. A lot of features are packed into that chunk of time but this isn't the place to describe them. The resulting first prompt lag is still just 20% of the threshold of perception, so I'm feeling pretty secure that this latency won't be noticeable. Importantly, when users add extra initialization code to their zsh startup files, it doesn't increase first prompt lag. It increases only first command lag, which zsh4humans has at a lower value than other configs. Overall I'm very happy with where zsh4humans stands.
If you don't care about tmux
, you can mentally subtract
its latencies from any row in
the table. Given that zplug is only slightly over 100% on two metrics, subtracting tmux from
it brings all latencies in the table into the green or yellow territory. Everything is pretty fast!
Understanding the differences in functionality is what really matters for an informed choice. This
document is only about performance though, so I won't go into it.
Deferred initialization
It's possible to defer some parts of zsh initialization and perform them when zsh has nothing else to do. This can be done with zinit turbo mode or zsh-defer. The latter is my project.
config | tmux | compsys | syntax highlight | auto suggest | git prompt | first prompt lag | first cmd lag | cmd lag | input lag |
---|---|---|---|---|---|---|---|---|---|
zinit-turbo | βοΈ | βοΈ | β | β | βοΈ | 9%<br>π’ | 39%<br>π’ | 24%<br>π’ | 62%<br>π‘ |
zsh-defer | βοΈ | βοΈ | β | β | βοΈ | 10%<br>π’ | 22%<br>π’ | 28%<br>π’ | 65%<br>π‘ |
In these configs the initialization of syntax highlighting and autosuggestions was deferred. When deferring initialization of some features, you have to be prepared to use zsh without those features for some time. The benchmark results indicate that the first command of the interactive shell didn't have syntax highlighting or autosuggestions. This makes sense. Zsh was busy processing the first command in Zsh Line Editor and hasn't reached the state of having nothing to do before the command has started executing.
Initialization of the vast majority of features is unsafe to defer. Anything that modifies environment variables, defines commands or changes the behavior of widgets shouldn't be deferred.
The only feature I know of whose initialization can be safely deferred is syntax highlighting. Autosuggestions must be initialized after syntax highlighting, so you would have to defer both of them or none. Unfortunately, deferring the initialization of autosuggestions is unsafe because it changes the behavior of some keys, so you cannot use autosuggestions if you defer syntax highlighting.
Deferred initialization runs within the context of Zsh Line Editor (zle). Some plugins don't expect to be loaded from zle and may fail to properly initialize. Loading such plugins from zle requires workarounds that often rely on the plugin's implementation details. This exposes the user to much higher risk of breakage when updating plugins.
Deferred initialization can reduce only first cmd lag. If done properly, it has no effect on other latencies. Given that there are many configs to choose from that are below the perception threshold on first cmd lag, deferred initialization doesn't solve any real problems while adding quite a few of its own.
So much for deferred initialization. Cannot recommend.
How not to benchmark
If you search online for tips on how to benchmark zsh startup, you'll find the following command or a variation thereof:
time zsh -lic "exit"
For the sake of completeness, zsh-bench
also measures this. This metric is shown as
exit_time_ms in the raw output. Let's look at a couple of raw benchmark results that pertain to
zsh startup speed.
config | first prompt lag (ms) | first command lag (ms) | exit time (ms) |
---|---|---|---|
agnoster | 32 | 33 | 2 |
powerlevel10k | 2 | 21 | 6 |
When using agnoster, exit
finishes in just 2ms. Yet, when you open a terminal, you'll be
looking at an empty screen for 32ms. What exactly happens on the 2ms mark that counts as "startup"?
Consider powerlevel10k for comparison. With this config exit
takes longer than with
agnoster but zsh starts faster: when you open a terminal, prompt appears virtually instantly and
the first command executes sooner.
Many zsh plugin managers have been optimized for fast exit
and are presenting it as a meaningful
measure of performance. The widely held belief that zinit is the fastest plugin manager is based
on the timing of exit
. Deferred initializationβpioneered by zinit turbo
modeβmay not be very useful in practice but it's extremely effective on
this metric. Unsurprisingly, zinit has been optimized for it.
This doesn't mean developers have been engaging in conscious deception. It was easy to unknowingly
fall into the trap. The timing of exit
is very close to first prompt lag and
first command lag in zsh configs from the older and simpler times. It used to be a proper
measure of zsh startup performance. At some point these latencies have diverged, the benchmark lost
its meaning, but the old habits remained.
zsh4humans clocks at 6ms on exit
. I'd be overjoyed if I could claim that zsh4humans
initializes that fast but there is no meaningful definition of initialization for which this claim
is true.
The output of time zsh -lic "exit"
tells you how long it takes to execute
zsh -lic "exit"
and nothing else. If you aren't in the habit of running zsh -lic "exit"
, there
is no reason for you to care one way or another about this number.
Since the release of zsh-bench several projects have switched from targeting exit
to meaningful
performance metrics. The ones I know of are zcomet, zim and antidote. There is hope that
this trend will continue.
Full benchmark data
- Fast desktop machine (all benchmark results inlined in this document are from this run):
- Date: 2023-02-27.
- OS: Ubuntu 22.04.
- CPU: AMD Ryzen Threadripper 3970x.
- Storage: NVMe M.2.
- Results: raw, normalized.
- MacBook Air (M1, 2020):
- Date: 2021-11-09.
- OS: macOS Monterey.
- Chip: Apple M1.
- Storage: SSD.
- Power: battery (not plugged into the power outlet).
- Results: raw, normalized.
- Raspberry Pi 4 Model B:
- Date: 2021-11-09.
- OS: Raspbian Buster (32 bit).
- CPU: ARM Cortex-A72.
- Storage: microSD.
- Results: raw, normalized.
Conclusions
- powerlevel10k is an effective tool for reducing startup and per-command lag.
- diy++ is a performant and relatively simple base for a self-bootstrapping zsh config if you want to build one from scratch.
- Plugin managers cannot beat diy++ on performance unless they cut corners. A fast plugin manager is one that doesn't slow things down much. The value provided by a plugin manager is convenience, not speed.
- All plugin managers and frameworks have good performance when configured properly. This includes ohmyzsh, despite a commonly held opinion that it's slow.
- From the "pure" plugin managers I've tested zplug has the best API but it's also the slowest. The slowdown is small enough that it won't matter to most users.
- Not all plugin managers can cleanly use Instant Prompt -- the closest thing to a silver bullet in the battle for startup speed.
- zsh4humans is faster than anything else with comparable features. It beats even diy++ on benchmarks thanks to tight integration of core features which cannot be replaced with third party plugins.
- Deferring zsh initialization with zinit turbo mode or zsh-defer is not worth it.
- The output of
time zsh -lic "exit"
does not tell you anything about the performance of interactive zsh.
Responses
This section lists public responses from the developers of analyzed projects.
zcomet
From README.md:
- October 13, 2021
Similarly on reddit:
I've taken your advice:
zcomet
no longer compiles rc files, andzcomet compinit
is no longercompinit -C
by default.Next I'll look into the issue of compatibility with your Instant Prompt.
zim
This summary:
Thanks to @romkatv's input and to his thoughts in zsh-bench, this is what we've improved in Zim:
- We changed our benchmarks to measure the time to the first prompt appearance (instead of the time to run
exit
). We're using a different tool (expect) than zsh-bench (script) to measure that time, and @romkatv helped us make use the times between our different approaches match.- We don't compile Zsh startup scripts, and we don't compile any scripts in the background anymore. The former is considered "cutting corners" in zsh-bench, and the latter unreliable. In fact, now Zim does not run anything in the background during your shell experience.
- We're using the same improved completion dumpfile check that zsh4humans uses during startup in our completion module, since using
compinit -C
alone is also considered "cutting corners" in zsh-bench.- We've also updated our templates to set
ZSH_AUTOSUGGEST_MANUAL_REBIND=1
and source the zsh-users/zsh-autosuggestions module last.
Debugging and validation
Several tools are included in zsh-bench to aid in debugging and validation of benchmark results.
Perform one iteration of login shell benchmark and retain temporary benchmark data:
~/zsh-bench/zsh-bench --iters 1 --scratch-dir /tmp/zsh-bench
Replay the screen of the TTY that zsh-bench
was acting on during benchmarking:
~/zsh-bench/dbg/replay --scratch-dir /tmp/zsh-bench
Replay at 10% speed and at most 1s delay between TTY updates:
~/zsh-bench/dbg/replay --scratch-dir /tmp/zsh-bench --delay-multiplier 10 --max-delay-ms 1000
Don't resize your terminal after running zsh-bench
so that everything replays correctly.
You'll see that at first zsh-bench
issues a short command that sources a script. This command gets
sent to the TTY right away without waiting for first prompt. The sourced file prints, and the result
of that printing signifies execution of the first command.
Then zsh-bench
starts measuring input latency. It prints a fairly long command composed of a bunch
of escaped abc
tokens, types one more character and waits for that character to be processed by
zle. This is performed several times
and then the command line is cleared without execution.
Then zsh-bench
measures command lag by spamming <kbd>Enter</kbd> and seeing how many prompts it
would get.
Print a TAB-separated table of timestamped raw writes to the TTY:
~/zsh-bench/dbg/timeline --scratch-dir /tmp/zsh-bench
See what happened at the specific timestamp:
~/zsh-bench/dbg/replay --scratch-dir /tmp/zsh-bench --pause-at-ms 10.149
The last argument is a timestamp in milliseconds. The replay will pause right before and right after
it. If you pass the value of first_prompt_lag_ms
or first_command_lag_ms
reported by zsh-bench
as the timestamp, you'll see what zsh-bench
considered first prompt and the output of
first command respectively. If zsh-bench
did its job correctly, the screen before
first_prompt_lag_ms
shouldn't have prompt but afterwards it should. Similarly, the screen before
first_command_lag_ms
shouldn't have ZB*-msg
but afterwards it should (the first command prints
ZB*-msg
where *
is a random number). Capability has_git_prompt
should be set if and only if
ZB*-branch
appears before ZB*-msg
. In other words, has_git_prompt
signifies that the first
prompt shows git branch.
License
MIT.
FAQ
Why is it important to benchmark my shell? Is it for enthusiasts?
It's not important to benchmark your shell. It is important for me to benchmark zsh plugins and configs that I publish so that users of my code have fast shell. Shell usersβor anyone for that matterβprefer fast software over slow whether they are enthusiasts or not.