configs/home/.zsh-kali/themes/spaceship-prompt/async

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2023-06-30 21:45:57 +02:00
#!/usr/bin/env zsh
#
# zsh-async
#
# version: v1.8.5
# author: Mathias Fredriksson
# url: https://github.com/mafredri/zsh-async
#
typeset -g ASYNC_VERSION=1.8.5
# Produce debug output from zsh-async when set to 1.
typeset -g ASYNC_DEBUG=${ASYNC_DEBUG:-0}
# Execute commands that can manipulate the environment inside the async worker. Return output via callback.
_async_eval() {
local ASYNC_JOB_NAME
# Rename job to _async_eval and redirect all eval output to cat running
# in _async_job. Here, stdout and stderr are not separated for
# simplicity, this could be improved in the future.
{
eval "$@"
} &> >(ASYNC_JOB_NAME=[async/eval] _async_job 'cat')
}
# Wrapper for jobs executed by the async worker, gives output in parseable format with execution time
_async_job() {
# Disable xtrace as it would mangle the output.
setopt localoptions noxtrace
# Store start time for job.
float -F duration=$EPOCHREALTIME
# Run the command and capture both stdout (`eval`) and stderr (`cat`) in
# separate subshells. When the command is complete, we grab write lock
# (mutex token) and output everything except stderr inside the command
# block, after the command block has completed, the stdin for `cat` is
# closed, causing stderr to be appended with a $'\0' at the end to mark the
# end of output from this job.
local jobname=${ASYNC_JOB_NAME:-$1} out
out="$(
local stdout stderr ret tok
{
stdout=$(eval "$@")
ret=$?
duration=$(( EPOCHREALTIME - duration )) # Calculate duration.
print -r -n - $'\0'${(q)jobname} $ret ${(q)stdout} $duration
} 2> >(stderr=$(cat) && print -r -n - " "${(q)stderr}$'\0')
)"
if [[ $out != $'\0'*$'\0' ]]; then
# Corrupted output (aborted job?), skipping.
return
fi
# Grab mutex lock, stalls until token is available.
read -r -k 1 -p tok || return 1
# Return output (<job_name> <return_code> <stdout> <duration> <stderr>).
print -r -n - "$out"
# Unlock mutex by inserting a token.
print -n -p $tok
}
# The background worker manages all tasks and runs them without interfering with other processes
_async_worker() {
# Reset all options to defaults inside async worker.
emulate -R zsh
# Make sure monitor is unset to avoid printing the
# pids of child processes.
unsetopt monitor
# Redirect stderr to `/dev/null` in case unforseen errors produced by the
# worker. For example: `fork failed: resource temporarily unavailable`.
# Some older versions of zsh might also print malloc errors (know to happen
# on at least zsh 5.0.2 and 5.0.8) likely due to kill signals.
exec 2>/dev/null
# When a zpty is deleted (using -d) all the zpty instances created before
# the one being deleted receive a SIGHUP, unless we catch it, the async
# worker would simply exit (stop working) even though visible in the list
# of zpty's (zpty -L). This has been fixed around the time of Zsh 5.4
# (not released).
if ! is-at-least 5.4.1; then
TRAPHUP() {
return 0 # Return 0, indicating signal was handled.
}
fi
local -A storage
local unique=0
local notify_parent=0
local parent_pid=0
local coproc_pid=0
local processing=0
local -a zsh_hooks zsh_hook_functions
zsh_hooks=(chpwd periodic precmd preexec zshexit zshaddhistory)
zsh_hook_functions=(${^zsh_hooks}_functions)
unfunction $zsh_hooks &>/dev/null # Deactivate all zsh hooks inside the worker.
unset $zsh_hook_functions # And hooks with registered functions.
unset zsh_hooks zsh_hook_functions # Cleanup.
close_idle_coproc() {
local -a pids
pids=(${${(v)jobstates##*:*:}%\=*})
# If coproc (cat) is the only child running, we close it to avoid
# leaving it running indefinitely and cluttering the process tree.
if (( ! processing )) && [[ $#pids = 1 ]] && [[ $coproc_pid = $pids[1] ]]; then
coproc :
coproc_pid=0
fi
}
child_exit() {
close_idle_coproc
# On older version of zsh (pre 5.2) we notify the parent through a
# SIGWINCH signal because `zpty` did not return a file descriptor (fd)
# prior to that.
if (( notify_parent )); then
# We use SIGWINCH for compatibility with older versions of zsh
# (pre 5.1.1) where other signals (INFO, ALRM, USR1, etc.) could
# cause a deadlock in the shell under certain circumstances.
kill -WINCH $parent_pid
fi
}
# Register a SIGCHLD trap to handle the completion of child processes.
trap child_exit CHLD
# Process option parameters passed to worker.
while getopts "np:uz" opt; do
case $opt in
n) notify_parent=1;;
p) parent_pid=$OPTARG;;
u) unique=1;;
z) notify_parent=0;; # Uses ZLE watcher instead.
esac
done
# Terminate all running jobs, note that this function does not
# reinstall the child trap.
terminate_jobs() {
trap - CHLD # Ignore child exits during kill.
coproc : # Quit coproc.
coproc_pid=0 # Reset pid.
if is-at-least 5.4.1; then
trap '' HUP # Catch the HUP sent to this process.
kill -HUP -$$ # Send to entire process group.
trap - HUP # Disable HUP trap.
else
# We already handle HUP for Zsh < 5.4.1.
kill -HUP -$$ # Send to entire process group.
fi
}
killjobs() {
local tok
local -a pids
pids=(${${(v)jobstates##*:*:}%\=*})
# No need to send SIGHUP if no jobs are running.
(( $#pids == 0 )) && continue
(( $#pids == 1 )) && [[ $coproc_pid = $pids[1] ]] && continue
# Grab lock to prevent half-written output in case a child
# process is in the middle of writing to stdin during kill.
(( coproc_pid )) && read -r -k 1 -p tok
terminate_jobs
trap child_exit CHLD # Reinstall child trap.
}
local request do_eval=0
local -a cmd
while :; do
# Wait for jobs sent by async_job.
read -r -d $'\0' request || {
# Unknown error occurred while reading from stdin, the zpty
# worker is likely in a broken state, so we shut down.
terminate_jobs
# Stdin is broken and in case this was an unintended
# crash, we try to report it as a last hurrah.
print -r -n $'\0'"'[async]'" $(( 127 + 3 )) "''" 0 "'$0:$LINENO: zpty fd died, exiting'"$'\0'
# We use `return` to abort here because using `exit` may
# result in an infinite loop that never exits and, as a
# result, high CPU utilization.
return $(( 127 + 1 ))
}
# We need to clean the input here because sometimes when a zpty
# has died and been respawned, messages will be prefixed with a
# carraige return (\r, or \C-M).
request=${request#$'\C-M'}
# Check for non-job commands sent to worker
case $request in
_killjobs) killjobs; continue;;
_async_eval*) do_eval=1;;
esac
# Parse the request using shell parsing (z) to allow commands
# to be parsed from single strings and multi-args alike.
cmd=("${(z)request}")
# Name of the job (first argument).
local job=$cmd[1]
# Check if a worker should perform unique jobs, unless
# this is an eval since they run synchronously.
if (( !do_eval )) && (( unique )); then
# Check if a previous job is still running, if yes,
# skip this job and let the previous one finish.
for pid in ${${(v)jobstates##*:*:}%\=*}; do
if [[ ${storage[$job]} == $pid ]]; then
continue 2
fi
done
fi
# Guard against closing coproc from trap before command has started.
processing=1
# Because we close the coproc after the last job has completed, we must
# recreate it when there are no other jobs running.
if (( ! coproc_pid )); then
# Use coproc as a mutex for synchronized output between children.
coproc cat
coproc_pid="$!"
# Insert token into coproc
print -n -p "t"
fi
if (( do_eval )); then
shift cmd # Strip _async_eval from cmd.
_async_eval $cmd
else
# Run job in background, completed jobs are printed to stdout.
_async_job $cmd &
# Store pid because zsh job manager is extremely unflexible (show jobname as non-unique '$job')...
storage[$job]="$!"
fi
processing=0 # Disable guard.
if (( do_eval )); then
do_eval=0
# When there are no active jobs we can't rely on the CHLD trap to
# manage the coproc lifetime.
close_idle_coproc
fi
done
}
#
# Get results from finished jobs and pass it to the to callback function. This is the only way to reliably return the
# job name, return code, output and execution time and with minimal effort.
#
# If the async process buffer becomes corrupt, the callback will be invoked with the first argument being `[async]` (job
# name), non-zero return code and fifth argument describing the error (stderr).
#
# usage:
# async_process_results <worker_name> <callback_function>
#
# callback_function is called with the following parameters:
# $1 = job name, e.g. the function passed to async_job
# $2 = return code
# $3 = resulting stdout from execution
# $4 = execution time, floating point e.g. 2.05 seconds
# $5 = resulting stderr from execution
# $6 = has next result in buffer (0 = buffer empty, 1 = yes)
#
async_process_results() {
setopt localoptions unset noshwordsplit noksharrays noposixidentifiers noposixstrings
local worker=$1
local callback=$2
local caller=$3
local -a items
local null=$'\0' data
integer -l len pos num_processed has_next
typeset -gA ASYNC_PROCESS_BUFFER
# Read output from zpty and parse it if available.
while zpty -r -t $worker data 2>/dev/null; do
ASYNC_PROCESS_BUFFER[$worker]+=$data
len=${#ASYNC_PROCESS_BUFFER[$worker]}
pos=${ASYNC_PROCESS_BUFFER[$worker][(i)$null]} # Get index of NULL-character (delimiter).
# Keep going until we find a NULL-character.
if (( ! len )) || (( pos > len )); then
continue
fi
while (( pos <= len )); do
# Take the content from the beginning, until the NULL-character and
# perform shell parsing (z) and unquoting (Q) as an array (@).
items=("${(@Q)${(z)ASYNC_PROCESS_BUFFER[$worker][1,$pos-1]}}")
# Remove the extracted items from the buffer.
ASYNC_PROCESS_BUFFER[$worker]=${ASYNC_PROCESS_BUFFER[$worker][$pos+1,$len]}
len=${#ASYNC_PROCESS_BUFFER[$worker]}
if (( len > 1 )); then
pos=${ASYNC_PROCESS_BUFFER[$worker][(i)$null]} # Get index of NULL-character (delimiter).
fi
has_next=$(( len != 0 ))
if (( $#items == 5 )); then
items+=($has_next)
$callback "${(@)items}" # Send all parsed items to the callback.
(( num_processed++ ))
elif [[ -z $items ]]; then
# Empty items occur between results due to double-null ($'\0\0')
# caused by commands being both pre and suffixed with null.
else
# In case of corrupt data, invoke callback with *async* as job
# name, non-zero exit status and an error message on stderr.
$callback "[async]" 1 "" 0 "$0:$LINENO: error: bad format, got ${#items} items (${(q)items})" $has_next
fi
done
done
(( num_processed )) && return 0
# Avoid printing exit value when `setopt printexitvalue` is active.`
[[ $caller = trap || $caller = watcher ]] && return 0
# No results were processed
return 1
}
# Watch worker for output
_async_zle_watcher() {
setopt localoptions noshwordsplit
typeset -gA ASYNC_PTYS ASYNC_CALLBACKS
local worker=$ASYNC_PTYS[$1]
local callback=$ASYNC_CALLBACKS[$worker]
if [[ -n $2 ]]; then
# from man zshzle(1):
# `hup' for a disconnect, `nval' for a closed or otherwise
# invalid descriptor, or `err' for any other condition.
# Systems that support only the `select' system call always use
# `err'.
# this has the side effect to unregister the broken file descriptor
async_stop_worker $worker
if [[ -n $callback ]]; then
$callback '[async]' 2 "" 0 "$0:$LINENO: error: fd for $worker failed: zle -F $1 returned error $2" 0
fi
return
fi;
if [[ -n $callback ]]; then
async_process_results $worker $callback watcher
fi
}
_async_send_job() {
setopt localoptions noshwordsplit noksharrays noposixidentifiers noposixstrings
local caller=$1
local worker=$2
shift 2
zpty -t $worker &>/dev/null || {
typeset -gA ASYNC_CALLBACKS
local callback=$ASYNC_CALLBACKS[$worker]
if [[ -n $callback ]]; then
$callback '[async]' 3 "" 0 "$0:$LINENO: error: no such worker: $worker" 0
else
print -u2 "$caller: no such async worker: $worker"
fi
return 1
}
zpty -w $worker "$@"$'\0'
}
#
# Start a new asynchronous job on specified worker, assumes the worker is running.
#
# usage:
# async_job <worker_name> <my_function> [<function_params>]
#
async_job() {
setopt localoptions noshwordsplit noksharrays noposixidentifiers noposixstrings
local worker=$1; shift
local -a cmd
cmd=("$@")
if (( $#cmd > 1 )); then
cmd=(${(q)cmd}) # Quote special characters in multi argument commands.
fi
_async_send_job $0 $worker "$cmd"
}
#
# Evaluate a command (like async_job) inside the async worker, then worker environment can be manipulated. For example,
# issuing a cd command will change the PWD of the worker which will then be inherited by all future async jobs.
#
# Output will be returned via callback, job name will be [async/eval].
#
# usage:
# async_worker_eval <worker_name> <my_function> [<function_params>]
#
async_worker_eval() {
setopt localoptions noshwordsplit noksharrays noposixidentifiers noposixstrings
local worker=$1; shift
local -a cmd
cmd=("$@")
if (( $#cmd > 1 )); then
cmd=(${(q)cmd}) # Quote special characters in multi argument commands.
fi
# Quote the cmd in case RC_EXPAND_PARAM is set.
_async_send_job $0 $worker "_async_eval $cmd"
}
# This function traps notification signals and calls all registered callbacks
_async_notify_trap() {
setopt localoptions noshwordsplit
local k
for k in ${(k)ASYNC_CALLBACKS}; do
async_process_results $k ${ASYNC_CALLBACKS[$k]} trap
done
}
#
# Register a callback for completed jobs. As soon as a job is finnished, async_process_results will be called with the
# specified callback function. This requires that a worker is initialized with the -n (notify) option.
#
# usage:
# async_register_callback <worker_name> <callback_function>
#
async_register_callback() {
setopt localoptions noshwordsplit nolocaltraps
typeset -gA ASYNC_PTYS ASYNC_CALLBACKS
local worker=$1; shift
ASYNC_CALLBACKS[$worker]="$*"
# Enable trap when the ZLE watcher is unavailable, allows
# workers to notify (via -n) when a job is done.
if [[ ! -o interactive ]] || [[ ! -o zle ]]; then
trap '_async_notify_trap' WINCH
elif [[ -o interactive ]] && [[ -o zle ]]; then
local fd w
for fd w in ${(@kv)ASYNC_PTYS}; do
if [[ $w == $worker ]]; then
zle -F $fd _async_zle_watcher # Register the ZLE handler.
break
fi
done
fi
}
#
# Unregister the callback for a specific worker.
#
# usage:
# async_unregister_callback <worker_name>
#
async_unregister_callback() {
typeset -gA ASYNC_CALLBACKS
unset "ASYNC_CALLBACKS[$1]"
}
#
# Flush all current jobs running on a worker. This will terminate any and all running processes under the worker, use
# with caution.
#
# usage:
# async_flush_jobs <worker_name>
#
async_flush_jobs() {
setopt localoptions noshwordsplit
local worker=$1; shift
# Check if the worker exists
zpty -t $worker &>/dev/null || return 1
# Send kill command to worker
async_job $worker "_killjobs"
# Clear the zpty buffer.
local junk
if zpty -r -t $worker junk '*'; then
(( ASYNC_DEBUG )) && print -n "async_flush_jobs $worker: ${(V)junk}"
while zpty -r -t $worker junk '*'; do
(( ASYNC_DEBUG )) && print -n "${(V)junk}"
done
(( ASYNC_DEBUG )) && print
fi
# Finally, clear the process buffer in case of partially parsed responses.
typeset -gA ASYNC_PROCESS_BUFFER
unset "ASYNC_PROCESS_BUFFER[$worker]"
}
#
# Start a new async worker with optional parameters, a worker can be told to only run unique tasks and to notify a
# process when tasks are complete.
#
# usage:
# async_start_worker <worker_name> [-u] [-n] [-p <pid>]
#
# opts:
# -u unique (only unique job names can run)
# -n notify through SIGWINCH signal
# -p pid to notify (defaults to current pid)
#
async_start_worker() {
setopt localoptions noshwordsplit noclobber
local worker=$1; shift
local -a args
args=("$@")
zpty -t $worker &>/dev/null && return
typeset -gA ASYNC_PTYS
typeset -h REPLY
typeset has_xtrace=0
if [[ -o interactive ]] && [[ -o zle ]]; then
# Inform the worker to ignore the notify flag and that we're
# using a ZLE watcher instead.
args+=(-z)
if (( ! ASYNC_ZPTY_RETURNS_FD )); then
# When zpty doesn't return a file descriptor (on older versions of zsh)
# we try to guess it anyway.
integer -l zptyfd
exec {zptyfd}>&1 # Open a new file descriptor (above 10).
exec {zptyfd}>&- # Close it so it's free to be used by zpty.
fi
fi
# Workaround for stderr in the main shell sometimes (incorrectly) being
# reassigned to /dev/null by the reassignment done inside the async
# worker.
# See https://github.com/mafredri/zsh-async/issues/35.
integer errfd=-1
# Redirect of errfd is broken on zsh 5.0.2.
if is-at-least 5.0.8; then
exec {errfd}>&2
fi
# Make sure async worker is started without xtrace
# (the trace output interferes with the worker).
[[ -o xtrace ]] && {
has_xtrace=1
unsetopt xtrace
}
if (( errfd != -1 )); then
zpty -b $worker _async_worker -p $$ $args 2>&$errfd
else
zpty -b $worker _async_worker -p $$ $args
fi
local ret=$?
# Re-enable it if it was enabled, for debugging.
(( has_xtrace )) && setopt xtrace
(( errfd != -1 )) && exec {errfd}>& -
if (( ret )); then
async_stop_worker $worker
return 1
fi
if ! is-at-least 5.0.8; then
# For ZSH versions older than 5.0.8 we delay a bit to give
# time for the worker to start before issuing commands,
# otherwise it will not be ready to receive them.
sleep 0.001
fi
if [[ -o interactive ]] && [[ -o zle ]]; then
if (( ! ASYNC_ZPTY_RETURNS_FD )); then
REPLY=$zptyfd # Use the guessed value for the file desciptor.
fi
ASYNC_PTYS[$REPLY]=$worker # Map the file desciptor to the worker.
fi
}
#
# Stop one or multiple workers that are running, all unfetched and incomplete work will be lost.
#
# usage:
# async_stop_worker <worker_name_1> [<worker_name_2>]
#
async_stop_worker() {
setopt localoptions noshwordsplit
local ret=0 worker k v
for worker in $@; do
# Find and unregister the zle handler for the worker
for k v in ${(@kv)ASYNC_PTYS}; do
if [[ $v == $worker ]]; then
zle -F $k
unset "ASYNC_PTYS[$k]"
fi
done
async_unregister_callback $worker
zpty -d $worker 2>/dev/null || ret=$?
# Clear any partial buffers.
typeset -gA ASYNC_PROCESS_BUFFER
unset "ASYNC_PROCESS_BUFFER[$worker]"
done
return $ret
}
#
# Initialize the required modules for zsh-async. To be called before using the zsh-async library.
#
# usage:
# async_init
#
async_init() {
(( ASYNC_INIT_DONE )) && return
typeset -g ASYNC_INIT_DONE=1
zmodload zsh/zpty
zmodload zsh/datetime
# Load is-at-least for reliable version check.
autoload -Uz is-at-least
# Check if zsh/zpty returns a file descriptor or not,
# shell must also be interactive with zle enabled.
typeset -g ASYNC_ZPTY_RETURNS_FD=0
[[ -o interactive ]] && [[ -o zle ]] && {
typeset -h REPLY
zpty _async_test :
(( REPLY )) && ASYNC_ZPTY_RETURNS_FD=1
zpty -d _async_test
}
}
async() {
async_init
}
async "$@"