q3aql/pfetch
q3aql/pfetch
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
3656e962c5
pfetch/pfetch
Dylan Araps 7de14e3b7e docs: update
2019-09-27 09:07:08 +03:00

1044 lines
30 KiB
Bash
Executable File
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#!/bin/sh
#
# pfetch - Simple POSIX sh fetch script.
log() {
# The 'log()' function handles the printing of information.
# In 'pfetch' (and 'neofetch'!) the printing of the ascii art and info
# happen independently of each other.
#
# The size of the ascii art is stored and the ascii is printed first.
# Once the ascii is printed, the cursor is located right below the art
# (See marker $[1]).
#
# Using the stored ascii size, the cursor is then moved to marker $[2].
# This is simply a cursor up escape sequence using the "height" of the
# ascii art.
#
# 'log()' then moves the cursor to the right the "width" of the ascii art
# with an additional amount of padding to add a gap between the art and
# the information (See marker $[3]).
#
# When 'log()' has executed, the cursor is then located at marker $[4].
# When 'log()' is run a second time, the next line of information is
# printed, moving the cursor to marker $[5].
#
# Markers $[4] and $[5] repeat all the way down through the ascii art
# until there is no more information left to print.
#
# Every time 'log()' is called the script keeps track of how many lines
# were printed. When printing is complete the cursor is then manually
# placed below the information and the art according to the "heights"
# of both.
#
# The math is simple: move cursor down $((ascii_height - info_height)).
# If the aim is to move the cursor from marker $[5] to marker $[6],
# plus the ascii height is 8 while the info height is 2 it'd be a move
# of 6 lines downwards.
#
# However, if the information printed is "taller" (takes up more lines)
# than the ascii art, the cursor isn't moved at all!
#
# Once the cursor is at marker $[6], the script exits. This is the gist
# of how this "dynamic" printing and layout works.
#
# This method allows ascii art to be stored without markers for info
# and it allows for easy swapping of info order and amount.
#
# $[2] ___ $[3] goldie@KISS
# $[4](.· | $[5] os KISS Linux
# (<> |
# / __ \
# ( / \ /|
# _/\ __)/_)
# \/-____\/
# $[1]
#
# $[6] /home/goldie $
# End here if no data was found.
[ "$2" ] || return
# Store the value of '$1' as we reset the argument list below.
name=$1
# Use 'set --' as a means of stripping all leading and trailing
# white-space from the info string. This also normalizes all
# whitespace inside of the string.
#
# Disable the shellcheck warning for word-splitting
# as it's safe and intended ('set -f' disables globbing).
# shellcheck disable=2046,2086
{
set -f
set +f -- $2
info=$*
}
# Move the cursor to the right, the width of the ascii art with an
# additional gap for text spacing.
printf '[%sC' "${ascii_width--1}"
# Print the info name and color the text.
printf '[3%s;1m%s' "${PF_COL1-4}" "$name"
# Print the info name and info data separator.
printf '%s' "$PF_SEP"
# Move the cursor backward the length of the *current* info name and
# then move it forwards the length of the *longest* info name. This
# aligns each info data line.
printf '[%sD[%sC' "${#name}" "${PF_ALIGN-$info_length}"
# Print the info data, color it and strip all leading whitespace
# from the string.
printf '[3%sm%s\n' "${PF_COL2-7}" "$info"
# Keep track of the number of times 'log()' has been run.
: $((info_height+=1))
}
get_title() {
# Username is retrieved by first checking '$USER' with a fallback
# to the 'whoami' command.
user=${USER:-$(whoami)}
# Hostname is retrieved by first checking '$HOSTNAME' with a fallback
# to the 'hostname' command.
#
# Disable the warning about '$HOSTNAME' being undefined in POSIX sh as
# the intention for using it is allowing the user to overwrite the
# value on invocation.
# shellcheck disable=SC2039
host=${HOSTNAME:-${hostname:-$(hostname)}}
log "[3${PF_COL3:-1}m${user}${c7}@[3${PF_COL3:-1}m${host}" " " >&6
}
get_os() {
# This function is called twice, once to detect the distribution name
# for the purposes of picking an ascii art early and secondly to display
# the distribution name in the info output (if enabled).
#
# On first run, this function displays _nothing_, only on the second
# invocation is 'log()' called.
[ "$distro" ] && {
log os "$distro" >&6
return
}
case $os in
Linux*)
# Some Linux disttributions (which are based on others)
# fail to identify as they **do not** change the upstream
# distributions identification packages or files.
#
# It is senseless to add a special case in the code for
# each and every distribution (which _is_ technically no
# different from what it is based on) as they're either too
# lazy to modify upstream's identification files or they
# don't have the know-how ship their own lsb-release package.
#
# This causes users to think there's a bug in system detection
# tools like neofetch or pfetch when they technically *do*
# function correctly.
if command -v lsb_release; then
distro=$(lsb_release -sd)
else
# Disable warning about shellcheck not being able
# to read '/etc/os-release'. This is fine.
# shellcheck source=/dev/null
. /etc/os-release && distro=$PRETTY_NAME
fi
# Special cases for distributions which don't follow
# any os-release/lsb standards whatsoever.
command -v crux && distro=$(crux)
command -v guix && distro='Guix System'
;;
Darwin*)
# Parse the SystemVersion.plist file to grab the macOS
# version. The file is in the following format:
#
# <key>ProductVersion</key>
# <string>10.14.6</string>
#
# 'IFS' is set to '<>' to enable splitting between the
# keys and a second 'read' is used to operate on the
# next line directly after a match.
#
# '_' is used to nullify a field. '_ _ line _' basically
# says "populate $line with the third field's contents".
while IFS='<>' read -r _ _ line _; do
case $line in
# Match 'ProductVersion' and read the next line
# directly as it contains the key's value.
ProductVersion)
IFS='<>' read -r _ _ mac_version _
break
;;
esac
done < /System/Library/CoreServices/SystemVersion.plist
# Use the ProductVersion to determine which macOS/OS X codename
# the system has. As far as I'm aware there's no "dynamic" way
# of grabbing this information.
case $mac_version in
10.4*) distro='Mac OS X Tiger' ;;
10.5*) distro='Mac OS X Leopard' ;;
10.6*) distro='Mac OS X Snow Leopard' ;;
10.7*) distro='Mac OS X Lion' ;;
10.8*) distro='OS X Mountain Lion' ;;
10.9*) distro='OS X Mavericks' ;;
10.10*) distro='OS X Yosemite' ;;
10.11*) distro='OS X El Capitan' ;;
10.12*) distro='macOS Sierra' ;;
10.13*) distro='macOS High Sierra' ;;
10.14*) distro='macOS Mojave' ;;
10.15*) distro='macOS Catalina' ;;
*) distro='macOS' ;;
esac
distro="$distro $mac_version"
;;
Haiku)
# Haiku uses 'uname -v' for version information
# instead of 'uname -r'.
distro="Haiku $(uname -v)"
;;
*)
# Catch all to ensure '$distro' is never blank.
# This also handles the BSDs.
distro="$os $kernel"
;;
esac
}
get_kernel() {
case $os in
# Don't print kernel output on some systems as the
# OS name includes it.
*BSD*|Haiku) ;;
*)
# '$kernel' is the cached output of 'uname -r'.
log kernel "$kernel" >&6
;;
esac
}
get_shell() {
log shell "${SHELL##*/}" >&6
}
get_host() {
case $os in
Linux*)
# Despite what these files are called, version doesn't
# always contain the version nor does name always contain
# the name.
read -r name < /sys/devices/virtual/dmi/id/product_name
read -r version < /sys/devices/virtual/dmi/id/product_version
read -r model < /sys/firmware/devicetree/base/model
host="$name $version $model"
;;
Darwin*|FreeBSD*)
host=$(sysctl -n hw.model)
;;
NetBSD*)
host=$(sysctl -n machdep.dmi.system-vendor \
machdep.dmi.system-product)
;;
*BSD*)
host=$(sysctl -n hw.vendor hw.product)
;;
Haiku)
# '$arch' ends up being the hostname(?) on Haiku and
# there is no other way to get host information.
return
;;
esac
# '$arch' is the cached output from 'uname -m'.
log host "${host:-$arch}" >&6
}
get_uptime() {
# Uptime works by retrieving the data in total seconds and then
# converting that data into days, hours and minutes using simple
# math.
case $os in
Linux*)
IFS=. read -r s _ < /proc/uptime
;;
Darwin*|*BSD*)
s=$(sysctl -n kern.boottime)
# Extract the uptime in seconds from the following output:
# [...] { sec = 1271934886, usec = 667779 } Thu Apr 22 12:14:46 2010
s=${s#*=}
s=${s%,*}
# The uptime format from 'sysctl' needs to be subtracted from
# the current time in seconds.
s=$(($(date +%s) - s))
;;
Haiku)
# The boot time is returned in microseconds, convert it to
# regular seconds.
s=$(($(system_time) / 1000000))
;;
esac
# Convert the uptime from seconds into days, hours and minutes.
d=$((s / 60 / 60 / 24))
h=$((s / 60 / 60 % 24))
m=$((s / 60 % 60))
# Only append days, hours and minutes if they're non-zero.
[ "$d" = 0 ] || uptime="${uptime}${d}d "
[ "$h" = 0 ] || uptime="${uptime}${h}h "
[ "$m" = 0 ] || uptime="${uptime}${m}m "
log uptime "${uptime:-0m}" >&6
}
get_pkgs() {
# This works by first checking for which package managers are
# installed and finally by printing each package manager's
# package list with each package one per line.
#
# The output from this is then piped to 'wc -l' to count each
# line, giving us the total package count of whatever package
# managers are installed.
#
# Backticks are *required* here as '/bin/sh' on macOS is
# 'bash 3.2' and it can't handle the following:
#
# var=$(
# code here
# )
#
# shellcheck disable=2006
packages=`
case $os in
Linux*)
# Commands which print packages one per line.
command -v kiss && kiss l
command -v bonsai && bonsai list
command -v pacman-key && pacman -Qq
command -v dpkg && dpkg-query -f '.\n' -W
command -v rpm && rpm -qa
command -v xbps-query && xbps-query -l
command -v apk && apk info
# Directories containing packages.
command -v brew && printf '%s\n' "$(brew --cellar)/"*
command -v emerge && printf '%s\n' /var/db/pkg/*/*/
command -v pkgtool && printf '%s\n' /var/log/packages/*
# GUIX requires two commands.
command -v guix && {
guix package -p /run/current-system/profile -I
guix package -I
}
# NIX requires two commands.
command -v nix-store && {
nix-store -q --requisites /run/current-system/sw
nix-store -q --requisites ~.nix-profile
}
;;
Darwin*)
# Commands which print packages one per line.
command -v pkgin && pkgin list
command -v port && port installed
# Directories containing packages.
command -v brew && printf '%s\n' /usr/local/Cellar/*
;;
FreeBSD*)
pkg info
;;
OpenBSD*)
printf '%s\n' /var/db/pkg/*/
;;
NetBSD*)
pkg_info
;;
Haiku)
printf '%s\n' /boot/system/package-links/*
;;
esac | wc -l
`
log pkgs "${packages:-?}" >&6
}
get_memory() {
case $os in
# Used memory is calculated using the following "formula" (Linux):
# MemUsed = MemTotal + Shmem - MemFree - Buffers - Cached - SReclaimable
# Source: https://github.com/KittyKatt/screenFetch/issues/386
Linux*)
# Parse the '/proc/meminfo' file splitting on ':' and 'k'.
# The format of the file is 'key: 000kB' and an additional
# split is used on 'k' to filter out 'kB'.
while IFS=:k read -r key val _; do
case $key in
MemTotal)
mem_used=$((mem_used + val))
mem_full=$val
;;
Shmem)
mem_used=$((mem_used + val))
;;
MemFree|Buffers|Cached|SReclaimable)
mem_used=$((mem_used - val))
;;
esac
done < /proc/meminfo
mem_used=$((mem_used / 1024))
mem_full=$((mem_full / 1024))
;;
# Used memory is calculated using the following "formula" (MacOS):
# (wired + active + occupied) * 4 / 1024
Darwin*)
mem_full=$(($(sysctl -n hw.memsize) / 1024 / 1024))
# Parse the 'vmstat' file splitting on ':' and '.'.
# The format of the file is 'key: 000.' and an additional
# split is used on '.' to filter it out.
while IFS=:. read -r key val; do
case $key in
*wired*|*active*|*occupied*)
mem_used=$((mem_used + ${val:-0}))
;;
esac
# Using '<<-EOF' is the only way to loop over a command's
# output without the use of a pipe ('|').
# This ensures that any variables defined in the while loop
# are still accessible in the script.
done <<-EOF
$(vm_stat)
EOF
mem_used=$((mem_used * 4 / 1024))
;;
OpenBSD*)
mem_full=$(($(sysctl -n hw.physmem) / 1024 / 1024))
# This is a really simpler parser for 'vmstat' which grabs
# the used memory amount in a lazy way. 'vmstat' prints 3
# lines of output with the needed value being stored in the
# final line.
#
# This loop simply grabs the 3rd element of each line until
# the EOF is reached. Each line overwrites the value of the
# previous one so we're left with what we wanted. This isn't
# slow as only 3 lines are parsed.
while read -r _ _ line _; do
mem_used=${line%%M}
# Using '<<-EOF' is the only way to loop over a command's
# output without the use of a pipe ('|').
# This ensures that any variables defined in the while loop
# are still accessible in the script.
done <<-EOF
$(vmstat)
EOF
;;
# Used memory is calculated using the following "formula" (FreeBSD):
# (inactive_count + free_count + cache_count) * page_size / 1024
FreeBSD*)
mem_full=$(($(sysctl -n hw.physmem) / 1024 / 1024))
# Use 'set --' to store the output of the command in the
# argument list. POSIX sh has no arrays but this is close enough.
#
# Disable the shellcheck warning for word-splitting
# as it's safe and intended ('set -f' disables globbing).
# shellcheck disable=2046
{
set -f
set +f -- $(sysctl -n hw.pagesize \
vm.stats.vm.v_inactive_count \
vm.stats.vm.v_free_count \
vm.stats.vm.v_cache_count)
}
# Calculate the amount of used memory.
# $1: hw.pagesize
# $2: vm.stats.vm.v_inactive_count
# $3: vm.stats.vm.v_free_count
# $4: vm.stats.vm.v_cache_count
mem_used=$((($2 + $3 + $4) * $1 / 1024 / 1024))
;;
NetBSD*)
mem_full=$(($(sysctl -n hw.physmem64) / 1024 / 1024))
# NetBSD implements a lot of the Linux '/proc' filesystem,
# this uses the same parser as the Linux memory detection.
while IFS=:k read -r key val _; do
case $key in
MemFree)
mem_free=$((val / 1024))
break
;;
esac
done < /proc/meminfo
mem_used=$((mem_full - mem_free))
;;
Haiku)
# Read the first line of 'sysinfo -mem' splitting on
# '(', ' ', and ')'. The needed information is then
# stored in the 5th and 7th elements. Using '_' "consumes"
# an element allowing us to proceed to the next one.
#
# The parsed format is as follows:
# 3501142016 bytes free (used/max 792645632 / 4293787648)
IFS='( )' read -r _ _ _ _ mem_used _ mem_full <<-EOF
$(sysinfo -mem)
EOF
mem_used=$((mem_used / 1024 / 1024))
mem_full=$((mem_full / 1024 / 1024))
;;
esac
log memory "${mem_used:-?}M / ${mem_full:-?}M" >&6
}
get_ascii() {
# This is a simple function to read the contents of
# an ascii file from 'stdin'. It allows for the use
# of '<<-EOF' to prevent the break in indentation in
# this source code.
#
# This function also sets the text colors according
# to the ascii color.
read_ascii() {
# 'PF_COL1': Set the info name color according to ascii color.
# 'PF_COL3': Set the title color to some other color. ¯\_(ツ)_/¯
PF_COL1=${PF_COL1:-${1:-7}}
PF_COL3=${PF_COL3:-$((${1:-7}%8+1))}
# POSIX sh has no 'var+=' so 'var=${var}append' is used. What's
# interesting is that 'var+=' _is_ supported inside '$(())'
# (arithmetic) though there's no support for 'var++/var--'.
#
# There is also no $'\n' to add a "literal"(?) newline to the
# string. The simplest workaround being to break the line inside
# the string (though this has the caveat of breaking indentation).
while IFS= read -r line; do
ascii="$ascii$line
"
done
}
# This checks for ascii art in the following order:
# '$1': Argument given to 'get_ascii()' directly.
# '$PF_ASCII': Environment variable set by user.
# '$distro': The detected distribution name.
# '$os': The name of the operating system/kernel.
#
# NOTE: Each ascii art below is indented using tabs, this
# allows indentation to continue naturally despite
# the use of '<<-EOF'.
case ${1:-${PF_ASCII:-${distro:-$os}}} in
[Aa]lpine*)
read_ascii 4 <<-EOF
${c4} /\\ /\\
/${c7}/ ${c4}\\ \\
/${c7}/ ${c4}\\ \\
/${c7}// ${c4}\\ \\
${c7}// ${c4}\\ \\
\\
EOF
;;
[Aa]rch*)
read_ascii 4 <<-EOF
${c6} /\\
/^^\\
/\\ \\
/${c7} __ \\
/ ( ) \\
/ __| |__\\\\
/// \\\\\\
EOF
;;
[Aa]rco*)
read_ascii 4 <<-EOF
${c4} /\\
/ \\
/ /\\ \\
/ / \\ \\
/ / \\ \\
/ / _____\\ \\
/_/ \`----.\\_\\
EOF
;;
[Aa]rtix*)
read_ascii 6 <<-EOF
${c4} /\\
/ \\
/\`'.,\\
/ ',
/ ,\`\\
/ ,.'\`. \\
/.,'\` \`'.\\
EOF
;;
[Cc]ent[Oo][Ss]*)
read_ascii 5 <<-EOF
${c2} ____${c3}^${c5}____
${c2} |\\ ${c3}|${c5} /|
${c2} | \\ ${c3}|${c5} / |
${c5}<---- ${c4}---->
${c4} | / ${c2}|${c3} \\ |
${c4} |/__${c2}|${c3}__\\|
${c2} v
EOF
;;
[Dd]ebian*)
read_ascii 1 <<-EOF
${c1} _____
/ __ \\
| / |
| \\___-
-_
--_
EOF
;;
[Ee]lementary*)
read_ascii <<-EOF
${c7} _______
/ ____ \\
/ | / /\\
|__\\ / / |
\\ /__/ /
\\_______/
EOF
;;
[Ff]edora*)
read_ascii 4 <<-EOF
${c7} _____
/ __)${c4}\\${c7}
| / ${c4}\\ \\${c7}
${c4}__${c7}_| |_${c4}_/ /${c7}
${c4}/ ${c7}(_ _)${c4}_/${c7}
${c4}/ /${c7} | |
${c4}\\ \\${c7}__/ |
${c4}\\${c7}(_____/
EOF
;;
[Ff]ree[Bb][Ss][Dd]*)
read_ascii 1 <<-EOF
${c1} /\\ _____ /\\
\\_) (_/
/ \\
| |
| |
\ /
--_____--
EOF
;;
[Gg]entoo*)
read_ascii 5 <<-EOF
${c5} _-----_
( \\
\\ 0 \\
${c7} \\ )
/ _/
( _-
\\____-
EOF
;;
[Gg]uix[Ss][Dd]*|guix*)
read_ascii 3 <<-EOF
${c3}|.__ __.|
|__ \\ / __|
\\ \\ / /
\\ \\ / /
\\ \\ / /
\\ \\/ /
\\__/
EOF
;;
[Hh]aiku*)
read_ascii 3 <<-EOF
${c3} ,^,
/ \\
*--_ ; ; _--*
\\ '" "' /
'. .'
.-'" "'-.
'-.__. .__.-'
|_|
EOF
;;
[Hh]yperbola*)
read_ascii <<-EOF
${c7} |\`__.\`/
\____/
.--.
/ \\
/ ___ \\
/ .\` \`.\\
/.\` \`.\\
EOF
;;
[Ll]inux*[Ll]ite*)
read_ascii 3 <<-EOF
${c3} /\\
/ \\
/ ${c7}/ ${c3}/
> ${c7}/ ${c3}/
\\ ${c7}\\ ${c3}\\
\\_${c7}\\${c3}_\\
${c7} \\
EOF
;;
[Ll]inux*[Mm]int*|[Mm]int)
read_ascii 2 <<-EOF
${c2} ___________
|_ \\
| ${c7}| _____ ${c2}|
| ${c7}| | | | ${c2}|
| ${c7}| | | | ${c2}|
| ${c7}\\__${c7}___/ ${c2}|
\\_________/
EOF
;;
[Ll]inux*)
read_ascii 4 <<-EOF
${c4} ___
(${c7}.· ${c4}|
(${c5}<> ${c4}|
/ ${c7}__ ${c4}\\
( ${c7}/ \\ ${c4}/|
${c5}_${c4}/\\ ${c7}__)${c4}/${c5}_${c4})
${c5}\/${c4}-____${c5}\/
EOF
;;
[Mm]ac[Oo][Ss]*|[Dd]arwin*)
read_ascii 1 <<-EOF
${c1} .:'
_ :'_
${c2} .'\`_\`-'_\`\`.
:________.-'
${c3}:_______:
${c4} :_______\`-;
${c5} \`._.-._.'
EOF
;;
[Mm]ageia*)
read_ascii 2 <<-EOF
${c6} *
*
**
${c7} /\\__/\\
/ \\
\\ /
\\____/
EOF
;;
[Mm]anjaro*)
read_ascii 2 <<-EOF
${c2}||||||||| ||||
||||||||| ||||
|||| ||||
|||| |||| ||||
|||| |||| ||||
|||| |||| ||||
|||| |||| ||||
EOF
;;
[Mm][Xx]*)
read_ascii <<-EOF
${c7} \\\\ /
\\\\/
\\\\
/\\/ \\\\
/ \\ /\\
/ \\/ \\
/__________\\
EOF
;;
[Nn]et[Bb][Ss][Dd]*)
read_ascii 3 <<-EOF
${c7}\\\\${c3}\`-______,----__
${c7} \\\\ ${c3}__,---\`_
${c7} \\\\ ${c3}\`.____
${c7} \\\\${c3}-______,----\`-
${c7} \\\\
\\\\
\\\\
EOF
;;
[Nn]ix[Oo][Ss]*)
read_ascii 4 <<-EOF
${c4} \\\\ \\\\ //
==\\\\__\\\\/ //
// \\\\//
==// //==
//\\\\___//
// /\\\\ \\\\==
// \\\\ \\\\
EOF
;;
[Oo]pen[Bb][Ss][Dd]*)
read_ascii 3 <<-EOF
${c3} _____
\\- -/
\\_/ \\
| ${c7}O O${c3} |
|_ < ) 3 )
/ \\ /
/-_____-\\
EOF
;;
openSUSE*|open*SUSE*|SUSE*|suse*)
read_ascii 2 <<-EOF
${c2} _______
__| __ \\
/ .\\ \\
\\__/ |
_______|
\\_______
__________/
EOF
;;
[Pp]arabola*)
read_ascii 5 <<-EOF
${c5} __ __ __ _
.\`_//_//_/ / \`.
/ .\`
/ .\`
/.\`
/\`
EOF
;;
[Pp]op!_[Oo][Ss]*)
read_ascii 6 <<-EOF
${c6}______
\\ _ \\ __
\\ \\ \\ \\ / /
\\ \\_\\ \\ / /
\\ ___\\ /_/
\\ \\ _
__\\_\\__(_)_
(___________)
EOF
;;
[Pp]ure[Oo][Ss]*)
read_ascii <<-EOF
${c7} _____________
| _________ |
| | | |
| | | |
| |_________| |
|_____________|
EOF
;;
[Ss]lackware*)
read_ascii 4 <<-EOF
${c4} ________
/ ______|
| |______
\\______ \\
______| |
| |________/
|____________
EOF
;;
[Vv]oid*)
read_ascii 2 <<-EOF
${c2} _______
_ \\______ -
| \\ ___ \\ |
| | / \ | |
| | \___/ | |
| \\______ \\_|
-_______\\
EOF
;;
*)
# On no match of a distribution ascii art, this function calls
# itself again, this time to look for a more generic OS related
# ascii art (KISS Linux -> Linux).
[ "$1" ] || {
get_ascii "$os"
return
}
printf 'error: %s is not currently supported.\n' "$os" >&6
printf 'error: Open an issue for support to be added.\n' >&6
exit 1
;;
esac
# Store the "width" (longest line) and "height" (number of lines)
# of the ascii art for positioning. This script prints to the screen
# *almost* like a TUI does. It uses escape sequences to allow dynamic
# printing of the information through user configuration.
#
# Iterate over each line of the ascii art to retrieve the above
# information. The 'sed' is used to strip 'm' color codes from
# the ascii art so they don't affect the width variable.
while read -r line; do
: $((ascii_height+=1))
ascii_width=$((${#line} > ascii_width ? ${#line} : ascii_width))
# Using '<<-EOF' is the only way to loop over a command's
# output without the use of a pipe ('|').
# This ensures that any variables defined in the while loop
# are still accessible in the script.
done <<-EOF
$(printf %s "$ascii" | sed 's/\[3.m//g')
EOF
# Add a gap between the ascii art and the information.
: $((ascii_width+=4))
# Print the ascii art and position the cursor back where we
# started prior to printing it.
# '[?7l': Disable line-wrapping.
# '[?25l': Hide the cursor.
# '[1m': Print the ascii in bold.
# '[m': Clear bold.
# '[%sA': Move the cursor up '$ascii_height' amount of lines.
printf '[?7l[?25l%s[%sA' "$ascii" "$ascii_height" >&6
}
main() {
# Leave the terminal how we found it on exit or Ctrl+C.
# '[?7h': Enable line-wrapping.
# '[?25h': Un-hide the cursor.
trap 'printf [?7h[?25h >&6' EXIT
# Hide 'stderr' unless the first argument is '-v'. This saves
# polluting the script with '2>/dev/null'.
[ "$1" = -v ] || exec 2>/dev/null
# Hide 'stdout' and selectively print to it using '>&6'.
# This gives full control over what it displayed on the screen.
exec 6>&1 >/dev/null
# Generic color list.
# Disable warning about unused variables.
# shellcheck disable=2034
{
c1=''; c2=''
c3=''; c4=''
c5=''; c6=''
c7=''; c8=''
}
# Store the output of 'uname' to avoid calling it multiple times
# throughout the script. 'read <<EOF' is the simplest way of reading
# a command into a list of variables.
read -r os kernel arch <<-EOF
$(uname -srm)
EOF
# Always run 'get_os' for the purposes of detecting which ascii
# art to display.
get_os
# Allow the user to specify the order and inclusion of information
# functions through the 'PF_INFO' environment variable.
# shellcheck disable=2086
{
# Disable globbing and set the positional parameters to the
# contents of 'PF_INFO'.
set -f
set +f ${PF_INFO-ascii title os host kernel uptime pkgs memory}
# Iterate over the info functions to determine the lengths of the
# "info names" for output alignment. The option names and subtitles
# match 1:1 so this is thankfully simple.
for info; do
command -v "get_$info" >/dev/null &&
info_length=$((${#info} > info_length ? ${#info} : info_length))
done
# Add an additional space of length to act as a gap.
: $((info_length+=1))
# Iterate over the above list and run any existing "get_" functions.
for info; do "get_$info"; done
}
# Position the cursor below both the ascii art and information lines
# according to the height of both. If the information exceeds the ascii
# art in height, don't touch the cursor, else move it down N lines.
cursor_pos=$((info_height > ascii_height ? 0 : ascii_height - info_height))
# Print '$cursor_pos' amount of newlines to correctly position the
# cursor. This used to be a 'printf $(seq X X)' however 'seq' is only
# typically available (by default) on GNU based systems!
while [ "${i:-0}" -le "$cursor_pos" ]; do
printf '\n'
: $((i+=1))
done >&6
}
main "$@"
Reference in New Issue View Git Blame Copy Permalink