#!/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' "${ascii_width--1}"
# Print the info name and color the text.
printf '�[3%s;1m%s�[m' "${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-$info_length}"
# Print the info data, color it and strip all leading whitespace
# from the string.
printf '�[3%sm%s�[m\n' "${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
hostname=${HOSTNAME:-${hostname:-$(hostname)}}
log "�[3${PF_COL3:-1}m${user}${c7}@�[3${PF_COL3:-1}m${hostname}" " " >&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 $os in
Linux*)
# Some Linux disttributions (which are based on others)
# fail to identify as they **do not** change the upstream
# distributions identification packages or files.
#
# It is senseless to add a special case in the code for
# each and every distribution (which _is_ technically no
# different from what it is based on) as they're either too
# lazy to modify upstream's identification files or they
# don't have the know-how (or means) to ship their own
# lsb-release package.
#
# This causes users to think there's a bug in system detection
# tools like neofetch or pfetch when they technically *do*
# function correctly.
#
# Exceptions are made for distributions which are independent,
# not based on another distribution or follow different
# standards.
#
# This applies only to distributions which follow the standard
# by shipping unmodified identification files and packages
# from their respective upstreams.
if command -v lsb_release; then
distro=$(lsb_release -sd)
# lsb_release sometimes adds quotes around the output,
# this simply remove quotes from the start/end if they
# exist.
distro=${distro##\"}
distro=${distro%%\"}
else
# Disable warning about shellcheck not being able
# to read '/etc/os-release'. This is fine.
# shellcheck source=/dev/null
. /etc/os-release && distro=$PRETTY_NAME
fi
# Special cases for (independent) distributions which
# don't follow any os-release/lsb standards whatsoever.
command -v crux && distro=$(crux)
command -v guix && distro='Guix System'
# Check to see if Linux is running in Windows 10 under
# WSL (Windows subsystem for Linux) and append a string
# accordingly.
#
# If the kernel version string ends in "-Microsoft",
# we're very likely running under Windows 10 in WSL.
#
# This also acts as a means of allowing the user to
# fake this by changing their kernel version to end in
# "Microsoft".
[ "${kernel%%*-Microsoft}" ] ||
distro="$distro on Windows 10"
;;
Darwin*)
# Parse the SystemVersion.plist file to grab the macOS
# version. The file is in the following format:
#
# ProductVersion
# 10.14.6
#
# '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 $mac_version"
;;
Haiku)
# Haiku uses 'uname -v' for version information
# instead of 'uname -r' which only prints '1'.
distro=$(uname -sv)
;;
*)
# Catch all to ensure '$distro' is never blank.
# This also handles the BSDs.
distro="$os $kernel"
;;
esac
}
get_kernel() {
case $os in
# Don't print kernel output on some systems as the
# OS name includes it.
*BSD*|Haiku|Minix) ;;
*)
# '$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)
;;
esac
# Turn the host string into an argument list so we can iterate
# over it and remove OEM strings and other information which
# shouldn't be displayed.
#
# 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 -- $host
host=
}
# Iterate over the host string word by word as a means of stripping
# unwanted and OEM information from the string as a whole.
#
# This could have been implemented using a long 'sed' command with
# a list of word replacements, however I want to show that something
# like this is possible in pure sh.
#
# This string reconstruction is needed as some OEMs either leave the
# identification information as "To be filled by OEM", "Default",
# "undefined" etc and we shouldn't print this to the screen.
for word; do
# This works by reconstructing the string by excluding words
# found in the "blacklist" below. Only non-matches are appended
# to the final host string.
case $word in
To | [Bb]e | [Ff]illed | by | O.E.M. | OEM |\
Not | Applicable | Specified | System | Product | Name |\
Version | Undefined | Default | string | INVALID | � )
continue
;;
esac
host="$host$word "
done
# '$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 $os in
Linux*|Minix*)
IFS=. read -r s _ < /proc/uptime
;;
Darwin*|*BSD*)
s=$(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 is just a simple wrapper around 'command -v' to avoid
# spamming '>/dev/null' throughout this function.
has() { command -v "$1" >/dev/null; }
# This works by first checking for which package managers are
# installed and finally by printing each package manager's
# package list with each package one per line.
#
# The output from this is then piped to 'wc -l' to count each
# line, giving us the total package count of whatever package
# managers are installed.
#
# Backticks are *required* here as '/bin/sh' on macOS is
# 'bash 3.2' and it can't handle the following:
#
# var=$(
# code here
# )
#
# shellcheck disable=2006
packages=`
case $os in
Linux*)
# Commands which print packages one per line.
has kiss && kiss l
has bonsai && bonsai list
has pacman-key && pacman -Qq
has dpkg && dpkg-query -f '.\n' -W
has rpm && rpm -qa
has xbps-query && xbps-query -l
has apk && apk info
has guix && guix package --list-installed
# Directories containing packages.
has brew && printf '%s\n' "$(brew --cellar)/"*
has emerge && printf '%s\n' /var/db/pkg/*/*/
has pkgtool && printf '%s\n' /var/log/packages/*
# NIX requires two commands.
has nix-store && {
nix-store -q --requisites /run/current-system/sw
nix-store -q --requisites ~.nix-profile
}
;;
Darwin*)
# Commands which print packages one per line.
has pkgin && pkgin list
has port && port installed
# Directories containing packages.
has 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/*
;;
Minix)
printf '%s\n' /usr/pkg/var/db/pkg/*/
;;
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=$((mem_full / 1024 / 1024))
;;
Minix)
# Minix includes the '/proc' filesystem though the format
# differs from Linux. The '/proc/meminfo' file is only a
# single line with space separated elements and elements
# 2 and 3 contain the total and free memory numbers.
read -r _ mem_full mem_free _ < /proc/meminfo
mem_used=$(((mem_full - mem_free) / 1024))
mem_full=$(( mem_full / 1024))
;;
esac
log memory "${mem_used:-?}M / ${mem_full:-?}M" >&6
}
get_palette() {
# Print the first 8 terminal colors. This uses the existing
# sequences to change text color with a sequence prepended
# to reverse the foreground and background colors.
#
# This allows us to save hardcoding a second set of sequences
# for background colors.
palette=" �[7m$c1 $c2 $c3 $c4 $c5 $c6 $c7 "
# Print the palette with a newline before and after.
# The '\033[%sC' moves the text to the right, the
# length of the ascii art.
printf '\n�[%sC%s�[m\n' "${ascii_width-1}" "$palette" >&6
}
get_ascii() {
# This is a simple function to read the contents of
# an ascii file from 'stdin'. It allows for the use
# of '<<-EOF' to prevent the break in indentation in
# this source code.
#
# This function also sets the text colors according
# to the ascii color.
read_ascii() {
# 'PF_COL1': Set the info name color according to ascii color.
# 'PF_COL3': Set the title color to some other color. ¯\_(ツ)_/¯
PF_COL1=${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]inix*)
read_ascii 4 <<-EOF
${c4} ,, ,,
;${c7},${c4} ', ,' ${c7},${c4};
; ${c7}',${c4} ',,' ${c7},'${c4} ;
; ${c7}',${c4} ${c7},'${c4} ;
; ${c7};, '' ,;${c4} ;
; ${c7};${c4};${c7}',,'${c4};${c7};${c4} ;
', ${c7};${c4};; ;;${c7};${c4} ,'
'${c7};${c4}' '${c7};${c4}'
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 '�[3Xm' 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�[1m%s�[m�[%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'.
[ "$1" = -v ] || exec 2>/dev/null
# Hide 'stdout' and selectively print to it using '>&6'.
# This gives full control over what it displayed on the screen.
exec 6>&1 >/dev/null
# Generic color list.
# Disable warning about unused variables.
# shellcheck disable=2034
{
c1='�[31m'; c2='�[32m'
c3='�[33m'; c4='�[34m'
c5='�[35m'; c6='�[36m'
c7='�[37m'; c8='�[38m'
}
# Store the output of 'uname' to avoid calling it multiple times
# throughout the script. 'read </dev/null &&
info_length=$((${#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'
: $((i+=1))
done >&6
}
main "$@"