100% puro bashSolo ! Senza forchetta!
Una versione finalizzata e aggiornata può essere trovata lì o in questa pagina:
ascii-clock for geeks . Ma non usarlo! Leggi la nota alla fine di questa risposta, sei stato avvisato! Usa invece questa versione perl !
Primo orologio semplice senza secondo segno di spunta.
Scalabile e modificabile:
time 2>&1 /tmp/asci-art.sh 10 10 10
. . . 12. . .
11. . 1
. .
. .
. .
10 2
. H M .
. .
. .
. .
9 3
. .
. .
. .
. .
8 4
. .
. .
. .
7 . . 5
. . . 6 . . .
real 0m0.356s
user 0m0.348s
sys 0m0.004s
Disegna un orologio 21x21 (10x2 + 1) a 10H10 in meno di un secondo.
Questo accetta 3 argomenti: Usage: ascii-clock.sh [ray of clock] [Hour] [Min]dove il raggio predefinito è 12, il disegno dell'orologio è l' 2 x ray + 1altezza delle linee e la doppia larghezza a causa dello spazio aggiunto per cercare di ottenere una forma rotonda.
Se lo script viene chiamato con 0o 1argomento, verrà ripetuto per ridisegnare ogni minuto. Altrimenti se viene specificato almeno Hour (secondo parametro), verrà disegnato solo una volta e uscirà.
Il Hmarker si trova al 70% del raggio e il Mmarker si trova al 90% del raggio.
Nessun uso di binari esterni come dateobc per il sorteggio!
(Grazie a @manatwork per l'incorporato read -t al suo posto, se/bin/sleep ).
Quindi tutto ciò è fatto da builtin comandi shell.
Usa la sequenza ANSI , ma solo per loop e per rendere audaci i marker.
#!/bin/bash
# Analog clock in Ascii-Art written in BASH V4.2 +=
RAY=${1:-12} NowH=$2 NowM=$3
sqrt() {
local -a _xx=(600000 200000)
local _x1=${_xx[$(($1&1))]} _x0=1
while [ $_x0 -ne $_x1 ] ;do
_x0=$_x1
[ $_x0 -eq 0 ] && _x1=0000 ||
printf -v _x1 "%u" $(( (${_x0}000 + ${1}00000000000/${_x0} )/2 ))
printf -v _x1 "%.0f" ${_x1:0:${#_x1}-3}.${_x1:${#_x1}-3}
done
_x1=0000$_x1
printf ${2+-v} $2 "%.3f" ${_x1:0:${#_x1}-4}.${_x1:${#_x1}-4}
}
clksin() { # $1:moment [0-60], $2:path length, $3:variable name
local _csin=(0 104528 207912 309017 406737 500000 587785 669131
743145 809017 866025 913545 951057 978148 994522 1000000)
local xsign=1 x=$1 ysign=-1 y=$1
[ $x -gt 30 ] && xsign=-1 x=$((60-x))
[ $x -gt 15 ] && x=$((30-x))
x=00000$((RAY*1000000+xsign*${2:-10}*${_csin[$x]}))
[ $y -gt 30 ] && y=$((60-y))
[ $y -gt 15 ] && ysign=1 y=$((30-y))
y=00000$((RAY*1000000+ysign*${2:-10}*${_csin[15-$y]}))
printf ${3+-v} $3 "%.0f %.0f" \
${y:0:${#y}-6}.${y:${#y}-6} ${x:0:${#x}-6}.${x:${#x}-6}
};
MLEN=000$((900*RAY))
printf -v MLEN "%.0f" ${MLEN:0:${#MLEN}-3}.${MLEN:${#MLEN}-3}
HLEN=000$((700*RAY))
printf -v HLEN "%.0f" ${HLEN:0:${#HLEN}-3}.${HLEN:${#HLEN}-3}
declare -A ticks
for ((i=1;i<=12;i++));do
clksin $((5*(i%12))) $RAY tick
ticks[$tick]=$i
done
while :;do
[ "$NowM" ] || printf -v NowM "%(%M)T\n" -1
clksin ${NowM#0} $MLEN NowM
[ "$NowH" ] || printf -v NowH "%(%H)T\n" -1
clksin $((5*(${NowH#0}%12))) $HLEN NowH
[ "$2" ] || echo -en \\e[H; # ANSI sequence for top left of console
for ((i=0;i<=2*RAY;i++));do
x=$((RAY-i))
sqrt $((RAY**2 - ${x#-}**2 )) y0
printf -v y0 "%.0f" $y0
for ((l=0;l<=2*RAY;l++));do
y=$((RAY-l));
sqrt $((RAY**2 - ${y#-}**2 )) x0
printf -v x0 "%.0f" $x0
if [ "${ticks["$i $l"]}" ] ;then
printf "%-2s" ${ticks["$i $l"]}
elif [ ${x#-} -eq $x0 ] || [ ${y#-} -eq $y0 ] ;then
echo -n .\
elif [ "$i $l" = "$NowM" ] ;then
echo -en \\e[1mM\ \\e[0m
elif [ "$i $l" = "$NowH" ] ;then
echo -en \\e[1mH\ \\e[0m
else
echo -n \ \
fi
done
echo -e \\e[K
done
echo -en \\e[J
[ "$2" ] && break # Exit if at least Hour was specified
printf -v SleepS "%(%S)T" -1
read -t $((60-${SleepS#0})) foo
unset NowH NowM
done
Questo potrebbe essere eseguito come:
for time in 10:10 15:00 12:30 06:00 09:15 16:40 ;do
echo - $time -{,}{,}{,}
./ascii-clock.sh 5 ${time//:/ }
echo -{,,,,,}{,}
done |
sed 's/\o033\[\(.m\|[JK]\)//g;/-$/!s/$/|/;s/-$/+/' |
column -c 80
Questo produrrà qualcosa di simile:
+- 10:10 - - - - - - - + - 12:30 - - - - - - - + - 09:15 - - - - - - - +
| . . 12. . | . . 12. . | . . 12. . |
| 11 1 | 11 H 1 | 11 1 |
| 10 2 | 10 2 | 10 2 |
|. H M . | . . | . . |
|. . | . . | . . |
|9 3 | 9 3 | 9 H M 3 |
|. . | . . | . . |
|. . | . . | . . |
| 8 4 | 8 4 | 8 4 |
| 7 5 | 7 M 5 | 7 5 |
| . . 6 . . | . . 6 . . | . . 6 . . |
+- - - - - - - - - - - + - - - - - - - - - - - + - - - - - - - - - - - +
+- 15:00 - - - - - - - + - 06:00 - - - - - - - + - 16:40 - - - - - - - +
| . . 12. . | . . 12. . | . . 12. . |
| 11 M 1 | 11 M 1 | 11 1 |
| 10 2 | 10 2 | 10 2 |
|. . | . . | . . |
|. . | . . | . . |
|9 H 3 | 9 3 | 9 3 |
|. . | . . | . . |
|. . | . . | . M H . |
| 8 4 | 8 4 | 8 4 |
| 7 5 | 7 H 5 | 7 5 |
| . . 6 . . | . . 6 . . | . . 6 . . |
+- - - - - - - - - - - + - - - - - - - - - - - + - - - - - - - - - - - +
O potrebbe essere eseguito come:
xterm -geom 86x44 -bg black -fg grey -e ./ascii-clock.sh 21 &
xterm -geom 103x52 -fn nil2 -bg black -fg grey -e ./ascii-clock.sh 25 &
gnome-terminal --geometry 103x52 --zoom .5 -e "./ascii-clock.sh 25" &
Alternativa: con disegno percorso completo:
#!/bin/bash
# Analog clock in Ascii-Art written in BASH V4.2 +=
RAY=${1:-12} NowH=$2 NowM=$3
sqrt() {
local -a _xx=(600000 200000)
local _x1=${_xx[$(($1&1))]} _x0=1
while [ $_x0 -ne $_x1 ] ;do
_x0=$_x1
[ $_x0 -eq 0 ] && _x1=0000 ||
printf -v _x1 "%u" $(( (${_x0}000 + ${1}00000000000/${_x0} )/2 ))
printf -v _x1 "%.0f" ${_x1:0:${#_x1}-3}.${_x1:${#_x1}-3}
done
_x1=0000$_x1
printf ${2+-v} $2 "%.3f" ${_x1:0:${#_x1}-4}.${_x1:${#_x1}-4}
}
clksin() { # $1:moment [0-60], $2:path length, $3:variable name
local _csin=(0 104528 207912 309017 406737 500000 587785 669131
743145 809017 866025 913545 951057 978148 994522 1000000)
local xsign=1 x=$1 ysign=-1 y=$1
[ $x -gt 30 ] && xsign=-1 x=$((60-x))
[ $x -gt 15 ] && x=$((30-x))
x=00000$((RAY*1000000+xsign*${2:-10}*${_csin[$x]}))
[ $y -gt 30 ] && y=$((60-y))
[ $y -gt 15 ] && ysign=1 y=$((30-y))
y=00000$((RAY*1000000+ysign*${2:-10}*${_csin[15-$y]}))
printf ${3+-v} $3 "%.0f %.0f" \
${y:0:${#y}-6}.${y:${#y}-6} ${x:0:${#x}-6}.${x:${#x}-6}
};
MLEN=000$((900*RAY))
printf -v MLEN "%.0f" ${MLEN:0:${#MLEN}-3}.${MLEN:${#MLEN}-3}
HLEN=000$((700*RAY))
printf -v HLEN "%.0f" ${HLEN:0:${#HLEN}-3}.${HLEN:${#HLEN}-3}
declare -A ticks
for ((i=1;i<=12;i++));do
clksin $((5*(i%12))) $RAY tick
ticks[$tick]=$i
done
while :;do
[ "$NowM" ] || printf -v NowM "%(%M)T\n" -1
unset MPath
declare -A MPath
for ((i=1;i<=MLEN;i++));do
clksin ${NowM#0} $i tick
MPath[$tick]=M
done
[ "$NowH" ] || printf -v NowH "%(%H)T\n" -1
unset HPath
declare -A HPath
for ((i=1;i<=HLEN;i++));do
clksin $((5*(${NowH#0}%12))) $i tick
HPath[$tick]=H
done
[ "$2" ] || echo -en \\e[H; # ANSI sequence for top left of console
for ((i=0;i<=2*RAY;i++));do
x=$((RAY-i))
sqrt $((RAY**2 - ${x#-}**2 )) y0
printf -v y0 "%.0f" $y0
for ((l=0;l<=2*RAY;l++));do
y=$((RAY-l));
sqrt $((RAY**2 - ${y#-}**2 )) x0
printf -v x0 "%.0f" $x0
if [ "${MPath["$i $l"]}" ] ;then
echo -en \\e[1m${MPath["$i $l"]}\ \\e[0m
elif [ "${HPath["$i $l"]}" ] ;then
echo -en \\e[1m${HPath["$i $l"]}\ \\e[0m
elif [ "${ticks["$i $l"]}" ] ;then
printf "%-2s" ${ticks["$i $l"]}
elif [ ${x#-} -eq $x0 ] || [ ${y#-} -eq $y0 ] ;then
echo -n .\
else
echo -n \ \
fi
done
echo -e \\e[K
done
echo -en \\e[J
[ "$2" ] && break # Exit if at least Hour was specified
printf -v SleepS "%(%S)T" -1
read -t $((60-${SleepS#0})) foo
unset NowH NowM
done
potrebbe produrre:
+- 10:10 - - - - - - - + - 12:30 - - - - - - - + - 09:15 - - - - - - - +
| . . 12. . | . . 12. . | . . 12. . |
| 11 1 | 11 H 1 | 11 1 |
| 10 2 | 10 H 2 | 10 2 |
|. H M . | . H . | . . |
|. H H H M M M . | . H . | . . |
|9 3 | 9 3 | 9 H H H H M M M M 3 |
|. . | . M . | . . |
|. . | . M . | . . |
| 8 4 | 8 M 4 | 8 4 |
| 7 5 | 7 M 5 | 7 5 |
| . . 6 . . | . . 6 . . | . . 6 . . |
+- - - - - - - - - - - + - - - - - - - - - - - + - - - - - - - - - - - +
+- 15:00 - - - - - - - + - 06:00 - - - - - - - + - 16:40 - - - - - - - +
| . . 12. . | . . 12. . | . . 12. . |
| 11 M 1 | 11 M 1 | 11 1 |
| 10 M 2 | 10 M 2 | 10 2 |
|. M . | . M . | . . |
|. M . | . M . | . . |
|9 H H H H 3 | 9 3 | 9 3 |
|. . | . H . | . M M M H H H . |
|. . | . H . | . M H . |
| 8 4 | 8 H 4 | 8 4 |
| 7 5 | 7 H 5 | 7 5 |
| . . 6 . . | . . 6 . . | . . 6 . . |
+- - - - - - - - - - - + - - - - - - - - - - - + - - - - - - - - - - - +
o
. . . . 12. . . .
. . . . . .
. . . .
. 11 1 .
. .
. .
. .
. .
. .
. .
10 2
. M .
. M M M .
. H M .
. H H M M .
. H M .
. H H H M M M .
. H M .
. H H M M .
. H M .
9 H M 3
. .
. .
. .
. .
. .
. .
. .
. .
. .
8 4
. .
. .
. .
. .
. .
. .
. 7 5 .
. . . .
. . . . . .
. . . . 6 . . . .
Ultima versione con rendering dei secondi tick e nanosleep da sincronizzare.
Funziona solo su Linux recenti, in quanto utilizza /proc/timer_listper calcolare la frazione di secondo in sospensione tra ogni aggiornamento.
#!/bin/bash
# Analog clock in Ascii-Art written in BASH V4.2 +=
RAY=${1:-12} NowH=$2 NowM=$3
# Hires Sleep Until
# there is a need to store offset in a static var
mapfile </proc/timer_list _timer_list
for ((_i=0;_i<${#_timer_list[@]};_i++));do
[[ ${_timer_list[_i]} =~ ^now ]] && TIMER_LIST_SKIP=$_i
[[ ${_timer_list[_i]} =~ offset:.*[1-9] ]] && \
TIMER_LIST_OFFSET=${_timer_list[_i]//[a-z.: ]} && \
break
done
unset _i _timer_list
readonly TIMER_LIST_OFFSET TIMER_LIST_SKIP
sleepUntilHires() {
local slp tzoff now quiet=false nsnow nsslp
local hms=(${1//:/ })
mapfile -n 1 -s $TIMER_LIST_SKIP nsnow </proc/timer_list
printf -v now '%(%s)T' -1
printf -v tzoff '%(%z)T\n' $now
nsnow=$((${nsnow//[a-z ]}+TIMER_LIST_OFFSET))
nsslp=$((2000000000-10#${nsnow:${#nsnow}-9}))
tzoff=$((0${tzoff:0:1}(3600*${tzoff:1:2}+60*${tzoff:3:2})))
slp=$(( ( 86400 + ( now - now%86400 ) +
10#$hms*3600+10#${hms[1]}*60+10#${hms[2]} -
tzoff - now - 1
) % 86400)).${nsslp:1}
read -t $slp foo
}
sqrt() {
local -a _xx=(600000 200000)
local _x1=${_xx[$(($1&1))]} _x0=1
while [ $_x0 -ne $_x1 ] ;do
_x0=$_x1
[ $_x0 -eq 0 ] && _x1=0000 ||
printf -v _x1 "%u" $(( (${_x0}000 + ${1}00000000000/${_x0} )/2 ))
printf -v _x1 "%.0f" ${_x1:0:${#_x1}-3}.${_x1:${#_x1}-3}
done
_x1=0000$_x1
printf ${2+-v} $2 "%.3f" ${_x1:0:${#_x1}-4}.${_x1:${#_x1}-4}
}
clksin() { # $1:moment [0-60], $2:path length, $3:variable name
local _csin=(0 104528 207912 309017 406737 500000 587785 669131
743145 809017 866025 913545 951057 978148 994522 1000000)
local xsign=1 x=$1 ysign=-1 y=$1
[ $x -gt 30 ] && xsign=-1 x=$((60-x))
[ $x -gt 15 ] && x=$((30-x))
x=00000$((RAY*1000000+xsign*${2:-10}*${_csin[$x]}))
[ $y -gt 30 ] && y=$((60-y))
[ $y -gt 15 ] && ysign=1 y=$((30-y))
y=00000$((RAY*1000000+ysign*${2:-10}*${_csin[15-$y]}))
printf ${3+-v} $3 "%.0f %.0f" \
${y:0:${#y}-6}.${y:${#y}-6} ${x:0:${#x}-6}.${x:${#x}-6}
};
SLEN=000$((870*RAY))
printf -v SLEN "%.0f" ${SLEN:0:${#SLEN}-3}.${SLEN:${#SLEN}-3}
MLEN=000$((780*RAY))
printf -v MLEN "%.0f" ${MLEN:0:${#MLEN}-3}.${MLEN:${#MLEN}-3}
HLEN=000$((650*RAY))
printf -v HLEN "%.0f" ${HLEN:0:${#HLEN}-3}.${HLEN:${#HLEN}-3}
declare -A ticks
for ((i=1;i<=12;i++));do
clksin $((5*(i%12))) $RAY tick
ticks[$tick]=$i
done
while :;do
[ "$NowM" ] || printf -v NowM "%(%M)T\n" -1
unset MPath
declare -A MPath
for ((i=1;i<=MLEN;i++));do
clksin ${NowM#0} $i tick
MPath[$tick]=M
done
[ "$NowH" ] || printf -v NowH "%(%H)T\n" -1
unset HPath
declare -A HPath
for ((i=1;i<=HLEN;i++));do
clksin $((5*(${NowH#0}%12))) $i tick
HPath[$tick]=H
done
printf -v NowS "%(%S)T\n" -1
clksin ${NowS#0} $SLEN STick
[ "$2" ] || echo -en \\e[H; # ANSI sequence for top left of console
for ((i=0;i<=2*RAY;i++));do
x=$((RAY-i))
sqrt $((RAY**2 - ${x#-}**2 )) y0
printf -v y0 "%.0f" $y0
for ((l=0;l<=2*RAY;l++));do
y=$((RAY-l));
sqrt $((RAY**2 - ${y#-}**2 )) x0
printf -v x0 "%.0f" $x0
if [ "$i $l" = "$STick" ] ;then
echo -en \\e[1ms\ \\e[0m
elif [ "${MPath["$i $l"]}" ] ;then
echo -en \\e[1m${MPath["$i $l"]}\ \\e[0m
elif [ "${HPath["$i $l"]}" ] ;then
echo -en \\e[1m${HPath["$i $l"]}\ \\e[0m
elif [ "${ticks["$i $l"]}" ] ;then
printf "%-2s" ${ticks["$i $l"]}
elif [ ${x#-} -eq $x0 ] || [ ${y#-} -eq $y0 ] ;then
echo -n .\
else
echo -n \ \
fi
done
echo -e \\e[K
done
echo -en \\e[J
[ "$2" ] && break # Exit if at least Hour was specified
printf -v SleepS "%(%s)T" -1
printf -v SleepS "%(%T)T" $((1+SleepS))
sleepUntilHires $SleepS
unset NowH NowM
done
Versione più offuscata (2702 byte):
Come richiesto da @manatwork , esiste una versione più giocata a golf .
Questa versione è colorata e presenta l'ora digitale sugli angoli.
#!/bin/bash
W=/proc;J=${1:-12} B=$2 A=$3 LANG=C R=$W/timer_list;if [ -f $R ];then Q=10
mapfile <$R e;for ((P=0;P<${#e[@]};P++));do ((Q+=${#e[P]}));[[ ${e[P]} =~ ^now
]]&&U=$Q;[[ ${e[P]} =~ offset:.*[1-9] ]]&&a=${e[P]//[a-z.: ]}&&break;done;c(){
local q p;read -N$U q <$R;q=${q%% nse*};q=$[${q##* }+a];p=$[2000000000-10#${q:
${#q}-9}];read -t .${p:1} M;};else c(){ local H;read -d\ H < $W/upti*;H=$[200
-10#${H#*.}];read -t .${H:1} M;};fi;u(){ local E=({6,2}00000) F=${E[$1&1]} G=1
while [ $G -ne $F ];do G=$F;[ $G -eq 0 ]&&F=0000||printf -v F "%u" $(((${G}000
+${1}00000000000/${G})/2));printf -v F "%.0f" ${F:0:${#F}-3}.${F:${#F}-3};done
F=0000$F;printf -v $2 "%.3f" ${F:0:${#F}-4}.${F:${#F}-4};};g(){ local t=($[7#0
] 104528 207912 309017 406737 500000 587785 669131 743145 809017 866025 913545
951057 978148 994522 1000000) j=1 x=$1 h=-1 y=$1;[ $x -gt 30 ]&&j=-1 x=$[60-x]
((x>15))&&x=$[30-x];x=00000$[J*1000000+j*${2:-10}*${t[$x]}];((y>30))&&y=$[60-y
];((y>15))&&h=1 y=$[30-y];y=00000$[J*1000000+h*${2:-10}*${t[15-y]}];printf -v\
$3 "%.0f %.0f" ${y:0:${#y}-6}.${y:${#y}-6} ${x:0:${#x}-6}.${x:${#x}-6};};v=000
v+=$((870 *J));printf -v v "%.0f" ${v:0:${#v}-3}.${v:${#v}-3};C=000$((780*J));
printf -v C "%.0f" ${C:0:${#C}-3}.${C:${#C}-3};D=000$[650*J];printf -v D %.f \
${D:0:${#D}-3}.${D:${#D}-3};declare -A m;for ((i=1;i<=12;i++));do g $[5*(i%12)
] $J w;m[$w]=$i;done;printf -v T "\e[1m%s\e[0m " . + \* o O;T=(${T});m["${J: \
} $J"]=${T} ;printf "\e[?25l\e[H\e[J";trap "printf '\e[?12l\e[?25h\e[$((2*J +3
))H\e[J';exit" 0 1 2 3 6 9 15; printf -v S "\\e[1;%dH%%(%%H)T\\e[%dH%%(%%M${Z:
})T\\e[%d;%dH%%(%%S)T" $[4*J] $[2*J+1] $[2*J+1] $[4*J];declare -A V;V["$[2 * J
] $[2*$J]"]=" ";while :;do [ "$A" ]||printf -v A "%(%M)T" -1;unset r;declare\
-A r;for ((i=1;i<=C;i++));do g ${A#0} $i w;r[$w]=M;done;[ "$B" ]||printf -v \
B "%(%H)T" -1;unset s;declare -A s;for ((i=1;i<=D;i++));do g $((5*( ${B#0}%12)
)) $i w;s[$w]=H;done;printf -v z "%(%S)T" -1;g ${z#0} $v n;[ "$2" ]||echo -en\
\\e[H;for ((i=0;i<=2*J;i++));do x=$[J-i];u $[J*J-${x#-}**2] N;printf -v N${Z:
} %.f $N;for ((l=0;l<=2*J;l++));do y=$[J-l];u $[J*J-${y#-}**2] O;printf -v O \
%.f $O;c=" ";if [ "$i $l" = "$n" ];then c=$'\e[36;1ms \e[m';elif [ "${r["${i:
} $l"]}" ] ;then c=$'\e[32;1m'${r["$i $l"]}$' \e[0m';elif [ "${s["$i $l"]}" ];
then c=$'\e[34;1m'${s["$i $l"]}$' \e[0m';elif [ "${m["$i $l"]}" ];then printf\
-v c "%-2s" "${m["$i $l"]}";elif [ ${x#-} -eq $O ] || [ ${y#-} -eq $N ] ;then
c=.\ ;else c=" ";fi;[ "$c" != "${V["$i $l"]}" ]&& V["$i $l"]="$c" && printf \
"\e[%s;%sH%-2s" $((1+i)) $[1+l*2] "$c";done;done;[ "$2" ] &&break;printf "${Z:
}\e[H\e[7mS\e[0m";c;printf "\e[H $S" -1 -1 -1;m["$J $J"]=${T[$[10#$z%${#T[@]}]
]};unset B A;done
Nota: non usarlo comunque!
Poiché questo è bash programm e poiché bash non è un linguaggio di programmazione, non è bene usarlo per un po '.
C'è una piccola demo del consumo di memoria in sole 5 ore, con un disegno di raggio di 7 caratteri:
$ ascii-clock.sh 7
After PMem PCpu Mem
0'30" 0.0% 21.6% 12.98M
10'30" 1.0% 20.9% 48.91M
1h 0'30" 5.6% 20.8% 228.63M
2h 0'31" 11.2% 20.8% 444.25M
3h 0'32" 16.8% 20.8% 659.91M
5h 0'00" 27.9% 20.8% 1.064G
Il vantaggio principale di questo è che quando ho bisogno di memoria, devo solo uccidere l'orologio.
( Nota: ho unito questo, la versione perl e una versione javascript dello stesso su ascii-clock per i geek ;-)
