tools/gpio/gpio-sloppy-logic-analyzer.sh - linux - Git at Google

 #!/bin/sh -eu
 # SPDX-License-Identifier: GPL-2.0
 #
 # Helper script for the Linux Kernel GPIO sloppy logic analyzer
 #
 # Copyright (C) Wolfram Sang <wsa@sang-engineering.com>
 # Copyright (C) Renesas Electronics Corporation

 samplefreq=1000000
 numsamples=250000
 cpusetdefaultdir='/sys/fs/cgroup'
 cpusetprefix='cpuset.'
 debugdir='/sys/kernel/debug'
 ladirname='gpio-sloppy-logic-analyzer'
 outputdir="$PWD"
 neededcmds='taskset zip'
 max_chans=8
 duration=
 initcpu=
 listinstances=0
 lainstance=
 lasysfsdir=
 triggerdat=
 trigger_bindat=
 progname="${0##*/}"
 print_help()
 {
 	cat << EOF
 $progname - helper script for the Linux Kernel Sloppy GPIO Logic Analyzer
 Available options:
 	-c|--cpu <n>: which CPU to isolate for sampling. Only needed once. Default <1>.
 		      Remember that a more powerful CPU gives you higher sampling speeds.
 		      Also CPU0 is not recommended as it usually does extra bookkeeping.
 	-d|--duration-us <SI-n>: number of microseconds to sample. Overrides -n, no default value.
 	-h|--help: print this help
 	-i|--instance <str>: name of the logic analyzer in case you have multiple instances. Default
 			     to first instance found
 	-k|--kernel-debug-dir <str>: path to the kernel debugfs mountpoint. Default: <$debugdir>
 	-l|--list-instances: list all available instances
 	-n|--num_samples <SI-n>: number of samples to acquire. Default <$numsamples>
 	-o|--output-dir <str>: directory to put the result files. Default: current dir
 	-s|--sample_freq <SI-n>: desired sampling frequency. Might be capped if too large.
 				 Default: <1000000>
 	-t|--trigger <str>: pattern to use as trigger. <str> consists of two-char pairs. First
 			    char is channel number starting at "1". Second char is trigger level:
 			    "L" - low; "H" - high; "R" - rising; "F" - falling
 			    These pairs can be combined with "+", so "1H+2F" triggers when probe 1
 			    is high while probe 2 has a falling edge. You can have multiple triggers
 			    combined with ",". So, "1H+2F,1H+2R" is like the example before but it
 			    waits for a rising edge on probe 2 while probe 1 is still high after the
 			    first trigger has been met.
 			    Trigger data will only be used for the next capture and then be erased.

 <SI-n> is an integer value where SI units "T", "G", "M", "K" are recognized, e.g. '1M500K' is 1500000.

 Examples:
 Samples $numsamples values at 1MHz with an already prepared CPU or automatically prepares CPU1 if needed,
 use the first logic analyzer instance found:
 	'$progname'
 Samples 50us at 2MHz waiting for a falling edge on channel 2. CPU and instance as above:
 	'$progname -d 50 -s 2M -t "2F"'

 Note that the process exits after checking all parameters but a sub-process still works in
 the background. The result is only available once the sub-process finishes.

 Result is a .sr file to be consumed with PulseView from the free Sigrok project. It is
 a zip file which also contains the binary sample data which may be consumed by others.
 The filename is the logic analyzer instance name plus a since-epoch timestamp.
 EOF
 }

 fail()
 {
 	echo "$1"
 	exit 1
 }

 parse_si()
 {
 	conv_si="$(printf $1 | sed 's/[tT]+\?/*1000G+/g; s/[gG]+\?/*1000M+/g; s/[mM]+\?/*1000K+/g; s/[kK]+\?/*1000+/g; s/+$//')"
 	si_val="$((conv_si))"
 }
 set_newmask()
 {
 	for f in $(find "$1" -iname "$2"); do echo "$newmask" > "$f" 2>/dev/null || true; done
 }

 init_cpu()
 {
 	isol_cpu="$1"

 	[ -d "$lacpusetdir" ] || mkdir "$lacpusetdir"

 	cur_cpu=$(cat "${lacpusetfile}cpus")
 	[ "$cur_cpu" = "$isol_cpu" ] && return
 	[ -z "$cur_cpu" ] || fail "CPU$isol_cpu requested but CPU$cur_cpu already isolated"

 	echo "$isol_cpu" > "${lacpusetfile}cpus" || fail "Could not isolate CPU$isol_cpu. Does it exist?"
 	echo 1 > "${lacpusetfile}cpu_exclusive"
 	echo 0 > "${lacpusetfile}mems"

 	oldmask=$(cat /proc/irq/default_smp_affinity)
 	newmask=$(printf "%x" $((0x$oldmask & ~(1 << isol_cpu))))

 	set_newmask '/proc/irq' '*smp_affinity'
 	set_newmask '/sys/devices/virtual/workqueue/' 'cpumask'

 	# Move tasks away from isolated CPU
 	for p in $(ps -o pid | tail -n +2); do
 		mask=$(taskset -p "$p") || continue
 		# Ignore tasks with a custom mask, i.e. not equal $oldmask
 		[ "${mask##*: }" = "$oldmask" ] || continue
 		taskset -p "$newmask" "$p" || continue
 	done 2>/dev/null >/dev/null

 	# Big hammer! Working with 'rcu_momentary_dyntick_idle()' for a more fine-grained solution
 	# still printed warnings. Same for re-enabling the stall detector after sampling.
 	echo 1 > /sys/module/rcupdate/parameters/rcu_cpu_stall_suppress

 	cpufreqgov="/sys/devices/system/cpu/cpu$isol_cpu/cpufreq/scaling_governor"
 	[ -w "$cpufreqgov" ] && echo 'performance' > "$cpufreqgov" || true
 }

 parse_triggerdat()
 {
 	oldifs="$IFS"
 	IFS=','; for trig in $1; do
 		mask=0; val1=0; val2=0
 		IFS='+'; for elem in $trig; do
 			chan=${elem%[lhfrLHFR]}
 			mode=${elem#$chan}
 			# Check if we could parse something and the channel number fits
 			[ "$chan" != "$elem" ] && [ "$chan" -le $max_chans ] || fail "Trigger syntax error: $elem"
 			bit=$((1 << (chan - 1)))
 			mask=$((mask | bit))
 			case $mode in
 				[hH]) val1=$((val1 | bit)); val2=$((val2 | bit));;
 				[fF]) val1=$((val1 | bit));;
 				[rR]) val2=$((val2 | bit));;
 			esac
 		done
 		trigger_bindat="$trigger_bindat$(printf '\\%o\\%o' $mask $val1)"
 		[ $val1 -ne $val2 ] && trigger_bindat="$trigger_bindat$(printf '\\%o\\%o' $mask $val2)"
 	done
 	IFS="$oldifs"
 }

 do_capture()
 {
 	taskset "$1" echo 1 > "$lasysfsdir"/capture || fail "Capture error! Check kernel log"

 	srtmp=$(mktemp -d)
 	echo 1 > "$srtmp"/version
 	cp "$lasysfsdir"/sample_data "$srtmp"/logic-1-1
 	cat > "$srtmp"/metadata << EOF
 [global]
 sigrok version=0.2.0

 [device 1]
 capturefile=logic-1
 total probes=$(wc -l < "$lasysfsdir"/meta_data)
 samplerate=${samplefreq}Hz
 unitsize=1
 EOF
 	cat "$lasysfsdir"/meta_data >> "$srtmp"/metadata

 	zipname="$outputdir/${lasysfsdir##*/}-$(date +%s).sr"
 	zip -jq "$zipname" "$srtmp"/*
 	rm -rf "$srtmp"
 	delay_ack=$(cat "$lasysfsdir"/delay_ns_acquisition)
 	[ "$delay_ack" -eq 0 ] && delay_ack=1
 	echo "Logic analyzer done. Saved '$zipname'"
 	echo "Max sample frequency this time: $((1000000000 / delay_ack))Hz."
 }

 rep=$(getopt -a -l cpu:,duration-us:,help,instance:,list-instances,kernel-debug-dir:,num_samples:,output-dir:,sample_freq:,trigger: -o c:d:hi:k:ln:o:s:t: -- "$@") || exit 1
 eval set -- "$rep"
 while true; do
 	case "$1" in
 	-c|--cpu) initcpu="$2"; shift;;
 	-d|--duration-us) parse_si $2; duration=$si_val; shift;;
 	-h|--help) print_help; exit 0;;
 	-i|--instance) lainstance="$2"; shift;;
 	-k|--kernel-debug-dir) debugdir="$2"; shift;;
 	-l|--list-instances) listinstances=1;;
 	-n|--num_samples) parse_si $2; numsamples=$si_val; shift;;
 	-o|--output-dir) outputdir="$2"; shift;;
 	-s|--sample_freq) parse_si $2; samplefreq=$si_val; shift;;
 	-t|--trigger) triggerdat="$2"; shift;;
 	--) break;;
 	*) fail "error parsing command line: $*";;
 	esac
 	shift
 done

 for f in $neededcmds; do
 	command -v "$f" >/dev/null || fail "Command '$f' not found"
 done

 # print cpuset mountpoint if any, errorcode > 0 if noprefix option was found
 cpusetdir=$(awk '$3 == "cgroup" && $4 ~ /cpuset/ { print $2; exit (match($4, /noprefix/) > 0) }' /proc/self/mounts) || cpusetprefix=''
 if [ -z "$cpusetdir" ]; then
 	cpusetdir="$cpusetdefaultdir"
 	[ -d $cpusetdir ] || mkdir $cpusetdir
 	mount -t cgroup -o cpuset none $cpusetdir || fail "Couldn't mount cpusets. Not in kernel or already in use?"
 fi

 lacpusetdir="$cpusetdir/$ladirname"
 lacpusetfile="$lacpusetdir/$cpusetprefix"
 sysfsdir="$debugdir/$ladirname"

 [ "$samplefreq" -ne 0 ] || fail "Invalid sample frequency"

 [ -d "$sysfsdir" ] || fail "Could not find logic analyzer root dir '$sysfsdir'. Module loaded?"
 [ -x "$sysfsdir" ] || fail "Could not access logic analyzer root dir '$sysfsdir'. Need root?"

 [ $listinstances -gt 0 ] && find "$sysfsdir" -mindepth 1 -type d | sed 's|.*/||' && exit 0

 if [ -n "$lainstance" ]; then
 	lasysfsdir="$sysfsdir/$lainstance"
 else
 	lasysfsdir=$(find "$sysfsdir" -mindepth 1 -type d -print -quit)
 fi
 [ -d "$lasysfsdir" ] || fail "Logic analyzer directory '$lasysfsdir' not found!"
 [ -d "$outputdir" ] || fail "Output directory '$outputdir' not found!"

 [ -n "$initcpu" ] && init_cpu "$initcpu"
 [ -d "$lacpusetdir" ] || { echo "Auto-Isolating CPU1"; init_cpu 1; }

 ndelay=$((1000000000 / samplefreq))
 echo "$ndelay" > "$lasysfsdir"/delay_ns

 [ -n "$duration" ] && numsamples=$((samplefreq * duration / 1000000))
 echo $numsamples > "$lasysfsdir"/buf_size

 if [ -n "$triggerdat" ]; then
 	parse_triggerdat "$triggerdat"
 	printf "$trigger_bindat" > "$lasysfsdir"/trigger 2>/dev/null || fail "Trigger data '$triggerdat' rejected"
 fi

 workcpu=$(cat "${lacpusetfile}effective_cpus")
 [ -n "$workcpu" ] || fail "No isolated CPU found"
 cpumask=$(printf '%x' $((1 << workcpu)))
 instance=${lasysfsdir##*/}
 echo "Setting up '$instance': $numsamples samples at ${samplefreq}Hz with ${triggerdat:-no} trigger using CPU$workcpu"
 do_capture "$cpumask" &
	#!/bin/sh -eu
	# SPDX-License-Identifier: GPL-2.0
	#
	# Helper script for the Linux Kernel GPIO sloppy logic analyzer
	#
	# Copyright (C) Wolfram Sang <wsa@sang-engineering.com>
	# Copyright (C) Renesas Electronics Corporation

	samplefreq=1000000
	numsamples=250000
	cpusetdefaultdir='/sys/fs/cgroup'
	cpusetprefix='cpuset.'
	debugdir='/sys/kernel/debug'
	ladirname='gpio-sloppy-logic-analyzer'
	outputdir="$PWD"
	neededcmds='taskset zip'
	max_chans=8
	duration=
	initcpu=
	listinstances=0
	lainstance=
	lasysfsdir=
	triggerdat=
	trigger_bindat=
	progname="${0##*/}"
	print_help()
	{
	cat << EOF
	$progname - helper script for the Linux Kernel Sloppy GPIO Logic Analyzer
	Available options:
	-c\|--cpu <n>: which CPU to isolate for sampling. Only needed once. Default <1>.
	Remember that a more powerful CPU gives you higher sampling speeds.
	Also CPU0 is not recommended as it usually does extra bookkeeping.
	-d\|--duration-us <SI-n>: number of microseconds to sample. Overrides -n, no default value.
	-h\|--help: print this help
	-i\|--instance <str>: name of the logic analyzer in case you have multiple instances. Default
	to first instance found
	-k\|--kernel-debug-dir <str>: path to the kernel debugfs mountpoint. Default: <$debugdir>
	-l\|--list-instances: list all available instances
	-n\|--num_samples <SI-n>: number of samples to acquire. Default <$numsamples>
	-o\|--output-dir <str>: directory to put the result files. Default: current dir
	-s\|--sample_freq <SI-n>: desired sampling frequency. Might be capped if too large.
	Default: <1000000>
	-t\|--trigger <str>: pattern to use as trigger. <str> consists of two-char pairs. First
	char is channel number starting at "1". Second char is trigger level:
	"L" - low; "H" - high; "R" - rising; "F" - falling
	These pairs can be combined with "+", so "1H+2F" triggers when probe 1
	is high while probe 2 has a falling edge. You can have multiple triggers
	combined with ",". So, "1H+2F,1H+2R" is like the example before but it
	waits for a rising edge on probe 2 while probe 1 is still high after the
	first trigger has been met.
	Trigger data will only be used for the next capture and then be erased.

	<SI-n> is an integer value where SI units "T", "G", "M", "K" are recognized, e.g. '1M500K' is 1500000.

	Examples:
	Samples $numsamples values at 1MHz with an already prepared CPU or automatically prepares CPU1 if needed,
	use the first logic analyzer instance found:
	'$progname'
	Samples 50us at 2MHz waiting for a falling edge on channel 2. CPU and instance as above:
	'$progname -d 50 -s 2M -t "2F"'

	Note that the process exits after checking all parameters but a sub-process still works in
	the background. The result is only available once the sub-process finishes.

	Result is a .sr file to be consumed with PulseView from the free Sigrok project. It is
	a zip file which also contains the binary sample data which may be consumed by others.
	The filename is the logic analyzer instance name plus a since-epoch timestamp.
	EOF
	}

	fail()
	{
	echo "$1"
	exit 1
	}

	parse_si()
	{
	conv_si="$(printf $1 \| sed 's/[tT]+\?/1000G+/g; s/[gG]+\?/1000M+/g; s/[mM]+\?/1000K+/g; s/[kK]+\?/1000+/g; s/+$//')"
	si_val="$((conv_si))"
	}
	set_newmask()
	{
	for f in $(find "$1" -iname "$2"); do echo "$newmask" > "$f" 2>/dev/null \|\| true; done
	}

	init_cpu()
	{
	isol_cpu="$1"

	[ -d "$lacpusetdir" ] \|\| mkdir "$lacpusetdir"

	cur_cpu=$(cat "${lacpusetfile}cpus")
	[ "$cur_cpu" = "$isol_cpu" ] && return
	[ -z "$cur_cpu" ] \|\| fail "CPU$isol_cpu requested but CPU$cur_cpu already isolated"

	echo "$isol_cpu" > "${lacpusetfile}cpus" \|\| fail "Could not isolate CPU$isol_cpu. Does it exist?"
	echo 1 > "${lacpusetfile}cpu_exclusive"
	echo 0 > "${lacpusetfile}mems"

	oldmask=$(cat /proc/irq/default_smp_affinity)
	newmask=$(printf "%x" $((0x$oldmask & ~(1 << isol_cpu))))

	set_newmask '/proc/irq' '*smp_affinity'
	set_newmask '/sys/devices/virtual/workqueue/' 'cpumask'

	# Move tasks away from isolated CPU
	for p in $(ps -o pid \| tail -n +2); do
	mask=$(taskset -p "$p") \|\| continue
	# Ignore tasks with a custom mask, i.e. not equal $oldmask
	[ "${mask##*: }" = "$oldmask" ] \|\| continue
	taskset -p "$newmask" "$p" \|\| continue
	done 2>/dev/null >/dev/null

	# Big hammer! Working with 'rcu_momentary_dyntick_idle()' for a more fine-grained solution
	# still printed warnings. Same for re-enabling the stall detector after sampling.
	echo 1 > /sys/module/rcupdate/parameters/rcu_cpu_stall_suppress

	cpufreqgov="/sys/devices/system/cpu/cpu$isol_cpu/cpufreq/scaling_governor"
	[ -w "$cpufreqgov" ] && echo 'performance' > "$cpufreqgov" \|\| true
	}

	parse_triggerdat()
	{
	oldifs="$IFS"
	IFS=','; for trig in $1; do
	mask=0; val1=0; val2=0
	IFS='+'; for elem in $trig; do
	chan=${elem%[lhfrLHFR]}
	mode=${elem#$chan}
	# Check if we could parse something and the channel number fits
	[ "$chan" != "$elem" ] && [ "$chan" -le $max_chans ] \|\| fail "Trigger syntax error: $elem"
	bit=$((1 << (chan - 1)))
	mask=$((mask \| bit))
	case $mode in
	[hH]) val1=$((val1 \| bit)); val2=$((val2 \| bit));;
	[fF]) val1=$((val1 \| bit));;
	[rR]) val2=$((val2 \| bit));;
	esac
	done
	trigger_bindat="$trigger_bindat$(printf '\\%o\\%o' $mask $val1)"
	[ $val1 -ne $val2 ] && trigger_bindat="$trigger_bindat$(printf '\\%o\\%o' $mask $val2)"
	done
	IFS="$oldifs"
	}

	do_capture()
	{
	taskset "$1" echo 1 > "$lasysfsdir"/capture \|\| fail "Capture error! Check kernel log"

	srtmp=$(mktemp -d)
	echo 1 > "$srtmp"/version
	cp "$lasysfsdir"/sample_data "$srtmp"/logic-1-1
	cat > "$srtmp"/metadata << EOF
	[global]
	sigrok version=0.2.0

	[device 1]
	capturefile=logic-1
	total probes=$(wc -l < "$lasysfsdir"/meta_data)
	samplerate=${samplefreq}Hz
	unitsize=1
	EOF
	cat "$lasysfsdir"/meta_data >> "$srtmp"/metadata

	zipname="$outputdir/${lasysfsdir##*/}-$(date +%s).sr"
	zip -jq "$zipname" "$srtmp"/*
	rm -rf "$srtmp"
	delay_ack=$(cat "$lasysfsdir"/delay_ns_acquisition)
	[ "$delay_ack" -eq 0 ] && delay_ack=1
	echo "Logic analyzer done. Saved '$zipname'"
	echo "Max sample frequency this time: $((1000000000 / delay_ack))Hz."
	}

	rep=$(getopt -a -l cpu:,duration-us:,help,instance:,list-instances,kernel-debug-dir:,num_samples:,output-dir:,sample_freq:,trigger: -o c:d:hi:k:ln:o:s:t: -- "$@") \|\| exit 1
	eval set -- "$rep"
	while true; do
	case "$1" in
	-c\|--cpu) initcpu="$2"; shift;;
	-d\|--duration-us) parse_si $2; duration=$si_val; shift;;
	-h\|--help) print_help; exit 0;;
	-i\|--instance) lainstance="$2"; shift;;
	-k\|--kernel-debug-dir) debugdir="$2"; shift;;
	-l\|--list-instances) listinstances=1;;
	-n\|--num_samples) parse_si $2; numsamples=$si_val; shift;;
	-o\|--output-dir) outputdir="$2"; shift;;
	-s\|--sample_freq) parse_si $2; samplefreq=$si_val; shift;;
	-t\|--trigger) triggerdat="$2"; shift;;
	--) break;;
	) fail "error parsing command line: $";;
	esac
	shift
	done

	for f in $neededcmds; do
	command -v "$f" >/dev/null \|\| fail "Command '$f' not found"
	done

	# print cpuset mountpoint if any, errorcode > 0 if noprefix option was found
	cpusetdir=$(awk '$3 == "cgroup" && $4 ~ /cpuset/ { print $2; exit (match($4, /noprefix/) > 0) }' /proc/self/mounts) \|\| cpusetprefix=''
	if [ -z "$cpusetdir" ]; then
	cpusetdir="$cpusetdefaultdir"
	[ -d $cpusetdir ] \|\| mkdir $cpusetdir
	mount -t cgroup -o cpuset none $cpusetdir \|\| fail "Couldn't mount cpusets. Not in kernel or already in use?"
	fi

	lacpusetdir="$cpusetdir/$ladirname"
	lacpusetfile="$lacpusetdir/$cpusetprefix"
	sysfsdir="$debugdir/$ladirname"

	[ "$samplefreq" -ne 0 ] \|\| fail "Invalid sample frequency"

	[ -d "$sysfsdir" ] \|\| fail "Could not find logic analyzer root dir '$sysfsdir'. Module loaded?"
	[ -x "$sysfsdir" ] \|\| fail "Could not access logic analyzer root dir '$sysfsdir'. Need root?"

	[ $listinstances -gt 0 ] && find "$sysfsdir" -mindepth 1 -type d \| sed 's\|.*/\|\|' && exit 0

	if [ -n "$lainstance" ]; then
	lasysfsdir="$sysfsdir/$lainstance"
	else
	lasysfsdir=$(find "$sysfsdir" -mindepth 1 -type d -print -quit)
	fi
	[ -d "$lasysfsdir" ] \|\| fail "Logic analyzer directory '$lasysfsdir' not found!"
	[ -d "$outputdir" ] \|\| fail "Output directory '$outputdir' not found!"

	[ -n "$initcpu" ] && init_cpu "$initcpu"
	[ -d "$lacpusetdir" ] \|\| { echo "Auto-Isolating CPU1"; init_cpu 1; }

	ndelay=$((1000000000 / samplefreq))
	echo "$ndelay" > "$lasysfsdir"/delay_ns

	[ -n "$duration" ] && numsamples=$((samplefreq * duration / 1000000))
	echo $numsamples > "$lasysfsdir"/buf_size

	if [ -n "$triggerdat" ]; then
	parse_triggerdat "$triggerdat"
	printf "$trigger_bindat" > "$lasysfsdir"/trigger 2>/dev/null \|\| fail "Trigger data '$triggerdat' rejected"
	fi

	workcpu=$(cat "${lacpusetfile}effective_cpus")
	[ -n "$workcpu" ] \|\| fail "No isolated CPU found"
	cpumask=$(printf '%x' $((1 << workcpu)))
	instance=${lasysfsdir##*/}
	echo "Setting up '$instance': $numsamples samples at ${samplefreq}Hz with ${triggerdat:-no} trigger using CPU$workcpu"
	do_capture "$cpumask" &