tools/klockstat.py - platform/external/bcc - Git at Google

 #!/usr/bin/env python
 #
 # klockstat traces lock events and display locks statistics.
 #
 # USAGE: klockstat
 #

 from __future__ import print_function
 from bcc import BPF, USDT
 import argparse
 import subprocess
 import ctypes as ct
 from time import sleep, strftime
 from datetime import datetime, timedelta
 import errno
 from sys import stderr

 examples = """
     klockstat                           # trace system wide
     klockstat -d 5                      # trace for 5 seconds only
     klockstat -i 5                      # display stats every 5 seconds
     klockstat -p 123                    # trace locks for PID 123
     klockstat -t 321                    # trace locks for TID 321
     klockstat -c pipe_                  # display stats only for lock callers with 'pipe_' substring
     klockstat -S acq_count              # sort lock acquired results on acquired count
     klockstat -S hld_total              # sort lock held results on total held time
     klockstat -S acq_count,hld_total    # combination of above
     klockstat -n 3                      # display 3 locks
     klockstat -s 3                      # display 3 levels of stack
 """

 # arg validation
 def positive_int(val):
     try:
         ival = int(val)
     except ValueError:
         raise argparse.ArgumentTypeError("must be an integer")

     if ival < 0:
         raise argparse.ArgumentTypeError("must be positive")
     return ival

 def positive_nonzero_int(val):
     ival = positive_int(val)
     if ival == 0:
         raise argparse.ArgumentTypeError("must be nonzero")
     return ival

 def stack_id_err(stack_id):
     # -EFAULT in get_stackid normally means the stack-trace is not available,
     # Such as getting kernel stack trace in userspace code
     return (stack_id < 0) and (stack_id != -errno.EFAULT)

 parser = argparse.ArgumentParser(
     description="",
     formatter_class=argparse.RawDescriptionHelpFormatter,
     epilog=examples)

 time_group = parser.add_mutually_exclusive_group()
 time_group.add_argument("-d", "--duration", type=int,
     help="total duration of trace in seconds")
 time_group.add_argument("-i", "--interval", type=int,
     help="print summary at this interval (seconds)")
 parser.add_argument("-n", "--locks", type=int, default=99999999,
     help="print given number of locks")
 parser.add_argument("-s", "--stacks", type=int, default=1,
     help="print given number of stack entries")
 parser.add_argument("-c", "--caller",
     help="print locks taken by given caller")
 parser.add_argument("-S", "--sort",
     help="sort data on <aq_field,hd_field>, fields: acq_[max|total|count] hld_[max|total|count]")
 parser.add_argument("-p", "--pid",
     help="trace this PID only")
 parser.add_argument("-t", "--tid",
     help="trace this TID only")
 parser.add_argument("--stack-storage-size", default=16384,
     type=positive_nonzero_int,
     help="the number of unique stack traces that can be stored and "
          "displayed (default 16384)")

 args = parser.parse_args()

 program = """
 #include <uapi/linux/ptrace.h>

 struct depth_id {
   u64 id;
   u64 depth;
 };

 BPF_ARRAY(enabled,   u64, 1);
 BPF_HASH(track,      u64, u64);
 BPF_HASH(time_aq,    u64, u64);
 BPF_HASH(lock_depth, u64, u64);
 BPF_HASH(time_held,  struct depth_id, u64);
 BPF_HASH(stack,      struct depth_id, int);

 BPF_HASH(aq_report_count, int, u64);
 BPF_HASH(aq_report_max,   int, u64);
 BPF_HASH(aq_report_total, int, u64);

 BPF_HASH(hl_report_count, int, u64);
 BPF_HASH(hl_report_max,   int, u64);
 BPF_HASH(hl_report_total, int, u64);

 BPF_STACK_TRACE(stack_traces, STACK_STORAGE_SIZE);

 static bool is_enabled(void)
 {
     int key = 0;
     u64 *ret;

     ret = enabled.lookup(&key);
     return ret && *ret == 1;
 }

 static bool allow_pid(u64 id)
 {
     u32 pid = id >> 32; // PID is higher part
     u32 tid = id;       // Cast and get the lower part

     FILTER

     return 1;
 }

 static int do_mutex_lock_enter(void *ctx, int skip)
 {
     if (!is_enabled())
         return 0;

     u64 id = bpf_get_current_pid_tgid();

     if (!allow_pid(id))
         return 0;

     u64 one = 1, zero = 0;

     track.update(&id, &one);

     u64 *depth = lock_depth.lookup(&id);

     if (!depth) {
         lock_depth.update(&id, &zero);

         depth = lock_depth.lookup(&id);
         /* something is wrong.. */
         if (!depth)
             return 0;
     }

     int stackid = stack_traces.get_stackid(ctx, skip);
     struct depth_id did = {
       .id    = id,
       .depth = *depth,
     };
     stack.update(&did, &stackid);

     u64 ts = bpf_ktime_get_ns();
     time_aq.update(&id, &ts);

     *depth += 1;
     return 0;
 }

 static void update_aq_report_count(int *stackid)
 {
     u64 *count, one = 1;

     count = aq_report_count.lookup(stackid);
     if (!count) {
         aq_report_count.update(stackid, &one);
     } else {
         *count += 1;
     }
 }

 static void update_hl_report_count(int *stackid)
 {
     u64 *count, one = 1;

     count = hl_report_count.lookup(stackid);
     if (!count) {
         hl_report_count.update(stackid, &one);
     } else {
         *count += 1;
     }
 }

 static void update_aq_report_max(int *stackid, u64 time)
 {
     u64 *max;

     max = aq_report_max.lookup(stackid);
     if (!max || *max < time)
         aq_report_max.update(stackid, &time);
 }

 static void update_hl_report_max(int *stackid, u64 time)
 {
     u64 *max;

     max = hl_report_max.lookup(stackid);
     if (!max || *max < time)
         hl_report_max.update(stackid, &time);
 }

 static void update_aq_report_total(int *stackid, u64 delta)
 {
     u64 *count, *time;

     count = aq_report_count.lookup(stackid);
     if (!count)
         return;

     time = aq_report_total.lookup(stackid);
     if (!time) {
         aq_report_total.update(stackid, &delta);
     } else {
         *time = *time + delta;
     }
 }

 static void update_hl_report_total(int *stackid, u64 delta)
 {
     u64 *count, *time;

     count = hl_report_count.lookup(stackid);
     if (!count)
         return;

     time = hl_report_total.lookup(stackid);
     if (!time) {
         hl_report_total.update(stackid, &delta);
     } else {
         *time = *time + delta;
     }
 }

 static int do_mutex_lock_return(void)
 {
     if (!is_enabled())
         return 0;

     u64 id = bpf_get_current_pid_tgid();

     if (!allow_pid(id))
         return 0;

     u64 *one = track.lookup(&id);

     if (!one)
         return 0;

     track.delete(&id);

     u64 *depth = lock_depth.lookup(&id);
     if (!depth)
         return 0;

     struct depth_id did = {
       .id    = id,
       .depth = *depth - 1,
     };

     u64 *aq = time_aq.lookup(&id);
     if (!aq)
         return 0;

     int *stackid = stack.lookup(&did);
     if (!stackid)
         return 0;

     int stackid_ = *stackid;
     u64 cur = bpf_ktime_get_ns();

     if (cur > *aq) {
         int val = cur - *aq;
         update_aq_report_count(&stackid_);
         update_aq_report_max(&stackid_, val);
         update_aq_report_total(&stackid_, val);
     }

     time_held.update(&did, &cur);
     return 0;
 }

 static int do_mutex_unlock_enter(void)
 {
     if (!is_enabled())
         return 0;

     u64 id = bpf_get_current_pid_tgid();

     if (!allow_pid(id))
         return 0;

     u64 *depth = lock_depth.lookup(&id);

     if (!depth || *depth == 0)
         return 0;

     *depth -= 1;

     struct depth_id did = {
       .id    = id,
       .depth = *depth,
     };

     u64 *held = time_held.lookup(&did);
     if (!held)
         return 0;

     int *stackid = stack.lookup(&did);
     if (!stackid)
         return 0;


     int stackid_ = *stackid;
     u64 cur = bpf_ktime_get_ns();

     if (cur > *held) {
         u64 val = cur - *held;
         update_hl_report_count(&stackid_);
         update_hl_report_max(&stackid_, val);
         update_hl_report_total(&stackid_, val);
     }

     stack.delete(&did);
     time_held.delete(&did);
     return 0;
 }
 """

 program_kprobe = """
 int mutex_unlock_enter(struct pt_regs *ctx)
 {
     return do_mutex_unlock_enter();
 }

 int mutex_lock_return(struct pt_regs *ctx)
 {
     return do_mutex_lock_return();
 }

 int mutex_lock_enter(struct pt_regs *ctx)
 {
     return do_mutex_lock_enter(ctx, 0);
 }
 """

 program_kfunc = """
 KFUNC_PROBE(mutex_unlock, void *lock)
 {
     return do_mutex_unlock_enter();
 }

 KRETFUNC_PROBE(mutex_lock, void *lock, int ret)
 {
     return do_mutex_lock_return();
 }

 KFUNC_PROBE(mutex_lock, void *lock)
 {
     return do_mutex_lock_enter(ctx, 3);
 }

 """

 program_kfunc_nested = """
 KFUNC_PROBE(mutex_unlock, void *lock)
 {
     return do_mutex_unlock_enter();
 }

 KRETFUNC_PROBE(mutex_lock_nested, void *lock, int ret)
 {
     return do_mutex_lock_return();
 }

 KFUNC_PROBE(mutex_lock_nested, void *lock)
 {
     return do_mutex_lock_enter(ctx, 3);
 }

 """

 is_support_kfunc = BPF.support_kfunc()
 if is_support_kfunc:
     if BPF.get_kprobe_functions(b"mutex_lock_nested"):
         program += program_kfunc_nested
     else:
         program += program_kfunc
 else:
     program += program_kprobe

 def sort_list(maxs, totals, counts):
     if (not args.sort):
         return maxs;

     for field in args.sort.split(','):
         if (field == "acq_max" or field == "hld_max"):
             return maxs
         if (field == "acq_total" or field == "hld_total"):
             return totals
         if (field == "acq_count" or field == "hld_count"):
             return counts

     print("Wrong sort argument: %s", args.sort)
     exit(-1)

 def display(sort, maxs, totals, counts):
     global missing_stacks
     global has_enomem

     for k, v in sorted(sort.items(), key=lambda sort: sort[1].value, reverse=True)[:args.locks]:
         missing_stacks += int(stack_id_err(k.value))
         has_enomem      = has_enomem or (k.value == -errno.ENOMEM)

         caller = "[Missed Kernel Stack]"
         stack  = []

         if (k.value >= 0):
             stack  = list(stack_traces.walk(k.value))
             caller = b.ksym(stack[1], show_offset=True)

             if (args.caller and caller.find(args.caller.encode())):
                 continue

         avg = totals[k].value / counts[k].value

         print("%40s %10lu %6lu %10lu %10lu" % (caller, avg, counts[k].value, maxs[k].value, totals[k].value))

         for addr in stack[2:args.stacks]:
             print("%40s" %  b.ksym(addr, show_offset=True))


 if args.tid:  # TID trumps PID
     program = program.replace('FILTER',
         'if (tid != %s) { return 0; }' % args.tid)
 elif args.pid:
     program = program.replace('FILTER',
         'if (pid != %s) { return 0; }' % args.pid)
 else:
     program = program.replace('FILTER', '')

 program = program.replace('STACK_STORAGE_SIZE', str(args.stack_storage_size))

 b = BPF(text=program)

 if not is_support_kfunc:
     b.attach_kprobe(event="mutex_unlock", fn_name="mutex_unlock_enter")
     # Depending on whether DEBUG_LOCK_ALLOC is set, the proper kprobe may be either mutex_lock or mutex_lock_nested
     if BPF.get_kprobe_functions(b"mutex_lock_nested"):
         b.attach_kretprobe(event="mutex_lock_nested", fn_name="mutex_lock_return")
         b.attach_kprobe(event="mutex_lock_nested", fn_name="mutex_lock_enter")
     else:
         b.attach_kretprobe(event="mutex_lock", fn_name="mutex_lock_return")
         b.attach_kprobe(event="mutex_lock", fn_name="mutex_lock_enter")

 enabled = b.get_table("enabled");

 stack_traces = b.get_table("stack_traces")
 aq_counts = b.get_table("aq_report_count")
 aq_maxs   = b.get_table("aq_report_max")
 aq_totals = b.get_table("aq_report_total")

 hl_counts = b.get_table("hl_report_count")
 hl_maxs   = b.get_table("hl_report_max")
 hl_totals = b.get_table("hl_report_total")

 aq_sort = sort_list(aq_maxs, aq_totals, aq_counts)
 hl_sort = sort_list(hl_maxs, hl_totals, hl_counts)

 print("Tracing lock events... Hit Ctrl-C to end.")

 # duration and interval are mutualy exclusive
 exiting = 0 if args.interval else 1
 exiting = 1 if args.duration else 0

 seconds = 99999999
 if args.interval:
     seconds = args.interval
 if args.duration:
     seconds = args.duration

 missing_stacks = 0
 has_enomem     = False

 while (1):
     enabled[ct.c_int(0)] = ct.c_int(1)

     try:
         sleep(seconds)
     except KeyboardInterrupt:
         exiting = 1

     enabled[ct.c_int(0)] = ct.c_int(0)

     print("\n%40s %10s %6s %10s %10s" % ("Caller", "Avg Spin", "Count", "Max spin", "Total spin"))
     display(aq_sort, aq_maxs, aq_totals, aq_counts)


     print("\n%40s %10s %6s %10s %10s" % ("Caller", "Avg Hold", "Count", "Max hold", "Total hold"))
     display(hl_sort, hl_maxs, hl_totals, hl_counts)

     if exiting:
         break;

     stack_traces.clear()
     aq_counts.clear()
     aq_maxs.clear()
     aq_totals.clear()
     hl_counts.clear()
     hl_maxs.clear()
     hl_totals.clear()

 if missing_stacks > 0:
     enomem_str = " Consider increasing --stack-storage-size."
     print("WARNING: %d stack traces lost and could not be displayed.%s" %
         (missing_stacks, (enomem_str if has_enomem else "")),
         file=stderr)
	#!/usr/bin/env python
	#
	# klockstat traces lock events and display locks statistics.
	#
	# USAGE: klockstat
	#

	from __future__ import print_function
	from bcc import BPF, USDT
	import argparse
	import subprocess
	import ctypes as ct
	from time import sleep, strftime
	from datetime import datetime, timedelta
	import errno
	from sys import stderr

	examples = """
	klockstat # trace system wide
	klockstat -d 5 # trace for 5 seconds only
	klockstat -i 5 # display stats every 5 seconds
	klockstat -p 123 # trace locks for PID 123
	klockstat -t 321 # trace locks for TID 321
	klockstat -c pipe_ # display stats only for lock callers with 'pipe_' substring
	klockstat -S acq_count # sort lock acquired results on acquired count
	klockstat -S hld_total # sort lock held results on total held time
	klockstat -S acq_count,hld_total # combination of above
	klockstat -n 3 # display 3 locks
	klockstat -s 3 # display 3 levels of stack
	"""

	# arg validation
	def positive_int(val):
	try:
	ival = int(val)
	except ValueError:
	raise argparse.ArgumentTypeError("must be an integer")

	if ival < 0:
	raise argparse.ArgumentTypeError("must be positive")
	return ival

	def positive_nonzero_int(val):
	ival = positive_int(val)
	if ival == 0:
	raise argparse.ArgumentTypeError("must be nonzero")
	return ival

	def stack_id_err(stack_id):
	# -EFAULT in get_stackid normally means the stack-trace is not available,
	# Such as getting kernel stack trace in userspace code
	return (stack_id < 0) and (stack_id != -errno.EFAULT)

	parser = argparse.ArgumentParser(
	description="",
	formatter_class=argparse.RawDescriptionHelpFormatter,
	epilog=examples)

	time_group = parser.add_mutually_exclusive_group()
	time_group.add_argument("-d", "--duration", type=int,
	help="total duration of trace in seconds")
	time_group.add_argument("-i", "--interval", type=int,
	help="print summary at this interval (seconds)")
	parser.add_argument("-n", "--locks", type=int, default=99999999,
	help="print given number of locks")
	parser.add_argument("-s", "--stacks", type=int, default=1,
	help="print given number of stack entries")
	parser.add_argument("-c", "--caller",
	help="print locks taken by given caller")
	parser.add_argument("-S", "--sort",
	help="sort data on <aq_field,hd_field>, fields: acq_[max\|total\|count] hld_[max\|total\|count]")
	parser.add_argument("-p", "--pid",
	help="trace this PID only")
	parser.add_argument("-t", "--tid",
	help="trace this TID only")
	parser.add_argument("--stack-storage-size", default=16384,
	type=positive_nonzero_int,
	help="the number of unique stack traces that can be stored and "
	"displayed (default 16384)")

	args = parser.parse_args()

	program = """
	#include <uapi/linux/ptrace.h>

	struct depth_id {
	u64 id;
	u64 depth;
	};

	BPF_ARRAY(enabled, u64, 1);
	BPF_HASH(track, u64, u64);
	BPF_HASH(time_aq, u64, u64);
	BPF_HASH(lock_depth, u64, u64);
	BPF_HASH(time_held, struct depth_id, u64);
	BPF_HASH(stack, struct depth_id, int);

	BPF_HASH(aq_report_count, int, u64);
	BPF_HASH(aq_report_max, int, u64);
	BPF_HASH(aq_report_total, int, u64);

	BPF_HASH(hl_report_count, int, u64);
	BPF_HASH(hl_report_max, int, u64);
	BPF_HASH(hl_report_total, int, u64);

	BPF_STACK_TRACE(stack_traces, STACK_STORAGE_SIZE);

	static bool is_enabled(void)
	{
	int key = 0;
	u64 *ret;

	ret = enabled.lookup(&key);
	return ret && *ret == 1;
	}

	static bool allow_pid(u64 id)
	{
	u32 pid = id >> 32; // PID is higher part
	u32 tid = id; // Cast and get the lower part

	FILTER

	return 1;
	}

	static int do_mutex_lock_enter(void *ctx, int skip)
	{
	if (!is_enabled())
	return 0;

	u64 id = bpf_get_current_pid_tgid();

	if (!allow_pid(id))
	return 0;

	u64 one = 1, zero = 0;

	track.update(&id, &one);

	u64 *depth = lock_depth.lookup(&id);

	if (!depth) {
	lock_depth.update(&id, &zero);

	depth = lock_depth.lookup(&id);
	/* something is wrong.. */
	if (!depth)
	return 0;
	}

	int stackid = stack_traces.get_stackid(ctx, skip);
	struct depth_id did = {
	.id = id,
	.depth = *depth,
	};
	stack.update(&did, &stackid);

	u64 ts = bpf_ktime_get_ns();
	time_aq.update(&id, &ts);

	*depth += 1;
	return 0;
	}

	static void update_aq_report_count(int *stackid)
	{
	u64 *count, one = 1;

	count = aq_report_count.lookup(stackid);
	if (!count) {
	aq_report_count.update(stackid, &one);
	} else {
	*count += 1;
	}
	}

	static void update_hl_report_count(int *stackid)
	{
	u64 *count, one = 1;

	count = hl_report_count.lookup(stackid);
	if (!count) {
	hl_report_count.update(stackid, &one);
	} else {
	*count += 1;
	}
	}

	static void update_aq_report_max(int *stackid, u64 time)
	{
	u64 *max;

	max = aq_report_max.lookup(stackid);
	if (!max \|\| *max < time)
	aq_report_max.update(stackid, &time);
	}

	static void update_hl_report_max(int *stackid, u64 time)
	{
	u64 *max;

	max = hl_report_max.lookup(stackid);
	if (!max \|\| *max < time)
	hl_report_max.update(stackid, &time);
	}

	static void update_aq_report_total(int *stackid, u64 delta)
	{
	u64 count, time;

	count = aq_report_count.lookup(stackid);
	if (!count)
	return;

	time = aq_report_total.lookup(stackid);
	if (!time) {
	aq_report_total.update(stackid, &delta);
	} else {
	time = time + delta;
	}
	}

	static void update_hl_report_total(int *stackid, u64 delta)
	{
	u64 count, time;

	count = hl_report_count.lookup(stackid);
	if (!count)
	return;

	time = hl_report_total.lookup(stackid);
	if (!time) {
	hl_report_total.update(stackid, &delta);
	} else {
	time = time + delta;
	}
	}

	static int do_mutex_lock_return(void)
	{
	if (!is_enabled())
	return 0;

	u64 id = bpf_get_current_pid_tgid();

	if (!allow_pid(id))
	return 0;

	u64 *one = track.lookup(&id);

	if (!one)
	return 0;

	track.delete(&id);

	u64 *depth = lock_depth.lookup(&id);
	if (!depth)
	return 0;

	struct depth_id did = {
	.id = id,
	.depth = *depth - 1,
	};

	u64 *aq = time_aq.lookup(&id);
	if (!aq)
	return 0;

	int *stackid = stack.lookup(&did);
	if (!stackid)
	return 0;

	int stackid_ = *stackid;
	u64 cur = bpf_ktime_get_ns();

	if (cur > *aq) {
	int val = cur - *aq;
	update_aq_report_count(&stackid_);
	update_aq_report_max(&stackid_, val);
	update_aq_report_total(&stackid_, val);
	}

	time_held.update(&did, &cur);
	return 0;
	}

	static int do_mutex_unlock_enter(void)
	{
	if (!is_enabled())
	return 0;

	u64 id = bpf_get_current_pid_tgid();

	if (!allow_pid(id))
	return 0;

	u64 *depth = lock_depth.lookup(&id);

	if (!depth \|\| *depth == 0)
	return 0;

	*depth -= 1;

	struct depth_id did = {
	.id = id,
	.depth = *depth,
	};

	u64 *held = time_held.lookup(&did);
	if (!held)
	return 0;

	int *stackid = stack.lookup(&did);
	if (!stackid)
	return 0;


	int stackid_ = *stackid;
	u64 cur = bpf_ktime_get_ns();

	if (cur > *held) {
	u64 val = cur - *held;
	update_hl_report_count(&stackid_);
	update_hl_report_max(&stackid_, val);
	update_hl_report_total(&stackid_, val);
	}

	stack.delete(&did);
	time_held.delete(&did);
	return 0;
	}
	"""

	program_kprobe = """
	int mutex_unlock_enter(struct pt_regs *ctx)
	{
	return do_mutex_unlock_enter();
	}

	int mutex_lock_return(struct pt_regs *ctx)
	{
	return do_mutex_lock_return();
	}

	int mutex_lock_enter(struct pt_regs *ctx)
	{
	return do_mutex_lock_enter(ctx, 0);
	}
	"""

	program_kfunc = """
	KFUNC_PROBE(mutex_unlock, void *lock)
	{
	return do_mutex_unlock_enter();
	}

	KRETFUNC_PROBE(mutex_lock, void *lock, int ret)
	{
	return do_mutex_lock_return();
	}

	KFUNC_PROBE(mutex_lock, void *lock)
	{
	return do_mutex_lock_enter(ctx, 3);
	}

	"""

	program_kfunc_nested = """
	KFUNC_PROBE(mutex_unlock, void *lock)
	{
	return do_mutex_unlock_enter();
	}

	KRETFUNC_PROBE(mutex_lock_nested, void *lock, int ret)
	{
	return do_mutex_lock_return();
	}

	KFUNC_PROBE(mutex_lock_nested, void *lock)
	{
	return do_mutex_lock_enter(ctx, 3);
	}

	"""

	is_support_kfunc = BPF.support_kfunc()
	if is_support_kfunc:
	if BPF.get_kprobe_functions(b"mutex_lock_nested"):
	program += program_kfunc_nested
	else:
	program += program_kfunc
	else:
	program += program_kprobe

	def sort_list(maxs, totals, counts):
	if (not args.sort):
	return maxs;

	for field in args.sort.split(','):
	if (field == "acq_max" or field == "hld_max"):
	return maxs
	if (field == "acq_total" or field == "hld_total"):
	return totals
	if (field == "acq_count" or field == "hld_count"):
	return counts

	print("Wrong sort argument: %s", args.sort)
	exit(-1)

	def display(sort, maxs, totals, counts):
	global missing_stacks
	global has_enomem

	for k, v in sorted(sort.items(), key=lambda sort: sort[1].value, reverse=True)[:args.locks]:
	missing_stacks += int(stack_id_err(k.value))
	has_enomem = has_enomem or (k.value == -errno.ENOMEM)

	caller = "[Missed Kernel Stack]"
	stack = []

	if (k.value >= 0):
	stack = list(stack_traces.walk(k.value))
	caller = b.ksym(stack[1], show_offset=True)

	if (args.caller and caller.find(args.caller.encode())):
	continue

	avg = totals[k].value / counts[k].value

	print("%40s %10lu %6lu %10lu %10lu" % (caller, avg, counts[k].value, maxs[k].value, totals[k].value))

	for addr in stack[2:args.stacks]:
	print("%40s" % b.ksym(addr, show_offset=True))


	if args.tid: # TID trumps PID
	program = program.replace('FILTER',
	'if (tid != %s) { return 0; }' % args.tid)
	elif args.pid:
	program = program.replace('FILTER',
	'if (pid != %s) { return 0; }' % args.pid)
	else:
	program = program.replace('FILTER', '')

	program = program.replace('STACK_STORAGE_SIZE', str(args.stack_storage_size))

	b = BPF(text=program)

	if not is_support_kfunc:
	b.attach_kprobe(event="mutex_unlock", fn_name="mutex_unlock_enter")
	# Depending on whether DEBUG_LOCK_ALLOC is set, the proper kprobe may be either mutex_lock or mutex_lock_nested
	if BPF.get_kprobe_functions(b"mutex_lock_nested"):
	b.attach_kretprobe(event="mutex_lock_nested", fn_name="mutex_lock_return")
	b.attach_kprobe(event="mutex_lock_nested", fn_name="mutex_lock_enter")
	else:
	b.attach_kretprobe(event="mutex_lock", fn_name="mutex_lock_return")
	b.attach_kprobe(event="mutex_lock", fn_name="mutex_lock_enter")

	enabled = b.get_table("enabled");

	stack_traces = b.get_table("stack_traces")
	aq_counts = b.get_table("aq_report_count")
	aq_maxs = b.get_table("aq_report_max")
	aq_totals = b.get_table("aq_report_total")

	hl_counts = b.get_table("hl_report_count")
	hl_maxs = b.get_table("hl_report_max")
	hl_totals = b.get_table("hl_report_total")

	aq_sort = sort_list(aq_maxs, aq_totals, aq_counts)
	hl_sort = sort_list(hl_maxs, hl_totals, hl_counts)

	print("Tracing lock events... Hit Ctrl-C to end.")

	# duration and interval are mutualy exclusive
	exiting = 0 if args.interval else 1
	exiting = 1 if args.duration else 0

	seconds = 99999999
	if args.interval:
	seconds = args.interval
	if args.duration:
	seconds = args.duration

	missing_stacks = 0
	has_enomem = False

	while (1):
	enabled[ct.c_int(0)] = ct.c_int(1)

	try:
	sleep(seconds)
	except KeyboardInterrupt:
	exiting = 1

	enabled[ct.c_int(0)] = ct.c_int(0)

	print("\n%40s %10s %6s %10s %10s" % ("Caller", "Avg Spin", "Count", "Max spin", "Total spin"))
	display(aq_sort, aq_maxs, aq_totals, aq_counts)


	print("\n%40s %10s %6s %10s %10s" % ("Caller", "Avg Hold", "Count", "Max hold", "Total hold"))
	display(hl_sort, hl_maxs, hl_totals, hl_counts)

	if exiting:
	break;

	stack_traces.clear()
	aq_counts.clear()
	aq_maxs.clear()
	aq_totals.clear()
	hl_counts.clear()
	hl_maxs.clear()
	hl_totals.clear()

	if missing_stacks > 0:
	enomem_str = " Consider increasing --stack-storage-size."
	print("WARNING: %d stack traces lost and could not be displayed.%s" %
	(missing_stacks, (enomem_str if has_enomem else "")),
	file=stderr)