parser = argparse.ArgumentParser()
parser.add_argument('log_file')
parser.add_argument('-q', '--queue', help='plot queue size', action='store_true')
-parser.add_argument('-e', '--encoder-threads', help='plot encoder thread activity', action='store_true')
+parser.add_argument('--encoder-threads', help='plot encoder thread activity', action='store_true')
parser.add_argument('-f', '--plot-first-encoder', help='plot more detailed activity of the first encoder thread', action='store_true')
parser.add_argument('-s', '--fps-stats', help='frames-per-second stats', action='store_true')
parser.add_argument('--encoder-stats', help='encoder thread activity stats', action='store_true')
-parser.add_argument('--dump-first-encoder', help='dump activity of the first encoder thread', action='store_true')
+parser.add_argument('--encoder-dump', help='dump activity of the specified encoder', action='store_true')
+parser.add_argument('-e', '--encoder', help='encoder index (from 0)')
parser.add_argument('--from', help='time in seconds to start at', type=int, dest='from_time')
parser.add_argument('--to', help='time in seconds to stop at', type=int, dest='to_time')
+parser.add_argument('--max-encoder-threads', help='maximum number of encoder threads to plot with --encoder-threads', type=int, default=None)
args = parser.parse_args()
def find_nth(haystack, needle, n):
try:
T = Time(time.mktime(time.strptime(l[:s])))
except:
- T = Time(time.mktime(time.strptime(l[:s], "%d.%m.%Y %H:%M:%S")))
+ try:
+ T = Time(time.mktime(time.strptime(l[:s], "%d.%m.%Y %H:%M:%S")))
+ except:
+ try:
+ T = Time(time.mktime(time.strptime(l[:s], "%d/%m/%Y %H:%M:%S")))
+ except:
+ x = l[:s]
+ if not x.endswith('M'):
+ x += 'M'
+ T = Time(time.mktime(time.strptime(x, "%d/%m/%Y %H:%M:%S %p")))
message = l[s+2:]
# T is elapsed time since the first log message
# y=0 thread is sleeping
# y=1 thread is awake
# y=2 thread is encoding
+ # y=3 thread is awaiting a remote encode
+
+ if args.max_encoder_threads is not None:
+ encoder_threads = encoder_threads[0:min(args.max_encoder_threads, len(encoder_threads))]
+
plt.figure()
N = len(encoder_threads)
n = 1
continue
if args.to_time is not None and e[0].float_seconds() >= args.to_time:
continue
+ if e[1] == 'start-remote-send' or e[1] == 'finish-remote-send' or e[1] == 'start-remote-receive' or e[1] == 'finish-remote-receive':
+ continue
x.append(e[0].float_seconds())
x.append(e[0].float_seconds())
y.append(previous)
y.append(2)
elif e[1] == 'finish-local-encode':
y.append(1)
+ elif e[1] == 'start-remote-encode':
+ y.append(3)
+ elif e[1] == 'finish-remote-encode':
+ y.append(1)
else:
print>>sys.stderr,'unknown event %s' % e[1]
sys.exit(1)
N = 6
n = 1
- for t in ['sleep', 'wake', 'begin_encode', 'end_encode']:
+ for t in ['encoder-sleep', 'encoder-wake', 'start-local-encode', 'finish-local-encode']:
plt.subplot(N, 1, n)
x = []
y = []
plt.show()
-elif args.dump_first_encoder:
- events = encoder_thread_events.itervalues().next()
- last = 0
- for e in events:
- print e[0].float_seconds(), (e[0].float_seconds() - last), e[1]
- last = e[0].float_seconds()
+elif args.encoder_dump:
+ for t in encoder_threads[int(args.encoder)]:
+ last = 0
+ for e in t.events:
+ print (e[0].float_seconds() - last), e[1]
+ last = e[0].float_seconds()
elif args.fps_stats:
local = 0
if total == 0:
continue
- print '\t%s: %2.f%%' % ('Asleep'.ljust(16), asleep.float_seconds() * 100 / total)
+ print '\t%s: %2.f%% %fs' % ('Asleep'.ljust(16), asleep.float_seconds() * 100 / total, asleep.float_seconds())
def print_with_fps(v, name, total, frames):
if v.float_seconds() > 1:
- print '\t%s: %2.f%% %.2ffps' % (name.ljust(16), v.float_seconds() * 100 / total, frames / v.float_seconds())
+ print '\t%s: %2.f%% %f %.2ffps' % (name.ljust(16), v.float_seconds() * 100 / total, v.float_seconds(), frames / v.float_seconds())
print_with_fps(local_encoding, 'Local encoding', total, wakes)
if sending.float_seconds() > 0: