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sshpeer: initial definition and implementation of new SSH protocol...
sshpeer: initial definition and implementation of new SSH protocol The existing SSH protocol has several design flaws. Future commits will elaborate on these flaws as new features are introduced to combat these flaws. For now, hopefully you can take me for my word that a ground up rewrite of the SSH protocol is needed. This commit lays the foundation for a new SSH protocol by defining a mechanism to upgrade the SSH transport channel away from the default (version 1) protocol to something modern (which we'll call "version 2" for now). This upgrade process is detailed in the internals documentation for the wire protocol. The gist of it is the client sends a request line preceding the "hello" command/line which basically says "I'm requesting an upgrade: here's what I support." If the server recognizes that line, it processes the upgrade request and the transport channel is switched to use the new version of the protocol. If not, it sends an empty response, which is how all Mercurial SSH servers from the beginning of time reacted to unknown commands. The upgrade request is effectively ignored and the client continues to use the existing version of the protocol as if nothing happened. The new version of the SSH protocol is completely identical to version 1 aside from the upgrade dance and the bytes that follow. The immediate bytes that follow the protocol switch are defined to be a length framed "capabilities: " line containing the remote's advertised capabilities. In reality, this looks very similar to what the "hello" response would look like. But it will evolve quickly. The methodology by which the protocol will evolve is important. I'm not going to introduce the new protocol all at once. That would likely lead to endless bike shedding and forward progress would stall. Instead, I intend to tricle out new features and diversions from the existing protocol in small, incremental changes. To support the gradual evolution of the protocol, the on-the-wire advertised protocol name contains an "exp" to denote "experimental" and a 4 digit field to capture the sub-version of the protocol. Whenever we make a BC change to the wire protocol, we can increment this version and lock out all older clients because it will appear as a completely different protocol version. This means we can incur as many breaking changes as we want. We don't have to commit to supporting any one feature or idea for a long period of time. We can even evolve the handshake mechanism, because that is defined as being an implementation detail of the negotiated protocol version! Hopefully this lowers the barrier to accepting changes to the protocol and for experimenting with "radical" ideas during its development. In core, sshpeer received most of the attention. We haven't even implemented the server bits for the new protocol in core yet. Instead, we add very primitive support to our test server, mainly just to exercise the added code paths in sshpeer. Differential Revision: https://phab.mercurial-scm.org/D2061 # no-check-commit because of required foo_bar naming
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statprof.py
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#!/usr/bin/env python
## statprof.py
## Copyright (C) 2012 Bryan O'Sullivan <bos@serpentine.com>
## Copyright (C) 2011 Alex Fraser <alex at phatcore dot com>
## Copyright (C) 2004,2005 Andy Wingo <wingo at pobox dot com>
## Copyright (C) 2001 Rob Browning <rlb at defaultvalue dot org>
## This library is free software; you can redistribute it and/or
## modify it under the terms of the GNU Lesser General Public
## License as published by the Free Software Foundation; either
## version 2.1 of the License, or (at your option) any later version.
##
## This library is distributed in the hope that it will be useful,
## but WITHOUT ANY WARRANTY; without even the implied warranty of
## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
## Lesser General Public License for more details.
##
## You should have received a copy of the GNU Lesser General Public
## License along with this program; if not, contact:
##
## Free Software Foundation Voice: +1-617-542-5942
## 59 Temple Place - Suite 330 Fax: +1-617-542-2652
## Boston, MA 02111-1307, USA gnu@gnu.org
"""
statprof is intended to be a fairly simple statistical profiler for
python. It was ported directly from a statistical profiler for guile,
also named statprof, available from guile-lib [0].
[0] http://wingolog.org/software/guile-lib/statprof/
To start profiling, call statprof.start():
>>> start()
Then run whatever it is that you want to profile, for example:
>>> import test.pystone; test.pystone.pystones()
Then stop the profiling and print out the results:
>>> stop()
>>> display()
% cumulative self
time seconds seconds name
26.72 1.40 0.37 pystone.py:79:Proc0
13.79 0.56 0.19 pystone.py:133:Proc1
13.79 0.19 0.19 pystone.py:208:Proc8
10.34 0.16 0.14 pystone.py:229:Func2
6.90 0.10 0.10 pystone.py:45:__init__
4.31 0.16 0.06 pystone.py:53:copy
...
All of the numerical data is statistically approximate. In the
following column descriptions, and in all of statprof, "time" refers
to execution time (both user and system), not wall clock time.
% time
The percent of the time spent inside the procedure itself (not
counting children).
cumulative seconds
The total number of seconds spent in the procedure, including
children.
self seconds
The total number of seconds spent in the procedure itself (not
counting children).
name
The name of the procedure.
By default statprof keeps the data collected from previous runs. If you
want to clear the collected data, call reset():
>>> reset()
reset() can also be used to change the sampling frequency from the
default of 1000 Hz. For example, to tell statprof to sample 50 times a
second:
>>> reset(50)
This means that statprof will sample the call stack after every 1/50 of
a second of user + system time spent running on behalf of the python
process. When your process is idle (for example, blocking in a read(),
as is the case at the listener), the clock does not advance. For this
reason statprof is not currently not suitable for profiling io-bound
operations.
The profiler uses the hash of the code object itself to identify the
procedures, so it won't confuse different procedures with the same name.
They will show up as two different rows in the output.
Right now the profiler is quite simplistic. I cannot provide
call-graphs or other higher level information. What you see in the
table is pretty much all there is. Patches are welcome :-)
Threading
---------
Because signals only get delivered to the main thread in Python,
statprof only profiles the main thread. However because the time
reporting function uses per-process timers, the results can be
significantly off if other threads' work patterns are not similar to the
main thread's work patterns.
"""
# no-check-code
from __future__ import absolute_import, division, print_function
import collections
import contextlib
import getopt
import inspect
import json
import os
import signal
import sys
import tempfile
import threading
import time
from . import (
encoding,
pycompat,
)
defaultdict = collections.defaultdict
contextmanager = contextlib.contextmanager
__all__ = ['start', 'stop', 'reset', 'display', 'profile']
skips = {"util.py:check", "extensions.py:closure",
"color.py:colorcmd", "dispatch.py:checkargs",
"dispatch.py:<lambda>", "dispatch.py:_runcatch",
"dispatch.py:_dispatch", "dispatch.py:_runcommand",
"pager.py:pagecmd", "dispatch.py:run",
"dispatch.py:dispatch", "dispatch.py:runcommand",
"hg.py:<module>", "evolve.py:warnobserrors",
}
###########################################################################
## Utils
def clock():
times = os.times()
return times[0] + times[1]
###########################################################################
## Collection data structures
class ProfileState(object):
def __init__(self, frequency=None):
self.reset(frequency)
def reset(self, frequency=None):
# total so far
self.accumulated_time = 0.0
# start_time when timer is active
self.last_start_time = None
# a float
if frequency:
self.sample_interval = 1.0 / frequency
elif not hasattr(self, 'sample_interval'):
# default to 1000 Hz
self.sample_interval = 1.0 / 1000.0
else:
# leave the frequency as it was
pass
self.remaining_prof_time = None
# for user start/stop nesting
self.profile_level = 0
self.samples = []
def accumulate_time(self, stop_time):
self.accumulated_time += stop_time - self.last_start_time
def seconds_per_sample(self):
return self.accumulated_time / len(self.samples)
state = ProfileState()
class CodeSite(object):
cache = {}
__slots__ = (u'path', u'lineno', u'function', u'source')
def __init__(self, path, lineno, function):
self.path = path
self.lineno = lineno
self.function = function
self.source = None
def __eq__(self, other):
try:
return (self.lineno == other.lineno and
self.path == other.path)
except:
return False
def __hash__(self):
return hash((self.lineno, self.path))
@classmethod
def get(cls, path, lineno, function):
k = (path, lineno)
try:
return cls.cache[k]
except KeyError:
v = cls(path, lineno, function)
cls.cache[k] = v
return v
def getsource(self, length):
if self.source is None:
lineno = self.lineno - 1
fp = None
try:
fp = open(self.path)
for i, line in enumerate(fp):
if i == lineno:
self.source = line.strip()
break
except:
pass
finally:
if fp:
fp.close()
if self.source is None:
self.source = ''
source = self.source
if len(source) > length:
source = source[:(length - 3)] + "..."
return source
def filename(self):
return os.path.basename(self.path)
class Sample(object):
__slots__ = (u'stack', u'time')
def __init__(self, stack, time):
self.stack = stack
self.time = time
@classmethod
def from_frame(cls, frame, time):
stack = []
while frame:
stack.append(CodeSite.get(frame.f_code.co_filename, frame.f_lineno,
frame.f_code.co_name))
frame = frame.f_back
return Sample(stack, time)
###########################################################################
## SIGPROF handler
def profile_signal_handler(signum, frame):
if state.profile_level > 0:
now = clock()
state.accumulate_time(now)
state.samples.append(Sample.from_frame(frame, state.accumulated_time))
signal.setitimer(signal.ITIMER_PROF,
state.sample_interval, 0.0)
state.last_start_time = now
stopthread = threading.Event()
def samplerthread(tid):
while not stopthread.is_set():
now = clock()
state.accumulate_time(now)
frame = sys._current_frames()[tid]
state.samples.append(Sample.from_frame(frame, state.accumulated_time))
state.last_start_time = now
time.sleep(state.sample_interval)
stopthread.clear()
###########################################################################
## Profiling API
def is_active():
return state.profile_level > 0
lastmechanism = None
def start(mechanism='thread'):
'''Install the profiling signal handler, and start profiling.'''
state.profile_level += 1
if state.profile_level == 1:
state.last_start_time = clock()
rpt = state.remaining_prof_time
state.remaining_prof_time = None
global lastmechanism
lastmechanism = mechanism
if mechanism == 'signal':
signal.signal(signal.SIGPROF, profile_signal_handler)
signal.setitimer(signal.ITIMER_PROF,
rpt or state.sample_interval, 0.0)
elif mechanism == 'thread':
frame = inspect.currentframe()
tid = [k for k, f in sys._current_frames().items() if f == frame][0]
state.thread = threading.Thread(target=samplerthread,
args=(tid,), name="samplerthread")
state.thread.start()
def stop():
'''Stop profiling, and uninstall the profiling signal handler.'''
state.profile_level -= 1
if state.profile_level == 0:
if lastmechanism == 'signal':
rpt = signal.setitimer(signal.ITIMER_PROF, 0.0, 0.0)
signal.signal(signal.SIGPROF, signal.SIG_IGN)
state.remaining_prof_time = rpt[0]
elif lastmechanism == 'thread':
stopthread.set()
state.thread.join()
state.accumulate_time(clock())
state.last_start_time = None
statprofpath = encoding.environ.get('STATPROF_DEST')
if statprofpath:
save_data(statprofpath)
return state
def save_data(path):
with open(path, 'w+') as file:
file.write(str(state.accumulated_time) + '\n')
for sample in state.samples:
time = str(sample.time)
stack = sample.stack
sites = ['\1'.join([s.path, str(s.lineno), s.function])
for s in stack]
file.write(time + '\0' + '\0'.join(sites) + '\n')
def load_data(path):
lines = open(path, 'r').read().splitlines()
state.accumulated_time = float(lines[0])
state.samples = []
for line in lines[1:]:
parts = line.split('\0')
time = float(parts[0])
rawsites = parts[1:]
sites = []
for rawsite in rawsites:
siteparts = rawsite.split('\1')
sites.append(CodeSite.get(siteparts[0], int(siteparts[1]),
siteparts[2]))
state.samples.append(Sample(sites, time))
def reset(frequency=None):
'''Clear out the state of the profiler. Do not call while the
profiler is running.
The optional frequency argument specifies the number of samples to
collect per second.'''
assert state.profile_level == 0, "Can't reset() while statprof is running"
CodeSite.cache.clear()
state.reset(frequency)
@contextmanager
def profile():
start()
try:
yield
finally:
stop()
display()
###########################################################################
## Reporting API
class SiteStats(object):
def __init__(self, site):
self.site = site
self.selfcount = 0
self.totalcount = 0
def addself(self):
self.selfcount += 1
def addtotal(self):
self.totalcount += 1
def selfpercent(self):
return self.selfcount / len(state.samples) * 100
def totalpercent(self):
return self.totalcount / len(state.samples) * 100
def selfseconds(self):
return self.selfcount * state.seconds_per_sample()
def totalseconds(self):
return self.totalcount * state.seconds_per_sample()
@classmethod
def buildstats(cls, samples):
stats = {}
for sample in samples:
for i, site in enumerate(sample.stack):
sitestat = stats.get(site)
if not sitestat:
sitestat = SiteStats(site)
stats[site] = sitestat
sitestat.addtotal()
if i == 0:
sitestat.addself()
return [s for s in stats.itervalues()]
class DisplayFormats:
ByLine = 0
ByMethod = 1
AboutMethod = 2
Hotpath = 3
FlameGraph = 4
Json = 5
Chrome = 6
def display(fp=None, format=3, data=None, **kwargs):
'''Print statistics, either to stdout or the given file object.'''
data = data or state
if fp is None:
import sys
fp = sys.stdout
if len(data.samples) == 0:
print('No samples recorded.', file=fp)
return
if format == DisplayFormats.ByLine:
display_by_line(data, fp)
elif format == DisplayFormats.ByMethod:
display_by_method(data, fp)
elif format == DisplayFormats.AboutMethod:
display_about_method(data, fp, **kwargs)
elif format == DisplayFormats.Hotpath:
display_hotpath(data, fp, **kwargs)
elif format == DisplayFormats.FlameGraph:
write_to_flame(data, fp, **kwargs)
elif format == DisplayFormats.Json:
write_to_json(data, fp)
elif format == DisplayFormats.Chrome:
write_to_chrome(data, fp, **kwargs)
else:
raise Exception("Invalid display format")
if format not in (DisplayFormats.Json, DisplayFormats.Chrome):
print('---', file=fp)
print('Sample count: %d' % len(data.samples), file=fp)
print('Total time: %f seconds' % data.accumulated_time, file=fp)
def display_by_line(data, fp):
'''Print the profiler data with each sample line represented
as one row in a table. Sorted by self-time per line.'''
stats = SiteStats.buildstats(data.samples)
stats.sort(reverse=True, key=lambda x: x.selfseconds())
print('%5.5s %10.10s %7.7s %-8.8s' %
('% ', 'cumulative', 'self', ''), file=fp)
print('%5.5s %9.9s %8.8s %-8.8s' %
("time", "seconds", "seconds", "name"), file=fp)
for stat in stats:
site = stat.site
sitelabel = '%s:%d:%s' % (site.filename(), site.lineno, site.function)
print('%6.2f %9.2f %9.2f %s' % (stat.selfpercent(),
stat.totalseconds(),
stat.selfseconds(),
sitelabel),
file=fp)
def display_by_method(data, fp):
'''Print the profiler data with each sample function represented
as one row in a table. Important lines within that function are
output as nested rows. Sorted by self-time per line.'''
print('%5.5s %10.10s %7.7s %-8.8s' %
('% ', 'cumulative', 'self', ''), file=fp)
print('%5.5s %9.9s %8.8s %-8.8s' %
("time", "seconds", "seconds", "name"), file=fp)
stats = SiteStats.buildstats(data.samples)
grouped = defaultdict(list)
for stat in stats:
grouped[stat.site.filename() + ":" + stat.site.function].append(stat)
# compute sums for each function
functiondata = []
for fname, sitestats in grouped.iteritems():
total_cum_sec = 0
total_self_sec = 0
total_percent = 0
for stat in sitestats:
total_cum_sec += stat.totalseconds()
total_self_sec += stat.selfseconds()
total_percent += stat.selfpercent()
functiondata.append((fname,
total_cum_sec,
total_self_sec,
total_percent,
sitestats))
# sort by total self sec
functiondata.sort(reverse=True, key=lambda x: x[2])
for function in functiondata:
if function[3] < 0.05:
continue
print('%6.2f %9.2f %9.2f %s' % (function[3], # total percent
function[1], # total cum sec
function[2], # total self sec
function[0]), # file:function
file=fp)
function[4].sort(reverse=True, key=lambda i: i.selfseconds())
for stat in function[4]:
# only show line numbers for significant locations (>1% time spent)
if stat.selfpercent() > 1:
source = stat.site.getsource(25)
stattuple = (stat.selfpercent(), stat.selfseconds(),
stat.site.lineno, source)
print('%33.0f%% %6.2f line %s: %s' % (stattuple), file=fp)
def display_about_method(data, fp, function=None, **kwargs):
if function is None:
raise Exception("Invalid function")
filename = None
if ':' in function:
filename, function = function.split(':')
relevant_samples = 0
parents = {}
children = {}
for sample in data.samples:
for i, site in enumerate(sample.stack):
if site.function == function and (not filename
or site.filename() == filename):
relevant_samples += 1
if i != len(sample.stack) - 1:
parent = sample.stack[i + 1]
if parent in parents:
parents[parent] = parents[parent] + 1
else:
parents[parent] = 1
if site in children:
children[site] = children[site] + 1
else:
children[site] = 1
parents = [(parent, count) for parent, count in parents.iteritems()]
parents.sort(reverse=True, key=lambda x: x[1])
for parent, count in parents:
print('%6.2f%% %s:%s line %s: %s' %
(count / relevant_samples * 100, parent.filename(),
parent.function, parent.lineno, parent.getsource(50)), file=fp)
stats = SiteStats.buildstats(data.samples)
stats = [s for s in stats
if s.site.function == function and
(not filename or s.site.filename() == filename)]
total_cum_sec = 0
total_self_sec = 0
total_self_percent = 0
total_cum_percent = 0
for stat in stats:
total_cum_sec += stat.totalseconds()
total_self_sec += stat.selfseconds()
total_self_percent += stat.selfpercent()
total_cum_percent += stat.totalpercent()
print(
'\n %s:%s Total: %0.2fs (%0.2f%%) Self: %0.2fs (%0.2f%%)\n' %
(
filename or '___',
function,
total_cum_sec,
total_cum_percent,
total_self_sec,
total_self_percent
), file=fp)
children = [(child, count) for child, count in children.iteritems()]
children.sort(reverse=True, key=lambda x: x[1])
for child, count in children:
print(' %6.2f%% line %s: %s' %
(count / relevant_samples * 100, child.lineno,
child.getsource(50)), file=fp)
def display_hotpath(data, fp, limit=0.05, **kwargs):
class HotNode(object):
def __init__(self, site):
self.site = site
self.count = 0
self.children = {}
def add(self, stack, time):
self.count += time
site = stack[0]
child = self.children.get(site)
if not child:
child = HotNode(site)
self.children[site] = child
if len(stack) > 1:
i = 1
# Skip boiler plate parts of the stack
while i < len(stack) and '%s:%s' % (stack[i].filename(), stack[i].function) in skips:
i += 1
if i < len(stack):
child.add(stack[i:], time)
root = HotNode(None)
lasttime = data.samples[0].time
for sample in data.samples:
root.add(sample.stack[::-1], sample.time - lasttime)
lasttime = sample.time
def _write(node, depth, multiple_siblings):
site = node.site
visiblechildren = [c for c in node.children.itervalues()
if c.count >= (limit * root.count)]
if site:
indent = depth * 2 - 1
filename = ''
function = ''
if len(node.children) > 0:
childsite = list(node.children.itervalues())[0].site
filename = (childsite.filename() + ':').ljust(15)
function = childsite.function
# lots of string formatting
listpattern = ''.ljust(indent) +\
('\\' if multiple_siblings else '|') +\
' %4.1f%% %s %s'
liststring = listpattern % (node.count / root.count * 100,
filename, function)
codepattern = '%' + str(55 - len(liststring)) + 's %s: %s'
codestring = codepattern % ('line', site.lineno, site.getsource(30))
finalstring = liststring + codestring
childrensamples = sum([c.count for c in node.children.itervalues()])
# Make frames that performed more than 10% of the operation red
if node.count - childrensamples > (0.1 * root.count):
finalstring = '\033[91m' + finalstring + '\033[0m'
# Make frames that didn't actually perform work dark grey
elif node.count - childrensamples == 0:
finalstring = '\033[90m' + finalstring + '\033[0m'
print(finalstring, file=fp)
newdepth = depth
if len(visiblechildren) > 1 or multiple_siblings:
newdepth += 1
visiblechildren.sort(reverse=True, key=lambda x: x.count)
for child in visiblechildren:
_write(child, newdepth, len(visiblechildren) > 1)
if root.count > 0:
_write(root, 0, False)
def write_to_flame(data, fp, scriptpath=None, outputfile=None, **kwargs):
if scriptpath is None:
scriptpath = encoding.environ['HOME'] + '/flamegraph.pl'
if not os.path.exists(scriptpath):
print("error: missing %s" % scriptpath, file=fp)
print("get it here: https://github.com/brendangregg/FlameGraph",
file=fp)
return
fd, path = tempfile.mkstemp()
file = open(path, "w+")
lines = {}
for sample in data.samples:
sites = [s.function for s in sample.stack]
sites.reverse()
line = ';'.join(sites)
if line in lines:
lines[line] = lines[line] + 1
else:
lines[line] = 1
for line, count in lines.iteritems():
file.write("%s %s\n" % (line, count))
file.close()
if outputfile is None:
outputfile = '~/flamegraph.svg'
os.system("perl ~/flamegraph.pl %s > %s" % (path, outputfile))
print("Written to %s" % outputfile, file=fp)
_pathcache = {}
def simplifypath(path):
'''Attempt to make the path to a Python module easier to read by
removing whatever part of the Python search path it was found
on.'''
if path in _pathcache:
return _pathcache[path]
hgpath = pycompat.fsencode(encoding.__file__).rsplit(os.sep, 2)[0]
for p in [hgpath] + sys.path:
prefix = p + os.sep
if path.startswith(prefix):
path = path[len(prefix):]
break
_pathcache[path] = path
return path
def write_to_json(data, fp):
samples = []
for sample in data.samples:
stack = []
for frame in sample.stack:
stack.append((frame.path, frame.lineno, frame.function))
samples.append((sample.time, stack))
print(json.dumps(samples), file=fp)
def write_to_chrome(data, fp, minthreshold=0.005, maxthreshold=0.999):
samples = []
laststack = collections.deque()
lastseen = collections.deque()
# The Chrome tracing format allows us to use a compact stack
# representation to save space. It's fiddly but worth it.
# We maintain a bijection between stack and ID.
stack2id = {}
id2stack = [] # will eventually be rendered
def stackid(stack):
if not stack:
return
if stack in stack2id:
return stack2id[stack]
parent = stackid(stack[1:])
myid = len(stack2id)
stack2id[stack] = myid
id2stack.append(dict(category=stack[0][0], name='%s %s' % stack[0]))
if parent is not None:
id2stack[-1].update(parent=parent)
return myid
def endswith(a, b):
return list(a)[-len(b):] == list(b)
# The sampling profiler can sample multiple times without
# advancing the clock, potentially causing the Chrome trace viewer
# to render single-pixel columns that we cannot zoom in on. We
# work around this by pretending that zero-duration samples are a
# millisecond in length.
clamp = 0.001
# We provide knobs that by default attempt to filter out stack
# frames that are too noisy:
#
# * A few take almost all execution time. These are usually boring
# setup functions, giving a stack that is deep but uninformative.
#
# * Numerous samples take almost no time, but introduce lots of
# noisy, oft-deep "spines" into a rendered profile.
blacklist = set()
totaltime = data.samples[-1].time - data.samples[0].time
minthreshold = totaltime * minthreshold
maxthreshold = max(totaltime * maxthreshold, clamp)
def poplast():
oldsid = stackid(tuple(laststack))
oldcat, oldfunc = laststack.popleft()
oldtime, oldidx = lastseen.popleft()
duration = sample.time - oldtime
if minthreshold <= duration <= maxthreshold:
# ensure no zero-duration events
sampletime = max(oldtime + clamp, sample.time)
samples.append(dict(ph='E', name=oldfunc, cat=oldcat, sf=oldsid,
ts=sampletime*1e6, pid=0))
else:
blacklist.add(oldidx)
# Much fiddling to synthesize correctly(ish) nested begin/end
# events given only stack snapshots.
for sample in data.samples:
tos = sample.stack[0]
name = tos.function
path = simplifypath(tos.path)
stack = tuple((('%s:%d' % (simplifypath(frame.path), frame.lineno),
frame.function) for frame in sample.stack))
qstack = collections.deque(stack)
if laststack == qstack:
continue
while laststack and qstack and laststack[-1] == qstack[-1]:
laststack.pop()
qstack.pop()
while laststack:
poplast()
for f in reversed(qstack):
lastseen.appendleft((sample.time, len(samples)))
laststack.appendleft(f)
path, name = f
sid = stackid(tuple(laststack))
samples.append(dict(ph='B', name=name, cat=path, ts=sample.time*1e6,
sf=sid, pid=0))
laststack = collections.deque(stack)
while laststack:
poplast()
events = [s[1] for s in enumerate(samples) if s[0] not in blacklist]
frames = collections.OrderedDict((str(k), v)
for (k,v) in enumerate(id2stack))
json.dump(dict(traceEvents=events, stackFrames=frames), fp, indent=1)
fp.write('\n')
def printusage():
print("""
The statprof command line allows you to inspect the last profile's results in
the following forms:
usage:
hotpath [-l --limit percent]
Shows a graph of calls with the percent of time each takes.
Red calls take over 10%% of the total time themselves.
lines
Shows the actual sampled lines.
functions
Shows the samples grouped by function.
function [filename:]functionname
Shows the callers and callees of a particular function.
flame [-s --script-path] [-o --output-file path]
Writes out a flamegraph to output-file (defaults to ~/flamegraph.svg)
Requires that ~/flamegraph.pl exist.
(Specify alternate script path with --script-path.)""")
def main(argv=None):
if argv is None:
argv = sys.argv
if len(argv) == 1:
printusage()
return 0
displayargs = {}
optstart = 2
displayargs['function'] = None
if argv[1] == 'hotpath':
displayargs['format'] = DisplayFormats.Hotpath
elif argv[1] == 'lines':
displayargs['format'] = DisplayFormats.ByLine
elif argv[1] == 'functions':
displayargs['format'] = DisplayFormats.ByMethod
elif argv[1] == 'function':
displayargs['format'] = DisplayFormats.AboutMethod
displayargs['function'] = argv[2]
optstart = 3
elif argv[1] == 'flame':
displayargs['format'] = DisplayFormats.FlameGraph
else:
printusage()
return 0
# process options
try:
opts, args = pycompat.getoptb(sys.argv[optstart:], "hl:f:o:p:",
["help", "limit=", "file=", "output-file=", "script-path="])
except getopt.error as msg:
print(msg)
printusage()
return 2
displayargs['limit'] = 0.05
path = None
for o, value in opts:
if o in ("-l", "--limit"):
displayargs['limit'] = float(value)
elif o in ("-f", "--file"):
path = value
elif o in ("-o", "--output-file"):
displayargs['outputfile'] = value
elif o in ("-p", "--script-path"):
displayargs['scriptpath'] = value
elif o in ("-h", "help"):
printusage()
return 0
else:
assert False, "unhandled option %s" % o
if not path:
print('must specify --file to load')
return 1
load_data(path=path)
display(**pycompat.strkwargs(displayargs))
return 0
if __name__ == "__main__":
sys.exit(main())