#!/usr/bin/python # # Tool for analyzing suspend/resume timing # Copyright (c) 2013, Intel Corporation. # # This program is free software; you can redistribute it and/or modify it # under the terms and conditions of the GNU General Public License, # version 2, as published by the Free Software Foundation. # # This program is distributed in the hope it will be useful, but WITHOUT # ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or # FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for # more details. # # You should have received a copy of the GNU General Public License along with # this program; if not, write to the Free Software Foundation, Inc., # 51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA. # # Authors: # Todd Brandt # # Description: # This tool is designed to assist kernel and OS developers in optimizing # their linux stack's suspend/resume time. Using a kernel image built # with a few extra options enabled, the tool will execute a suspend and # will capture dmesg and ftrace data until resume is complete. This data # is transformed into a device timeline and a callgraph to give a quick # and detailed view of which devices and callbacks are taking the most # time in suspend/resume. The output is a single html file which can be # viewed in firefox or chrome. # # The following kernel build options are required: # CONFIG_PM_DEBUG=y # CONFIG_PM_SLEEP_DEBUG=y # CONFIG_FTRACE=y # CONFIG_FUNCTION_TRACER=y # CONFIG_FUNCTION_GRAPH_TRACER=y # # For kernel versions older than 3.15: # The following additional kernel parameters are required: # (e.g. in file /etc/default/grub) # GRUB_CMDLINE_LINUX_DEFAULT="... initcall_debug log_buf_len=16M ..." # # ----------------- LIBRARIES -------------------- import sys import time import os import string import re import platform from datetime import datetime import struct # ----------------- CLASSES -------------------- # Class: SystemValues # Description: # A global, single-instance container used to # store system values and test parameters class SystemValues: version = 3.0 verbose = False testdir = '.' tpath = '/sys/kernel/debug/tracing/' fpdtpath = '/sys/firmware/acpi/tables/FPDT' epath = '/sys/kernel/debug/tracing/events/power/' traceevents = [ 'suspend_resume', 'device_pm_callback_end', 'device_pm_callback_start' ] modename = { 'freeze': 'Suspend-To-Idle (S0)', 'standby': 'Power-On Suspend (S1)', 'mem': 'Suspend-to-RAM (S3)', 'disk': 'Suspend-to-disk (S4)' } mempath = '/dev/mem' powerfile = '/sys/power/state' suspendmode = 'mem' hostname = 'localhost' prefix = 'test' teststamp = '' dmesgfile = '' ftracefile = '' htmlfile = '' rtcwake = False rtcwaketime = 10 rtcpath = '' android = False adb = 'adb' devicefilter = [] stamp = 0 execcount = 1 x2delay = 0 usecallgraph = False usetraceevents = False usetraceeventsonly = False notestrun = False altdevname = dict() postresumetime = 0 tracertypefmt = '# tracer: (?P.*)' firmwarefmt = '# fwsuspend (?P[0-9]*) fwresume (?P[0-9]*)$' postresumefmt = '# post resume time (?P[0-9]*)$' stampfmt = '# suspend-(?P[0-9]{2})(?P[0-9]{2})(?P[0-9]{2})-'+\ '(?P[0-9]{2})(?P[0-9]{2})(?P[0-9]{2})'+\ ' (?P.*) (?P.*) (?P.*)$' def __init__(self): self.hostname = platform.node() if(self.hostname == ''): self.hostname = 'localhost' rtc = "rtc0" if os.path.exists('/dev/rtc'): rtc = os.readlink('/dev/rtc') rtc = '/sys/class/rtc/'+rtc if os.path.exists(rtc) and os.path.exists(rtc+'/date') and \ os.path.exists(rtc+'/time') and os.path.exists(rtc+'/wakealarm'): self.rtcpath = rtc def setOutputFile(self): if((self.htmlfile == '') and (self.dmesgfile != '')): m = re.match('(?P.*)_dmesg\.txt$', self.dmesgfile) if(m): self.htmlfile = m.group('name')+'.html' if((self.htmlfile == '') and (self.ftracefile != '')): m = re.match('(?P.*)_ftrace\.txt$', self.ftracefile) if(m): self.htmlfile = m.group('name')+'.html' if(self.htmlfile == ''): self.htmlfile = 'output.html' def initTestOutput(self, subdir): if(not self.android): self.prefix = self.hostname v = open('/proc/version', 'r').read().strip() kver = string.split(v)[2] else: self.prefix = 'android' v = os.popen(self.adb+' shell cat /proc/version').read().strip() kver = string.split(v)[2] testtime = datetime.now().strftime('suspend-%m%d%y-%H%M%S') if(subdir != "."): self.testdir = subdir+"/"+testtime else: self.testdir = testtime self.teststamp = \ '# '+testtime+' '+self.prefix+' '+self.suspendmode+' '+kver self.dmesgfile = \ self.testdir+'/'+self.prefix+'_'+self.suspendmode+'_dmesg.txt' self.ftracefile = \ self.testdir+'/'+self.prefix+'_'+self.suspendmode+'_ftrace.txt' self.htmlfile = \ self.testdir+'/'+self.prefix+'_'+self.suspendmode+'.html' os.mkdir(self.testdir) def setDeviceFilter(self, devnames): self.devicefilter = string.split(devnames) def rtcWakeAlarm(self): os.system('echo 0 > '+self.rtcpath+'/wakealarm') outD = open(self.rtcpath+'/date', 'r').read().strip() outT = open(self.rtcpath+'/time', 'r').read().strip() mD = re.match('^(?P[0-9]*)-(?P[0-9]*)-(?P[0-9]*)', outD) mT = re.match('^(?P[0-9]*):(?P[0-9]*):(?P[0-9]*)', outT) if(mD and mT): # get the current time from hardware utcoffset = int((datetime.now() - datetime.utcnow()).total_seconds()) dt = datetime(\ int(mD.group('y')), int(mD.group('m')), int(mD.group('d')), int(mT.group('h')), int(mT.group('m')), int(mT.group('s'))) nowtime = int(dt.strftime('%s')) + utcoffset else: # if hardware time fails, use the software time nowtime = int(datetime.now().strftime('%s')) alarm = nowtime + self.rtcwaketime os.system('echo %d > %s/wakealarm' % (alarm, self.rtcpath)) sysvals = SystemValues() # Class: DeviceNode # Description: # A container used to create a device hierachy, with a single root node # and a tree of child nodes. Used by Data.deviceTopology() class DeviceNode: name = '' children = 0 depth = 0 def __init__(self, nodename, nodedepth): self.name = nodename self.children = [] self.depth = nodedepth # Class: Data # Description: # The primary container for suspend/resume test data. There is one for # each test run. The data is organized into a cronological hierarchy: # Data.dmesg { # root structure, started as dmesg & ftrace, but now only ftrace # contents: times for suspend start/end, resume start/end, fwdata # phases { # 10 sequential, non-overlapping phases of S/R # contents: times for phase start/end, order/color data for html # devlist { # device callback or action list for this phase # device { # a single device callback or generic action # contents: start/stop times, pid/cpu/driver info # parents/children, html id for timeline/callgraph # optionally includes an ftrace callgraph # optionally includes intradev trace events # } # } # } # } # class Data: dmesg = {} # root data structure phases = [] # ordered list of phases start = 0.0 # test start end = 0.0 # test end tSuspended = 0.0 # low-level suspend start tResumed = 0.0 # low-level resume start tLow = 0.0 # time spent in low-level suspend (standby/freeze) fwValid = False # is firmware data available fwSuspend = 0 # time spent in firmware suspend fwResume = 0 # time spent in firmware resume dmesgtext = [] # dmesg text file in memory testnumber = 0 idstr = '' html_device_id = 0 stamp = 0 outfile = '' def __init__(self, num): idchar = 'abcdefghijklmnopqrstuvwxyz' self.testnumber = num self.idstr = idchar[num] self.dmesgtext = [] self.phases = [] self.dmesg = { # fixed list of 10 phases 'suspend_prepare': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#CCFFCC', 'order': 0}, 'suspend': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#88FF88', 'order': 1}, 'suspend_late': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#00AA00', 'order': 2}, 'suspend_noirq': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#008888', 'order': 3}, 'suspend_machine': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#0000FF', 'order': 4}, 'resume_machine': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#FF0000', 'order': 5}, 'resume_noirq': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#FF9900', 'order': 6}, 'resume_early': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#FFCC00', 'order': 7}, 'resume': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#FFFF88', 'order': 8}, 'resume_complete': {'list': dict(), 'start': -1.0, 'end': -1.0, 'row': 0, 'color': '#FFFFCC', 'order': 9} } self.phases = self.sortedPhases() def getStart(self): return self.dmesg[self.phases[0]]['start'] def setStart(self, time): self.start = time self.dmesg[self.phases[0]]['start'] = time def getEnd(self): return self.dmesg[self.phases[-1]]['end'] def setEnd(self, time): self.end = time self.dmesg[self.phases[-1]]['end'] = time def isTraceEventOutsideDeviceCalls(self, pid, time): for phase in self.phases: list = self.dmesg[phase]['list'] for dev in list: d = list[dev] if(d['pid'] == pid and time >= d['start'] and time <= d['end']): return False return True def addIntraDevTraceEvent(self, action, name, pid, time): if(action == 'mutex_lock_try'): color = 'red' elif(action == 'mutex_lock_pass'): color = 'green' elif(action == 'mutex_unlock'): color = 'blue' else: # create separate colors based on the name v1 = len(name)*10 % 256 v2 = string.count(name, 'e')*100 % 256 v3 = ord(name[0])*20 % 256 color = '#%06X' % ((v1*0x10000) + (v2*0x100) + v3) for phase in self.phases: list = self.dmesg[phase]['list'] for dev in list: d = list[dev] if(d['pid'] == pid and time >= d['start'] and time <= d['end']): e = TraceEvent(action, name, color, time) if('traceevents' not in d): d['traceevents'] = [] d['traceevents'].append(e) return d break return 0 def capIntraDevTraceEvent(self, action, name, pid, time): for phase in self.phases: list = self.dmesg[phase]['list'] for dev in list: d = list[dev] if(d['pid'] == pid and time >= d['start'] and time <= d['end']): if('traceevents' not in d): return for e in d['traceevents']: if(e.action == action and e.name == name and not e.ready): e.length = time - e.time e.ready = True break return def trimTimeVal(self, t, t0, dT, left): if left: if(t > t0): if(t - dT < t0): return t0 return t - dT else: return t else: if(t < t0 + dT): if(t > t0): return t0 + dT return t + dT else: return t def trimTime(self, t0, dT, left): self.tSuspended = self.trimTimeVal(self.tSuspended, t0, dT, left) self.tResumed = self.trimTimeVal(self.tResumed, t0, dT, left) self.start = self.trimTimeVal(self.start, t0, dT, left) self.end = self.trimTimeVal(self.end, t0, dT, left) for phase in self.phases: p = self.dmesg[phase] p['start'] = self.trimTimeVal(p['start'], t0, dT, left) p['end'] = self.trimTimeVal(p['end'], t0, dT, left) list = p['list'] for name in list: d = list[name] d['start'] = self.trimTimeVal(d['start'], t0, dT, left) d['end'] = self.trimTimeVal(d['end'], t0, dT, left) if('ftrace' in d): cg = d['ftrace'] cg.start = self.trimTimeVal(cg.start, t0, dT, left) cg.end = self.trimTimeVal(cg.end, t0, dT, left) for line in cg.list: line.time = self.trimTimeVal(line.time, t0, dT, left) if('traceevents' in d): for e in d['traceevents']: e.time = self.trimTimeVal(e.time, t0, dT, left) def normalizeTime(self, tZero): # first trim out any standby or freeze clock time if(self.tSuspended != self.tResumed): if(self.tResumed > tZero): self.trimTime(self.tSuspended, \ self.tResumed-self.tSuspended, True) else: self.trimTime(self.tSuspended, \ self.tResumed-self.tSuspended, False) # shift the timeline so that tZero is the new 0 self.tSuspended -= tZero self.tResumed -= tZero self.start -= tZero self.end -= tZero for phase in self.phases: p = self.dmesg[phase] p['start'] -= tZero p['end'] -= tZero list = p['list'] for name in list: d = list[name] d['start'] -= tZero d['end'] -= tZero if('ftrace' in d): cg = d['ftrace'] cg.start -= tZero cg.end -= tZero for line in cg.list: line.time -= tZero if('traceevents' in d): for e in d['traceevents']: e.time -= tZero def newPhaseWithSingleAction(self, phasename, devname, start, end, color): for phase in self.phases: self.dmesg[phase]['order'] += 1 self.html_device_id += 1 devid = '%s%d' % (self.idstr, self.html_device_id) list = dict() list[devname] = \ {'start': start, 'end': end, 'pid': 0, 'par': '', 'length': (end-start), 'row': 0, 'id': devid, 'drv': '' }; self.dmesg[phasename] = \ {'list': list, 'start': start, 'end': end, 'row': 0, 'color': color, 'order': 0} self.phases = self.sortedPhases() def newPhase(self, phasename, start, end, color, order): if(order < 0): order = len(self.phases) for phase in self.phases[order:]: self.dmesg[phase]['order'] += 1 if(order > 0): p = self.phases[order-1] self.dmesg[p]['end'] = start if(order < len(self.phases)): p = self.phases[order] self.dmesg[p]['start'] = end list = dict() self.dmesg[phasename] = \ {'list': list, 'start': start, 'end': end, 'row': 0, 'color': color, 'order': order} self.phases = self.sortedPhases() def setPhase(self, phase, ktime, isbegin): if(isbegin): self.dmesg[phase]['start'] = ktime else: self.dmesg[phase]['end'] = ktime def dmesgSortVal(self, phase): return self.dmesg[phase]['order'] def sortedPhases(self): return sorted(self.dmesg, key=self.dmesgSortVal) def sortedDevices(self, phase): list = self.dmesg[phase]['list'] slist = [] tmp = dict() for devname in list: dev = list[devname] tmp[dev['start']] = devname for t in sorted(tmp): slist.append(tmp[t]) return slist def fixupInitcalls(self, phase, end): # if any calls never returned, clip them at system resume end phaselist = self.dmesg[phase]['list'] for devname in phaselist: dev = phaselist[devname] if(dev['end'] < 0): dev['end'] = end vprint('%s (%s): callback didnt return' % (devname, phase)) def deviceFilter(self, devicefilter): # remove all by the relatives of the filter devnames filter = [] for phase in self.phases: list = self.dmesg[phase]['list'] for name in devicefilter: dev = name while(dev in list): if(dev not in filter): filter.append(dev) dev = list[dev]['par'] children = self.deviceDescendants(name, phase) for dev in children: if(dev not in filter): filter.append(dev) for phase in self.phases: list = self.dmesg[phase]['list'] rmlist = [] for name in list: pid = list[name]['pid'] if(name not in filter and pid >= 0): rmlist.append(name) for name in rmlist: del list[name] def fixupInitcallsThatDidntReturn(self): # if any calls never returned, clip them at system resume end for phase in self.phases: self.fixupInitcalls(phase, self.getEnd()) def newActionGlobal(self, name, start, end): # which phase is this device callback or action "in" targetphase = "none" overlap = 0.0 for phase in self.phases: pstart = self.dmesg[phase]['start'] pend = self.dmesg[phase]['end'] o = max(0, min(end, pend) - max(start, pstart)) if(o > overlap): targetphase = phase overlap = o if targetphase in self.phases: self.newAction(targetphase, name, -1, '', start, end, '') return True return False def newAction(self, phase, name, pid, parent, start, end, drv): # new device callback for a specific phase self.html_device_id += 1 devid = '%s%d' % (self.idstr, self.html_device_id) list = self.dmesg[phase]['list'] length = -1.0 if(start >= 0 and end >= 0): length = end - start list[name] = {'start': start, 'end': end, 'pid': pid, 'par': parent, 'length': length, 'row': 0, 'id': devid, 'drv': drv } def deviceIDs(self, devlist, phase): idlist = [] list = self.dmesg[phase]['list'] for devname in list: if devname in devlist: idlist.append(list[devname]['id']) return idlist def deviceParentID(self, devname, phase): pdev = '' pdevid = '' list = self.dmesg[phase]['list'] if devname in list: pdev = list[devname]['par'] if pdev in list: return list[pdev]['id'] return pdev def deviceChildren(self, devname, phase): devlist = [] list = self.dmesg[phase]['list'] for child in list: if(list[child]['par'] == devname): devlist.append(child) return devlist def deviceDescendants(self, devname, phase): children = self.deviceChildren(devname, phase) family = children for child in children: family += self.deviceDescendants(child, phase) return family def deviceChildrenIDs(self, devname, phase): devlist = self.deviceChildren(devname, phase) return self.deviceIDs(devlist, phase) def printDetails(self): vprint(' test start: %f' % self.start) for phase in self.phases: dc = len(self.dmesg[phase]['list']) vprint(' %16s: %f - %f (%d devices)' % (phase, \ self.dmesg[phase]['start'], self.dmesg[phase]['end'], dc)) vprint(' test end: %f' % self.end) def masterTopology(self, name, list, depth): node = DeviceNode(name, depth) for cname in list: clist = self.deviceChildren(cname, 'resume') cnode = self.masterTopology(cname, clist, depth+1) node.children.append(cnode) return node def printTopology(self, node): html = '' if node.name: info = '' drv = '' for phase in self.phases: list = self.dmesg[phase]['list'] if node.name in list: s = list[node.name]['start'] e = list[node.name]['end'] if list[node.name]['drv']: drv = ' {'+list[node.name]['drv']+'}' info += ('
  • %s: %.3fms
  • ' % (phase, (e-s)*1000)) html += '
  • '+node.name+drv+'' if info: html += '
      '+info+'
    ' html += '
  • ' if len(node.children) > 0: html += '
      ' for cnode in node.children: html += self.printTopology(cnode) html += '
    ' return html def rootDeviceList(self): # list of devices graphed real = [] for phase in self.dmesg: list = self.dmesg[phase]['list'] for dev in list: if list[dev]['pid'] >= 0 and dev not in real: real.append(dev) # list of top-most root devices rootlist = [] for phase in self.dmesg: list = self.dmesg[phase]['list'] for dev in list: pdev = list[dev]['par'] if(re.match('[0-9]*-[0-9]*\.[0-9]*[\.0-9]*\:[\.0-9]*$', pdev)): continue if pdev and pdev not in real and pdev not in rootlist: rootlist.append(pdev) return rootlist def deviceTopology(self): rootlist = self.rootDeviceList() master = self.masterTopology('', rootlist, 0) return self.printTopology(master) # Class: TraceEvent # Description: # A container for trace event data found in the ftrace file class TraceEvent: ready = False name = '' time = 0.0 color = '#FFFFFF' length = 0.0 action = '' def __init__(self, a, n, c, t): self.action = a self.name = n self.color = c self.time = t # Class: FTraceLine # Description: # A container for a single line of ftrace data. There are six basic types: # callgraph line: # call: " dpm_run_callback() {" # return: " }" # leaf: " dpm_run_callback();" # trace event: # tracing_mark_write: SUSPEND START or RESUME COMPLETE # suspend_resume: phase or custom exec block data # device_pm_callback: device callback info class FTraceLine: time = 0.0 length = 0.0 fcall = False freturn = False fevent = False depth = 0 name = '' type = '' def __init__(self, t, m, d): self.time = float(t) # is this a trace event if(d == 'traceevent' or re.match('^ *\/\* *(?P.*) \*\/ *$', m)): if(d == 'traceevent'): # nop format trace event msg = m else: # function_graph format trace event em = re.match('^ *\/\* *(?P.*) \*\/ *$', m) msg = em.group('msg') emm = re.match('^(?P.*?): (?P.*)', msg) if(emm): self.name = emm.group('msg') self.type = emm.group('call') else: self.name = msg self.fevent = True return # convert the duration to seconds if(d): self.length = float(d)/1000000 # the indentation determines the depth match = re.match('^(?P *)(?P.*)$', m) if(not match): return self.depth = self.getDepth(match.group('d')) m = match.group('o') # function return if(m[0] == '}'): self.freturn = True if(len(m) > 1): # includes comment with function name match = re.match('^} *\/\* *(?P.*) *\*\/$', m) if(match): self.name = match.group('n') # function call else: self.fcall = True # function call with children if(m[-1] == '{'): match = re.match('^(?P.*) *\(.*', m) if(match): self.name = match.group('n') # function call with no children (leaf) elif(m[-1] == ';'): self.freturn = True match = re.match('^(?P.*) *\(.*', m) if(match): self.name = match.group('n') # something else (possibly a trace marker) else: self.name = m def getDepth(self, str): return len(str)/2 def debugPrint(self, dev): if(self.freturn and self.fcall): print('%s -- %f (%02d): %s(); (%.3f us)' % (dev, self.time, \ self.depth, self.name, self.length*1000000)) elif(self.freturn): print('%s -- %f (%02d): %s} (%.3f us)' % (dev, self.time, \ self.depth, self.name, self.length*1000000)) else: print('%s -- %f (%02d): %s() { (%.3f us)' % (dev, self.time, \ self.depth, self.name, self.length*1000000)) # Class: FTraceCallGraph # Description: # A container for the ftrace callgraph of a single recursive function. # This can be a dpm_run_callback, dpm_prepare, or dpm_complete callgraph # Each instance is tied to a single device in a single phase, and is # comprised of an ordered list of FTraceLine objects class FTraceCallGraph: start = -1.0 end = -1.0 list = [] invalid = False depth = 0 def __init__(self): self.start = -1.0 self.end = -1.0 self.list = [] self.depth = 0 def setDepth(self, line): if(line.fcall and not line.freturn): line.depth = self.depth self.depth += 1 elif(line.freturn and not line.fcall): self.depth -= 1 line.depth = self.depth else: line.depth = self.depth def addLine(self, line, match): if(not self.invalid): self.setDepth(line) if(line.depth == 0 and line.freturn): if(self.start < 0): self.start = line.time self.end = line.time self.list.append(line) return True if(self.invalid): return False if(len(self.list) >= 1000000 or self.depth < 0): if(len(self.list) > 0): first = self.list[0] self.list = [] self.list.append(first) self.invalid = True if(not match): return False id = 'task %s cpu %s' % (match.group('pid'), match.group('cpu')) window = '(%f - %f)' % (self.start, line.time) if(self.depth < 0): print('Too much data for '+id+\ ' (buffer overflow), ignoring this callback') else: print('Too much data for '+id+\ ' '+window+', ignoring this callback') return False self.list.append(line) if(self.start < 0): self.start = line.time return False def slice(self, t0, tN): minicg = FTraceCallGraph() count = -1 firstdepth = 0 for l in self.list: if(l.time < t0 or l.time > tN): continue if(count < 0): if(not l.fcall or l.name == 'dev_driver_string'): continue firstdepth = l.depth count = 0 l.depth -= firstdepth minicg.addLine(l, 0) if((count == 0 and l.freturn and l.fcall) or (count > 0 and l.depth <= 0)): break count += 1 return minicg def sanityCheck(self): stack = dict() cnt = 0 for l in self.list: if(l.fcall and not l.freturn): stack[l.depth] = l cnt += 1 elif(l.freturn and not l.fcall): if(l.depth not in stack): return False stack[l.depth].length = l.length stack[l.depth] = 0 l.length = 0 cnt -= 1 if(cnt == 0): return True return False def debugPrint(self, filename): if(filename == 'stdout'): print('[%f - %f]') % (self.start, self.end) for l in self.list: if(l.freturn and l.fcall): print('%f (%02d): %s(); (%.3f us)' % (l.time, \ l.depth, l.name, l.length*1000000)) elif(l.freturn): print('%f (%02d): %s} (%.3f us)' % (l.time, \ l.depth, l.name, l.length*1000000)) else: print('%f (%02d): %s() { (%.3f us)' % (l.time, \ l.depth, l.name, l.length*1000000)) print(' ') else: fp = open(filename, 'w') print(filename) for l in self.list: if(l.freturn and l.fcall): fp.write('%f (%02d): %s(); (%.3f us)\n' % (l.time, \ l.depth, l.name, l.length*1000000)) elif(l.freturn): fp.write('%f (%02d): %s} (%.3f us)\n' % (l.time, \ l.depth, l.name, l.length*1000000)) else: fp.write('%f (%02d): %s() { (%.3f us)\n' % (l.time, \ l.depth, l.name, l.length*1000000)) fp.close() # Class: Timeline # Description: # A container for a suspend/resume html timeline. In older versions # of the script there were multiple timelines, but in the latest # there is only one. class Timeline: html = {} scaleH = 0.0 # height of the row as a percent of the timeline height rowH = 0.0 # height of each row in percent of the timeline height row_height_pixels = 30 maxrows = 0 height = 0 def __init__(self): self.html = { 'timeline': '', 'legend': '', 'scale': '' } def setRows(self, rows): self.maxrows = int(rows) self.scaleH = 100.0/float(self.maxrows) self.height = self.maxrows*self.row_height_pixels r = float(self.maxrows - 1) if(r < 1.0): r = 1.0 self.rowH = (100.0 - self.scaleH)/r # Class: TestRun # Description: # A container for a suspend/resume test run. This is necessary as # there could be more than one, and they need to be separate. class TestRun: ftrace_line_fmt_fg = \ '^ *(?P