#!/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 # # Links: # Home Page # https://01.org/suspendresume # Source repo # https://github.com/01org/suspendresume # Documentation # Getting Started # https://01.org/suspendresume/documentation/getting-started # Command List: # https://01.org/suspendresume/documentation/command-list # # 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 # CONFIG_KPROBES=y # CONFIG_KPROBES_ON_FTRACE=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 import ConfigParser # ----------------- CLASSES -------------------- # Class: SystemValues # Description: # A global, single-instance container used to # store system values and test parameters class SystemValues: ansi = False version = '4.2' verbose = False addlogs = False mindevlen = 0.001 mincglen = 1.0 srgap = 0 cgexp = False outdir = '' 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' ] testcommand = '' mempath = '/dev/mem' powerfile = '/sys/power/state' suspendmode = 'mem' hostname = 'localhost' prefix = 'test' teststamp = '' dmesgstart = 0.0 dmesgfile = '' ftracefile = '' htmlfile = '' embedded = False rtcwake = False rtcwaketime = 10 rtcpath = '' devicefilter = [] stamp = 0 execcount = 1 x2delay = 0 usecallgraph = False usetraceevents = False usetraceeventsonly = False usetracemarkers = True usekprobes = True usedevsrc = False notestrun = False devprops = dict() postresumetime = 0 devpropfmt = '# Device Properties: .*' 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.*)$' kprobecolor = 'rgba(204,204,204,0.5)' synccolor = 'rgba(204,204,204,0.5)' debugfuncs = [] tracefuncs = { 'sys_sync': dict(), 'pm_prepare_console': dict(), 'pm_notifier_call_chain': dict(), 'freeze_processes': dict(), 'freeze_kernel_threads': dict(), 'pm_restrict_gfp_mask': dict(), 'acpi_suspend_begin': dict(), 'suspend_console': dict(), 'acpi_pm_prepare': dict(), 'syscore_suspend': dict(), 'arch_enable_nonboot_cpus_end': dict(), 'syscore_resume': dict(), 'acpi_pm_finish': dict(), 'resume_console': dict(), 'acpi_pm_end': dict(), 'pm_restore_gfp_mask': dict(), 'thaw_processes': dict(), 'pm_restore_console': dict(), 'CPU_OFF': { 'func':'_cpu_down', 'args_x86_64': {'cpu':'%di:s32'}, 'format': 'CPU_OFF[{cpu}]', 'mask': 'CPU_.*_DOWN' }, 'CPU_ON': { 'func':'_cpu_up', 'args_x86_64': {'cpu':'%di:s32'}, 'format': 'CPU_ON[{cpu}]', 'mask': 'CPU_.*_UP' }, } dev_tracefuncs = { # general wait/delay/sleep 'msleep': { 'args_x86_64': {'time':'%di:s32'} }, 'udelay': { 'func':'__const_udelay', 'args_x86_64': {'loops':'%di:s32'} }, 'acpi_os_stall': dict(), # ACPI 'acpi_resume_power_resources': dict(), 'acpi_ps_parse_aml': dict(), # filesystem 'ext4_sync_fs': dict(), # ATA 'ata_eh_recover': { 'args_x86_64': {'port':'+36(%di):s32'} }, # i915 'i915_gem_restore_gtt_mappings': dict(), 'intel_opregion_setup': dict(), 'intel_dp_detect': dict(), 'intel_hdmi_detect': dict(), 'intel_opregion_init': dict(), } kprobes_postresume = [ { 'name': 'ataportrst', 'func': 'ata_eh_recover', 'args': {'port':'+36(%di):s32'}, 'format': 'ata{port}_port_reset', 'mask': 'ata.*_port_reset' } ] kprobes = dict() timeformat = '%.3f' def __init__(self): # if this is a phoronix test run, set some default options if('LOG_FILE' in os.environ and 'TEST_RESULTS_IDENTIFIER' in os.environ): self.embedded = True self.addlogs = True self.htmlfile = os.environ['LOG_FILE'] 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 if (hasattr(sys.stdout, 'isatty') and sys.stdout.isatty()): self.ansi = True def setPrecision(self, num): if num < 0 or num > 6: return self.timeformat = '%.{0}f'.format(num) 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, testpath=''): self.prefix = self.hostname v = open('/proc/version', 'r').read().strip() kver = string.split(v)[2] n = datetime.now() testtime = n.strftime('suspend-%m%d%y-%H%M%S') if not testpath: testpath = n.strftime('suspend-%y%m%d-%H%M%S') if(subdir != "."): self.testdir = subdir+"/"+testpath else: self.testdir = testpath self.teststamp = \ '# '+testtime+' '+self.prefix+' '+self.suspendmode+' '+kver if(self.embedded): self.dmesgfile = \ '/tmp/'+testtime+'_'+self.suspendmode+'_dmesg.txt' self.ftracefile = \ '/tmp/'+testtime+'_'+self.suspendmode+'_ftrace.txt' return 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' if not os.path.isdir(self.testdir): os.mkdir(self.testdir) def setDeviceFilter(self, devnames): self.devicefilter = string.split(devnames) def rtcWakeAlarmOn(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)) def rtcWakeAlarmOff(self): os.system('echo 0 > %s/wakealarm' % self.rtcpath) def initdmesg(self): # get the latest time stamp from the dmesg log fp = os.popen('dmesg') ktime = '0' for line in fp: line = line.replace('\r\n', '') idx = line.find('[') if idx > 1: line = line[idx:] m = re.match('[ \t]*(\[ *)(?P[0-9\.]*)(\]) (?P.*)', line) if(m): ktime = m.group('ktime') fp.close() self.dmesgstart = float(ktime) def getdmesg(self): # store all new dmesg lines since initdmesg was called fp = os.popen('dmesg') op = open(self.dmesgfile, 'a') for line in fp: line = line.replace('\r\n', '') idx = line.find('[') if idx > 1: line = line[idx:] m = re.match('[ \t]*(\[ *)(?P[0-9\.]*)(\]) (?P.*)', line) if(not m): continue ktime = float(m.group('ktime')) if ktime > self.dmesgstart: op.write(line) fp.close() op.close() def addFtraceFilterFunctions(self, file): fp = open(file) list = fp.read().split('\n') fp.close() for i in list: if len(i) < 2: continue self.tracefuncs[i] = dict() def getFtraceFilterFunctions(self, current): rootCheck(True) if not current: os.system('cat '+self.tpath+'available_filter_functions') return fp = open(self.tpath+'available_filter_functions') master = fp.read().split('\n') fp.close() if len(self.debugfuncs) > 0: for i in self.debugfuncs: if i in master: print i else: print self.colorText(i) else: for i in self.tracefuncs: if 'func' in self.tracefuncs[i]: i = self.tracefuncs[i]['func'] if i in master: print i else: print self.colorText(i) def setFtraceFilterFunctions(self, list): fp = open(self.tpath+'available_filter_functions') master = fp.read().split('\n') fp.close() flist = '' for i in list: if i not in master: continue if ' [' in i: flist += i.split(' ')[0]+'\n' else: flist += i+'\n' fp = open(self.tpath+'set_graph_function', 'w') fp.write(flist) fp.close() def kprobeMatch(self, name, target): if name not in self.kprobes: return False if re.match(self.kprobes[name]['mask'], target): return True return False def basicKprobe(self, name): self.kprobes[name] = {'name': name,'func': name,'args': dict(),'format': name,'mask': name} def defaultKprobe(self, name, kdata): k = kdata for field in ['name', 'format', 'mask', 'func']: if field not in k: k[field] = name archargs = 'args_'+platform.machine() if archargs in k: k['args'] = k[archargs] else: k['args'] = dict() k['format'] = name self.kprobes[name] = k def kprobeColor(self, name): if name not in self.kprobes or 'color' not in self.kprobes[name]: return '' return self.kprobes[name]['color'] def kprobeDisplayName(self, name, dataraw): if name not in self.kprobes: self.basicKprobe(name) data = '' quote=0 # first remvoe any spaces inside quotes, and the quotes for c in dataraw: if c == '"': quote = (quote + 1) % 2 if quote and c == ' ': data += '_' elif c != '"': data += c fmt, args = self.kprobes[name]['format'], self.kprobes[name]['args'] arglist = dict() # now process the args for arg in sorted(args): arglist[arg] = '' m = re.match('.* '+arg+'=(?P.*) ', data); if m: arglist[arg] = m.group('arg') else: m = re.match('.* '+arg+'=(?P.*)', data); if m: arglist[arg] = m.group('arg') out = fmt.format(**arglist) out = out.replace(' ', '_').replace('"', '') return out def kprobeText(self, kprobe): name, fmt, func, args = kprobe['name'], kprobe['format'], kprobe['func'], kprobe['args'] if re.findall('{(?P[a-z,A-Z,0-9]*)}', func): doError('Kprobe "%s" has format info in the function name "%s"' % (name, func), False) for arg in re.findall('{(?P[a-z,A-Z,0-9]*)}', fmt): if arg not in args: doError('Kprobe "%s" is missing argument "%s"' % (name, arg), False) val = 'p:%s_cal %s' % (name, func) for i in sorted(args): val += ' %s=%s' % (i, args[i]) val += '\nr:%s_ret %s $retval\n' % (name, func) return val def addKprobes(self): # first test each kprobe print('INITIALIZING KPROBES...') rejects = [] for name in sorted(self.kprobes): if not self.testKprobe(self.kprobes[name]): rejects.append(name) # remove all failed ones from the list for name in rejects: vprint('Skipping KPROBE: %s' % name) self.kprobes.pop(name) self.fsetVal('', 'kprobe_events') kprobeevents = '' # set the kprobes all at once for kp in self.kprobes: val = self.kprobeText(self.kprobes[kp]) vprint('Adding KPROBE: %s\n%s' % (kp, val.strip())) kprobeevents += self.kprobeText(self.kprobes[kp]) self.fsetVal(kprobeevents, 'kprobe_events') # verify that the kprobes were set as ordered check = self.fgetVal('kprobe_events') linesout = len(kprobeevents.split('\n')) linesack = len(check.split('\n')) if linesack < linesout: # if not, try appending the kprobes 1 by 1 for kp in self.kprobes: kprobeevents = self.kprobeText(self.kprobes[kp]) self.fsetVal(kprobeevents, 'kprobe_events', 'a') self.fsetVal('1', 'events/kprobes/enable') def testKprobe(self, kprobe): kprobeevents = self.kprobeText(kprobe) if not kprobeevents: return False try: self.fsetVal(kprobeevents, 'kprobe_events') check = self.fgetVal('kprobe_events') except: return False linesout = len(kprobeevents.split('\n')) linesack = len(check.split('\n')) if linesack < linesout: return False return True def fsetVal(self, val, path, mode='w'): file = self.tpath+path if not os.path.exists(file): return False try: fp = open(file, mode) fp.write(val) fp.close() except: pass return True def fgetVal(self, path): file = self.tpath+path res = '' if not os.path.exists(file): return res try: fp = open(file, 'r') res = fp.read() fp.close() except: pass return res def cleanupFtrace(self): if(self.usecallgraph or self.usetraceevents): self.fsetVal('0', 'events/kprobes/enable') self.fsetVal('', 'kprobe_events') def setupAllKprobes(self): for name in self.tracefuncs: self.defaultKprobe(name, self.tracefuncs[name]) for name in self.dev_tracefuncs: self.defaultKprobe(name, self.dev_tracefuncs[name]) def isCallgraphFunc(self, name): if len(self.debugfuncs) < 1 and self.suspendmode == 'command': return True if name in self.debugfuncs: return True funclist = [] for i in self.tracefuncs: if 'func' in self.tracefuncs[i]: funclist.append(self.tracefuncs[i]['func']) else: funclist.append(i) if name in funclist: return True return False def initFtrace(self, testing=False): tp = self.tpath print('INITIALIZING FTRACE...') # turn trace off self.fsetVal('0', 'tracing_on') self.cleanupFtrace() # set the trace clock to global self.fsetVal('global', 'trace_clock') # set trace buffer to a huge value self.fsetVal('nop', 'current_tracer') self.fsetVal('100000', 'buffer_size_kb') # go no further if this is just a status check if testing: return if self.usekprobes: # add tracefunc kprobes so long as were not using full callgraph if(not self.usecallgraph or len(self.debugfuncs) > 0): for name in self.tracefuncs: self.defaultKprobe(name, self.tracefuncs[name]) if self.usedevsrc: for name in self.dev_tracefuncs: self.defaultKprobe(name, self.dev_tracefuncs[name]) else: self.usedevsrc = False self.addKprobes() # initialize the callgraph trace, unless this is an x2 run if(self.usecallgraph): # set trace type self.fsetVal('function_graph', 'current_tracer') self.fsetVal('', 'set_ftrace_filter') # set trace format options self.fsetVal('print-parent', 'trace_options') self.fsetVal('funcgraph-abstime', 'trace_options') self.fsetVal('funcgraph-cpu', 'trace_options') self.fsetVal('funcgraph-duration', 'trace_options') self.fsetVal('funcgraph-proc', 'trace_options') self.fsetVal('funcgraph-tail', 'trace_options') self.fsetVal('nofuncgraph-overhead', 'trace_options') self.fsetVal('context-info', 'trace_options') self.fsetVal('graph-time', 'trace_options') self.fsetVal('0', 'max_graph_depth') if len(self.debugfuncs) > 0: self.setFtraceFilterFunctions(self.debugfuncs) elif self.suspendmode == 'command': self.fsetVal('', 'set_graph_function') else: cf = ['dpm_run_callback'] if(self.usetraceeventsonly): cf += ['dpm_prepare', 'dpm_complete'] for fn in self.tracefuncs: if 'func' in self.tracefuncs[fn]: cf.append(self.tracefuncs[fn]['func']) else: cf.append(fn) self.setFtraceFilterFunctions(cf) if(self.usetraceevents): # turn trace events on events = iter(self.traceevents) for e in events: self.fsetVal('1', 'events/power/'+e+'/enable') # clear the trace buffer self.fsetVal('', 'trace') def verifyFtrace(self): # files needed for any trace data files = ['buffer_size_kb', 'current_tracer', 'trace', 'trace_clock', 'trace_marker', 'trace_options', 'tracing_on'] # files needed for callgraph trace data tp = self.tpath if(self.usecallgraph): files += [ 'available_filter_functions', 'set_ftrace_filter', 'set_graph_function' ] for f in files: if(os.path.exists(tp+f) == False): return False return True def verifyKprobes(self): # files needed for kprobes to work files = ['kprobe_events', 'events'] tp = self.tpath for f in files: if(os.path.exists(tp+f) == False): return False return True def colorText(self, str): if not self.ansi: return str return '\x1B[31;40m'+str+'\x1B[m' sysvals = SystemValues() # Class: DevProps # Description: # Simple class which holds property values collected # for all the devices used in the timeline. class DevProps: syspath = '' altname = '' async = True xtraclass = '' xtrainfo = '' def out(self, dev): return '%s,%s,%d;' % (dev, self.altname, self.async) def debug(self, dev): print '%s:\n\taltname = %s\n\t async = %s' % (dev, self.altname, self.async) def altName(self, dev): if not self.altname or self.altname == dev: return dev return '%s [%s]' % (self.altname, dev) def xtraClass(self): if self.xtraclass: return ' '+self.xtraclass if not self.async: return ' sync' return '' def xtraInfo(self): if self.xtraclass: return ' '+self.xtraclass if self.async: return ' async' return ' sync' # 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 = '' dev_ubiquitous = ['msleep', 'udelay'] 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() self.devicegroups = [] for phase in self.phases: self.devicegroups.append([phase]) 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 targetDevice(self, phaselist, start, end, pid=-1): tgtdev = '' for phase in phaselist: list = self.dmesg[phase]['list'] for devname in list: dev = list[devname] if(pid >= 0 and dev['pid'] != pid): continue devS = dev['start'] devE = dev['end'] if(start < devS or start >= devE or end <= devS or end > devE): continue tgtdev = dev break return tgtdev def addDeviceFunctionCall(self, displayname, kprobename, proc, pid, start, end, cdata, rdata): machstart = self.dmesg['suspend_machine']['start'] machend = self.dmesg['resume_machine']['end'] tgtdev = self.targetDevice(self.phases, start, end, pid) if not tgtdev and start >= machstart and end < machend: # device calls in machine phases should be serial tgtdev = self.targetDevice(['suspend_machine', 'resume_machine'], start, end) if not tgtdev: if 'scsi_eh' in proc: self.newActionGlobal(proc, start, end, pid) self.addDeviceFunctionCall(displayname, kprobename, proc, pid, start, end, cdata, rdata) else: vprint('IGNORE: %s[%s](%d) [%f - %f] | %s | %s | %s' % (displayname, kprobename, pid, start, end, cdata, rdata, proc)) return False # detail block fits within tgtdev if('src' not in tgtdev): tgtdev['src'] = [] title = cdata+' '+rdata mstr = '\(.*\) *(?P.*) *\((?P.*)\+.* arg1=(?P.*)' m = re.match(mstr, title) if m: c = m.group('caller') a = m.group('args').strip() r = m.group('ret') if len(r) > 6: r = '' else: r = 'ret=%s ' % r l = '%0.3fms' % ((end - start) * 1000) if kprobename in self.dev_ubiquitous: title = '%s(%s) <- %s, %s(%s)' % (displayname, a, c, r, l) else: title = '%s(%s) %s(%s)' % (displayname, a, r, l) e = TraceEvent(title, kprobename, start, end - start) tgtdev['src'].append(e) return True 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('src' in d): for e in d['src']: e.time = self.trimTimeVal(e.time, t0, dT, left) def normalizeTime(self, tZero): # 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) 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() self.devicegroups.append([phasename]) 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): for p in self.phases: if self.dmesg[p]['end'] > dev['start']: dev['end'] = self.dmesg[p]['end'] break 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 isInsideTimeline(self, start, end): if(self.start <= start and self.end > start): return True return False def phaseOverlap(self, phases): rmgroups = [] newgroup = [] for group in self.devicegroups: for phase in phases: if phase not in group: continue for p in group: if p not in newgroup: newgroup.append(p) if group not in rmgroups: rmgroups.append(group) for group in rmgroups: self.devicegroups.remove(group) self.devicegroups.append(newgroup) def newActionGlobal(self, name, start, end, pid=-1, color=''): # if event starts before timeline start, expand timeline if(start < self.start): self.setStart(start) # if event ends after timeline end, expand the timeline if(end > self.end): self.setEnd(end) # which phase is this device callback or action "in" targetphase = "none" htmlclass = '' overlap = 0.0 phases = [] 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 > 0: phases.append(phase) if o > overlap: if overlap > 0 and phase == 'post_resume': continue targetphase = phase overlap = o if pid == -2: htmlclass = ' bg' if len(phases) > 1: htmlclass = ' bg' self.phaseOverlap(phases) if targetphase in self.phases: newname = self.newAction(targetphase, name, pid, '', start, end, '', htmlclass, color) return (targetphase, newname) return False def newAction(self, phase, name, pid, parent, start, end, drv, htmlclass='', color=''): # 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 if pid == -2: i = 2 origname = name while(name in list): name = '%s[%d]' % (origname, i) i += 1 list[name] = {'start': start, 'end': end, 'pid': pid, 'par': parent, 'length': length, 'row': 0, 'id': devid, 'drv': drv } if htmlclass: list[name]['htmlclass'] = htmlclass if color: list[name]['color'] = color return name 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 deviceChildrenAllPhases(self, devname): devlist = [] for phase in self.phases: list = self.deviceChildren(devname, phase) for dev in list: if dev not in devlist: devlist.append(dev) return devlist def masterTopology(self, name, list, depth): node = DeviceNode(name, depth) for cname in list: # avoid recursions if name == cname: continue clist = self.deviceChildrenAllPhases(cname) 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'] pid = list[dev]['pid'] if(pid < 0 or re.match('[0-9]*-[0-9]*\.[0-9]*[\.0-9]*\:[\.0-9]*$', pdev)): continue if pdev and pdev not in real and pdev not in rootlist: rootlist.append(pdev) return rootlist def deviceTopology(self): rootlist = self.rootDeviceList() master = self.masterTopology('', rootlist, 0) return self.printTopology(master) def selectTimelineDevices(self, widfmt, tTotal, mindevlen): # only select devices that will actually show up in html self.tdevlist = dict() for phase in self.dmesg: devlist = [] list = self.dmesg[phase]['list'] for dev in list: length = (list[dev]['end'] - list[dev]['start']) * 1000 width = widfmt % (((list[dev]['end']-list[dev]['start'])*100)/tTotal) if width != '0.000000' and length >= mindevlen: devlist.append(dev) self.tdevlist[phase] = devlist # Class: TraceEvent # Description: # A container for trace event data found in the ftrace file class TraceEvent: text = '' time = 0.0 length = 0.0 title = '' row = 0 def __init__(self, a, n, t, l): self.title = a self.text = n self.time = t self.length = l # Class: FTraceLine # Description: # A container for a single line of ftrace data. There are six basic types: # callgraph line: # call: " dpm_run_callback() {" # return: " }" # leaf: " dpm_run_callback();" # trace event: # tracing_mark_write: SUSPEND START or RESUME COMPLETE # suspend_resume: phase or custom exec block data # device_pm_callback: device callback info class FTraceLine: time = 0.0 length = 0.0 fcall = False freturn = False fevent = False fkprobe = False depth = 0 name = '' type = '' def __init__(self, t, m='', d=''): self.time = float(t) if not m and not d: return # is this a trace event if(d == 'traceevent' or re.match('^ *\/\* *(?P.*) \*\/ *$', m)): if(d == 'traceevent'): # nop format trace event msg = m else: # function_graph format trace event em = re.match('^ *\/\* *(?P.*) \*\/ *$', m) msg = em.group('msg') emm = re.match('^(?P.*?): (?P.*)', msg) if(emm): self.name = emm.group('msg') self.type = emm.group('call') else: self.name = msg km = re.match('^(?P.*)_cal$', self.type) if km: self.fcall = True self.fkprobe = True self.type = km.group('n') return km = re.match('^(?P.*)_ret$', self.type) if km: self.freturn = True self.fkprobe = True self.type = km.group('n') return self.fevent = True return # convert the duration to seconds if(d): self.length = float(d)/1000000 # the indentation determines the depth match = re.match('^(?P *)(?P.*)$', 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').strip() # 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').strip() # function call with no children (leaf) elif(m[-1] == ';'): self.freturn = True match = re.match('^(?P.*) *\(.*', m) if(match): self.name = match.group('n').strip() # 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)) def startMarker(self): global sysvals # Is this the starting line of a suspend? if not self.fevent: return False if sysvals.usetracemarkers: if(self.name == 'SUSPEND START'): return True return False else: if(self.type == 'suspend_resume' and re.match('suspend_enter\[.*\] begin', self.name)): return True return False def endMarker(self): # Is this the ending line of a resume? if not self.fevent: return False if sysvals.usetracemarkers: if(self.name == 'RESUME COMPLETE'): return True return False else: if(self.type == 'suspend_resume' and re.match('thaw_processes\[.*\] end', self.name)): return True return False # 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 pid = 0 def __init__(self, pid): self.start = -1.0 self.end = -1.0 self.list = [] self.depth = 0 self.pid = pid def addLine(self, line, debug=False): # if this is already invalid, just leave if(self.invalid): return False # invalidate on too much data or bad depth if(len(self.list) >= 1000000 or self.depth < 0): self.invalidate(line) return False # compare current depth with this lines pre-call depth prelinedep = line.depth if(line.freturn and not line.fcall): prelinedep += 1 last = 0 lasttime = line.time virtualfname = 'execution_misalignment' if len(self.list) > 0: last = self.list[-1] lasttime = last.time # handle low misalignments by inserting returns if prelinedep < self.depth: if debug and last: print '-------- task %d --------' % self.pid last.debugPrint() idx = 0 # add return calls to get the depth down while prelinedep < self.depth: if debug: print 'MISALIGN LOW (add returns): C%d - eC%d' % (self.depth, prelinedep) self.depth -= 1 if idx == 0 and last and last.fcall and not last.freturn: # special case, turn last call into a leaf last.depth = self.depth last.freturn = True last.length = line.time - last.time if debug: last.debugPrint() else: vline = FTraceLine(lasttime) vline.depth = self.depth vline.name = virtualfname vline.freturn = True self.list.append(vline) if debug: vline.debugPrint() idx += 1 if debug: line.debugPrint() print '' # handle high misalignments by inserting calls elif prelinedep > self.depth: if debug and last: print '-------- task %d --------' % self.pid last.debugPrint() idx = 0 # add calls to get the depth up while prelinedep > self.depth: if debug: print 'MISALIGN HIGH (add calls): C%d - eC%d' % (self.depth, prelinedep) if idx == 0 and line.freturn and not line.fcall: # special case, turn this return into a leaf line.fcall = True prelinedep -= 1 else: vline = FTraceLine(lasttime) vline.depth = self.depth vline.name = virtualfname vline.fcall = True if debug: vline.debugPrint() self.list.append(vline) self.depth += 1 if not last: self.start = vline.time idx += 1 if debug: line.debugPrint() print '' # process the call and set the new depth if(line.fcall and not line.freturn): self.depth += 1 elif(line.freturn and not line.fcall): self.depth -= 1 if len(self.list) < 1: self.start = line.time self.list.append(line) if(line.depth == 0 and line.freturn): if(self.start < 0): self.start = line.time self.end = line.time if line.fcall: self.end += line.length if self.list[0].name == virtualfname: self.invalid = True return True return False def invalidate(self, line): if(len(self.list) > 0): first = self.list[0] self.list = [] self.list.append(first) self.invalid = True id = 'task %s' % (self.pid) window = '(%f - %f)' % (self.start, line.time) if(self.depth < 0): vprint('Too much data for '+id+\ ' (buffer overflow), ignoring this callback') else: vprint('Too much data for '+id+\ ' '+window+', ignoring this callback') def slice(self, t0, tN): minicg = FTraceCallGraph(0) 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) if((count == 0 and l.freturn and l.fcall) or (count > 0 and l.depth <= 0)): break count += 1 return minicg def repair(self, enddepth): # bring the depth back to 0 with additional returns fixed = False last = self.list[-1] for i in reversed(range(enddepth)): t = FTraceLine(last.time) t.depth = i t.freturn = True fixed = self.addLine(t) if fixed: self.end = last.time return True return False def postProcess(self, debug=False): 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): if debug: print 'Post Process Error: Depth missing' l.debugPrint() return False # transfer total time from return line to call line stack[l.depth].length = l.length stack.pop(l.depth) l.length = 0 cnt -= 1 if(cnt == 0): # trace caught the whole call tree return True elif(cnt < 0): if debug: print 'Post Process Error: Depth is less than 0' return False # trace ended before call tree finished return self.repair(cnt) def deviceMatch(self, pid, data): found = False # add the callgraph data to the device hierarchy borderphase = { 'dpm_prepare': 'suspend_prepare', 'dpm_complete': 'resume_complete' } if(self.list[0].name in borderphase): p = borderphase[self.list[0].name] list = data.dmesg[p]['list'] for devname in list: dev = list[devname] if(pid == dev['pid'] and self.start <= dev['start'] and self.end >= dev['end']): dev['ftrace'] = self.slice(dev['start'], dev['end']) found = True return found for p in data.phases: if(data.dmesg[p]['start'] <= self.start and self.start <= data.dmesg[p]['end']): list = data.dmesg[p]['list'] for devname in list: dev = list[devname] if(pid == dev['pid'] and self.start <= dev['start'] and self.end >= dev['end']): dev['ftrace'] = self found = True break break return found def newActionFromFunction(self, data): name = self.list[0].name if name in ['dpm_run_callback', 'dpm_prepare', 'dpm_complete']: return fs = self.start fe = self.end if fs < data.start or fe > data.end: return phase = '' for p in data.phases: if(data.dmesg[p]['start'] <= self.start and self.start < data.dmesg[p]['end']): phase = p break if not phase: return out = data.newActionGlobal(name, fs, fe, -2) if out: phase, myname = out data.dmesg[phase]['list'][myname]['ftrace'] = self def debugPrint(self): print('[%f - %f] %s (%d)') % (self.start, self.end, self.list[0].name, self.pid) 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(' ') # Class: Timeline # Description: # A container for a device timeline which calculates # all the html properties to display it correctly class Timeline: html = {} height = 0 # total timeline height scaleH = 20 # timescale (top) row height rowH = 30 # device row height bodyH = 0 # body height rows = 0 # total timeline rows phases = [] rowmaxlines = dict() rowcount = dict() rowheight = dict() def __init__(self, rowheight): self.rowH = rowheight self.html = { 'header': '', 'timeline': '', 'legend': '', } # Function: getDeviceRows # Description: # determine how may rows the device funcs will take # Arguments: # rawlist: the list of devices/actions for a single phase # Output: # The total number of rows needed to display this phase of the timeline def getDeviceRows(self, rawlist): # clear all rows and set them to undefined lendict = dict() for item in rawlist: item.row = -1 lendict[item] = item.length list = [] for i in sorted(lendict, key=lendict.get, reverse=True): list.append(i) remaining = len(list) rowdata = dict() row = 1 # try to pack each row with as many ranges as possible while(remaining > 0): if(row not in rowdata): rowdata[row] = [] for i in list: if(i.row >= 0): continue s = i.time e = i.time + i.length valid = True for ritem in rowdata[row]: rs = ritem.time re = ritem.time + ritem.length if(not (((s <= rs) and (e <= rs)) or ((s >= re) and (e >= re)))): valid = False break if(valid): rowdata[row].append(i) i.row = row remaining -= 1 row += 1 return row # Function: getPhaseRows # Description: # Organize the timeline entries into the smallest # number of rows possible, with no entry overlapping # Arguments: # list: the list of devices/actions for a single phase # devlist: string list of device names to use # Output: # The total number of rows needed to display this phase of the timeline def getPhaseRows(self, dmesg, devlist): # clear all rows and set them to undefined remaining = len(devlist) rowdata = dict() row = 0 lendict = dict() myphases = [] for item in devlist: if item[0] not in self.phases: self.phases.append(item[0]) if item[0] not in myphases: myphases.append(item[0]) self.rowmaxlines[item[0]] = dict() self.rowheight[item[0]] = dict() dev = dmesg[item[0]]['list'][item[1]] dev['row'] = -1 lendict[item] = float(dev['end']) - float(dev['start']) if 'src' in dev: dev['devrows'] = self.getDeviceRows(dev['src']) lenlist = [] for i in sorted(lendict, key=lendict.get, reverse=True): lenlist.append(i) orderedlist = [] for item in lenlist: dev = dmesg[item[0]]['list'][item[1]] if dev['pid'] == -2: orderedlist.append(item) for item in lenlist: if item not in orderedlist: orderedlist.append(item) # try to pack each row with as many ranges as possible while(remaining > 0): rowheight = 1 if(row not in rowdata): rowdata[row] = [] for item in orderedlist: dev = dmesg[item[0]]['list'][item[1]] if(dev['row'] < 0): s = dev['start'] e = dev['end'] valid = True for ritem in rowdata[row]: rs = ritem['start'] re = ritem['end'] if(not (((s <= rs) and (e <= rs)) or ((s >= re) and (e >= re)))): valid = False break if(valid): rowdata[row].append(dev) dev['row'] = row remaining -= 1 if 'devrows' in dev and dev['devrows'] > rowheight: rowheight = dev['devrows'] for phase in myphases: self.rowmaxlines[phase][row] = rowheight self.rowheight[phase][row] = rowheight * self.rowH row += 1 if(row > self.rows): self.rows = int(row) for phase in myphases: self.rowcount[phase] = row return row def phaseRowHeight(self, phase, row): return self.rowheight[phase][row] def phaseRowTop(self, phase, row): top = 0 for i in sorted(self.rowheight[phase]): if i >= row: break top += self.rowheight[phase][i] return top # Function: calcTotalRows # Description: # Calculate the heights and offsets for the header and rows def calcTotalRows(self): maxrows = 0 standardphases = [] for phase in self.phases: total = 0 for i in sorted(self.rowmaxlines[phase]): total += self.rowmaxlines[phase][i] if total > maxrows: maxrows = total if total == self.rowcount[phase]: standardphases.append(phase) self.height = self.scaleH + (maxrows*self.rowH) self.bodyH = self.height - self.scaleH for phase in standardphases: for i in sorted(self.rowheight[phase]): self.rowheight[phase][i] = self.bodyH/self.rowcount[phase] # Function: createTimeScale # Description: # Create the timescale for a timeline block # Arguments: # m0: start time (mode begin) # mMax: end time (mode end) # tTotal: total timeline time # mode: suspend or resume # Output: # The html code needed to display the time scale def createTimeScale(self, m0, mMax, tTotal, mode): timescale = '
    {1}
    \n' rline = '
    Resume
    \n' output = '
    \n' # set scale for timeline mTotal = mMax - m0 tS = 0.1 if(tTotal <= 0): return output+'
    \n' if(tTotal > 4): tS = 1 divTotal = int(mTotal/tS) + 1 divEdge = (mTotal - tS*(divTotal-1))*100/mTotal for i in range(divTotal): htmlline = '' if(mode == 'resume'): pos = '%0.3f' % (100 - ((float(i)*tS*100)/mTotal)) val = '%0.fms' % (float(i)*tS*1000) htmlline = timescale.format(pos, val) if(i == 0): htmlline = rline else: pos = '%0.3f' % (100 - ((float(i)*tS*100)/mTotal) - divEdge) val = '%0.fms' % (float(i-divTotal+1)*tS*1000) if(i == divTotal - 1): val = 'Suspend' htmlline = timescale.format(pos, val) output += htmlline output += '\n' return output # Class: TestProps # Description: # A list of values describing the properties of these test runs class TestProps: stamp = '' tracertype = '' S0i3 = False fwdata = [] ftrace_line_fmt_fg = \ '^ *(?P