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from __future__ import with_statement
import os
import string
import re
import tarfile
from collections import defaultdict
from samples import *
from process_tree import ProcessTree
class ParseError(Exception):
"""Represents errors during parse of the bootchart."""
def __init__(self, value):
self.value = value
def __str__(self):
return self.value
def _parse_headers(file):
"""Parses the headers of the bootchart."""
def parse((headers,last), line):
if '=' in line: last,value = map(string.strip, line.split('=', 1))
else: value = line.strip()
headers[last] += value
return headers,last
return reduce(parse, file.read().split('\n'), (defaultdict(str),''))[0]
def _parse_timed_blocks(file):
"""Parses (ie., splits) a file into so-called timed-blocks. A
timed-block consists of a timestamp on a line by itself followed
by zero or more lines of data for that point in time."""
def parse(block):
lines = block.split('\n')
if not lines:
raise ParseError('expected a timed-block consisting a timestamp followed by data lines')
try:
return (int(lines[0]), lines[1:])
except ValueError:
raise ParseError("expected a timed-block, but timestamp '%s' is not an integer" % lines[0])
blocks = file.read().split('\n\n')
return [parse(block) for block in blocks if block.strip()]
def _parse_proc_ps_log(file):
"""
* See proc(5) for details.
*
* {pid, comm, state, ppid, pgrp, session, tty_nr, tpgid, flags, minflt, cminflt, majflt, cmajflt, utime, stime,
* cutime, cstime, priority, nice, 0, itrealvalue, starttime, vsize, rss, rlim, startcode, endcode, startstack,
* kstkesp, kstkeip}
"""
processMap = {}
ltime = 0
timed_blocks = _parse_timed_blocks(file)
for time, lines in timed_blocks:
for line in lines:
tokens = line.split(' ')
offset = [index for index, token in enumerate(tokens[1:]) if token.endswith(')')][0]
pid, cmd, state, ppid = int(tokens[0]), ' '.join(tokens[1:2+offset]), tokens[2+offset], int(tokens[3+offset])
userCpu, sysCpu, stime= int(tokens[13+offset]), int(tokens[14+offset]), int(tokens[21+offset])
if processMap.has_key(pid):
process = processMap[pid]
process.cmd = cmd.replace('(', '').replace(')', '') # why rename after latest name??
else:
process = Process(pid, cmd, ppid, min(time, stime))
processMap[pid] = process
if process.last_user_cpu_time is not None and process.last_sys_cpu_time is not None and ltime is not None:
userCpuLoad, sysCpuLoad = process.calc_load(userCpu, sysCpu, time - ltime)
cpuSample = CPUSample('null', userCpuLoad, sysCpuLoad, 0.0)
process.samples.append(ProcessSample(time, state, cpuSample))
process.last_user_cpu_time = userCpu
process.last_sys_cpu_time = sysCpu
ltime = time
startTime = timed_blocks[0][0]
avgSampleLength = (ltime - startTime)/(len(timed_blocks)-1)
for process in processMap.values():
process.set_parent(processMap)
for process in processMap.values():
process.calc_stats(avgSampleLength)
return ProcessStats(processMap.values(), avgSampleLength, startTime, ltime)
def _parse_proc_stat_log(file):
samples = []
ltimes = None
for time, lines in _parse_timed_blocks(file):
# CPU times {user, nice, system, idle, io_wait, irq, softirq}
tokens = lines[0].split();
times = [ int(token) for token in tokens[1:] ]
if ltimes:
user = float((times[0] + times[1]) - (ltimes[0] + ltimes[1]))
system = float((times[2] + times[5] + times[6]) - (ltimes[2] + ltimes[5] + ltimes[6]))
idle = float(times[3] - ltimes[3])
iowait = float(times[4] - ltimes[4])
aSum = max(user + system + idle + iowait, 1)
samples.append( CPUSample(time, user/aSum, system/aSum, iowait/aSum) )
ltimes = times
# skip the rest of statistics lines
return samples
def _parse_proc_disk_stat_log(file, numCpu):
"""
Parse file for disk stats, but only look at the whole disks, eg. sda,
not sda1, sda2 etc. The format of relevant lines should be:
{major minor name rio rmerge rsect ruse wio wmerge wsect wuse running use aveq}
"""
DISK_REGEX = 'hd.$|sd.$'
def is_relevant_line(line):
return len(line.split()) == 14 and re.match(DISK_REGEX, line.split()[2])
disk_stat_samples = []
for time, lines in _parse_timed_blocks(file):
sample = DiskStatSample(time)
relevant_tokens = [line.split() for line in lines if is_relevant_line(line)]
for tokens in relevant_tokens:
disk, rsect, wsect, use = tokens[2], int(tokens[5]), int(tokens[9]), int(tokens[12])
sample.add_diskdata([rsect, wsect, use])
disk_stat_samples.append(sample)
disk_stats = []
for sample1, sample2 in zip(disk_stat_samples[:-1], disk_stat_samples[1:]):
interval = sample1.time - sample2.time
sums = [ a - b for a, b in zip(sample1.diskdata, sample2.diskdata) ]
readTput = sums[0] / 2.0 * 100.0 / interval
writeTput = sums[1] / 2.0 * 100.0 / interval
util = float( sums[2] ) / 10 / interval / numCpu
util = max(0.0, min(1.0, util))
disk_stats.append(DiskSample(sample2.time, readTput, writeTput, util))
return disk_stats
def get_num_cpus(headers):
"""Get the number of CPUs from the system.cpu header property. As the
CPU utilization graphs are relative, the number of CPUs currently makes
no difference."""
if headers is None:
return 1
cpu_model = headers.get("system.cpu")
if cpu_model is None:
return 1
mat = re.match(".*\\((\\d+)\\)", cpu_model)
if mat is None:
return 1
return int(mat.group(1))
class ParserState:
def __init__(self):
self.processes = {}
self.start = {}
self.end = {}
def valid(self):
return len(self.processes) != 0
_relevant_files = set(["header", "proc_diskstats.log", "proc_ps.log", "proc_stat.log"])
def _do_parse(state, filename, file):
#print filename
#writer.status("parsing '%s'" % filename)
paths = filename.split("/")
task = paths[-1]
pn = paths[-2]
start = None
end = None
for line in file:
if line.startswith("Started:"):
start = int(float(line.split()[-1]))
elif line.startswith("Ended:"):
end = int(float(line.split()[-1]))
if start and end and (end - start) > 8:
state.processes[pn + ":" + task] = [start, end]
state.start[start] = pn + ":" + task
state.end[end] = pn + ":" + task
return state
def parse_file(state, filename):
basename = os.path.basename(filename)
with open(filename, "rb") as file:
return _do_parse(state, filename, file)
def parse_paths(state, paths):
for path in paths:
root,extension = os.path.splitext(path)
if not(os.path.exists(path)):
print "warning: path '%s' does not exist, ignoring." % path
continue
if os.path.isdir(path):
files = [ f for f in [os.path.join(path, f) for f in os.listdir(path)] ]
files.sort()
state = parse_paths(state, files)
elif extension in [".tar", ".tgz", ".tar.gz"]:
tf = None
try:
tf = tarfile.open(path, 'r:*')
for name in tf.getnames():
state = _do_parse(state, name, tf.extractfile(name))
except tarfile.ReadError, error:
raise ParseError("error: could not read tarfile '%s': %s." % (path, error))
finally:
if tf != None:
tf.close()
else:
state = parse_file(state, path)
return state
def parse(paths, prune):
state = parse_paths(ParserState(), paths)
if not state.valid():
raise ParseError("empty state: '%s' does not contain a valid bootchart" % ", ".join(paths))
#monitored_app = state.headers.get("profile.process")
#proc_tree = ProcessTree(state.ps_stats, monitored_app, prune)
return state
def split_res(res, n):
""" Split the res into n pieces """
res_list = []
if n > 1:
s_list = sorted(res.start.keys())
frag_size = len(s_list) / float(n)
# Need the top value
if frag_size > int(frag_size):
frag_size = int(frag_size + 1)
else:
frag_size = int(frag_size)
start = 0
end = frag_size
while start < end:
state = ParserState()
for i in range(start, end):
# Add these lines for reference
#state.processes[pn + ":" + task] = [start, end]
#state.start[start] = pn + ":" + task
#state.end[end] = pn + ":" + task
p = res.start[s_list[i]]
s = s_list[i]
e = res.processes[p][1]
state.processes[p] = [s, e]
state.start[s] = p
state.end[e] = p
start = end
end = end + frag_size
if end > len(s_list):
end = len(s_list)
res_list.append(state)
else:
res_list.append(res)
return res_list
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