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#!/usr/bin/env python
import defapp
from os.path import splitext, basename
from optparse import make_option as o
from tempfile import NamedTemporaryFile as Tmp
import csv
from plot import decode
from gnuplot import gnuplot, FORMATS
MACHINE_TOPOLOGY = {
'jupiter-cs' : (4, [('preempt', lambda x, y: x == y),
('mem', lambda x, y: x != y)]),
# Socket0 Socket1 Socket2 Socket3
# ------ ------- ------- -------
# | 0, 4| | 1, 5| | 2, 6| | 3, 7|
# | 8,12| | 9,13| |10,14| |11,15|
# |16,20| |17,21| |18,22| |19,23|
# ------- ------- ------- -------
'ludwig.cs.unc.edu' : (24, [('preempt', lambda x, y: x == y),
('l2',
lambda x, y: abs(y - x) == 4),
('l3',
lambda x, y:
abs(y - x) > 4 and \
abs(y - x) % 4 == 0),
('mem', lambda x, y: abs(y - x) % 4 != 0)])
}
PMO_PARAM = {
'wss' : 'WSS',
'host' : 'host',
'wcycle' : 'write-cycle'
}
PMO_MEM = {
'mem' : 'a migration through main memory',
'l3' : 'a migration through a shared L3 cache',
'l2' : 'a migration through a shared L2 cache',
'preempt' : 'a preemption',
'all' : 'either a migration or preemption',
}
PMO_SUBPLOTS = [
# x, y, y-delta, split according to mem-hierarchy?
(0, 6, None, False),
(0, 7, None, False),
(0, 8, None, False),
(0, 9, None, False),
(0, 10, None, True),
(3, 10, None, True),
(0, 10, 9, True),
(3, 10, 9, True),
]
PMO_COL_LABEL = [('measurement', 'sample', 'index'),
('write cycles', 'wcycle', 'every nth access'),
('WSS', 'wcc', 'kilobytes'),
('suspension length', 'delay', 'microseconds'),
('CPU (preempted on)', 'from', 'processor'),
('CPU (resumed on)', 'to', 'processor'),
('cold access', 'cold', 'cycles'),
('first hot access', 'hot1', 'cycles'),
('second hot access', 'hot2', 'cycles'),
('third hot access', 'hot3', 'cycles'),
('access after resuming', 'after', 'cycles')
]
PMO_FROM_CPU = 4
PMO_TO_CPU = 5
options = [
o('-f', '--format', action='store', dest='format', type='choice',
choices=FORMATS, help='output format'),
o(None, '--paper', action='store_true', dest='paper'),
o(None, '--wide', action='store_true', dest='wide'),
o(None, '--split', action='store_true', dest='split'),
]
defaults = {
'format' : 'show',
'paper' : False,
'split' : False,
'wide' : False,
}
def extract_cols(data, xcol, ycol1, ycol2, cast=int, cpu_filter=lambda x, y: True):
for row in data:
fcpu = int(row[PMO_FROM_CPU])
tcpu = int(row[PMO_TO_CPU])
if cpu_filter(fcpu, tcpu):
if ycol2 is None:
yield (row[xcol], cast(row[ycol1]))
else:
yield (row[xcol], cast(row[ycol1]) - cast(row[ycol2]))
class CyclePlotter(defapp.App):
def __init__(self):
defapp.App.__init__(self, options, defaults, no_std_opts=True)
def setup_pmo_graphs(self, datafile, conf):
host = conf['host']
if host in MACHINE_TOPOLOGY:
(cpus, hier) = MACHINE_TOPOLOGY[host]
plots = []
data = list(csv.reader(open(datafile)))
for (xcol, ycol, yminus, by_mem_hierarchy) in PMO_SUBPLOTS:
sub = [('all', lambda x, y: True)]
if by_mem_hierarchy:
sub += hier
for tag, test in sub:
tmp = Tmp()
for row in extract_cols(data,
xcol, ycol, yminus,
cpu_filter=test):
tmp.write("%s, %s\n" % row)
tmp.flush()
plots.append((tmp, xcol, ycol, yminus, tag))
return plots
else:
self.err('Unkown host: %s' % host)
return None
def plot_preempt_migrate(self, datafile, name, conf):
plots = self.setup_pmo_graphs(datafile, conf)
if plots is None:
print "Skipping %s..." % datafile
return
for (tmp, xcol, ycol, yminus, tag) in plots:
xtag = PMO_COL_LABEL[xcol][1]
ytag = PMO_COL_LABEL[ycol][1]
dtag = "-delta-%s" % PMO_COL_LABEL[yminus][1] if not yminus is None else ""
figname = "%s_%s%s-vs-%s_%s" % (name, ytag, dtag, xtag, tag)
xunit = PMO_COL_LABEL[xcol][2]
yunit = PMO_COL_LABEL[ycol][2]
ylabel = PMO_COL_LABEL[ycol][0]
xlabel = PMO_COL_LABEL[xcol][0]
title = "%s" % ylabel
if ycol == 10:
title += " from %s" % PMO_MEM[tag]
for key in conf:
if key in PMO_PARAM:
title += " %s=%s" % (PMO_PARAM[key], conf[key])
gnuplot([(tmp.name, 1, 2, ylabel)],
xlabel="%s (%s)" % (xlabel, xunit),
ylabel="%s (%s)" % ("access cost" if yminus is None
else "delta to %s" % PMO_COL_LABEL[yminus][0],
yunit),
title=title,
style='points',
format=self.options.format,
fname=figname)
def plot_file(self, datafile):
bname = basename(datafile)
name, ext = splitext(bname)
if ext != '.csv':
self.err("Warning: '%s' doesn't look like a CSV file."
% bname)
conf = decode(name)
if 'pmo' in conf:
self.plot_preempt_migrate(datafile, name, conf)
else:
self.err("Skipped '%s'; unkown experiment type."
% bname)
def default(self, _):
for datafile in self.args:
self.plot_file(datafile)
if __name__ == "__main__":
CyclePlotter().launch()
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