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|
#!/usr/bin/env python
#
# This file is Copyright (c) 2010 by the GPSD project
# BSD terms apply: see the file COPYING in the distribution root for details.
"""
usage: regress-builder [-r limit] [-s seed]
Test-compile gpsd with each of every possible combination of device-driver
options, excluding stub drivers we don't support yet. This does a good
job of catching bugs after driver API changes.
The -r option sets Monte Carlo mode (random-walk through configuration space)
and limits the number of tests. The -s, if given, sets a seed; the default is
to seed from the system time.
If no options are given, the script performs a sequential test of all
possibilities. This requires time on the order of 2 ** n where n is
the count of options.
"""
import os, sys, random, getopt, time
driver_names = (
"aivdm",
"ashtech",
#"earthmate",
"evermore",
"fv18",
"garmin",
"garmintxt",
"geostar",
"gpsclock",
"itrax",
"mtk3301",
"navcom",
"nmea",
"ntrip",
"oncore",
"oceanserver",
"rtcm104v2",
#"rtcm104v3",
"sirf",
"superstar2",
#"tnt",
"tripmate",
"tsip",
"ubx",
"timing",
"clientdebug",
"oldstyle",
"ntpshm",
"pps",
"reconfigure",
"controlsend",
)
cyclesize = 2 ** len(driver_names)
def Sequential():
"Generate sequential test vectors for exhautive search."
for i in xrange(cyclesize):
yield i
return
def MonteCarlo(seed):
"Generate a random shuffle of test vectors for Monte Carlo testing."
# All the magic here is in the choice of modulus. Any odd number will
# be relatively prime to any power of two and thus be sufficient to step
# around the cycle hitting each number exactly once. We'd like adjacent
# stops to have a large distance from each other. Number theory says the
# best way to do this is to choose a modulus close to cyclesize / phi,
# where phi is the golden ratio (1 + 5**0.5)/2.
modulus = int(cyclesize / 1.618033980)
if modulus % 2 == 0:
modulus += 1
for i in xrange(cyclesize):
yield (seed + i * modulus) % cyclesize
return
class TestFactory:
"Manage compilation tests."
Preamble = '''
env X_LIBS="" \\
CPPFLAGS="-I/usr/local/include " \\
LDFLAGS=" -L/usr/local/lib -g" \\
CFLAGS="-g -O2 -W -Wall" \\
./configure --prefix=/home/gpsd --disable-shared \\
'''
def n2v(self, n):
"Number to test-vector"
v = [0] * len(driver_names)
i = 0
while n > 0:
v[i] = n % 2
i += 1
n = n >> 1
return v
def test_header(self, vector):
hdr = ""
for (i, name) in enumerate(driver_names):
hdr += "--" + ("disable", "enable")[vector[i]] + "-" + name + " "
return hdr[:-1]
def make(self, vector):
if os.system("make 2>&1 > /dev/null"):
print "FAILED: ", self.test_header(vector)
else:
print "SUCCEEDED:", self.test_header(vector)
def configure_build(self, vector):
test = TestFactory.Preamble
for (i, name) in enumerate(driver_names):
test += " --" + ("disable", "enable")[vector[i]] + "-" + name + " \\\n"
test += "\n"
if os.system("("+ test + ") >/dev/null"):
print "configure FAILED:", self.test_header(vector)
else:
self.make(vector)
def filter(self, vector):
"Tell us whether this combination needs to be tested."
# No drivers at all won't even configure
if vector == [0] * len(driver_names):
return False
compiled_in = map(lambda e: e[1], filter(lambda e: e[0], zip(vector, driver_names)))
def on(name):
return name in compiled_in
def off(name):
return name not in compiled_in
# START OF FILTERS
#
# Some types require NMEA support and shouldn't be built without it.
if off("nmea") and (on("fv18") or on("earthmate") or on("tripmate")):
return False
# Earthmate, FV-18 and TripMate code scopes don't overlap.
if on("fv18") + on("earthmate") + on("tripmate") not in (0, 3):
return False
# SiRF has no overlapping code scopes with the DLE-led protocols
# (TSIP, Garmin, Evermore) but the DLE-led protocols have
# overlaps in the packet sniffer.
if on("sirf") != (on("tsip") or on("garmin") or on("evermore")):
return False
#
# END OF FILTERS
return True
def run(self, generator, limit=cyclesize):
expect = 0
for i in range(cyclesize):
if self.filter(self.n2v(i)):
expect += 1
print "# Expect %d of %d tests." % (expect, cyclesize)
starttime = time.time()
included = 0
excluded = 0
for n in generator:
if limit == 0:
return
vector = self.n2v(n)
if not self.filter(vector):
print "EXCLUDED:", self.test_header(vector)
excluded += 1
else:
self.configure_build(vector)
included += 1
limit -= 1
elapsed = int(time.time() - starttime)
hours = elapsed/3600
minutes = (elapsed - (hours * 3600)) / 60
seconds = elapsed - (hours * 3600) - (minutes * 60)
print "%d tests, %d excluded, in %dh%dm%ds" % (included, excluded, hours, minutes, seconds)
if __name__ == '__main__':
try:
(options, arguments) = getopt.getopt(sys.argv[1:], "n:r:")
except getopt.GetoptError, msg:
print "regress-builder: " + str(msg)
raise SystemExit, 1
montecarlo = False
limit = cyclesize
seed = int(time.time())
for (switch, val) in options:
if switch == '-r':
montecarlo = True
limit = int(val)
elif switch == '-s':
montecarlo = True
seed = int(val)
if montecarlo:
print "Monte Carlo test seeded with %d" % seed
TestFactory().run(MonteCarlo(seed), limit)
else:
print "Sequential compilation test"
TestFactory().run(Sequential())
|
