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#!/usr/bin/env python
"""
Usage: leapsecond.py [-v] { [-h] | [-f filename] | [-g filename]
| [-H filename] | [-I isodate] | [-O unixdate]
| [-i rfcdate] | [-o unixdate] | [-n MMMYYYY] }
Options:
-I take a date in ISO8601 format and convert to Unix-UTC time
-O take a date in Unix-UTC time and convert to ISO8601.
-i take a date in RFC822 format and convert to Unix-UTC time
-o take a date in Unix-UTC time and convert to RFC822.
-f fetch leap-second offset data and save to local cache file
-H make leapsecond include
-h print this help
-v be verbose
-g generate a plot of leap-second dates over time. The command you
probably want is something like (depending on if your gnuplot install
does or does not support X11.
leapsecond.py -g leapseconds.cache | gnuplot --persist
leapsecond.py -g leapseconds.cache | gnuplot -e 'set terminal svg' - \\
| display
-n compute Unix gmt time for an IERS leap-second event given as a
three-letter English Gregorian month abbreviation followed by a
4-digit year.
Public urls and local cache file used:
http://hpiers.obspm.fr/iers/bul/bulc/bulletinc.dat
http://hpiers.obspm.fr/iers/bul/bulc/UTC-TAI.history
ftp://maia.usno.navy.mil/ser7/tai-utc.dat
leapseconds.cache
This file is Copyright (c) 2013 by the GPSD project
SPDX-License-Identifier: BSD-2-clause
"""
# This code runs compatibly under Python 2 and 3.x for x >= 2.
# Preserve this property!
from __future__ import absolute_import, print_function, division
import calendar
import math
import os
import random
import re
import signal
import sys
import time
try:
import urllib.request as urlrequest # Python 3
except ImportError:
import urllib as urlrequest # Python 2
# Set a socket timeout for slow servers
import socket
socket.setdefaulttimeout(30)
del socket
# *** Duplicate some code from gps.misc to avoid a dependency ***
# Determine a single class for testing "stringness"
try:
STR_CLASS = basestring # Base class for 'str' and 'unicode' in Python 2
except NameError:
STR_CLASS = str # In Python 3, 'str' is the base class
# Polymorphic str/bytes handling
BINARY_ENCODING = 'latin-1'
if bytes is str: # In Python 2 these functions can be null transformations
polystr = str
else: # Otherwise we do something real
def polystr(o):
"Convert bytes or str to str with proper encoding."
if isinstance(o, str):
return o
if isinstance(o, bytes):
return str(o, encoding=BINARY_ENCODING)
raise ValueError
def isotime(s):
"""Convert timestamps in ISO8661 format to and from Unix time including
optional fractional seconds.
"""
if isinstance(s, int):
return time.strftime("%Y-%m-%dT%H:%M:%S", time.gmtime(s))
elif isinstance(s, float):
date = int(s)
msec = s - date
date = time.strftime("%Y-%m-%dT%H:%M:%S", time.gmtime(s))
return date + "." + repr(msec)[3:]
elif isinstance(s, STR_CLASS):
if s[-1] == "Z":
s = s[:-1]
if "." in s:
(date, msec) = s.split(".")
else:
date = s
msec = "0"
# Note: no leap-second correction!
return calendar.timegm(time.strptime(date, "%Y-%m-%dT%H:%M:%S")) \
+ float("0." + msec)
else:
raise TypeError
# *** End of duplicated code ***
verbose = 0
__locations = [
(
# U.S. Navy's offset-history file
"ftp://maia.usno.navy.mil/ser7/tai-utc.dat",
r" TAI-UTC= +([0-9-]+)[^\n]*\n$",
1,
19, # Magic TAI-GPS offset -> (leapseconds 1980)
"ftp://maia.usno.navy.mil/ser7/tai-utc.dat",
),
(
# International Earth Rotation Service Bulletin C
"http://hpiers.obspm.fr/iers/bul/bulc/bulletinc.dat",
r" UTC-TAI = ([0-9-]+)",
-1,
19, # Magic TAI-GPS offset -> (leapseconds 1980)
"http://hpiers.obspm.fr/iers/bul/bulc/UTC-TAI.history",
),
]
GPS_EPOCH = 315964800 # 6 Jan 1980 00:00:00
SECS_PER_WEEK = 60 * 60 * 24 * 7 # Seconds per GPS week
ROLLOVER = 1024 # 10-bit week rollover
def gps_week(t):
return (t - GPS_EPOCH) // SECS_PER_WEEK % ROLLOVER
def gps_rollovers(t):
return (t - GPS_EPOCH) // SECS_PER_WEEK // ROLLOVER
def retrieve():
"Retrieve current leap-second from Web sources."
random.shuffle(__locations) # To spread the load
for (url, regexp, sign, offset, _) in __locations:
try:
if os.path.exists(url):
ifp = open(url)
else:
ifp = urlrequest.urlopen(url)
txt = polystr(ifp.read())
ifp.close()
if verbose:
sys.stderr.write("%s\n" % txt)
m = re.search(regexp, txt)
if m:
return int(m.group(1)) * sign - offset
except IOError:
if verbose:
sys.stderr.write("IOError: %s\n" % url)
return None
def last_insertion_time():
"Give last potential insertion time for a leap second."
# We need the Unix times for midnights Jan 1 and Jul 1 this year.
when = time.gmtime()
(tm_year, tm_mon, tm_mday, tm_hour, tm_min,
tm_sec, tm_wday, tm_yday, tm_isdst) = when
tm_mday = 1
tm_hour = tm_min = tm_sec = 0
tm_mon = 1
jan_t = (tm_year, tm_mon, tm_mday, tm_hour, tm_min,
tm_sec, tm_wday, tm_yday, tm_isdst)
jan = int(calendar.timegm(jan_t))
tm_mon = 7
jul_t = (tm_year, tm_mon, tm_mday, tm_hour, tm_min,
tm_sec, tm_wday, tm_yday, tm_isdst)
jul = int(calendar.timegm(jul_t))
# We have the UTC times of the potential insertion points this year.
now = time.time()
if now > jul:
return jul
return jan
def save_leapseconds(outfile):
"""Fetch the leap-second history data and make a leap-second list since
Unix epoch GMT (1970-01-01T00:00:00).
"""
random.shuffle(__locations) # To spread the load
for (_, _, _, _, url) in __locations:
skip = True
try:
fetchobj = urlrequest.urlopen(url)
except IOError:
sys.stderr.write("Fetch from %s failed.\n" % url)
continue
# This code assumes that after 1980, leap-second increments are
# always integrally one second and every increment is listed here
fp = open(outfile, "w")
for line in fetchobj:
line = polystr(line)
if verbose:
sys.stderr.write("%s\n" % line[:-1])
if line.startswith(" 1980"):
skip = False
if skip:
continue
fields = line.strip().split()
if len(fields) < 2:
continue
md = leapbound(fields[0], fields[1])
if verbose:
sys.stderr.write("# %s\n" % md)
fp.write(repr(iso_to_unix(md)) + "\t# " + str(md) + "\n")
fp.close()
return
sys.stderr.write("%s not updated.\n" % outfile)
def fetch_leapsecs(filename):
"Get a list of leap seconds from the local cache of the USNO history"
leapsecs = []
for line in open(str(filename)):
leapsecs.append(float(line.strip().split()[0]))
return leapsecs
def make_leapsecond_include(infile):
"""Get the current leap second count and century from the local cache
usable as C preprocessor #define
"""
# Underscore prefixes avoids warning W0612 from pylint,
# which doesn't count substitution through locals() as use.
leapjumps = fetch_leapsecs(infile)
now = int(time.time())
_century = time.strftime("%Y", time.gmtime(now))[:2] + "00"
_week = gps_week(now)
_rollovers = gps_rollovers(now)
_isodate = isotime(now - now % SECS_PER_WEEK)
_leapsecs = 0
for leapjump in leapjumps:
if leapjump < time.time():
_leapsecs += 1
return """\
/*
* Constants used for GPS time detection and rollover correction.
*
* Correct for week beginning %(_isodate)s
*/
#define BUILD_CENTURY\t%(_century)s
#define BUILD_WEEK\t%(_week)d # Assumes 10-bit week counter
#define BUILD_LEAPSECONDS\t%(_leapsecs)d
#define BUILD_ROLLOVERS\t%(_rollovers)d # Assumes 10-bit week counter
""" % locals()
def conditional_leapsecond_fetch(outfile, timeout):
"""Conditionally fetch leapsecond data,
w. timeout in case of evil firewalls.
"""
if not os.path.exists(outfile):
stale = True
else:
# If there can't have been a leapsecond insertion since the
# last time the cache was updated, we don't need to refresh.
# This test cuts way down on the frequency with which we fetch.
stale = last_insertion_time() > os.path.getmtime(outfile)
if not stale:
return True
def handler(_signum, _frame):
raise IOError
try:
signal.signal(signal.SIGALRM, handler)
except ValueError:
# Parallel builds trigger this - signal only works in main thread
sys.stdout.write("Signal set failed; ")
return False
signal.alarm(timeout)
sys.stdout.write("Attempting leap-second fetch...")
try:
save_leapseconds(outfile)
sys.stdout.write("succeeded.\n")
except IOError:
sys.stdout.write("failed; ")
return False
signal.alarm(0)
return True
def leastsquares(tuples):
"Generate coefficients for a least-squares fit to the specified data."
sum_x = 0
sum_y = 0
sum_xx = 0
sum_xy = 0
for (x, y) in tuples:
sum_x = sum_x + x
sum_y = sum_y + y
xx = math.pow(x, 2)
sum_xx = sum_xx + xx
xy = x * y
sum_xy = sum_xy + xy
n = len(tuples)
c = (-sum_x * sum_xy + sum_xx * sum_y) / (n * sum_xx - sum_x * sum_x)
b = (-sum_x * sum_y + n * sum_xy) / (n * sum_xx - sum_x * sum_x)
# y = b * x + c
maxerr = 0
for (x, y) in tuples:
err = y - (x * b + c)
if err > maxerr:
maxerr = err
return (b, c, maxerr)
def iso_to_unix(tv):
"Local Unix time to iso date."
return calendar.timegm(time.strptime(tv, "%Y-%m-%dT%H:%M:%S"))
def unix_to_iso(tv):
"ISO date to UTC Unix time."
return time.strftime("%Y-%m-%dT%H:%M:%S", time.gmtime(tv))
def graph_history(filename):
"Generate a GNUPLOT plot of the leap-second history."
raw = fetch_leapsecs(filename)
(b, c, e) = leastsquares(list(zip(list(range(len(raw))), raw)))
e /= (60 * 60 * 24 * 7)
dates = [time.strftime("%Y-%m-%d", time.localtime(t)) for t in raw]
# Adding 190 days to scale
enddate = time.strftime("%Y-%m-%d", time.localtime(raw[-1] + 16416000))
fmt = ''
fmt += '# Least-squares approximation of Unix time from leapsecond is:\n'
fmt += 'lsq(x) = %s * x + %s\n' % (b, c)
fmt += '# Maximum residual error is %.2f weeks\n' % e
fmt += 'set autoscale\n'
fmt += 'set ylabel "GPS-UTC (s)"\n'
fmt += 'set yrange [-1:%d]\n' % (len(dates))
fmt += 'set xlabel "Leap second date"\n'
fmt += 'set xtics rotate by 300\n'
fmt += 'set timefmt "%Y-%m-%d"\n'
fmt += 'set xdata time\n'
fmt += 'set format x "%Y-%m-%d"\n'
fmt += 'set xrange ["%s":"%s"]\n' % ("1979-09-01", enddate)
fmt += 'set key left top box\n'
fmt += 'plot "-" using 3:1 title "Leap second inserted" with points ;\n'
for (i, (r, d)) in enumerate(zip(raw, dates)):
fmt += "%d\t%s\t%s\n" % (i, r, d)
fmt += 'e\n'
print(fmt)
def rfc822_to_unix(tv):
"Local Unix time to RFC822 date."
return calendar.timegm(time.strptime(tv, "%d %b %Y %H:%M:%S"))
def unix_to_rfc822(tv):
"RFC822 date to gmt Unix time."
return time.strftime("%d %b %Y %H:%M:%S", time.gmtime(tv))
def printnext(val):
"Compute Unix time correponsing to a scheduled leap second."
if val[:3].lower() not in ("jun", "dec"):
sys.stderr.write("leapsecond.py: -n argument must begin with "
"'Jun' or 'Dec'\n")
raise SystemExit(1)
else:
month = val[:3].lower()
if len(val) != 7:
sys.stderr.wrrite("leapsecond.py: -n argument must be of "
"the form {jun|dec}nnnn.\n")
raise SystemExit(1)
try:
year = int(val[3:])
except ValueError:
sys.stderr.write("leapsecond.py: -n argument must end "
"with a 4-digit year.\n")
raise SystemExit(1)
# Date looks valid
tv = leapbound(year, month)
print("%d /* %s */" % (iso_to_unix(tv), tv))
def leapbound(year, month):
"Return a leap-second date in RFC822 form."
# USNO lists JAN and JUL (month following the leap second).
# IERS lists DEC. and JUN. (month preceding the leap second).
# Note: It is also possible for leap seconds to occur in end-Mar and
# end-Sep although none have occurred yet
if month.upper()[:3] == "JAN":
tv = "%s-12-31T23:59:60" % (int(year) - 1)
elif month.upper()[:3] in ("JUN", "JUL"):
tv = "%s-06-30T23:59:59" % year
elif month.upper()[:3] == "DEC":
tv = "%s-12-31T23:59:59" % year
return tv
# Main part
def usage():
print(__doc__)
raise SystemExit(0)
if __name__ == '__main__':
import getopt
(options, arguments) = getopt.getopt(sys.argv[1:], "hvf:g:H:i:n:o:I:O:")
for (switch, val) in options:
if switch == '-h': # help, get usage only
usage()
elif switch == '-v': # be verbose
verbose = 1
elif switch == '-f': # Fetch USNO data to cache locally
save_leapseconds(val)
raise SystemExit(0)
elif switch == '-g': # Graph the leap_second history
graph_history(val)
raise SystemExit(0)
elif switch == '-H': # make leapsecond include
sys.stdout.write(make_leapsecond_include(val))
raise SystemExit(0)
elif switch == '-i': # Compute Unix time from RFC822 date
print(rfc822_to_unix(val))
raise SystemExit(0)
elif switch == '-n': # Compute possible next leapsecond
printnext(val)
raise SystemExit(0)
elif switch == '-o': # Compute RFC822 date from Unix time
print(unix_to_rfc822(float(val)))
raise SystemExit(0)
elif switch == '-I': # Compute Unix time from ISO8601 date
print(isotime(val))
raise SystemExit(0)
elif switch == '-O': # Compute ISO8601 date from Unix time
print(isotime(float(val)))
raise SystemExit(0)
# End
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