def _mktime(interp, is_gmt, hour, minute, second, month, day, year, dst=-1):
now = timelib.timelib_time_ctor()
adjust_seconds = 0
if is_gmt:
timelib.timelib_unixtime2gmt(now, int(pytime.time()))
else:
now.c_tz_info = interp.get_default_timezone("mktime").timelib_timezone
now.c_zone_type = timelib.TIMELIB_ZONETYPE_ID
timelib.timelib_unixtime2local(now, int(pytime.time()))
if year >= 0 and year < 70:
year += 2000
elif year >= 70 and year <= 100:
year += 1900
now.c_y = rffi.cast(lltype.Signed, year)
now.c_d = rffi.cast(lltype.Signed, day)
now.c_m = rffi.cast(lltype.Signed, month)
now.c_s = rffi.cast(lltype.Signed, second)
now.c_i = rffi.cast(lltype.Signed, minute)
now.c_h = rffi.cast(lltype.Signed, hour)
if is_gmt:
timelib.timelib_update_ts(now,
lltype.nullptr(timelib.timelib_tzinfo.TO))
else:
timelib.timelib_update_ts(
now,
interp.get_default_timezone("mktime").timelib_timezone)
if dst != -1:
interp.space.ec.deprecated(
"mktime(): The is_dst parameter is deprecated")
if is_gmt:
if dst == 1:
adjust_seconds -= 3600
else:
tmp_offset = timelib.timelib_get_time_zone_info(
now.c_sse,
interp.get_default_timezone("mktime").timelib_timezone)
if dst == 1 and intmask(tmp_offset.c_is_dst) == 0:
adjust_seconds -= 3600
if dst == 0 and intmask(tmp_offset.c_is_dst) == 1:
adjust_seconds += 3600
timelib.timelib_time_offset_dtor(tmp_offset)
error = lltype.malloc(rffi.CArrayPtr(lltype.Signed).TO,
1,
flavor='raw',
zero=True)
timestamp = timelib.timelib_date_to_int(now, error)
timestamp += adjust_seconds
timelib.timelib_time_dtor(now)
lltype.free(error, flavor='raw')
return timestamp
def date_timestamp_get(interp, w_datetime):
error = lltype.malloc(
rffi.CArrayPtr(lltype.Signed).TO, 1, flavor='raw', zero=True
)
timestamp = timelib.timelib_date_to_int(w_datetime.timelib_time, error)
lltype.free(error, flavor='raw')
return interp.space.wrap(timestamp)
def date_timestamp_get(interp, w_datetime):
error = lltype.malloc(rffi.CArrayPtr(lltype.Signed).TO,
1,
flavor='raw',
zero=True)
timestamp = timelib.timelib_date_to_int(w_datetime.timelib_time, error)
lltype.free(error, flavor='raw')
return interp.space.wrap(timestamp)
def date_sun_info(interp, time, latitude, longitude):
space = interp.space
timelib_time = timelib.timelib_time_ctor()
timelib_timezone = interp.get_default_timezone("date").timelib_timezone
timelib_time.c_tz_info = timelib_timezone
timelib_time.c_zone_type = timelib.TIMELIB_ZONETYPE_ID
timelib.timelib_unixtime2local(timelib_time, time)
timelib_time_2 = timelib.timelib_time_ctor()
dummy = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO, 1, flavor='raw')
ddummy = lltype.malloc(rffi.CArrayPtr(lltype.Float).TO, 1, flavor='raw')
c_rise = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO, 1, flavor='raw')
c_set = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO, 1, flavor='raw')
c_transit = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO,
1,
flavor='raw')
ret_val = []
# Get sun up/down and transit
rs = timelib.timelib_astro_rise_set_altitude(timelib_time, longitude,
latitude, -35.0 / 60, 1,
ddummy, ddummy, c_rise, c_set,
c_transit)
if rs == -1:
ret_val.append((space.wrap("sunrise"), space.w_False))
ret_val.append((space.wrap("sunset"), space.w_False))
elif rs == 1:
ret_val.append((space.wrap("sunrise"), space.w_True))
ret_val.append((space.wrap("sunset"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append(
(space.wrap("sunrise"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
timelib_time_2.c_sse = c_set[0]
ret_val.append(
(space.wrap("sunset"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
timelib_time_2.c_sse = c_transit[0]
ret_val.append(
(space.wrap("transit"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
# Get civil twilight
rs = timelib.timelib_astro_rise_set_altitude(timelib_time, longitude,
latitude, -6.0, 0, ddummy,
ddummy, c_rise, c_set,
c_transit)
if rs == -1:
ret_val.append((space.wrap("civil_twilight_begin"), space.w_False))
ret_val.append((space.wrap("civil_twilight_end"), space.w_False))
elif rs == 1:
ret_val.append((space.wrap("civil_twilight_begin"), space.w_True))
ret_val.append((space.wrap("civil_twilight_end"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append(
(space.wrap("civil_twilight_begin"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
timelib_time_2.c_sse = c_set[0]
ret_val.append(
(space.wrap("civil_twilight_end"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
# Get nautical twilight
rs = timelib.timelib_astro_rise_set_altitude(timelib_time, longitude,
latitude, -12.0, 0, ddummy,
ddummy, c_rise, c_set,
c_transit)
if rs == -1:
ret_val.append((space.wrap("nautical_twilight_begin"), space.w_False))
ret_val.append((space.wrap("nautical_twilight_end"), space.w_False))
elif rs == 1:
ret_val.append((space.wrap("nautical_twilight_begin"), space.w_True))
ret_val.append((space.wrap("nautical_twilight_end"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append(
(space.wrap("nautical_twilight_begin"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
timelib_time_2.c_sse = c_set[0]
ret_val.append(
(space.wrap("nautical_twilight_end"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
# Get astronomical twilight
rs = timelib.timelib_astro_rise_set_altitude(timelib_time, longitude,
latitude, -18.0, 0, ddummy,
ddummy, c_rise, c_set,
c_transit)
if rs == -1:
ret_val.append(
(space.wrap("astronomical_twilight_begin"), space.w_False))
ret_val.append(
(space.wrap("astronomical_twilight_end"), space.w_False))
elif rs == 1:
ret_val.append(
(space.wrap("astronomical_twilight_begin"), space.w_True))
ret_val.append((space.wrap("astronomical_twilight_end"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append(
(space.wrap("astronomical_twilight_begin"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
timelib_time_2.c_sse = c_set[0]
ret_val.append(
(space.wrap("astronomical_twilight_end"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))))
timelib.timelib_time_dtor(timelib_time)
timelib.timelib_time_dtor(timelib_time_2)
return space.new_array_from_pairs(ret_val)
def date_sun_info(interp, time, latitude, longitude):
space = interp.space
timelib_time = timelib.timelib_time_ctor()
timelib_timezone = interp.get_default_timezone("date").timelib_timezone
timelib_time.c_tz_info = timelib_timezone
timelib_time.c_zone_type = timelib.TIMELIB_ZONETYPE_ID
timelib.timelib_unixtime2local(timelib_time, time)
timelib_time_2 = timelib.timelib_time_ctor()
dummy = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO, 1, flavor='raw')
ddummy = lltype.malloc(rffi.CArrayPtr(lltype.Float).TO, 1, flavor='raw')
c_rise = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO, 1, flavor='raw')
c_set = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO, 1, flavor='raw')
c_transit = lltype.malloc(rffi.CArrayPtr(rffi.LONGLONG).TO, 1, flavor='raw')
ret_val = []
# Get sun up/down and transit
rs = timelib.timelib_astro_rise_set_altitude(
timelib_time,
longitude, latitude,
-35.0/60, 1,
ddummy, ddummy, c_rise, c_set, c_transit
)
if rs == -1:
ret_val.append((space.wrap("sunrise"), space.w_False))
ret_val.append((space.wrap("sunset"), space.w_False))
elif rs == 1:
ret_val.append((space.wrap("sunrise"), space.w_True))
ret_val.append((space.wrap("sunset"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append((
space.wrap("sunrise"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
timelib_time_2.c_sse = c_set[0]
ret_val.append((
space.wrap("sunset"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
timelib_time_2.c_sse = c_transit[0]
ret_val.append((
space.wrap("transit"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
# Get civil twilight
rs = timelib.timelib_astro_rise_set_altitude(
timelib_time,
longitude, latitude,
-6.0, 0,
ddummy, ddummy, c_rise, c_set, c_transit
)
if rs == -1:
ret_val.append((space.wrap("civil_twilight_begin"), space.w_False))
ret_val.append((space.wrap("civil_twilight_end"), space.w_False))
elif rs == 1:
ret_val.append((space.wrap("civil_twilight_begin"), space.w_True))
ret_val.append((space.wrap("civil_twilight_end"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append((
space.wrap("civil_twilight_begin"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
timelib_time_2.c_sse = c_set[0]
ret_val.append((
space.wrap("civil_twilight_end"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
# Get nautical twilight
rs = timelib.timelib_astro_rise_set_altitude(
timelib_time,
longitude, latitude,
-12.0, 0,
ddummy, ddummy, c_rise, c_set, c_transit
)
if rs == -1:
ret_val.append((space.wrap("nautical_twilight_begin"), space.w_False))
ret_val.append((space.wrap("nautical_twilight_end"), space.w_False))
elif rs == 1:
ret_val.append((space.wrap("nautical_twilight_begin"), space.w_True))
ret_val.append((space.wrap("nautical_twilight_end"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append((
space.wrap("nautical_twilight_begin"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
timelib_time_2.c_sse = c_set[0]
ret_val.append((
space.wrap("nautical_twilight_end"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
# Get astronomical twilight
rs = timelib.timelib_astro_rise_set_altitude(
timelib_time,
longitude, latitude,
-18.0, 0,
ddummy, ddummy, c_rise, c_set, c_transit
)
if rs == -1:
ret_val.append((space.wrap("astronomical_twilight_begin"), space.w_False))
ret_val.append((space.wrap("astronomical_twilight_end"), space.w_False))
elif rs == 1:
ret_val.append((space.wrap("astronomical_twilight_begin"), space.w_True))
ret_val.append((space.wrap("astronomical_twilight_end"), space.w_True))
else:
timelib_time_2.c_sse = c_rise[0]
ret_val.append((
space.wrap("astronomical_twilight_begin"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
timelib_time_2.c_sse = c_set[0]
ret_val.append((
space.wrap("astronomical_twilight_end"),
space.wrap(timelib.timelib_date_to_int(timelib_time_2, dummy))
))
timelib.timelib_time_dtor(timelib_time)
timelib.timelib_time_dtor(timelib_time_2)
return space.new_array_from_pairs(ret_val)
def _mktime(interp, is_gmt, hour, minute, second,
month, day, year, dst=-1):
now = timelib.timelib_time_ctor()
adjust_seconds = 0
if is_gmt:
timelib.timelib_unixtime2gmt(now, int(pytime.time()))
else:
now.c_tz_info = interp.get_default_timezone("mktime").timelib_timezone
now.c_zone_type = timelib.TIMELIB_ZONETYPE_ID
timelib.timelib_unixtime2local(now, int(pytime.time()))
if year >= 0 and year < 70:
year += 2000
elif year >= 70 and year <= 100:
year += 1900
now.c_y = rffi.cast(lltype.Signed, year)
now.c_d = rffi.cast(lltype.Signed, day)
now.c_m = rffi.cast(lltype.Signed, month)
now.c_s = rffi.cast(lltype.Signed, second)
now.c_i = rffi.cast(lltype.Signed, minute)
now.c_h = rffi.cast(lltype.Signed, hour)
if is_gmt:
timelib.timelib_update_ts(
now,
lltype.nullptr(timelib.timelib_tzinfo.TO))
else:
timelib.timelib_update_ts(
now,
interp.get_default_timezone("mktime").timelib_timezone)
if dst != -1:
interp.space.ec.deprecated(
"mktime(): The is_dst parameter is deprecated"
)
if is_gmt:
if dst == 1:
adjust_seconds -= 3600
else:
tmp_offset = timelib.timelib_get_time_zone_info(
now.c_sse, interp.get_default_timezone("mktime").timelib_timezone
)
if dst == 1 and intmask(tmp_offset.c_is_dst) == 0:
adjust_seconds -= 3600
if dst == 0 and intmask(tmp_offset.c_is_dst) == 1:
adjust_seconds += 3600
timelib.timelib_time_offset_dtor(tmp_offset)
error = lltype.malloc(
rffi.CArrayPtr(lltype.Signed).TO, 1, flavor='raw', zero=True
)
timestamp = timelib.timelib_date_to_int(now, error)
timestamp += adjust_seconds
timelib.timelib_time_dtor(now)
lltype.free(error, flavor='raw')
return timestamp