#!/usr/bin/env python
# -*- coding: utf-8 -*-
"""
Utility objects.
:copyright:
Lion Krischer (krischer@geophysik.uni-muenchen.de), 2013
:license:
GNU Lesser General Public License, Version 3
(https://www.gnu.org/copyleft/lesser.html)
"""
from __future__ import (absolute_import, division, print_function,
unicode_literals)
from future.builtins import * # NOQA
import copy
import re
from obspy import UTCDateTime
from obspy.core.util.base import ComparingObject
from obspy.core.util.obspy_types import (FloatWithUncertaintiesAndUnit,
FloatWithUncertaintiesFixedUnit)
[docs]class BaseNode(ComparingObject):
"""
From the StationXML definition:
A base node type for derivation of: Network, Station and Channel
types.
The parent class for the network, station and channel classes.
"""
[docs] def __init__(self, code, description=None, comments=None, start_date=None,
end_date=None, restricted_status=None, alternate_code=None,
historical_code=None, data_availability=None):
"""
:type code: str
:param code: The SEED network, station, or channel code
:type description: str, optional
:param description: A description of the resource
:type comments: list of :class:`Comment`, optional
:param comments: An arbitrary number of comments to the resource
:type start_date: :class:`~obspy.core.utcdatetime.UTCDateTime`,
optional
:param start_date: The start date of the resource
:type end_date: :class:`~obspy.core.utcdatetime.UTCDateTime`, optional
:param end_date: The end date of the resource
:type restricted_status: str, optional
:param restricted_status: The restriction status
:type alternate_code: str, optional
:param alternate_code: A code used for display or association,
alternate to the SEED-compliant code.
:type historical_code: str, optional
:param historical_code: A previously used code if different from the
current code.
:type data_availability: :class:`~obspy.station.util.DataAvailability`
:param data_availability: Information about time series availability
for the network/station/channel.
"""
self.code = code
self.comments = comments or []
self.description = description
self.start_date = start_date
self.end_date = end_date
self.restricted_status = restricted_status
self.alternate_code = alternate_code
self.historical_code = historical_code
self.data_availability = data_availability
@property
def code(self):
return self._code
@code.setter
def code(self, value):
if not value:
msg = "A Code is required"
raise ValueError(msg)
self._code = str(value).strip()
@property
def alternate_code(self):
"""
From the StationXML definition:
A code used for display or association, alternate to the
SEED-compliant code.
"""
return self._alternate_code
@alternate_code.setter
def alternate_code(self, value):
if value:
self._alternate_code = value.strip()
else:
self._alternate_code = None
@property
def historical_code(self):
"""
From the StationXML definition:
A previously used code if different from the current code.
"""
return self._historical_code
@historical_code.setter
def historical_code(self, value):
if value:
self._historical_code = value.strip()
else:
self._historical_code = None
[docs] def copy(self):
"""
Returns a deepcopy of the object.
:rtype: same class as original object
:return: Copy of current object.
.. rubric:: Examples
1. Create a station object and copy it
>>> from obspy import read_inventory
>>> sta = read_inventory()[0][0]
>>> sta2 = sta.copy()
The two objects are not the same:
>>> sta is sta2
False
But they have equal data (before applying further processing):
>>> sta == sta2
True
2. The following example shows how to make an alias but not copy the
data. Any changes on ``st3`` would also change the contents of
``st``.
>>> sta3 = sta
>>> sta is sta3
True
>>> sta == sta3
True
"""
return copy.deepcopy(self)
[docs] def is_active(self, time=None, starttime=None, endtime=None):
"""
Checks if the item was active at some given point in time (`time`)
and/or if it was active at some point during a certain time range
(`starttime`, `endtime`).
.. note::
If none of the time constraints is specified the result will always
be `True`.
:type time: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param time: Only include networks/stations/channels active at given
point in time.
:type starttime: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param starttime: Only include networks/stations/channels active at or
after given point in time (i.e. channels ending before given time
will not be shown).
:type endtime: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param endtime: Only include networks/stations/channels active before
or at given point in time (i.e. channels starting after given time
will not be shown).
:rtype: bool
:returns: `True`/`False` depending on whether the item matches the
specified time criteria.
"""
if time is not None:
if self.start_date is not None and time < self.start_date:
return False
if self.end_date is not None and time > self.end_date:
return False
if starttime is not None and self.end_date is not None:
if starttime > self.end_date:
return False
if endtime is not None and self.start_date is not None:
if endtime < self.start_date:
return False
return True
[docs]class DataAvailability(ComparingObject):
"""
A description of time series data availability. This information should
be considered transient and is primarily useful as a guide for
generating time series data requests. The information for a
DataAvailability (time) span may be specific to the time range used in a
request that resulted in the document or limited to the availability of
data within the request range. These details may or may not be
retained when synchronizing metadata between data centers.
"""
[docs] def __init__(self, start, end):
self.start = UTCDateTime(start)
self.end = UTCDateTime(end)
[docs] def __str__(self):
return "Data Availability from %s to %s." % (str(self.start),
str(self.end))
[docs] def _repr_pretty_(self, p, cycle):
p.text(str(self))
[docs]class Equipment(ComparingObject):
"""
An object containing a detailed description of an equipment.
"""
[docs] def __init__(self, type=None, description=None, manufacturer=None,
vendor=None, model=None, serial_number=None,
installation_date=None, removal_date=None,
calibration_dates=None, resource_id=None):
"""
:type type: str
:param type: The equipment type
:type description: str
:param description: Description of the equipment
:type manufacturer: str
:param manufacturer: The manufacturer of the equipment
:type vendor: str
:param vendor: The vendor of the equipment
:type model: str
:param model: The model of the equipment
:type serial_number: str
:param serial_number: The serial number of the equipment
:type installation_date: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param installation_date: The installation date of the equipment
:type removal_date: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param removal_date: The removal data of the equipment
:type calibration_dates: list of
:class:`~obspy.core.utcdatetime.UTCDateTime`
:param calibration_dates: A list with all calibration dates of the
equipment.
:type resource_id: str
:param resource_id: This field contains a string that should serve as a
unique resource identifier. This identifier can be interpreted
differently depending on the data center/software that generated
the document. Also, we recommend to use something like
GENERATOR:Meaningful ID. As a common behavior equipment with the
same ID should contain the same information/be derived from the
same base instruments.
"""
self.type = type
self.description = description
self.manufacturer = manufacturer
self.vendor = vendor
self.model = model
self.serial_number = serial_number
self.installation_date = installation_date
self.removal_date = removal_date
self.calibration_dates = calibration_dates or []
self.resource_id = resource_id
@property
def installation_date(self):
return self._installation_date
@installation_date.setter
def installation_date(self, value):
if value is None or isinstance(value, UTCDateTime):
self._installation_date = value
return
self._installation_date = UTCDateTime(value)
@property
def removal_date(self):
return self._removal_date
@removal_date.setter
def removal_date(self, value):
if value is None or isinstance(value, UTCDateTime):
self._removal_date = value
return
self._removal_date = UTCDateTime(value)
[docs] def __str__(self):
ret = ("Equipment:\n"
"\tType: {type}\n"
"\tDescription: {description}\n"
"\tManufacturer: {manufacturer}\n"
"\tVendor: {vendor}\n"
"\tModel: {model}\n"
"\tSerial number: {serial_number}\n"
"\tInstallation date: {installation_date}\n"
"\tRemoval date: {removal_date}\n"
"\tResource id: {resource_id}\n"
"\tCalibration Dates:\n")
for calib_date in self.calibration_dates:
ret += "\t\t%s\n" % calib_date
ret = ret.format(**self.__dict__)
return ret
[docs] def _repr_pretty_(self, p, cycle):
p.text(str(self))
[docs]class Operator(ComparingObject):
"""
An operating agency and associated contact persons. If there are multiple
operators, each one should be encapsulated within an Operator object. Since
the Contact element is a generic type that represents any contact person,
it also has its own optional Agency element.
"""
[docs] def __init__(self, agencies, contacts=None, website=None):
"""
:type agencies: list of str
:param agencies: The agencies of the operator.
:type contacts: list of :class:`Person`, optional
:param contacts: One or more contact persons.
:type website: str, optional
:param website: The website.
"""
self.agencies = agencies
self.contacts = contacts or []
self.website = website
@property
def agencies(self):
return self._agencies
@agencies.setter
def agencies(self, value):
if not hasattr(value, "__iter__") or len(value) < 1:
msg = ("agencies needs to be iterable, e.g. a list, and contain "
"at least one entry.")
raise ValueError(msg)
self._agencies = value
@property
def contacts(self):
return self._contacts
@contacts.setter
def contacts(self, value):
if not hasattr(value, "__iter__"):
msg = ("contacts needs to be iterable, e.g. a list.")
raise ValueError(msg)
self._contacts = value
[docs]class Person(ComparingObject):
"""
From the StationXML definition:
Representation of a person's contact information. A person can belong
to multiple agencies and have multiple email addresses and phone
numbers.
"""
email_pattern = re.compile("[\w\.\-_]+@[\w\.\-_]+")
[docs] def __init__(self, names=None, agencies=None, emails=None, phones=None):
"""
:type names: list of str, optional
:param names: Self-explanatory. Multiple names allowed.
:type agencies: list of str, optional
:param agencies: Self-explanatory. Multiple agencies allowed.
:type emails: list of str, optional
:param emails: Self-explanatory. Multiple emails allowed.
:type phones: list of :class:`PhoneNumber`, optional
:param phones: Self-explanatory. Multiple phone numbers allowed.
"""
self.names = names or []
self.agencies = agencies or []
self.emails = emails or []
self.phones = phones or []
@property
def names(self):
return self._names
@names.setter
def names(self, value):
if not hasattr(value, "__iter__"):
msg = "names needs to be iterable, e.g. a list."
raise ValueError(msg)
self._names = value
@property
def agencies(self):
return self._agencies
@agencies.setter
def agencies(self, value):
if not hasattr(value, "__iter__"):
msg = "agencies needs to be iterable, e.g. a list."
raise ValueError(msg)
self._agencies = value
@property
def emails(self):
return self._emails
@emails.setter
def emails(self, values):
if not hasattr(values, "__iter__"):
msg = "emails needs to be iterable, e.g. a list."
raise ValueError(msg)
for value in values:
if re.match(self.email_pattern, value) is None:
msg = ("emails needs to match the pattern "
"'[\w\.\-_]+@[\w\.\-_]+'")
raise ValueError(msg)
self._emails = values
@property
def phones(self):
return self._phones
@phones.setter
def phones(self, values):
if not hasattr(values, "__iter__"):
msg = "phones needs to be iterable, e.g. a list."
raise ValueError(msg)
self._phones = values
[docs]class PhoneNumber(ComparingObject):
"""
A simple object representing a phone number.
"""
phone_pattern = re.compile("^[0-9]+-[0-9]+$")
[docs] def __init__(self, area_code, phone_number, country_code=None,
description=None):
"""
:type area_code: int
:param area_code: The area code.
:type phone_number: str
:param phone_number: The phone number minus the country and area code.
Must be in the form "[0-9]+-[0-9]+", e.g. 1234-5678.
:type country_code: int, optional
:param country_code: The country code.
:type description: str, optional
:param description: Any additional information.
"""
self.country_code = country_code
self.area_code = area_code
self.phone_number = phone_number
self.description = description
@property
def phone_number(self):
return self._phone_number
@phone_number.setter
def phone_number(self, value):
if re.match(self.phone_pattern, value) is None:
msg = "phone_number needs to match the pattern '[0-9]+-[0-9]+'"
raise ValueError(msg)
self._phone_number = value
[docs]class ExternalReference(ComparingObject):
"""
From the StationXML definition:
This type contains a URI and description for external data that users
may want to reference in StationXML.
"""
[docs] def __init__(self, uri, description):
"""
:type uri: str
:param uri: The URI to the external data.
:type description: str
:param description: A description of the external data.
"""
self.uri = uri
self.description = description
[docs]class Site(ComparingObject):
"""
From the StationXML definition:
Description of a site location using name and optional geopolitical
boundaries (country, city, etc.).
"""
[docs] def __init__(self, name, description=None, town=None, county=None,
region=None, country=None):
"""
:type name: str
:param name: The commonly used name of this station, equivalent to the
SEED blockette 50, field 9.
:type description: str, optional
:param description: A longer description of the location of this
station, e.g. "NW corner of Yellowstone National Park" or "20
miles west of Highway 40."
:type town: str, optional
:param town: The town or city closest to the station.
:type county: str, optional
:param county: The county.
:type region: str, optional
:param region: The state, province, or region of this site.
:type country: str, optional
:param country: The country.
"""
self.name = name
self.description = description
self.town = town
self.county = county
self.region = region
self.country = country
[docs] def __str__(self):
ret = ("Site: {name}\n"
"\tDescription: {description}\n"
"\tTown: {town}\n"
"\tCounty: {county}\n"
"\tRegion: {region}\n"
"\tCountry: {country}")
ret = ret.format(
name=self.name, description=self.description,
town=self.town, county=self.county, region=self.region,
country=self.country)
return ret
[docs] def _repr_pretty_(self, p, cycle):
p.text(str(self))
[docs]class Latitude(FloatWithUncertaintiesFixedUnit):
"""
Latitude object
:type value: float
:param value: Latitude value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
:type datum: str
:param datum: Datum for latitude coordinate
"""
_minimum = -90
_maximum = 90
_unit = "DEGREES"
[docs] def __init__(self, value, lower_uncertainty=None, upper_uncertainty=None,
datum=None):
"""
"""
self.datum = datum
super(Latitude, self).__init__(
value, lower_uncertainty=lower_uncertainty,
upper_uncertainty=upper_uncertainty)
[docs]class Longitude(FloatWithUncertaintiesFixedUnit):
"""
Longitude object
:type value: float
:param value: Longitude value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
:type datum: str
:param datum: Datum for longitude coordinate
"""
_minimum = -180
_maximum = 180
unit = "DEGREES"
[docs] def __init__(self, value, lower_uncertainty=None, upper_uncertainty=None,
datum=None):
"""
"""
self.datum = datum
super(Longitude, self).__init__(
value, lower_uncertainty=lower_uncertainty,
upper_uncertainty=upper_uncertainty)
[docs]class Distance(FloatWithUncertaintiesAndUnit):
"""
Distance object
:type value: float
:param value: Distance value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
:type unit: str
:param unit: Unit for distance measure.
"""
[docs] def __init__(self, value, lower_uncertainty=None, upper_uncertainty=None,
unit="METERS"):
super(Distance, self).__init__(
value, lower_uncertainty=lower_uncertainty,
upper_uncertainty=upper_uncertainty)
self._unit = unit
[docs]class Azimuth(FloatWithUncertaintiesFixedUnit):
"""
Azimuth object
:type value: float
:param value: Azimuth value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
"""
_minimum = 0
_maximum = 360
unit = "DEGREES"
[docs]class Dip(FloatWithUncertaintiesFixedUnit):
"""
Dip object
:type value: float
:param value: Dip value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
"""
_minimum = -90
_maximum = 90
unit = "DEGREES"
[docs]class ClockDrift(FloatWithUncertaintiesFixedUnit):
"""
ClockDrift object
:type value: float
:param value: ClockDrift value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
"""
_minimum = 0
unit = "SECONDS/SAMPLE"
[docs]class SampleRate(FloatWithUncertaintiesFixedUnit):
"""
SampleRate object
:type value: float
:param value: ClockDrift value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
"""
unit = "SAMPLES/S"
[docs]class Frequency(FloatWithUncertaintiesFixedUnit):
"""
Frequency object
:type value: float
:param value: Frequency value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
"""
unit = "HERTZ"
[docs]class Angle(FloatWithUncertaintiesFixedUnit):
"""
Angle object
:type value: float
:param value: Angle value
:type lower_uncertainty: float
:param lower_uncertainty: Lower uncertainty (aka minusError)
:type upper_uncertainty: float
:param upper_uncertainty: Upper uncertainty (aka plusError)
"""
_minimum = -360
_maximum = 360
unit = "DEGREES"
if __name__ == '__main__':
import doctest
doctest.testmod(exclude_empty=True)