Source code for astroquery.ipac.irsa.irsa_dust.core

# Licensed under a 3-clause BSD style license - see LICENSE.rst
from astropy.table import Table, Column
import astropy.units as u
from astropy import coordinates

from astroquery.ipac.irsa.irsa_dust import utils
from astroquery.ipac.irsa.irsa_dust import conf
from astroquery.utils import commons
from astroquery.query import BaseQuery


# TODO Add support for server url from JSON cache
__all__ = ["IrsaDust", "IrsaDustClass"]

EXT_DESC = "E(B-V) Reddening"
EM_DESC = "100 Micron Emission"
TEMP_DESC = "Dust Temperature"

INPUT = "input"
OBJ_NAME = "objname"
REG_SIZE = "regSize"
DESC = "desc"
IMAGE_URL = "imageUrl"

STATISTICS = "statistics"
REF_PIXEL_VALUE = "refPixelValue"
REF_COORDINATE = "refCoordinate"
MEAN_VALUE = "meanValue"
STD = "std"
MAX_VALUE = "maxValue"
MIN_VALUE = "minValue"
SANDF = "SandF"
SFD = "SFD"

DATA_IMAGE = "./data/image"
DATA_TABLE = "./data/table"


[docs]class IrsaDustClass(BaseQuery): DUST_SERVICE_URL = conf.server TIMEOUT = conf.timeout image_type_to_section = { 'temperature': 't', 'ebv': 'r', '100um': 'e' }
[docs] def get_images(self, coordinate, radius=None, image_type=None, timeout=TIMEOUT, get_query_payload=False, show_progress=True): """ A query function that performs a coordinate-based query to acquire Irsa-Dust images. Parameters ---------- coordinate : str Can be either the name of an object or a coordinate string If a name, must be resolvable by NED, SIMBAD, 2MASS, or SWAS. Examples of acceptable coordinate strings, can be found `here. <https://irsa.ipac.caltech.edu/applications/DUST/docs/coordinate.html>`_ radius : str / `~astropy.units.Quantity`, optional The size of the region to include in the dust query, in radian, degree or hour as per format specified by `~astropy.coordinates.Angle` or `~astropy.units.Quantity`. Defaults to 5 degrees. image_type : str, optional When missing returns for all the images. Otherwise returns only for image of the specified type which must be one of ``'temperature'``, ``'ebv'``, ``'100um'``. Defaults to `None`. timeout : int, optional Time limit for establishing successful connection with remote server. Defaults to `~astroquery.ipac.irsa.irsa_dust.IrsaDustClass.TIMEOUT`. get_query_payload : bool, optional If `True` then returns the dictionary of query parameters, posted to remote server. Defaults to `False`. Returns ------- A list of `~astropy.io.fits.HDUList` objects """ if get_query_payload: return self._args_to_payload(coordinate, radius=radius) readable_objs = self.get_images_async( coordinate, radius=radius, image_type=image_type, timeout=timeout, get_query_payload=get_query_payload, show_progress=show_progress) return [obj.get_fits() for obj in readable_objs]
[docs] def get_images_async(self, coordinate, radius=None, image_type=None, timeout=TIMEOUT, get_query_payload=False, show_progress=True): """ A query function similar to `astroquery.ipac.irsa.irsa_dust.IrsaDustClass.get_images` but returns file-handlers to the remote files rather than downloading them. Useful for asynchronous queries so that the actual download may be performed later. Parameters ---------- coordinate : str Can be either the name of an object or a coordinate string If a name, must be resolvable by NED, SIMBAD, 2MASS, or SWAS. Examples of acceptable coordinate strings, can be found `here. <https://irsa.ipac.caltech.edu/applications/DUST/docs/coordinate.html>`_ radius : str / `~astropy.units.Quantity`, optional The size of the region to include in the dust query, in radian, degree or hour as per format specified by `~astropy.coordinates.Angle` or `~astropy.units.Quantity`. Defaults to 5 degrees. image_type : str, optional When missing returns for all the images. Otherwise returns only for image of the specified type which must be one of ``'temperature'``, ``'ebv'``, ``'100um'``. Defaults to `None`. timeout : int, optional Time limit for establishing successful connection with remote server. Defaults to `~astroquery.ipac.irsa.irsa_dust.IrsaDustClass.TIMEOUT`. get_query_payload : bool, optional If `True` then returns the dictionary of query parameters, posted to remote server. Defaults to `False`. Returns ------- list : list A list of context-managers that yield readable file-like objects. """ if get_query_payload: return self._args_to_payload(coordinate, radius=radius) image_urls = self.get_image_list( coordinate, radius=radius, image_type=image_type, timeout=timeout) # Images are assumed to be FITS files # they MUST be read as binary for python3 to parse them return [commons.FileContainer(U, encoding='binary', show_progress=show_progress) for U in image_urls]
[docs] def get_image_list(self, coordinate, radius=None, image_type=None, timeout=TIMEOUT): """ Query function that performs coordinate-based query and returns a list of URLs to the Irsa-Dust images. Parameters ---------- coordinate : str Can be either the name of an object or a coordinate string If a name, must be resolvable by NED, SIMBAD, 2MASS, or SWAS. Examples of acceptable coordinate strings, can be found `here. <https://irsa.ipac.caltech.edu/applications/DUST/docs/coordinate.html>`_ radius : str / `~astropy.units.Quantity`, optional The size of the region to include in the dust query, in radian, degree or hour as per format specified by `~astropy.coordinates.Angle` or `~astropy.units.Quantity`. Defaults to 5 degrees. image_type : str, optional When missing returns for all the images. Otherwise returns only for image of the specified type which must be one of ``'temperature'``, ``'ebv'``, ``'100um'``. Defaults to `None`. timeout : int, optional Time limit for establishing successful connection with remote server. Defaults to `~astroquery.ipac.irsa.irsa_dust.IrsaDustClass.TIMEOUT`. get_query_payload : bool If `True` then returns the dictionary of query parameters, posted to remote server. Defaults to `False`. Returns ------- url_list : list A list of URLs to the FITS images corresponding to the queried object. """ url = self.DUST_SERVICE_URL request_payload = self._args_to_payload(coordinate, radius=radius) response = self._request("POST", url, data=request_payload, timeout=timeout) return self.extract_image_urls(response.text, image_type=image_type)
[docs] def get_extinction_table(self, coordinate, radius=None, timeout=TIMEOUT, show_progress=True): """ Query function that fetches the extinction table from the query result. Parameters ---------- coordinate : str Can be either the name of an object or a coordinate string If a name, must be resolvable by NED, SIMBAD, 2MASS, or SWAS. Examples of acceptable coordinate strings, can be found `here. <https://irsa.ipac.caltech.edu/applications/DUST/docs/coordinate.html>`_ radius : str / `~astropy.units.Quantity`, optional The size of the region to include in the dust query, in radian, degree or hour as per format specified by `~astropy.coordinates.Angle` or `~astropy.units.Quantity`. Defaults to 5 degrees. timeout : int, optional Time limit for establishing successful connection with remote server. Defaults to `~astroquery.ipac.irsa.irsa_dust.IrsaDustClass.TIMEOUT`. Returns ------- table : `~astropy.table.Table` """ readable_obj = self.get_extinction_table_async( coordinate, radius=radius, timeout=timeout, show_progress=show_progress) # guess=False to suppress error messages related to bad guesses table = Table.read(readable_obj.get_string(), format='ipac', guess=False) # Fix up units: 'micron' and 'mag', not 'microns' and 'mags' for column in table.columns.values(): if str(column.unit) in {'microns', 'mags'}: column.unit = str(column.unit)[:-1] return table
[docs] def get_extinction_table_async(self, coordinate, radius=None, timeout=TIMEOUT, show_progress=True): """ A query function similar to `astroquery.ipac.irsa.irsa_dust.IrsaDustClass.get_extinction_table` but returns a file-handler to the remote files rather than downloading it. Useful for asynchronous queries so that the actual download may be performed later. Parameters ---------- coordinate : str Can be either the name of an object or a coordinate string If a name, must be resolvable by NED, SIMBAD, 2MASS, or SWAS. Examples of acceptable coordinate strings, can be found `here. <https://irsa.ipac.caltech.edu/applications/DUST/docs/coordinate.html>`_ radius : str, optional The size of the region to include in the dust query, in radian, degree or hour as per format specified by `~astropy.coordinates.Angle`. Defaults to 5 degrees. timeout : int, optional Time limit for establishing successful connection with remote server. Defaults to `~astroquery.ipac.irsa.irsa_dust.IrsaDustClass.TIMEOUT`. Returns ------- result : A context manager that yields a file like readable object. """ url = self.DUST_SERVICE_URL request_payload = self._args_to_payload(coordinate, radius=radius) response = self._request("POST", url, data=request_payload, timeout=timeout) xml_tree = utils.xml(response.text) result = SingleDustResult(xml_tree, coordinate) return commons.FileContainer(result.ext_detail_table(), show_progress=show_progress)
[docs] def get_query_table(self, coordinate, radius=None, section=None, timeout=TIMEOUT, url=DUST_SERVICE_URL): """ Create and return an `~astropy.table.Table` representing the query response(s). When ``section`` is missing, returns the full table. When a section is specified (``'location'``, ``'temperature'``, ``'ebv'``, or ``'100um'``), only that portion of the table is returned. Parameters ---------- coordinate : str Can be either the name of an object or a coordinate string If a name, must be resolvable by NED, SIMBAD, 2MASS, or SWAS. Examples of acceptable coordinate strings, can be found `here. <https://irsa.ipac.caltech.edu/applications/DUST/docs/coordinate.html>`_ radius : str / `~astropy.units.Quantity`, optional The size of the region to include in the dust query, in radian, degree or hour as per format specified by `~astropy.coordinates.Angle` or `~astropy.units.Quantity`. Defaults to 5 degrees. section : str, optional When missing, all the sections of the query result are returned. Otherwise only the specified section (``'ebv'``, ``'100um'``, ``'temperature'``, ``'location'``) is returned. Defaults to `None`. timeout : int, optional Time limit for establishing successful connection with remote server. Defaults to `~astroquery.ipac.irsa.irsa_dust.IrsaDustClass.TIMEOUT`. url : str, optional Only provided for debugging. Should generally not be assigned. Defaults to `~astroquery.ipac.irsa.irsa_dust.IrsaDustClass.DUST_SERVICE_URL`. Returns ------- table : `~astropy.table.Table` Table representing the query results, (all or as per specified). """ request_payload = self._args_to_payload(coordinate, radius=radius) response = self._request("POST", url, data=request_payload, timeout=timeout) xml_tree = utils.xml(response.text) result = SingleDustResult(xml_tree, coordinate) if section is None or section in ["location", "loc", "l"]: return result.table(section=section) try: section = self.image_type_to_section[section] return result.table(section=section) except KeyError: msg = ('section must be one of the following:\n' 'ebv, temperature, location or 100um.') raise ValueError(msg)
def _args_to_payload(self, coordinate, radius=None): """ Accepts the query parameters and returns a dictionary suitable to be sent as data via a HTTP POST request. Parameters ---------- coordinate : str Can be either the name of an object or a coordinate string If a name, must be resolvable by NED, SIMBAD, 2MASS, or SWAS. Examples of acceptable coordinate strings, can be found `here <https://irsa.ipac.caltech.edu/applications/DUST/docs/coordinate.html>`_ radius : str / `~astropy.units.Quantity`, optional The size of the region to include in the dust query, in radian, degree or hour as per format specified by `~astropy.coordinates.Angle` or `~astropy.units.Quantity`. Defaults to 5 degrees. Returns ------- payload : dict A dictionary that specifies the data for an HTTP POST request """ if isinstance(coordinate, str): try: # If the coordinate is a resolvable name, pass that name # directly to irsa_dust because it can handle it (and that # changes the return value associated metadata) C = commons.ICRSCoord.from_name(coordinate) payload = {"locstr": coordinate} except coordinates.name_resolve.NameResolveError: C = commons.parse_coordinates(coordinate).transform_to('fk5') # check if this is resolvable? payload = {"locstr": "{0} {1}".format(C.ra.deg, C.dec.deg)} elif isinstance(coordinate, coordinates.SkyCoord): C = coordinate.transform_to('fk5') payload = {"locstr": "{0} {1}".format(C.ra.deg, C.dec.deg)} # check if radius is given with proper units if radius is not None: reg_size = coordinates.Angle(radius).deg # check if radius falls in the acceptable range if reg_size < 2 or reg_size > 37.5: raise ValueError("Radius (in any unit) must be in the" " range of 2.0 to 37.5 degrees") payload["regSize"] = reg_size return payload
[docs] def extract_image_urls(self, raw_xml, image_type=None): """ Extracts the image URLs from the query results and returns these as a list. If section is missing or ``'all'`` returns all the URLs, otherwise returns URL corresponding to the section specified (``'emission'``, ``'reddening'``, ``'temperature'``). Parameters ---------- raw_xml : str XML response returned by the query as a string image_type : str, optional When missing returns for all the images. Otherwise returns only for image of the specified type which must be one of ``'temperature'``, ``'ebv'``, ``'100um'``. Defaults to `None`. Returns ------- url_list : list list of URLs to images extracted from query results. """ # get the xml tree from the response xml_tree = utils.xml(raw_xml) result = SingleDustResult(xml_tree) if image_type is None: url_list = [result.image(sec) for sec in ['r', 'e', 't']] else: try: section = self.image_type_to_section[image_type] url_list = [result.image(section)] except KeyError: msg = ('image_type must be one of the following:\n' 'ebv, temperature or 100um.') raise ValueError(msg) return url_list
[docs] def list_image_types(self): """ Returns a list of image_types available in the Irsa Dust query results """ return [key for key in self.image_type_to_section]
class SingleDustResult: """ Represents the response to a dust query for a single object or location. Provides methods to return the response as an `~astropy.table.Table`, and to retrieve FITS images listed as urls in the initial response. It can also return the url to a detailed extinction table provided in the initial response. Not intended to be instantiated by the end user. """ def __init__(self, xml_tree, query_loc=None): """ Parameters ---------- xml_root : `xml.etree.ElementTree` the xml tree representing the response to the query query_loc : str the location string specified in the query """ self._xml = xml_tree self._query_loc = query_loc self._location_section = LocationSection(xml_tree) ext_node = utils.find_result_node(EXT_DESC, xml_tree) self._ext_section = ExtinctionSection(ext_node) em_node = utils.find_result_node(EM_DESC, xml_tree) self._em_section = EmissionSection(em_node) temp_node = utils.find_result_node(TEMP_DESC, xml_tree) self._temp_section = TemperatureSection(temp_node) self._result_sections = [self._location_section, self._ext_section, self._em_section, self._temp_section] @property def query_loc(self): """Return the location string used in the query.""" return self._query_loc @property def xml(self): """Return the raw xml underlying this SingleDustResult.""" return self._xml def table(self, section=None): """ Create and return a `~astropy.table.Table` representing the query response. Parameters ---------- section : str (optional) the name of the section to include in the table. If not provided, the entire table will be returned. """ code = self._section_code(section) if code == "all": return self._table_all() else: return self._table(code) def values(self, section=None): """ Return the data values contained in the query response, i.e. the list of values corresponding to a row in the result table. Parameters ---------- section : str the name of the section to include in the response If no section is given, all sections will be included. """ code = self._section_code(section) sections = self._sections(code) values = [] for sec in sections: values.extend(sec.values()) return values def _section_code(self, section): """ Return a one-letter code identifying the section. Parameters ---------- section : str the name or abbreviated name of the section Returns ------- str: a one-letter code identifying the section. """ if section is None or section == "all": return "all" else: if section in ["location", "loc", "l"]: return "l" elif section in ["reddening", "red", "r"]: return "r" elif section in ["emission", "em", "e"]: return "e" elif section in ["temperature", "temp", "t"]: return "t" else: msg = """section must be one of the following: 'all', 'location', 'loc', 'l', 'reddening', 'red', 'r', 'emission', 'em', 'e', 'temperature', 'temp', 't'.""" raise ValueError(msg) def _sections(self, code): """ Parameters ---------- code : str the one-letter code name of the section Returns ------- The section corresponding to the code, or a list containing all sections if no section is provided. """ if code == 'l': return [self._location_section] elif code == 'r': return [self._ext_section] elif code == 'e': return [self._em_section] elif code == 't': return [self._temp_section] return [self._location_section, self._ext_section, self._em_section, self._temp_section] def _table_all(self): """ Create and return the full table containing all four sections: location, extinction, emission, and temperature. Returns ------- table : `~astropy.table.Table` table containing the data from the query response """ columns = (self._location_section.columns + self._ext_section.columns + self._em_section.columns + self._temp_section.columns) table = Table(data=columns) values = self.values() table.add_row(vals=values) return table def _table(self, section): """ Create and return a smaller table containing only one section of the overall DustResult table. Parameters ---------- section : str a string indicating the section to be returned """ # Get the specified section section_object = self._sections(section)[0] # Create the table columns = section_object.columns table = Table(data=columns) # Populate the table values = section_object.values() table.add_row(vals=values) return table def ext_detail_table(self): """ Get the url of the additional, detailed table of extinction data for various filters. There is a url for this table given in the initial response to the query. Returns ------- table_url : str url of the detailed table of extinction data by filter """ table_url = self._ext_section.table_url # response = utils.ext_detail_table(table_url) # if sys.version_info > (3, 0): # read_response = response.read().decode("utf-8") # else: # read_response = response.read() # table = Table.read(read_response, format="ipac") # return table return table_url def image(self, section): """ Get the FITS image url associated with the given section. The extinction, emission, and temperature sections each provide a url to a FITS image. Parameters ---------- section : str the name of the section Returns ------- url : str the url to the FITS image """ # Get the url of the image for the given section image_url = None if section in ["reddening", "red", "r"]: image_url = self._ext_section.image_url elif section in ["emission", "em", "e"]: image_url = self._em_section.image_url elif section in ["temperature", "temp", "t"]: image_url = self._temp_section.image_url if image_url is None: msg = """section must be one of the following values: 'reddening', 'red', 'r', 'emission', 'em', 'e', 'temperature', 'temp', 't'""" raise ValueError(msg) return image_url def __str__(self): """Return a string representation of the table.""" string = "[DustResult: \n\t" for section in self._result_sections: if len(string) > 15: string += ",\n\t" string += section.__str__() string += "]" return string class BaseDustNode: """ A node in the result xml that has been enhanced to return values and Columns appropriate to its type (String, Number, or Coord). """ def __init__(self, xml_node): """ Parameters ---------- xml_node : `xml.etree.ElementTree` the xml node that provides the raw data for this DustNode """ self._name = xml_node.tag def set_value(self, node_text): """Override in subclasses.""" pass @property def name(self): """Return the xml node name.""" return self._name @property def value(self): """Return the value extracted from the node.""" return self._value @property def columns(self): """Return the column or columns associated with this item in the `~astropy.table.Table`.""" return self._columns def __str__(self): """Return a string representation of this item.""" col_str = "[Column: " for column in self._columns: for format_str in column.pformat(show_units=True): col_str += format_str string = "name: " + self._name + ", " + col_str + "]" return string class StringNode(BaseDustNode): """ A node that contains text. """ def __init__(self, xml_node, col_name, length): """ Parameters ---------- xml_node : `xml.etree.ElementTree` the xml node that provides the raw data for this DustNode col_name : str the name of the column associated with this item length : int the size of the column associated with this item """ BaseDustNode.__init__(self, xml_node) self._value = xml_node.text.strip() self._length = length self._columns = [Column(name=col_name, dtype="S" + str(length))] def __str__(self): """Return a string representation of this item.""" base_string = BaseDustNode.__str__(self) string = ("[StringNode: " + base_string + ", value: " + self._value + "]") return string class NumberNode(BaseDustNode): """ A node that contains a number. Outputs a single column containing the number. """ def __init__(self, xml_node, col_name, units=None): """ Parameters ---------- xml_node : `xml.etree.ElementTree` the xml node that provides the raw data for this DustNode col_name : str the name of the column associated with this item units : `~astropy.units.Unit` the units associated with this item """ BaseDustNode.__init__(self, xml_node) self._value = utils.parse_number(xml_node.text) self._columns = [Column(name=col_name, unit=units)] def __str__(self): """Return a string representation of the item.""" base_string = BaseDustNode.__str__(self) string = ("[NumberNode: " + base_string + ", value: " + str(self._value) + "]") return string class CoordNode(BaseDustNode): """ A node that contains RA, Dec coordinates. Outputs three values / columns: RA, Dec and a coordinate system description string. """ def __init__(self, xml_node, col_names): """ Parameters ---------- xml_node : `xml.etree.ElementTree` the xml node that provides the raw data for this DustNode col_names : str the names of the columns associated with this item """ BaseDustNode.__init__(self, xml_node) self._value = utils.parse_coords(xml_node.text) units = u.deg self._columns = [Column(name=col_names[0], unit=units), Column(name=col_names[1], unit=units), Column(name=col_names[2], dtype="S25")] def __str__(self): """Return a string representation of the item.""" base_string = BaseDustNode.__str__(self) values_str = ("values: " + str(self._value[0]) + ", " + str(self._value[1]) + ", " + str(self._value[2])) string = ("[CoordNode: " + base_string + ", " + values_str + "]") return string class BaseResultSection: """ Represents a group of related nodes/columns in a DustResults object. A DustResults table contains four main sections: 1-location 2-extinction 3-emission 4-temperature In addition, the extinction, emission, and temperature sections each contain a nested statistics subsection. """ def node_dict(self, names, xml_root): """ Find all the nodes with the given names under the given root, and put them in a dictionary. Parameters ---------- names : list[str] the names of the nodes to find xml_root : `xml.etree.ElementTree` the root of the xml tree to search Returns ------- nodes : dictionary a dictionary of xml nodes, where the keys are the node names """ nodes = {} for name in names: found_node = xml_root.find(name) if found_node is None: raise ValueError("Could not find node '" + name + "'") nodes[name] = found_node return nodes def create_columns(self): """Build the columns associated with this section.""" columns = [] for dust_node in self._dust_nodes: if isinstance(dust_node._columns, list): columns.extend(dust_node._columns) else: columns.append(dust_node._columns) self._columns = columns @property def columns(self): """Return the list of columns associated with this section.""" return self._columns def values(self): """Return the list of data values associated with this section, i.e. the data corresponding to a single row in the results table.""" values = [] for dust_node in self._dust_nodes: if isinstance(dust_node._value, list): values.extend(dust_node._value) else: values.append(dust_node._value) return values def __str__(self): """Return a string representation of the section.""" string = "\n\t\t" for dust_node in self._dust_nodes: if len(string) > 6: string += ",\n\t\t" string += dust_node.__str__() return string class LocationSection(BaseResultSection): """ The location section of the DustResults object. """ def __init__(self, xml_root): """ Parameters ---------- xml_root : `xml.etree.ElementTree` the xml tree where the data for this section resides """ location_node = xml_root.find(INPUT) names = [OBJ_NAME, REG_SIZE] xml_nodes = self.node_dict(names, location_node) # Create the section's DustNodes self._dust_nodes = [CoordNode( xml_nodes[OBJ_NAME], col_names=["RA", "Dec", "coord sys"]), NumberNode(xml_nodes[REG_SIZE], REG_SIZE, u.deg)] self.create_columns() def __str__(self): """Return a string representation of the section.""" base_string = BaseResultSection.__str__(self) string = "[LocationSection: " + base_string + "]" return string class StatsSection(BaseResultSection): """ The statistics subsection of one of an extinction, emission, or temperature section. """ def __init__(self, xml_root, col_prefix, suffix=""): """ Parameters ---------- xml_root : `xml.etree.ElementTree` The xml tree containing the data for this section col_prefix : str the prefix to use in column names for this section suffix : str the suffix that appears in the node names (e.g. 'SandF' or 'SDF') """ names = [ REF_PIXEL_VALUE + suffix, REF_COORDINATE, MEAN_VALUE + suffix, STD + suffix, MAX_VALUE + suffix, MIN_VALUE + suffix] xml_nodes = self.node_dict(names, xml_root) # Create the DustNodes self._dust_nodes = [ NumberNode(xml_nodes[REF_PIXEL_VALUE + suffix], col_prefix + " ref"), CoordNode(xml_nodes[REF_COORDINATE], col_names=[col_prefix + " ref RA", col_prefix + " ref Dec", col_prefix + " ref coord sys"]), NumberNode(xml_nodes[MEAN_VALUE + suffix], col_prefix + " mean"), NumberNode(xml_nodes[STD + suffix], col_prefix + " std"), NumberNode(xml_nodes[MAX_VALUE + suffix], col_prefix + " max"), NumberNode(xml_nodes[MIN_VALUE + suffix], col_prefix + " min")] self._units = utils.parse_units( xml_nodes[REF_PIXEL_VALUE + suffix].text) self.create_columns() @property def units(self): """Return the units associated with this section.""" return self._units @property def dust_nodes(self): """Return the list of DustNodes in this section.""" return self._dust_nodes def __str__(self): """Return a string representation of the section.""" base_string = "\n\t\t\t\t" for dust_node in self._dust_nodes: if len(base_string) > 6: base_string += ",\n\t\t\t\t" base_string += dust_node.__str__() string = "\n\t\t\t[StatisticsSection: " + base_string + "]" return string class ExtinctionSection(BaseResultSection): """ The extinction (reddening) section in a DustResults object. """ def __init__(self, xml_root): """ Parameters ---------- xml_root : `xml.etree.ElementTree` The xml tree containing the data for this section """ # Find the section's xml nodes names = [DESC, DATA_IMAGE, DATA_TABLE, STATISTICS] xml_nodes = self.node_dict(names, xml_root) # Build the DustNodes self._dust_nodes = [StringNode(xml_nodes[DESC], "ext desc", 100), StringNode(xml_nodes[DATA_IMAGE], "ext image", 255), StringNode(xml_nodes[DATA_TABLE], "ext table", 255)] # Create statistics subsections self._stats_sandf = StatsSection(xml_nodes[STATISTICS], "ext SandF", "SandF") self._stats_sfd = StatsSection(xml_nodes[STATISTICS], "ext SFD", "SFD") self.create_columns() def create_columns(self): """Build the columns associated with this section.""" BaseResultSection.create_columns(self) self._columns.extend(self._stats_sandf.columns) self._columns.extend(self._stats_sfd.columns) @property def table_url(self): """Return the url where the extinction detail table can be found.""" table_url = self._dust_nodes[2]._value return table_url @property def image_url(self): """Return the url of the FITS image associated with this section.""" return self._dust_nodes[1]._value def values(self): """Return the data values associated with this section, i.e. the list of values corresponding to a single row in the results table.""" ext_values = BaseResultSection.values(self) ext_values.extend(self._stats_sandf.values()) ext_values.extend(self._stats_sfd.values()) return ext_values def __str__(self): """Return a string representation of the section.""" base_string = BaseResultSection.__str__(self) string = ("[ExtinctionSection: " + base_string + self._stats_sandf.__str__() + self._stats_sfd.__str__() + "]") return string class EmissionSection(BaseResultSection): """ The emission section in a DustResults object. """ def __init__(self, xml_root): """ Parameters ---------- xml_root : `xml.etree.ElementTree` The xml tree containing the data for this section """ names = [DESC, DATA_IMAGE, STATISTICS] xml_nodes = self.node_dict(names, xml_root) # Create the DustNodes self._dust_nodes = [StringNode(xml_nodes[DESC], "em desc", 100), StringNode(xml_nodes[DATA_IMAGE], "em image", 255)] # Create the statistics subsection self._stats = StatsSection(xml_nodes[STATISTICS], "em") self.create_columns() def create_columns(self): """Build the columns associated with this section.""" BaseResultSection.create_columns(self) self._columns.extend(self._stats.columns) def values(self): """Return the data values associated with this section, i.e. the list of values corresponding to a single row in the results table.""" values = BaseResultSection.values(self) values.extend(self._stats.values()) return values @property def image_url(self): """Return the url of the FITS image associated with this section.""" return self._dust_nodes[1]._value def __str__(self): """Return a string representation of the section.""" base_string = BaseResultSection.__str__(self) string = "[EmissionSection: " + \ base_string + self._stats.__str__() + "]" return string IrsaDust = IrsaDustClass() class TemperatureSection(BaseResultSection): """ The temperature section in a DustResults object. """ def __init__(self, xml_root): """ Parameters ---------- xml_root : `xml.etree.ElementTree` The xml tree containing the data for this section """ names = [DESC, DATA_IMAGE, STATISTICS] xml_nodes = self.node_dict(names, xml_root) # Create the DustNodes self._dust_nodes = [StringNode(xml_nodes[DESC], "temp desc", 100), StringNode(xml_nodes[DATA_IMAGE], "temp image", 255)] # Create the statistics subsection self._stats = StatsSection(xml_nodes[STATISTICS], "temp") self.create_columns() def create_columns(self): """Build the columns associated with this section.""" BaseResultSection.create_columns(self) self._columns.extend(self._stats.columns) def values(self): """Return the data values associated with this section, i.e. the list of values corresponding to a single row in the results table.""" values = BaseResultSection.values(self) values.extend(self._stats.values()) return values @property def image_url(self): """Return the url of the FITS image associated with this section.""" return self._dust_nodes[1]._value def __str__(self): """Return a string representation of the section.""" base_string = BaseResultSection.__str__(self) string = "[TemperatureSection: " + \ base_string + self._stats.__str__() + "]" return string