# -*- coding: utf-8 -*-
"""
The abstract_dataset module provides the AbstractDataset class
that is the base class for all map layer and Space Time Datasets.
(C) 2011-2013 by the GRASS Development Team
This program is free software under the GNU General Public
License (>=v2). Read the file COPYING that comes with GRASS
for details.
:authors: Soeren Gebbert
"""
from abc import ABCMeta, abstractmethod
from .core import get_tgis_message_interface, init_dbif, get_enable_mapset_check, get_current_mapset
from .temporal_topology_dataset_connector import TemporalTopologyDatasetConnector
from .spatial_topology_dataset_connector import SpatialTopologyDatasetConnector
###############################################################################
[docs]class AbstractDataset(SpatialTopologyDatasetConnector,
TemporalTopologyDatasetConnector):
"""This is the base class for all datasets
(raster, vector, raster3d, strds, stvds, str3ds)"""
__metaclass__ = ABCMeta
def __init__(self):
SpatialTopologyDatasetConnector.__init__(self)
TemporalTopologyDatasetConnector.__init__(self)
self.msgr = get_tgis_message_interface()
[docs] def reset_topology(self):
"""Reset any information about temporal topology"""
self.reset_spatial_topology()
self.reset_temporal_topology()
[docs] def get_number_of_relations(self):
"""Return a dictionary in which the keys are the relation names and the
value are the number of relations.
The following relations are available:
Spatial relations:
- equivalent
- overlap
- in
- contain
- meet
- cover
- covered
Temporal relations:
- equal
- follows
- precedes
- overlaps
- overlapped
- during (including starts, finishes)
- contains (including started, finished)
- starts
- started
- finishes
- finished
To access topological information the spatial, temporal or booth
topologies must be build first using the SpatioTemporalTopologyBuilder.
:return: The dictionary with relations as keys and number as values or
None in case the topology wasn't build
"""
if self.is_temporal_topology_build() and not self.is_spatial_topology_build():
return self.get_number_of_temporal_relations()
elif self.is_spatial_topology_build() and not self.is_temporal_topology_build():
self.get_number_of_spatial_relations()
else:
return self.get_number_of_temporal_relations() + \
self.get_number_of_spatial_relations()
return None
[docs] def set_topology_build_true(self):
"""Use this method when the spatio-temporal topology was build"""
self.set_spatial_topology_build_true()
self.set_temporal_topology_build_true()
[docs] def set_topology_build_false(self):
"""Use this method when the spatio-temporal topology was not build"""
self.set_spatial_topology_build_false()
self.set_temporal_topology_build_false()
[docs] def is_topology_build(self):
"""Check if the spatial and temporal topology was build
:return: A dictionary with "spatial" and "temporal" as keys that
have boolen values
"""
d = {}
d["spatial"] = self.is_spatial_topology_build()
d["temporal"] = self.is_temporal_topology_build()
return d
[docs] def print_topology_info(self):
if self.is_temporal_topology_build():
self.print_temporal_topology_info()
if self.is_spatial_topology_build():
self.print_spatial_topology_info()
[docs] def print_topology_shell_info(self):
if self.is_temporal_topology_build():
self.print_temporal_topology_shell_info()
if self.is_spatial_topology_build():
self.print_spatial_topology_shell_info()
[docs] @abstractmethod
def reset(self, ident):
"""Reset the internal structure and set the identifier
This method creates the dataset specific internal objects
that store the base information, the spatial and temporal extent
and the metadata. It must be implemented in the dataset
specific subclasses. This is the code for the
vector dataset:
.. code-block:: python
self.base = VectorBase(ident=ident)
self.absolute_time = VectorAbsoluteTime(ident=ident)
self.relative_time = VectorRelativeTime(ident=ident)
self.spatial_extent = VectorSpatialExtent(ident=ident)
self.metadata = VectorMetadata(ident=ident)
:param ident: The identifier of the dataset that "name@mapset" or
in case of vector maps "name:layer@mapset"
"""
[docs] @abstractmethod
def is_stds(self):
"""Return True if this class is a space time dataset
:return: True if this class is a space time dataset, False otherwise
"""
[docs] @abstractmethod
def get_type(self):
"""Return the type of this class as string
The type can be "vector", "raster", "raster3d", "stvds", "strds" or "str3ds"
:return: "vector", "raster", "raster3d", "stvds", "strds" or "str3ds"
"""
[docs] @abstractmethod
def get_new_instance(self, ident):
"""Return a new instance with the type of this class
:param ident: The identifier of the new dataset instance
:return: A new instance with the type of this object
"""
[docs] @abstractmethod
def spatial_overlapping(self, dataset):
"""Return True if the spatial extents overlap
:param dataset: The abstract dataset to check spatial overlapping
:return: True if self and the provided dataset spatial overlap
"""
[docs] @abstractmethod
def spatial_intersection(self, dataset):
"""Return the spatial intersection as spatial_extent
object or None in case no intersection was found.
:param dataset: The abstract dataset to intersect with
:return: The intersection spatial extent
"""
[docs] @abstractmethod
def spatial_union(self, dataset):
"""Return the spatial union as spatial_extent
object or None in case the extents does not overlap or meet.
:param dataset: The abstract dataset to create a union with
:return: The union spatial extent
"""
[docs] @abstractmethod
def spatial_disjoint_union(self, dataset):
"""Return the spatial union as spatial_extent object.
:param dataset: The abstract dataset to create a union with
:return: The union spatial extent
"""
[docs] @abstractmethod
def spatial_relation(self, dataset):
"""Return the spatial relationship between self and dataset
:param dataset: The abstract dataset to compute the spatial
relation with self
:return: The spatial relationship as string
"""
[docs] @abstractmethod
def print_info(self):
"""Print information about this class in human readable style"""
[docs] @abstractmethod
def print_shell_info(self):
"""Print information about this class in shell style"""
[docs] @abstractmethod
def print_self(self):
"""Print the content of the internal structure to stdout"""
[docs] def set_id(self, ident):
"""Set the identifier of the dataset"""
self.base.set_id(ident)
self.temporal_extent.set_id(ident)
self.spatial_extent.set_id(ident)
self.metadata.set_id(ident)
if self.is_stds() is False:
self.stds_register.set_id(ident)
[docs] def get_id(self):
"""Return the unique identifier of the dataset
:return: The id of the dataset "name(:layer)@mapset" as string
"""
return self.base.get_id()
[docs] def get_name(self):
"""Return the name
:return: The name of the dataset as string
"""
return self.base.get_name()
[docs] def get_mapset(self):
"""Return the mapset
:return: The mapset in which the dataset was created as string
"""
return self.base.get_mapset()
[docs] def get_temporal_extent_as_tuple(self):
"""Returns a tuple of the valid start and end time
Start and end time can be either of type datetime or of type
integer, depending on the temporal type.
:return: A tuple of (start_time, end_time)
"""
start = self.temporal_extent.get_start_time()
end = self.temporal_extent.get_end_time()
return (start, end)
[docs] def get_absolute_time(self):
"""Returns the start time, the end
time of the map as tuple
The start time is of type datetime.
The end time is of type datetime in case of interval time,
or None on case of a time instance.
:return: A tuple of (start_time, end_time)
"""
start = self.absolute_time.get_start_time()
end = self.absolute_time.get_end_time()
return (start, end)
[docs] def get_relative_time(self):
"""Returns the start time, the end
time and the temporal unit of the dataset as tuple
The start time is of type integer.
The end time is of type integer in case of interval time,
or None on case of a time instance.
:return: A tuple of (start_time, end_time, unit)
"""
start = self.relative_time.get_start_time()
end = self.relative_time.get_end_time()
unit = self.relative_time.get_unit()
return (start, end, unit)
[docs] def get_relative_time_unit(self):
"""Returns the relative time unit
:return: The relative time unit as string, None if not present
"""
return self.relative_time.get_unit()
[docs] def check_relative_time_unit(self, unit):
"""Check if unit is of type year(s), month(s), day(s), hour(s),
minute(s) or second(s)
:param unit: The unit string
:return: True if success, False otherwise
"""
# Check unit
units = ["year", "years", "month", "months", "day", "days", "hour",
"hours", "minute", "minutes", "second", "seconds"]
if unit not in units:
return False
return True
[docs] def get_temporal_type(self):
"""Return the temporal type of this dataset
The temporal type can be absolute or relative
:return: The temporal type of the dataset as string
"""
return self.base.get_ttype()
[docs] def get_spatial_extent_as_tuple(self):
"""Return the spatial extent as tuple
Top and bottom are set to 0 in case of a two dimensional spatial
extent.
:return: A the spatial extent as tuple (north, south, east, west,
top, bottom)
"""
return self.spatial_extent.get_spatial_extent_as_tuple()
[docs] def get_spatial_extent(self):
"""Return the spatial extent
"""
return self.spatial_extent
[docs] def select(self, dbif=None):
"""Select temporal dataset entry from database and fill
the internal structure
The content of every dataset is stored in the temporal database.
This method must be used to fill this object with the content
from the temporal database.
:param dbif: The database interface to be used
"""
dbif, connected = init_dbif(dbif)
self.base.select(dbif)
self.temporal_extent.select(dbif)
self.spatial_extent.select(dbif)
self.metadata.select(dbif)
if self.is_stds() is False:
self.stds_register.select(dbif)
if connected:
dbif.close()
[docs] def is_in_db(self, dbif=None):
"""Check if the dataset is registered in the database
:param dbif: The database interface to be used
:return: True if the dataset is registered in the database
"""
return self.base.is_in_db(dbif)
[docs] @abstractmethod
def delete(self):
"""Delete dataset from database if it exists"""
[docs] def insert(self, dbif=None, execute=True):
"""Insert dataset into database
:param dbif: The database interface to be used
:param execute: If True the SQL statements will be executed.
If False the prepared SQL statements are returned
and must be executed by the caller.
:return: The SQL insert statement in case execute=False, or an
empty string otherwise
"""
if get_enable_mapset_check() is True and self.get_mapset() != get_current_mapset():
self.msgr.fatal(_("Unable to insert dataset <%(ds)s> of type "
"%(type)s in the temporal database. The mapset "
"of the dataset does not match the current "
"mapset") % {"ds": self.get_id(),
"type": self.get_type()})
dbif, connected = init_dbif(dbif)
# Build the INSERT SQL statement
statement = self.base.get_insert_statement_mogrified(dbif)
statement += self.temporal_extent.get_insert_statement_mogrified(dbif)
statement += self.spatial_extent.get_insert_statement_mogrified(dbif)
statement += self.metadata.get_insert_statement_mogrified(dbif)
if self.is_stds() is False:
statement += self.stds_register.get_insert_statement_mogrified(dbif)
if execute:
dbif.execute_transaction(statement)
if connected:
dbif.close()
return ""
if connected:
dbif.close()
return statement
[docs] def update(self, dbif=None, execute=True, ident=None):
"""Update the dataset entry in the database from the internal structure
excluding None variables
:param dbif: The database interface to be used
:param execute: If True the SQL statements will be executed.
If False the prepared SQL statements are returned
and must be executed by the caller.
:param ident: The identifier to be updated, useful for renaming
:return: The SQL update statement in case execute=False, or an
empty string otherwise
"""
if get_enable_mapset_check() is True and self.get_mapset() != get_current_mapset():
self.msgr.fatal(_("Unable to update dataset <%(ds)s> of type "
"%(type)s in the temporal database. The mapset "
"of the dataset does not match the current "
"mapset") % {"ds": self.get_id(),
"type": self.get_type()})
dbif, connected = init_dbif(dbif)
# Build the UPDATE SQL statement
statement = self.base.get_update_statement_mogrified(dbif, ident)
statement += self.temporal_extent.get_update_statement_mogrified(dbif,
ident)
statement += self.spatial_extent.get_update_statement_mogrified(dbif,
ident)
statement += self.metadata.get_update_statement_mogrified(dbif, ident)
if self.is_stds() is False:
statement += self.stds_register.get_update_statement_mogrified(dbif, ident)
if execute:
dbif.execute_transaction(statement)
if connected:
dbif.close()
return ""
if connected:
dbif.close()
return statement
[docs] def update_all(self, dbif=None, execute=True, ident=None):
"""Update the dataset entry in the database from the internal structure
and include None variables.
:param dbif: The database interface to be used
:param execute: If True the SQL statements will be executed.
If False the prepared SQL statements are returned
and must be executed by the caller.
:param ident: The identifier to be updated, useful for renaming
:return: The SQL update statement in case execute=False, or an
empty string otherwise
"""
if get_enable_mapset_check() is True and self.get_mapset() != get_current_mapset():
self.msgr.fatal(_("Unable to update dataset <%(ds)s> of type "
"%(type)s in the temporal database. The mapset"
" of the dataset does not match the current "
"mapset") % {"ds": self.get_id(),
"type": self.get_type()})
dbif, connected = init_dbif(dbif)
# Build the UPDATE SQL statement
statement = self.base.get_update_all_statement_mogrified(dbif, ident)
statement += self.temporal_extent.get_update_all_statement_mogrified(dbif,
ident)
statement += self.spatial_extent.get_update_all_statement_mogrified(dbif,
ident)
statement += self.metadata.get_update_all_statement_mogrified(dbif,
ident)
if self.is_stds() is False:
statement += self.stds_register.get_update_all_statement_mogrified(dbif, ident)
if execute:
dbif.execute_transaction(statement)
if connected:
dbif.close()
return ""
if connected:
dbif.close()
return statement
[docs] def is_time_absolute(self):
"""Return True in case the temporal type is absolute
:return: True if temporal type is absolute, False otherwise
"""
if "temporal_type" in self.base.D:
return self.base.get_ttype() == "absolute"
else:
return None
[docs] def is_time_relative(self):
"""Return True in case the temporal type is relative
:return: True if temporal type is relative, False otherwise
"""
if "temporal_type" in self.base.D:
return self.base.get_ttype() == "relative"
else:
return None
[docs] def get_temporal_extent(self):
"""Return the temporal extent of the correct internal type
"""
if self.is_time_absolute():
return self.absolute_time
if self.is_time_relative():
return self.relative_time
return None
temporal_extent = property(fget=get_temporal_extent)
[docs] def temporal_relation(self, dataset):
"""Return the temporal relation of self and the provided dataset
:return: The temporal relation as string
"""
return self.temporal_extent.temporal_relation(dataset.temporal_extent)
[docs] def temporal_intersection(self, dataset):
"""Intersect self with the provided dataset and
return a new temporal extent with the new start and end time
:param dataset: The abstract dataset to temporal intersect with
:return: The new temporal extent with start and end time,
or None in case of no intersection
"""
return self.temporal_extent.intersect(dataset.temporal_extent)
[docs] def temporal_union(self, dataset):
"""Creates a union with the provided dataset and
return a new temporal extent with the new start and end time.
:param dataset: The abstract dataset to create temporal union with
:return: The new temporal extent with start and end time,
or None in case of no intersection
"""
return self.temporal_extent.union(dataset.temporal_extent)
[docs] def temporal_disjoint_union(self, dataset):
"""Creates a union with the provided dataset and
return a new temporal extent with the new start and end time.
:param dataset: The abstract dataset to create temporal union with
:return: The new temporal extent with start and end time
"""
return self.temporal_extent.disjoint_union(dataset.temporal_extent)
###############################################################################
[docs]class AbstractDatasetComparisonKeyStartTime(object):
"""This comparison key can be used to sort lists of abstract datasets
by start time
Example:
.. code-block:: python
# Return all maps in a space time raster dataset as map objects
map_list = strds.get_registered_maps_as_objects()
# Sort the maps in the list by start time
sorted_map_list = sorted(map_list, key=AbstractDatasetComparisonKeyStartTime)
"""
def __init__(self, obj, *args):
self.obj = obj
def __lt__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return startA < startB
def __gt__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return startA > startB
def __eq__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return startA == startB
def __le__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return startA <= startB
def __ge__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return startA >= startB
def __ne__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return startA != startB
###############################################################################
[docs]class AbstractDatasetComparisonKeyEndTime(object):
"""This comparison key can be used to sort lists of abstract datasets
by end time
Example:
.. code-block:: python
# Return all maps in a space time raster dataset as map objects
map_list = strds.get_registered_maps_as_objects()
# Sort the maps in the list by end time
sorted_map_list = sorted(map_list, key=AbstractDatasetComparisonKeyEndTime)
"""
def __init__(self, obj, *args):
self.obj = obj
def __lt__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return endA < endB
def __gt__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return endA > endB
def __eq__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return endA == endB
def __le__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return endA <= endB
def __ge__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return endA >= endB
def __ne__(self, other):
startA, endA = self.obj.get_temporal_extent_as_tuple()
startB, endB = other.obj.get_temporal_extent_as_tuple()
return endA != endB
###############################################################################
if __name__ == "__main__":
import doctest
doctest.testmod()
