fudgeo 0.1.0

GeoPackage support from Python. fudgeo is a simple package for creating OGC GeoPackages, Feature Classes, Tables, and geometries (read and write).

fudgeo

fudgeo removes the fear uncertainty doubt from using GeoPackages with Python. fudgeo is a simple package for creating OGC GeoPackages, Feature Classes, Tables, and geometries (read and write).

Inspired by elements of pygeopkg.

For more details on OGC GeoPackages, please see the OGC web page.

Installation

fudgeo is available from the Python Package Index.

Python Compatibility

The fudgeo library is compatible with Python 3.9.

Usage

fudgeo can be used to:

• Create a new empty GeoPackage or Open an existing GeoPackage.
• Create new Feature Classes and Tables
• Insert feature (geometry and attributes) into a Feature Class.
• Insert rows into a Table (in the normal SQLite way)

Create an Empty GeoPackage / Open GeoPackage

from fudgeo.geopkg import GeoPackage

# Creates an empty geopackage
gpkg = GeoPackage.create(r'c:\data\example.gpkg')

# Opens an existing Geopackage (no validation)
gpkg = GeoPackage(r'c:\data\example.gpkg')

Geopackages are created with three default Spatial References defined automatically, a pair of Spatial References to handle undefined cases, and a WGS 84 entry.

The definition of the WGS84 entry is flexible - meaning that the WKT for WGS84 can be setup per the users liking. As an example, use with Esri's ArcGIS means either using the EPSG WKT or the ESRI WKT. By default the ESRI WKT is used - However, if EPSG WKT is desired, you may provide a flavor parameter to the create method specifying EPSG.

# Creates an empty geopackage
gpkg = GeoPackage.create(r'c:\temp\test.gpkg', flavor='EPSG')

Create a Feature Class

Use the create_feature_class method of a GeoPackage to make a new feature class. Feature classes require a name and a Spatial Reference, the name must follow SQLite naming requirements. Each feature class is defined with fid and SHAPE fields, additional fields can be defined during creation.

A Feature Class can be created with Z or M (or both) enabled. If either of these options are enabled, the geometry inserted into the Feature Class must include a value for the option specified.

from fudgeo.geopkg import GeoPackage, SpatialReferenceSystem, Field
from fudgeo.enumeration import GeometryType, SQLFieldType

gpkg = GeoPackage.create(r'c:\temp\test.gpkg')

srs_wkt = (
    'PROJCS["WGS_1984_UTM_Zone_23N",'
    'GEOGCS["GCS_WGS_1984",'
    'DATUM["D_WGS_1984",'
    'SPHEROID["WGS_1984",6378137.0,298.257223563]],'
    'PRIMEM["Greenwich",0.0],'
    'UNIT["Degree",0.0174532925199433]],'
    'PROJECTION["Transverse_Mercator"],'
    'PARAMETER["False_Easting",500000.0],'
    'PARAMETER["False_Northing",0.0],'
    'PARAMETER["Central_Meridian",-45.0],'
    'PARAMETER["Scale_Factor",0.9996],'
    'PARAMETER["Latitude_Of_Origin",0.0],'
    'UNIT["Meter",1.0]]')

srs = SpatialReferenceSystem(
    'WGS_1984_UTM_Zone_23N', 'EPSG', 32623, srs_wkt)
fields = (
    Field('heart_rate', SQLFieldType.integer),
    Field('power', SQLFieldType.double),
    Field('comment', SQLFieldType.text, 100),
    Field('is_valid', SQLFieldType.boolean))

fc = gpkg.create_feature_class(
    'test', srs, fields=fields, shape_type=GeometryType.point)

Read more about spatial references in GeoPackages here

Insert Features into a Feature Class (SQL)

Features can be inserted into a Feature Class using SQL.

This example shows the creation of a random point Feature Class and builds upon the code from previous examples. Note that the create Feature Class portion of the code is omitted...

from random import choice, randint
from string import ascii_uppercase, digits
from fudgeo.geometry import Point
from fudgeo.geopkg import GeoPackage

# NOTE Builds from previous examples 
gpkg = GeoPackage(r'c:\data\example.gpkg')

# Generate some random points and attributes
rows = []
for i in range(10000):
    rand_str = ''.join(choice(ascii_uppercase + digits) for _ in range(10))
    rand_int = randint(0, 1000)
    rand_x = randint(300000, 600000)
    rand_y = randint(1, 100000)
    rows.append((Point(x=rand_x, y=rand_y, srs_id=32623), rand_int, rand_str))

with gpkg.connection as conn:
    conn.executemany(
        """INSERT INTO test (SHAPE, heart_rate, comment) 
           VALUES (?, ?, ?)""", rows)

Geometry Examples

Review the tests for fudgeo for a comprehensive look into creating geometries, below are some examples showing the simplicity of this package.

from fudgeo.geometry import Point, LineStringZM, Polygon

# Point in WGS 84
pt = Point(x=-119, y=34)

# Line with ZM Values for use with UTM Zone 23N (WGS 84)
coords = [(300000, 1, 10, 0), (300000, 4000000, 20, 1000),
          (700000, 4000000, 30, 2000), (700000, 1, 40, 3000)]
line = LineStringZM(coords, srs_id=32623)

# list of rings where a ring is simply the list of points it contains.
rings = [[(300000, 1), (300000, 4000000), (700000, 4000000),
          (700000, 1), (300000, 1)]]
poly = Polygon(rings, srs_id=32623)

Select Features from GeoPackage (SQL)

When selecting features from a GeoPackage feature class use SQL. For the most part (mainly simple geometries) this can be done via a basic select statement like:

gpkg = GeoPackage(r'c:\data\example.gpkg')
cursor = gpkg.connection.execute(
    """SELECT SHAPE, heart_rate FROM test""")
features = cursor.fetchall()

This will return a list of tuples where each tuple contains a Point object and an integer (heart rate).

When working with extended geometry types (those with Z and/or M) then the approach is to ensure SQLite knows how to convert the geopackage stored geometry to a fudgeo geometry, this is done like so (pretending here that we created test table as a point geometry with z enabled):

gpkg = GeoPackage(r'c:\data\example.gpkg')
cursor = gpkg.connection.execute(
    """SELECT SHAPE "[PointZ]", heart_rate FROM test""")
features = cursor.fetchall()

License

MIT