arcgis.geometry module¶

The arcgis.geometry module defines useful geometry types for working with geographic information and GIS functionality. It provides functions which use geometric types as input and output as well as functions for easily converting geometries between different representations.

Several functions accept geometries represented as dictionaries and the geometry objects in this module behave like them as well as support the ‘.’ (dot) notation providing attribute access.

Note

It is recommended to have ArcPy or Shapely downloaded for most Geometry methods and property usage.

Examples:

# Example Point

>>> pt = Point({"x" : -118.15, "y" : 33.80, "spatialReference" : {"wkid" : 4326}})
>>> print (pt.is_valid)
True
>>> print (pt.type) # POINT
'POINT'
>>> print (pt)
'{"x" : -118.15, "y" : 33.80, "spatialReference" : {"wkid" : 4326}}'
>>> print (pt.x, pt.y)
(-118.15,33.80)

# Example Polyline

>>> line = {
  "paths" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832]],
             [[-97.06326,32.759],[-97.06298,32.755]]],
  "spatialReference" : {"wkid" : 4326}
}
>>> polyline = Polyline(line)
>>> print(polyline)
'{"paths" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832]],[[-97.06326,32.759],[-97.06298,32.755]]],"spatialReference" : {"wkid" : 4326}}'
>>> print(polyline.is_valid)
True

# Example INVALID Geometry

>>> line = {
  "paths" : [[[-97.06138],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832]],
             [[-97.06326,32.759],[-97.06298,32.755]]],
  "spatialReference" : {"wkid" : 4326}
}
>>> polyline = Polyline(line)
>>> print(polyline)
'''{"paths" : [[[-97.06138],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832]],
[[-97.06326,32.759],[-97.06298,32.755]]],"spatialReference" : {"wkid" : 4326}}'''
>>>print(polyline.is_valid)
False

The same patterna can be repeated for Polygon, MultiPoint and SpatialReference.

You can create a Geometry even when you don’t know the exact type. The Geometry constructor can find the geometry type and returns the correct type as the example below demonstrates:

# Example Unknown Geometry Type

>>> geom = Geometry({
  "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
              [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
              [-97.06326,32.759]]],
  "spatialReference" : {"wkid" : 4326}
})
>>> print (geom.type) # Polygon
'Polygon'
>>> print(isinstance(geom, Polygon)
True

Point¶

class arcgis.geometry.Point(iterable=None, **kwargs)¶

The Point class contains x and y fields along with a SpatialReference field. A Point can also contain m and z fields. A Point is empty when its x field is present and has the value null or the string NaN. An empty point has no location in space.

coordinates()¶

Retrieves the coordinates of the Point as an np.array

#Usage Example

>>> coords = point.coordinates()
>>> coords
    [x1,y1,m1,z1]

Returns: An np.array containing coordinate values

svg(scale_factor=1, fill_color=None)¶

Returns a SVG (Scalable Vector Graphic) circle element for the Point geometry. SVG defines vector-based graphics in XML format.

Keys	Description
scale_factor	An optional float. Multiplication factor for the SVG circle diameter. Default is 1.
fill_color	An optional string. Hex string for fill color. Default is to use “#66cc99” if geometry is valid, and “#ff3333” if invalid.

Returns: An SVG circle element

property type¶: Gets the type of the current Point object.

MultiPoint¶

class arcgis.geometry.MultiPoint(iterable=None, **kwargs)¶

A multipoint contains an array of Point, along with a SpatialReference field. A multipoint can also have boolean-valued hasZ and hasM fields. These fields control the interpretation of elements of the points array.

Note

Omitting an hasZ or hasM field is equivalent to setting it to false.

Each element of the points array is itself an array of two, three, or four numbers. It will have two elements for 2D points, two or three elements for 2D points with Ms, three elements for 3D points, and three or four elements for 3D points with Ms. In all cases, the x coordinate is at index 0 of a point’s array, and the y coordinate is at index 1. For 2D points with Ms, the m coordinate, if present, is at index 2. For 3D points, the Z coordinate is required and is at index 2. For 3D points with Ms, the Z coordinate is at index 2, and the M coordinate, if present, is at index 3.

Note

An empty multipoint has a points field with no elements. Empty points are ignored.

coordinates()¶

Retrieves the coordinates of the MultiPoint as an np.array

#Usage Example

>>> coords = multiPoint.coordinates()
>>> coords
    [ [x1,y1,m1,z1], [x2,y2,m2,z2],...]

Returns: An np.array containing coordinate values for each point

svg(scale_factor=1.0, fill_color=None)¶

Returns a group of SVG (Scalable Vector Graphic) circle element for the MultiPoint geometry.

Keys	Description
scale_factor	An optional float. Multiplication factor for the SVG circle diameter. Default is 1.
fill_color	An optional string. Hex string for fill color. Default is to use “#66cc99” if geometry is valid, and “#ff3333” if invalid.

Returns: A group of SVG circle elements

property type¶: Gets the type of the current MultiPoint object.

Polyline¶

class arcgis.geometry.Polyline(iterable=None, **kwargs)¶

The Polyline contains an array of paths or curvePaths and a SpatialReference. For Polylines with curvePaths, see the sections on JSON curve object and Polyline with curve. Each path is represented as an array of Point, and each point in the path is represented as an array of numbers. A Polyline can also have boolean-valued hasM and hasZ fields.

Note

See the description of MultiPoint for details on how the point arrays are interpreted.

An empty PolyLine is represented with an empty array for the paths field. Nulls and/or NaNs embedded in an otherwise defined coordinate stream for Polylines and Polygon objects is a syntax error.

coordinates()¶

Retrieves the coordinates of the Polyline as a np.array

#Usage Example

>>> coords = polyLine.coordinates()
>>> coords
    [ [x1,y1,m1,z1], [x2,y2,m2,z2],...]

Returns: An np.array containing coordinate values

svg(scale_factor=1, stroke_color=None)¶

Retrieves SVG (Scalable Vector Graphic) polyline element for the LineString geometry.

Keys	Description
scale_factor	An optional float. Multiplication factor for the SVG stroke-width. Default is 1.
stroke_color	An optional string. Hex string for fill color. Default is to use “#66cc99” if geometry is valid, and “#ff3333” if invalid.

Returns: The SVG polyline element for the LineString Geometry

property type¶: Gets the type of the current Polyline object.

Polygon¶

class arcgis.geometry.Polygon(iterable=None, **kwargs)¶

The Polygon contains an array of rings or curveRings and a SpatialReference. For Polygons with curveRings, see the sections on JSON curve object and Polygon with curve. Each ring is represented as an array of Point. The first point of each ring is always the same as the last point. Each point in the ring is represented as an array of numbers. A Polygon can also have boolean-valued hasM and hasZ fields.

An empty Polygon is represented with an empty array for the rings field. Null and/or NaNs embedded in an otherwise defined coordinate stream for Polyline and Polygons is a syntax error. Polygons should be topologically simple. Exterior rings are oriented clockwise, while holes are oriented counter-clockwise. Rings can touch at a vertex or self-touch at a vertex, but there should be no other intersections. Polygons returned by services are topologically simple. When drawing a polygon, use the even-odd fill rule. The even-odd fill rule will guarantee that the polygon will draw correctly even if the ring orientation is not as described above.

coordinates()¶

Retrieves the coordinates of the Polygon as an np.array

#Usage Example

>>> coords = polygon.coordinates()
>>> coords
    [ [x1,y1,m1,z1], [x2,y2,m2,z2],...,[x1,y1,m1,z1] ]

Returns: An np.array containing coordinate values

svg(scale_factor=1, fill_color=None)¶

The svg method retrieves SVG (Scalable Vecotr Graphic) polygon element. SVG defines vector-based graphics in XML format.

Keys	Description
scale_factor	An optional float. Multiplication factor for the SVG stroke-width. Default is 1.
fill_color	An optional string. Hex string for fill color. Default is to use “#66cc99” if geometry is valid, and “#ff3333” if invalid.

Returns: The SVG polygon element

property type¶: Gets the type of the current Polyline object.

Envelope¶

class arcgis.geometry.Envelope(iterable=None, **kwargs)¶

The Envelope class represents a rectangle defined by a range of values for each coordinate and attribute. It also has a SpatialReference field. The fields for the z and m ranges are optional.

Note

An empty Envelope has no points in space and is defined by the presence of an xmin field a null value or a NaN string.

coordinates()¶

The coordinates method retrieves the coordinates of the Envelope as a np.array

#Usage Example

>>> coords = envelope.coordinates()
>>> coords
    [ [x1,y1,m1,z1], [x2,y2,m2,z2],...]

Returns: An np.array containing coordinate values

property geohash¶

The geohash method retrieves a geohash string of the extent of the ``Envelope.

Returns: A geohash String

property geohash_covers¶

The geohash_covers method retrieves a list of up to the four longest geohash strings that fit within the extent of the Envelope.

Returns: A list of geohash Strings

property geohash_neighbors¶

Gets a list of the geohash neighbor strings for the extent of the Envelope.

Returns: A list of geohash neighbor Strings

property height¶

Gets the extent height value.

Returns: The extent height value

property polygon¶

Gets the Envelope as a Polygon object.

Returns: A Polygon object

svg(scale_factor=1, fill_color=None)¶

Returns a SVG (Scalable Vector Graphic) envelope element for the Envelope geometry.

Keys	Description
scale_factor	An optional float. Multiplication factor for the SVG circle diameter. Default is 1.
fill_color	An optional string. Hex string for fill color. Default is to use “#66cc99” if geometry is valid, and “#ff3333” if invalid.

Returns: A SVG envelope element

property type¶: Gets the type of the current Polyline object.

property width¶

Gets the extent width value.

Returns: The extent width value

SpatialReference¶

class arcgis.geometry.SpatialReference(iterable=None, **kwargs)¶

A SpatialReference object can be defined using a well-known ID (wkid) or well-known text (wkt). The default tolerance and resolution values for the associated coordinate system are used.

Note

The x, y and z tolerance values are 1 mm or the equivalent in the unit of the coordinate system. If the coordinate system uses feet, the tolerance is 0.00328083333 ft. The resolution values are 10x smaller or 1/10 the tolerance values. Thus, 0.0001 m or 0.0003280833333 ft. For geographic coordinate systems using degrees, the equivalent of a mm at the equator is used.

The well-known ID (WKID) for a given spatial reference can occasionally change. For example, the WGS 1984 Web Mercator (Auxiliary Sphere) projection was originally assigned WKID 102100, but was later changed to 3857. To ensure backward compatibility with older spatial data servers, the JSON wkid property will always be the value that was originally assigned to an SR when it was created. An additional property, latestWkid, identifies the current WKID value (as of a given software release) associated with the same spatial reference.

A SpatialReference object can optionally include a definition for a vertical coordinate system (VCS), which is used to interpret the z-values of a geometry. A VCS defines units of measure, the location of z = 0, and whether the positive vertical direction is up or down. When a vertical coordinate system is specified with a WKID, the same caveat as mentioned above applies.

Note

There are two VCS WKID properties: vcsWkid and latestVcsWkid. A VCS WKT can also be embedded in the string value of the wkt property. In other words, the WKT syntax can be used to define an SR with both horizontal and vertical components in one string. If either part of an SR is custom, the entire SR will be serialized with only the wkt property.

Note

Starting at 10.3, Image Service supports image coordinate systems.

property as_arcpy¶

The as_arcpy property retrieves the class as an arcpy SpatialReference object.

Returns: An arcpy SpatialReference object

svg(scale_factor=1, fill_color=None)¶

Retrieves SVG (Scalable Vector Graphic) polygon element for a SpatialReference field.

Keys	Description
scale_factor	An optional float. Multiplication factor for the SVG stroke-width. Default is 1.
fill_color	An optional string. Hex string for fill color. Default is to use “#66cc99” if geometry is valid, and “#ff3333” if invalid.

Returns: The SVG element

property type¶: Gets the type of the current Point object.

Geometry¶

class arcgis.geometry.Geometry(iterable=None, **kwargs)¶

The base class for all geometries.

You can create a Geometry even when you don’t know the exact type. The Geometry constructor is able to figure out the geometry type and returns the correct type as the example below demonstrates:

#Usage Example: Unknown Geometry

>>> geom = Geometry({
>>>     "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>     "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> print (geom.type) # POLYGON
>>> print (isinstance(geom, Polygon) # True

property EWKT¶

Gets the extended well-known text (EWKT) representation for OGC geometry. It provides a portable representation of a geometry value as a text string.

Note

Any true curves in the geometry will be densified into approximate curves in the WKT string.

Returns: A String

property JSON¶

The JSON method retrieves an Esri JSON representation of the Geometry object as a string.

Returns: A string representing a Geometry object

property WKB¶

Gets the well-known binary (WKB) representation for OGC geometry. It provides a portable representation of a geometry value as a contiguous stream of bytes.

Returns: bytes

property WKT¶

Gets the well-known text (WKT) representation for OGC geometry. It provides a portable representation of a geometry value as a text string.

Note

Any true curves in the geometry will be densified into approximate curves in the WKT string.

Returns: A string

angle_distance_to(second_geometry, method='GEODESIC')¶

The angle_distance_to method retrieves a tuple of angle and distance to another Point using a measurement type.

Note

The angle_distance_to method requires ArcPy. If ArcPy is not installed, none is returned.

Parameter	Description
second_geometry	Required Geometry. An `Geometry` object.
method	Optional String. PLANAR measurements reflect the projection of geographic data onto the 2D surface (in other words, they will not take into account the curvature of the earth). GEODESIC, GREAT_ELLIPTIC, and LOXODROME measurement types may be chosen as an alternative, if desired.

Returns: A tuple of angle and distance to another Point using a measurement type.

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.angle_distance_to(second_geometry = geom2,
>>>                        method="PLANAR")
    {54.5530, 1000.1111}

property area¶

The area method retrieves the area of a Polygon feature. The units of the returned area are based off the SpatialReference field.

Note

None for all other feature types.

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.area
-1.869999999973911e-06

Returns: A float

property as_arcpy¶

The as_arcpy method retrieves the Geometry as an ArcPy Geometry.

If ArcPy is not installed, none is returned.

Note

The as_arcpy method requires ArcPy

Returns: An Geometry object

property as_shapely¶

The as_shapely method retrieves a shapely Geometry object

Returns: A shapely Geometry object. If shapely is not installed, None is returned

boundary()¶

The boundary method constructs the boundary of the Geometry object.

Returns: A Geometry object

buffer(distance)¶

The buffer method constructs a Polygon at a specified distance from the Geometry object.

Note

The buffer method requires ArcPy

Parameter	Description
distance	Required float. The buffer distance. The buffer distance is in the same units as the geometry that is being buffered. A negative distance can only be specified against a polygon geometry.

Returns: A Polygon object

property centroid¶

The centroid method retrieves the center of the Geometry object

Note

The centroid method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.centroid
(-97.06258999999994, 32.754333333000034)

Returns: A tuple(x,y) indicating the center

clip(envelope)¶

The clip method constructs the intersection of the Geometry object and the specified extent.

Note

The clip method requires ArcPy. If ArcPy is not installed, none is returned.

Parameter	Description
envelope	Required tuple. The tuple must have (XMin, YMin, XMax, YMax) each value represents the lower left bound and upper right bound of the extent.

Returns: The Geometry object clipped to the extent

contains(second_geometry, relation=None)¶

Indicates if the base Geometry object contains the comparison Geometry object.

Note

The contain method requires ArcPy/Shapely

Parameter

Description

second_geometry

Required Geometry object. A second geometry

relation

Optional string. The spatial relationship type.

BOUNDARY - Relationship has no restrictions for interiors or boundaries.
CLEMENTINI - Interiors of geometries must intersect. Specifying CLEMENTINI is equivalent to specifying None. This is the default.
PROPER - Boundaries of geometries must not intersect.

Returns: A boolean indicating containment (True), or no containment (False)

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.contains(second_geometry = geom2,
                  relation="CLEMENTINI")
    True

convex_hull()¶

Constructs the Geometry object that is the minimal bounding Polygon such that all outer angles are convex.

Returns: A Geometry object

crosses(second_geometry)¶

Indicates if the two Geometry objects intersect in a geometry of a lesser shape type.

Note

The crosses method requires ArcPy/Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A boolean indicating yes (True), or no (False)

cut(cutter)¶

Splits this Geometry object into a part left of the cutting Polyline and a part right of it.

Note

The cut method requires ArcPy

Parameter	Description
cutter	Required `Polyline`. The cutting polyline geometry

Returns: a list of two Geometry objects

densify(method, distance, deviation)¶

Creates a new Geometry object with added vertices

Note

The densify method requires ArcPy

Parameter	Description
method	Required String. The type of densification: `DISTANCE`, `ANGLE`, or `GEODESIC`
distance	Required float. The maximum distance between vertices. The actual distance between vertices will usually be less than the maximum distance as new vertices will be evenly distributed along the original segment. If using a type of DISTANCE or ANGLE, the distance is measured in the units of the geometry’s spatial reference. If using a type of GEODESIC, the distance is measured in meters.
deviation	Required float. `Densify` uses straight lines to approximate curves. You use deviation to control the accuracy of this approximation. The deviation is the maximum distance between the new segment and the original curve. The smaller its value, the more segments will be required to approximate the curve.

Returns: A new Geometry object

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom2 = geom.densify(method = "GEODESIC",
                         distance = 1244.0,
                         deviation = 100.0)

difference(second_geometry)¶

Constructs the Geometry object that is composed only of the region unique to the base geometry but not part of the other geometry.

Note

The difference method requires ArcPy/Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A Geometry object

disjoint(second_geometry)¶

Indicates if the base and comparison Geometry objects share no Point objects in common.

Note

The disjoint method requires ArcPy/Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A boolean indicating no Point objects in common (True), or some in common (False)

distance_to(second_geometry)¶

Retrieves the minimum distance between two Geometry objects. If the geometries intersect, the minimum distance is 0.

Note

Both geometries must have the same projection.

Note

The distance_to method requires ArcPy/Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A float

property envelope¶

The envelope method retrieves the geoextent as an Envelope object

Returns: Envelope

equals(second_geometry)¶

Indicates if the base and comparison Geometry objects are of the same shape type and define the same set of points in the plane. This is a 2D comparison only; M and Z values are ignored.

Note

The equals method requires ArcPy or Shapely

Parameter	Description
second_geometry	Required `Geometry`. A second geometry

Returns: Boolean indicating True if geometries are equal else False

property extent¶

Get the extent of the Geometry object as a tuple containing xmin, ymin, xmax, ymax

Note

The extent method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.extent
(-97.06326, 32.749, -97.06124, 32.837)

Returns: A tuple

property first_point¶

The first method retrieves first coordinate point of the geometry.

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.first_point
{'x': -97.06138, 'y': 32.837, 'spatialReference': {'wkid': 4326, 'latestWkid': 4326}}

Returns: A Geometry object

classmethod from_shapely(shapely_geometry, spatial_reference=None)¶

Creates a Python API Geometry object from a Shapely geometry object.

Note

Must have shapely installed

Parameter	Description
shapely_geometry	Required Shapely Geometry Single instance of Shapely Geometry to be converted to ArcGIS Python API geometry instance.
spatial_reference	Optional SpatialReference Defines the spatial reference for the output geometry.

Returns: A Geometry object

# Usage Example: importing shapely geometry object and setting spatial reference to WGS84

Geometry.from_shapely(
    shapely_geometry=shapely_geometry_object,
    spatial_reference={'wkid': 4326}
)

generalize(max_offset)¶

Creates a new simplified Geometry object using a specified maximum offset tolerance.

Note

The generalize method requires ArcPy or Shapely**

Parameter	Description
max_offset	Required float. The maximum offset tolerance.

Returns: A Geometry object

property geoextent¶

The geoextent property retrieves the current feature’s extent

#Usage Example
>>> g = Geometry({...})
>>> g.geoextent
(1,2,3,4)

Returns: tuple

property geometry_type¶

Gets the geometry type:

A Polygon
A Polyline
A Point
A MultiPoint

>>> geom = Geometry({
>>>     "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.geometry_type
'polygon'

Returns: A string indicating the geometry type

get_area(method, units=None)¶

Retrieves the area of the Geometry using a measurement type.

Note

The get_area method requires ArcPy or Shapely**

Parameter	Description
method	Required String. PLANAR measurements reflect the projection of geographic data onto the 2D surface (in other words, they will not take into account the curvature of the earth). GEODESIC, GREAT_ELLIPTIC, LOXODROME, and PRESERVE_SHAPE measurement types may be chosen as an alternative, if desired.
units	Optional String. Areal unit of measure keywords: ACRES \| ARES \| HECTARES \| SQUARECENTIMETERS \| SQUAREDECIMETERS \| SQUAREINCHES \| SQUAREFEET \| SQUAREKILOMETERS \| SQUAREMETERS \| SQUAREMILES \| SQUAREMILLIMETERS \| SQUAREYARDS

Returns: A float representing the area of the Geometry object

get_length(method, units)¶

Retrieves the length of the Geometry using a measurement type.

Note

The get_length method requires ArcPy or Shapely

Parameter	Description
method	Required String. PLANAR measurements reflect the projection of geographic data onto the 2D surface (in other words, they will not take into account the curvature of the earth). GEODESIC, GREAT_ELLIPTIC, LOXODROME, and PRESERVE_SHAPE measurement types may be chosen as an alternative, if desired.
units	Required String. Linear unit of measure keywords: CENTIMETERS \| DECIMETERS \| FEET \| INCHES \| KILOMETERS \| METERS \| MILES \| MILLIMETERS \| NAUTICALMILES \| YARDS

Returns: A float representing the length of the Geometry object

get_part(index=None)¶

Retrieves an array of Point objects for a particular part of a Geometry object or an array containing a number of arrays, one for each part.

Note

The get_part method requires ArcPy

Parameter	Description
index	Required Integer. The index position of the `Geometry` object.

Returns: A Geometry object

property has_m¶

The has_m method determines if the geometry has a M value.

Returns: A boolean indicating yes (True), or no (False)

property has_z¶

The has_z method determines if the geometry has a Z value.

Returns: A boolean indicating yes (True), or no (False)

property hull_rectangle¶

The hull_rectangle method retrieves the space-delimited string of the coordinate pairs of the convex hull rectangle.

Note

The hull-rectangle method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.hull_rectangle
'-97.06153 32.749 -97.0632940971127 32.7490060186843 -97.0629938635673 32.8370055061228 -97.0612297664546 32.8369994874385'

Returns: A space-delimited string

intersect(second_geometry, dimension=1)¶

Constructs a Geometry object that is the geometric intersection of the two input geometries. Different dimension values can be used to create different shape types. The intersection of two geometries of the same shape type is a geometry containing only the regions of overlap between the original geometries.

Note

The intersect method requires ArcPy or Shapely

Parameter

Description

second_geometry

Required Geometry object. A second geometry

dimension

Required Integer. The topological dimension (shape type) of the resulting geometry.

1 -A zero-dimensional geometry (Point or MultiPoint).
2 -A one-dimensional geometry (Polyline).
4 -A two-dimensional geometry (Polygon).

Returns: A Geometry object indicating an intersection, or None for no intersection

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> type(geom.intersect(second_geometry = geom2, dimension = 4))
    arcgis.geometry._types.Polygon

property is_empty¶

Determines if the geometry is empty.

Returns: A boolean indicating empty (True), or filled (False)

property is_multipart¶

The is_multipart method determines if the number of parts for this geometry is more than one.

Note

The is_multipart method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>              [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.is_multipart
True

Returns: A boolean indicating yes (True), or no (False)

property label_point¶

Gets the Point at which the label is located. The label_point is always located within or on a feature.

Note

The label_point method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>> })
>>> geom.label_point
{'x': -97.06258999999994, 'y': 32.754333333000034, 'spatialReference': {'wkid': 4326, 'latestWkid': 4326}}

Returns: A Point object

property last_point¶

The last_point method retrieves the last coordinate Point of the feature.

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.last_point
{'x': -97.06326, 'y': 32.759, 'spatialReference': {'wkid': 4326, 'latestWkid': 4326}}

Returns: A Point object

property length¶

Gets length of the linear feature. The length units is the same as the SpatialReference field.

Note

The length method returns zero for Point and MultiPoint feature types.

Note

The length method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.length
0.03033576008004027

Returns: A float

property length3D¶

The length3D method retrieves the 3D length of the linear feature. Zero for point and multipoint The length units is the same as the SpatialReference field.

Note

The length3D method returns zero for Point and MultiPoint feature types.

Note

The length3D method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.length3D
0.03033576008004027

Returns: A float

measure_on_line(second_geometry, as_percentage=False)¶

Retrieves a measure from the start Point of this line to the in_point.

Note

The measure_on_line method requires ArcPy

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry
as_percentage	Optional Boolean. If False, the measure will be returned as a distance; if True, the measure will be returned as a percentage.

Returns: A float

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.measure_on_line(second_geometry = geom2,
                         as_percentage = True)
    0.33

overlaps(second_geometry)¶

Indicates if the intersection of the two Geometry objects has the same shape type as one of the input geometries and is not equivalent to either of the input geometries.

Note

The overlaps method requires ArcPy or Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A boolean indicating an intersection of same shape type (True), or different type (False)

property part_count¶

The part_count method retrieves the number of Geometry parts for the feature.

>>> geom = Geometry({
  "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
              [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
              [-97.06326,32.759]]],
  "spatialReference" : {"wkid" : 4326}
})
>>> geom.part_count
1

Returns: An Integer representing the amount of Geometry parts

property point_count¶

The point_count method retrieves total number of Point objects for the feature.

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.point_count
9

Returns: An Integer representing the amount of Point objects

point_from_angle_and_distance(angle, distance, method='GEODESCIC')¶

Retrieves a Point at a given angle and distance, in degrees and meters, using the specified measurement type.

Note

The point_from_angle_and_distance method requires ArcPy

Parameter	Description
angle	Required Float. The angle in degrees to the returned point.
distance	Required Float. The distance in meters to the returned point.
method	Optional String. PLANAR measurements reflect the projection of geographic data onto the 2D surface (in other words, they will not take into account the curvature of the earth). GEODESIC, GREAT_ELLIPTIC, LOXODROME, and PRESERVE_SHAPE measurement types may be chosen as an alternative, if desired.

Returns: A Point object

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> point = geom.point_from_angle_and_distance(angle=60,
                                               distance = 100000,
                                               method = "PLANAR")
>>> point.type
    "POINT"

position_along_line(value, use_percentage=False)¶

Retrieves a Point on a line at a specified distance from the beginning of the line.

Note

The position_along_line method requires ArcPy or Shapely

Parameter	Description
value	Required Float. The distance along the line.
use_percentage	Optional Boolean. The distance may be specified as a fixed unit of measure or a ratio of the length of the line. If True, value is used as a percentage; if False, value is used as a distance. Note For percentages, the value should be expressed as a double from 0.0 (0%) to 1.0 (100%).

Returns: A Geometry object

project_as(spatial_reference, transformation_name=None)¶

Projects a Geometry object and optionally applies a geotransformation.

Note

The project_as method requires ArcPy or pyproj>=1.9 and PROJ.4

Parameter	Description
spatial_reference	Required SpatialReference. The new spatial reference. This can be a `SpatialReference` object or the coordinate system name.
transformation_name	Required String. The `geotransformation` name.

Returns: A Geometry object

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom2 = geom.project_as(spatial_reference="GCS",
                            transformation_name = "transformation")
>>> geom2.type
    arcgis.geometry.Geometry

query_point_and_distance(second_geometry, use_percentage=False)¶

Finds the Point on the Polyline nearest to the in_point and the distance between those points. query_point_and_distance retrieves information about the side of the line the in_point is on as well as the distance along the line where the nearest point occurs.

Note

The query_point_and_distance method requires ArcPy

Note

The query_point_and_distance method only is valid for Polyline geometries.

Parameter	Description
second_geometry	Required `Point` object. A second geometry
as_percentage	Optional boolean - if False, the measure will be returned as distance, True, measure will be a percentage

Returns: A tuple of the point and the distance

rotate(theta, inplace=False)¶

Rotates a Geometry object counter-clockwise by a given angle.

Parameter	Description
theta	Required Float. The rotation angle.
inplace	Optional Boolean. If True, the value is updated in the object, False creates a new object

Returns: A Geometry object

scale(x_scale=1, y_scale=1, inplace=False)¶

Scales a Geometry object in either the x,y or both directions.

Parameter	Description
x_scale	Optional Float. The x-scale factor.
y_scale	Optional Float. The y-scale factor.
inplace	Optional Boolean. If True, the value is updated in the object, False creates a new object

Returns: A Geometry object

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom2 = geom.sacle(x_scale = 3,
                       y_scale = 0.5,
                       inplace = False)

segment_along_line(start_measure, end_measure, use_percentage=False)¶

Retrieves a Polyline between start and end measures. segment_along_line is similar to the positionAlongLine method but will return a polyline segment between two points on the polyline instead of a single Point.

Note

The segment_along_line method requires ArcPy

Parameter	Description
start_measure	Required Float. The starting distance from the beginning of the line.
end_measure	Required Float. The ending distance from the beginning of the line.
use_percentage	Optional Boolean. The start and end measures may be specified as fixed units or as a ratio. If True, start_measure and end_measure are used as a percentage; if False, start_measure and end_measure are used as a distance. Note For percentages, the measures should be expressed as a double from 0.0 (0 percent) to 1.0 (100 percent).

Returns: A float

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.segment_along_line(start_measure =0,
                            end_measure= 1000,
                            use_percentage = True)
    0.56

skew(x_angle=0, y_angle=0, inplace=False)¶

Creates a skew transform along one or both axes.

Parameter	Description
x_angle	optional Float. Angle to skew in the x coordinate
y_angle	Optional Float. Angle to skew in the y coordinate
inplace	Optional Boolean. If True, the value is updated in the object, False creates a new object

Returns: A Geometry object

snap_to_line(second_geometry)¶

The snap_to_line method retrieves a new Point based on in_point snapped to this Geometry object.

Note

The snap_to_line method requires ArcPy

Parameter	Description
second_geometry	Required `Geometry` - A second geometry

Returns: A Point object

property spatial_reference¶

Gets the SpatialReference of the geometry.

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.spatial_reference
<SpatialReference Class>

Returns: A SpatialReference object

symmetric_difference(second_geometry)¶

The symmetric_difference method constructs a new Geometry object that is the union of two geometries minus the intersection of those geometries.

Note

The two input geometries must be the same shape type.

Note

The symmetric_difference method requires ArcPy or Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A Geometry object

touches(second_geometry)¶

Indicates if the boundaries of the two Geometry objects intersect.

Note

The touches method requires ArcPy or Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A boolean indicating whether the Geometry objects touch (True), or if they do not touch (False)

translate(x_offset=0, y_offset=0, inplace=False)¶

Moves a Geometry object in the x and y direction by a given distance.

Parameter	Description
x_offset	Optional Float. Translation x offset
y_offset	Optional Float. Translation y offset
inplace	Optional Boolean. If True, updates the existing Geometry,else it creates a new Geometry object

Returns: A Geometry object

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.translate(x_offset = 40,
                   y_offset = 50,
                   inplace = True)

property true_centroid¶

Gets the Point representing the center of gravity for a feature.

Note

The true_centroid method requires ArcPy or Shapely

>>> geom = Geometry({
>>>   "rings" : [[[-97.06138,32.837],[-97.06133,32.836],[-97.06124,32.834],[-97.06127,32.832],
>>>               [-97.06138,32.837]],[[-97.06326,32.759],[-97.06298,32.755],[-97.06153,32.749],
>>>               [-97.06326,32.759]]],
>>>   "spatialReference" : {"wkid" : 4326}
>>>                 })
>>> geom.true_centroid
{'x': -97.06272135472369, 'y': 32.746201426025, 'spatialReference': {'wkid': 4326, 'latestWkid': 4326}}

Returns: A Point object

union(second_geometry)¶

Constructs the Geometry object that is the set-theoretic union of the input geometries.

Note

The union method requires ArcPy or Shapely

Parameter	Description
second_geometry	Required `Geometry` object. A second geometry

Returns: A Geometry object

within(second_geometry, relation=None)¶

Indicates if the base Geometry object is within the comparison Geometry object.

Note

The within method requires ArcPy or Shapely

Parameter

Description

second_geometry

Required Geometry object. A second geometry

relation

Optional String. The spatial relationship type.

BOUNDARY - Relationship has no restrictions for interiors or boundaries.
CLEMENTINI - Interiors of geometries must intersect. Specifying CLEMENTINI is equivalent to specifying None. This is the default.
PROPER - Boundaries of geometries must not intersect.

Returns: A boolean indicating the Geometry object is within (True), or not within (False)

areas_and_lengths¶

arcgis.geometry.areas_and_lengths(polygons, length_unit, area_unit, calculation_type, spatial_ref=4326, gis=None, future=False)¶

The areas_and_lengths function calculates areas and perimeter lengths for each Polygon specified in the input array.

Keys	Description
polygons	The array of `Polygon` whose areas and lengths are to be computed.
length_unit	The length unit in which the perimeters of polygons will be calculated. If `calculation_type` is planar, then `length_unit` can be any esriUnits constant (string or integer). If `calculationType` is not planar, then `length_unit` must be a linear esriUnits constant, such as esriSRUnit_Meter`(i.e. `9001`\|`LengthUnits.METER) or esriSRUnit_SurveyMile`(i.e. `9035`\|`LengthUnits.SURVEYMILE). If `length_unit` is not specified, the units are derived from `spatial_ref`. If `spatial_ref` is not specified as well, the units are in meters. For a list of valid units, see esriSRUnitType Constants and esriSRUnit2Type Constants.
area_unit	The area unit in which areas of polygons will be calculated. If calculation_type is planar, then area_unit can be any esriAreaUnits constant (dict or enum). If `calculation_type` is not planar, then `area_unit` must be a esriAreaUnits constant such as AreaUnits.SQUAREMETERS (i.e. {“areaUnit”: “esriSquareMeters”}) or AreaUnits.SQUAREMILES (i.e. {“areaUnit”: “esriSquareMiles”}). If `area_unit` is not specified, the units are derived from `spatial_ref`. If `spatial_ref` is not specified, then the units are in square meters. For a list of valid units, see esriAreaUnits Constants. The list of valid esriAreaUnits constants include, esriSquareInches \| esriSquareFeet \| esriSquareYards \| esriAcres \| esriSquareMiles \| esriSquareMillimeters \| esriSquareCentimeters \| esriSquareDecimeters \| esriSquareMeters \| esriAres \| esriHectares \| esriSquareKilometers.
calculation_type	The type defined for the area and length calculation of the input geometries. The type can be one of the following values: 1. planar - Planar measurements use 2D Euclidean distance to calculate area and length. This should only be used if the area or length needs to be calculated in the given `SpatialReference`. Otherwise, use `preserveShape`. 2. geodesic - Use this type if you want to calculate an area or length using only the vertices of the `Polygon` and define the lines between the points as geodesic segments independent of the actual shape of the `Polygon`. A geodesic segment is the shortest path between two points on an ellipsoid. 3. preserveShape - This type calculates the area or length of the geometry on the surface of the Earth ellipsoid. The shape of the geometry in its coordinate system is preserved.
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: A JSON as dictionary, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> # Use case 1
>>> areas_and_lengths(polygons =[polygon1, polygon2,...],
                      length_unit = 9001,
                      area_unit = {"areaUnit": "esriSquareMeters"},
                      calculation_type = "planar")
>>> # Use case 2
>>> from arcgis.geometry import LengthUnits, AreaUnits
>>> areas_and_lengths(polygons =[polygon1, polygon2,...],
                      length_unit = LengthUnits.METER,
                      area_unit = AreaUnits.SQUAREMETERS,
                      calculation_type = "planar",
                      future = True)

auto_complete¶

arcgis.geometry.auto_complete(polygons=None, polylines=None, spatial_ref=None, gis=None, future=False)¶

The auto_complete function simplifies the process of constructing new Polygon objects that are adjacent to other polygons. It constructs polygons that fill in the gaps between existing polygons and a set of Polyline objects.

Keys	Description
polygons	A List of `Polygon` objects
polylines	A List of `Polyline` objects
spatial_ref	A `SpatialReference` of the input geometries WKID
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: A Polygon object, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

buffer¶

arcgis.geometry.buffer(geometries, in_sr, distances, unit, out_sr=None, buffer_sr=None, union_results=None, geodesic=None, gis=None, future=False)¶

The buffer function is performed on a geometry service resource The result of this function is a buffered Polygon at the specified distances for the input Geometry array.

Note

The options are available to union buffers and to use geodesic distance.

Keys	Description
geometries	The array of geometries to be buffered
in_sr	The well-known ID of the `SpatialReference` or a spatial reference JSON object for the input geometries.
distances	The distances that each of the input geometries is buffered.
unit	The units for calculating each buffer distance. If unit is not specified, the units are derived from `bufferSR`. If `bufferSR` is not specified, the units are derived from `in_sr`.
out_sr	The well-known ID of the `SpatialReference` or a spatial reference JSON object for the output geometries.
buffer_sr	The well-known ID of the `SpatialReference` or a spatial reference JSON object for the buffer geometries.
union_results	A boolean. If True, all geometries buffered at a given distance are unioned into a single (gis,possibly multipart) `Polygon`, and the unioned geometry is placed in the output array. The default is False.
geodesic	Set geodesic to true to buffer the input geometries using geodesic distance. Geodesic distance is the shortest path between two points along the ellipsoid of the earth. If geodesic is set to False, the 2D Euclidean distance is used to buffer the input geometries. Note The default value depends on the geometry type, unit and bufferSR.
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: A list of Polygon object, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> buffer(geometries =[geom1, geom2,...],
           in_sr = "wkid_in",
           unit = LengthUnits.METER,
           out_sr = "wkid_out",
           buffer_sr = "wkid_buffer",
           union_results =True,
           geodesic = True,
           future = True)

convex_hull¶

arcgis.geometry.convex_hull(geometries, spatial_ref=None, gis=None, future=False)¶

The convex_hull function is performed on a Geometry Service resource. It returns the minimum bounding shape that contains the input geometry. The input geometry can be a Point, MultiPoint, Polyline , or Polygon object.

Note

The convex hull is typically a polygon but can also be a polyline or point in degenerate cases.

Keys	Description
geometries	A list of `Point`, `MultiPoint`, `Polyline`, or `Polygon` objects. The structure of each geometry in the array is defined the same as the JSON geometry objects returned by the ArcGIS REST API. Note `Geometry` objects can be obtained by querying a `FeatureLayer`, returning it as a Pandas data frame, and then assigning variables to a geometry based on the row index. >>> flyr_item = gis.content.search("*", "Feature Layer")[0] >>> flyr_df = flyr_item.query(where="1=1", as_df=True) >>> geom0 = flyr_df.loc[0].SHAPE
spatial_ref	An integer value, or a `SpatialReference` object defined using the the Well-Known ID (wkid) of the Spatial Reference. Note See Spatial Reference in the Geometry objects help, or Using Spatial References for details on concepts and resources for finding specific wkid values. >>> geom_result = convex_hull(geometries=[geometry_object] spatial_ref=<wkid>) or >>> geom_result = convex_hull(geometries=[geometry_object], spatial_ref={"wkid": <wkid>}) or >>> from arcgis.geometry import SpatialReference >>> sr_obj_wkid = SpatialReference(<wkid>) >>> geom_result = convex_hull(geometries=[geometry_object], spatial_ref=sr_obj_wkid)
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: A list containing the Geometry object of the result, or if future=True, a Future object. Call result() on the future to get the response details.

# Usage Example:

>>> from arcgis.gis import GIS
>>> from arcgis.geometry import convex_hull

>>> gis = GIS(profile="your_organization_profile")

>>> flyr_item = gis.content.get("<item_id for feature layer>")
>>> flyr = flyr_item.layers[0]

>>> df = flyr.query(where="OBJECTID=1", as_df=True)

>>> geom1 = df.loc[0].SHAPE
>>> hull_geom1 = convex_hull(geometries=[geom1],
                             spatial_ref={"wkid": 2056})

>>> hull_geom1[0]

{'rings': [[[2664507.7925999984, 1212609.7138999999],
.,
.,
[2664678.264199998, 1212618.6860999987],
[2664507.7925999984, 1212609.7138999999]]],
'spatialReference': {'wkid': {'wkid': 2056}}}

cut¶

arcgis.geometry.cut(cutter, target, spatial_ref=None, gis=None, future=False)¶

The cut function is performed on a Geometry service resource. This function splits the target Polyline or Polygon where it is crossed by the cutter polyline.

Note

At 10.1 and later, this function calls simplify on the input cutter and target geometries.

Keys	Description
cutter	The `Polyline` that will be used to divide the target into pieces where it crosses the target.The spatial reference of the polylines is specified by `spatial_ref`. Note The structure of the polyline is the same as the structure of the JSON polyline objects returned by the ArcGIS REST API.
target	The array of `Polyline` or `Polygon` to be cut. The structure of the geometry is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API. The spatial reference of the target geometry array is specified by spatial_ref.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or a JSON object for the output geometry
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: A List of Geometry objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

densify¶

arcgis.geometry.densify(geometries, spatial_ref, max_segment_length, length_unit, geodesic=False, gis=None, future=False)¶

The densify function is performed using the GIS geometry engine. This function densifies Geometry objects by plotting Point objects between existing vertices.

Keys	Description
geometries	An array of `Point`, `MultiPoint`, `Polyline`, or `Polygon` objects. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
spatial_ref	The `well-known ID` or a spatial reference JSON object for the input `Polyline` object. Note For a list of valid WKID values, see Projected coordinate systems and Geographic coordinate systems.
max_segment_len	All segments longer than `maxSegmentLength` are replaced with sequences of lines no longer than `max_segment_length`.
length_unit	The length unit of `max_segment_length`. If `geodesic` is set to false, then the units are derived from `spatial_ref`, and `length_unit` is ignored. If `geodesic` is set to true, then `length_unit` must be a linear unit. In a case where `length_unit` is not specified and `spatial_ref` is a PCS, the units are derived from `spatial_ref`. In a case where `length_unit` is not specified and `spatial_ref` is a GCS, then the units are meters.
geodesic	If geodesic is set to true, then geodesic distance is used to calculate max_segment_length. Geodesic distance is the shortest path between two points along the ellipsoid of the earth. If geodesic is set to false, then 2D Euclidean distance is used to calculate max_segment_length. The default is false.
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: A list of Geometry object, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> densify(geometries =[geom1, geom2,...],
            spatial_ref = "wkid",
            max_segment_length = 100.0,
            length_unit = LengthUnits.METER,
            geodesic = True,
            future = False)

difference¶

arcgis.geometry.difference(geometries, spatial_ref, geometry, gis=None, future=False)¶

The difference function is performed on a geometry service resource. This function constructs the set-theoretic difference between each element of an array of geometries and another geometry the so-called difference geometry. In other words, let B be the difference geometry. For each geometry, A, in the input geometry array, it constructs A-B.

Keys	Description
geometries	An array of `Point`, `MultiPoint`, `Polyline`, or `Polygon` objects. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
geometry	A single geometry of any type and of a dimension equal to or greater than the elements of geometries. The structure of geometry is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API. The use of simple syntax is not supported.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: A list of Geometry objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

distance¶

arcgis.geometry.distance(spatial_ref, geometry1, geometry2, distance_unit='', geodesic=False, gis=None, future=False)¶

The distance function is performed on a geometry service resource. It reports the 2D Euclidean or geodesic distance between the two Geometry objects.

Keys	Description
geometry1	The `Geometry` object from which the distance is measured. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
geometry2	The `Geometry` object to which the distance is measured. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
distance_unit	Optional. One of `LengthUnits` enumeration members. See Geometry Service distance for full details.
geodesic	If `geodesic` is set to true, then the geodesic distance between the `geometry1` and `geometry2` geometries is returned. Geodesic distance is the shortest path between two points along the ellipsoid of the earth. If `geodesic` is set to false or not specified, the planar distance is returned. The default value is false.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: The 2D or geodesic distance between the two Geometry objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

find_transformation¶

arcgis.geometry.find_transformation(in_sr, out_sr, extent_of_interest=None, num_of_results=1, gis=None, future=False)¶

The find_transformations function is performed on a Geometry service resource. This function returns a list of applicable geographic transformations you should use when projecting geometries from the input SpatialReference to the output SpatialReference. The transformations are in JSON format and are returned in order of most applicable to least applicable. Recall that a geographic transformation is not needed when the input and output spatial references have the same underlying geographic coordinate systems. In this case, findTransformations returns an empty list.

Note

Every returned geographic transformation is a forward transformation meaning that it can be used as-is to project from the input spatial reference to the output spatial reference. In the case where a predefined transformation needs to be applied in the reverse direction, it is returned as a forward composite transformation containing one transformation and a transformForward element with a value of false.

Keys	Description
in_sr	The well-known ID of the `SpatialReference` or a spatial reference JSON object for the input geometries.
out_sr	The well-known ID of the `SpatialReference` or a spatial reference JSON object for the output geometries.
ext_of_interest	The bounding box of the area of interest specified as a JSON envelope.If provided, the extent of interest is used to return the most applicable geographic transformations for the area. Note If a `SpatialReference` is not included in the JSON envelope, the `in_sr` is used for the envelope.
num_of_results	The number of geographic transformations to return. The default value is 1. Note If `num_of_results` has a value of -1, all applicable transformations are returned.
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: A List of geographic transformations, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

from_geo_coordinate_string¶

arcgis.geometry.from_geo_coordinate_string(spatial_ref, strings, conversion_type, conversion_mode=None, gis=None, future=False)¶

The from_geo_coordinate_string function is performed on a Geometry service resource. The function converts an array of well-known strings into xy-coordinates based on the conversion type and SpatialReference supplied by the user. An optional conversion mode parameter is available for some conversion types. See to_geo_coordinate_strings for more information on the opposite conversion.

Keys	Description
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
strings	An array of strings formatted as specified by conversion_type. Syntax: [<string1>,…,<stringN>]
conversion-type	The conversion type of the input strings. Note Valid conversion types are: MGRS - Military Grid Reference System USNG - United States National Grid UTM - Universal Transverse Mercator GeoRef - World Geographic Reference System GARS - Global Area Reference System DMS - Degree Minute Second DDM - Degree Decimal Minute DD - Decimal Degree
conversion_mode	Conversion options for MGRS, UTM and GARS conversion types. Note Valid conversion modes for MGRS are: mgrsDefault - Default. Uses the spheroid from the given spatial reference. mgrsNewStyle - Treats all spheroids as new, like WGS 1984. The 80 degree longitude falls into Zone 60. mgrsOldStyle - Treats all spheroids as old, like Bessel 1841. The 180 degree longitude falls into Zone 60. mgrsNewWith180InZone01 - Same as mgrsNewStyle except the 180 degree longitude falls into Zone 01 mgrsOldWith180InZone01 - Same as mgrsOldStyle except the 180 degree longitude falls into Zone 01 Note Valid conversion modes for UTM are: utmDefault - Default. No options. utmNorthSouth - Uses north/south latitude indicators instead of zone numbers - Non-standard. Default is recommended
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: An array of (x,y) coordinates, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> coords = from_geo_coordinate_string(spatial_ref = "wkid",
                                strings = ["01N AA 66021 00000","11S NT 00000 62155", "31U BT 94071 65288"]
                                conversion_type = "MGRS",
                                conversion_mode = "mgrs_default",
                                future = False)
>>> coords
    [[x1,y1], [x2,y2], [x3,y3]]

generalize¶

arcgis.geometry.generalize(spatial_ref, geometries, max_deviation, deviation_unit=None, gis=None, future=False)¶

The generalize function is performed on a Geometry service resource. The generalize function simplifies the input geometries using the Douglas-Peucker algorithm with a specified maximum deviation distance.

Note

The output geometries will contain a subset of the original input vertices.

Keys	Description
geometries	The array `Geometry` objects to be generalized.
max_deviation	`max_deviation` sets the maximum allowable offset, which will determine the degree of simplification. This value limits the distance the output geometry can differ from the input geometry.
deviation_unit	If `geodesic` is set to true, then the geodesic distance between the `geometry1` and `geometry2` geometries is returned. Geodesic distance is the shortest path between two points along the ellipsoid of the earth. If `geodesic` is set to false or not specified, the planar distance is returned. The default value is false.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: An array of the simplified Geometry objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

intersect¶

arcgis.geometry.intersect(spatial_ref, geometries, geometry, gis=None, future=False)¶

The intersect function is performed on a Geometry service resource. This function constructs the set-theoretic intersection between an array of geometries and another geometry.

Note

The dimension of each resultant geometry is the minimum dimension of the input geometry in the geometries array and the other geometry specified by the geometry parameter.

Keys	Description
geometries	An array of `Point`, `MultiPoint`, `Polyline`, or `Polygon` objects. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
geometry	A single `Geometry` of any type and of a dimension equal to or greater than the elements of geometries. The structure of geometry is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API. The use of simple syntax is not supported.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: The set-theoretic dimension between Geometry objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

label_points¶

arcgis.geometry.label_points(spatial_ref, polygons, gis=None, future=False)¶

The label_points function is performed on a Geometry service resource. The labelPoints function calculates an interior Point for each Polygon specified in the input array. These interior points can be used by clients for labeling the polygons.

Keys	Description
polygons	An array of `Polygon` objects whose label `Point` objects are to be computed. The spatial reference of the polygons is specified by `spatial_ref`.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: An array of Point objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

lengths¶

arcgis.geometry.lengths(spatial_ref, polylines, length_unit, calculation_type, gis=None, future=False)¶

The lengths function is performed on a Geometry service resource. This function calculates the` 2D Euclidean` or geodesic lengths of each Polyline specified in the input array.

Keys	Description
polylines	The array of `Polyline` whose lengths are to be computed.
length_unit	The length unit in which the length of `Polyline` will be calculated. If `calculation_type` is planar, then `length_unit` can be any esriUnits constant. If `lengthUnit` is not specified, the units are derived from `spatial_ref`. If `calculationType` is not planar, then lengthUnit must be a linear esriUnits constant, such as esriSRUnit_Meter or esriSRUnit_SurveyMile. If `length_unit` is not specified, the units are meters. For a list of valid units, see esriSRUnitType Constants and esriSRUnit2Type Constant.
calculation_type	The type defined for the length calculation of the input geometries. The type can be one of the following values: 1. planar - Planar measurements use 2D Euclidean distance to calculate area and length. This should only be used if the area or length needs to be calculated in the given `SpatialReference`. Otherwise, use `preserveShape`. 2. geodesic - Use this type if you want to calculate an area or length using only the vertices of the `Polygon` and define the lines between the points as geodesic segments independent of the actual shape of the `Polygon`. A geodesic segment is the shortest path between two points on an ellipsoid. 3. preserveShape - This type calculates the area or length of the geometry on the surface of the Earth ellipsoid. The shape of the geometry in its coordinate system is preserved.
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: A list of floats of 2D-Euclidean or Geodesic lengths, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

offset¶

arcgis.geometry.offset(geometries, offset_distance, offset_unit, offset_how='esriGeometryOffsetRounded', bevel_ratio=10, simplify_result=False, spatial_ref=None, gis=None, future=False)¶

The offset function is performed on a Geometry service resource. This function constructs geometries that are offset from the given input geometries. If the offset parameter is positive, the constructed offset will be on the right side of the geometry. Left side offsets are constructed with negative parameters.

Note

Tracing the geometry from its first vertex to the last will give you a direction along the geometry. It is to the right and left perspective of this direction that the positive and negative parameters will dictate where the offset is constructed. In these terms, it is simple to infer where the offset of even horizontal geometries will be constructed.

Keys	Description
geometries	An array of `Point`, `MultiPoint`, `Polyline`, or `Polygon` objects. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
offset_distance	Specifies the distance for constructing an offset based on the input geometries. Note If the `offset_distance` parameter is positive, the constructed offset will be on the right side of the curve. Left-side offsets are constructed with negative values.
offset_unit	A unit for offset distance. If a unit is not specified, the units are derived from `spatial_ref`.
offset_how	The `offset_how` parameter determines how outer corners between segments are handled. The three options are as follows: `esriGeometryOffsetRounded` - Rounds the corner between extended offsets. `esriGeometryOffsetBevelled` - Squares off the corner after a given ratio distance. 3. `esriGeometryOffsetMitered` - Attempts to allow extended offsets to naturally intersect, but if that intersection occurs too far from the corner, the corner is eventually bevelled off at a fixed distance.
bevel_ratio	`bevel_ratio` is multiplied by the `offset_distance`, and the result determines how far a mitered offset intersection can be located before it is bevelled. When mitered is specified, bevel_ratio is ignored and 10 is used internally. When bevelled is specified, 1.1 will be used if bevel_ratio is not specified. `bevel_ratio` is ignored for rounded offset.
simplify_result	if `simplify_result` is set to true, then self intersecting loops will be removed from the result offset geometries. The default is false.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: A list of Geometry objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> new_job = offset( geometries = [geom1,geom2,...],
                      offset_distance = 100,
                      offset_unit = "esriMeters",
                      offset_how = "esriGeometryOffsetRounded",
                      bevel_ratio = 0,
                      simplify_result = True
                      spatial_ref = "wkid",
                      future = True)

project¶

arcgis.geometry.project(geometries, in_sr, out_sr, transformation='', transform_forward=False, gis=None, future=False)¶

The project function is performed on a Geometry service resource. This function projects an array of input geometries from the input SpatialReference to the output SpatialReference

Keys	Description
geometries	An array of `Point`, `MultiPoint`, `Polyline`, or `Polygon` objects. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
in_sr	The well-known ID of the `SpatialReference` or a spatial reference JSON object for the input geometries.
out_sr	The well-known ID of the `SpatialReference` or a spatial reference JSON object for the output geometries.
transformations	The WKID or a JSON object specifying the geographic transformation (gis,also known as datum transformation) to be applied to the projected geometries. Note A transformation is needed only if the output `SpatialReference` contains a different geographic coordinate system than the input spatial reference.
transformforward	A Boolean value indicating whether or not to transform forward. The forward or reverse direction of transformation is implied in the name of the transformation. If transformation is specified, a value for the `transform_Forward` parameter must also be specified. The default value is false.
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: A list of Geometry objects in the out_sr coordinate system, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

#Usage Example

>>> result = project(geometries = [{"x": -17568824.55, "y": 2428377.35}, {"x": -17568456.88, "y": 2428431.352}],
                     in_sr = 3857,
                     out_sr = 4326)
    [{"x": -157.82343617279275, "y": 21.305781607280093}, {"x": -157.8201333369876, "y": 21.306233559873714}]

relation¶

arcgis.geometry.relation(geometries1, geometries2, spatial_ref, spatial_relation='esriGeometryRelationIntersection', relation_param='', gis=None, future=False)¶

The relation function is performed on a Geometry service resource. This function determines the pairs of geometries from the input geometry arrays that participate in the specified spatial relation. Both arrays are assumed to be in the spatial reference specified by spatial_ref, which is a required parameter. Geometry types cannot be mixed within an array.

Note

The relations are evaluated in 2D. In other words, z coordinates are not used.

Keys	Description
geometry1	The first array of `Geometry` objects to compute relations.
geometry2	The second array of `Geometry` objects to compute relations.
relation_param	The Shape Comparison Language string to be evaluated.
spatial_relation	The spatial relationship to be tested between the two input geometry arrays. Values: esriGeometryRelationCross \| esriGeometryRelationDisjoint \| esriGeometryRelationIn \| esriGeometryRelationInteriorIntersection \| esriGeometryRelationIntersection \| esriGeometryRelationLineCoincidence \| esriGeometryRelationLineTouch \| esriGeometryRelationOverlap \| esriGeometryRelationPointTouch \| esriGeometryRelationTouch \| esriGeometryRelationWithin \| esriGeometryRelationRelation
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns

A JSON dict of geometryNIndex between two lists of geometries, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> new_res = relation(geometry1 = [geom1,geom2,...],
                       geometry2 = [geom21,geom22,..],
                       relation_param = "relationParameter",
                       spatial_relation = "esriGeometryRelationPointTouch"
                       spatial_ref = "wkid",
                       future = False)
>>> new_res
    {'relations': [{'geometry1Index': 0, 'geometry2Index': 0}]}

reshape¶

arcgis.geometry.reshape(spatial_ref, target, reshaper, gis=None, future=False)¶

The reshape function is performed on a Geometry service resource. It reshapes a Polyline or Polygon feature by constructing a polyline over the feature. The feature takes the shape of the reshaper polyline from the first place the reshaper intersects the feature to the last.

Keys	Description
target	The `Polyline` or `Polygon` to be reshaped.
reshaper	The single-part `Polyline` that does the reshaping.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or a JSON object for the input geometry
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: A reshaped Polyline or Polygon object, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

to_geo_coordinate_string¶

arcgis.geometry.to_geo_coordinate_string(spatial_ref, coordinates, conversion_type, conversion_mode='mgrsDefault', num_of_digits=None, rounding=True, add_spaces=True, gis=None, future=False)¶

The to_geo_coordinate_string function is performed on a Geometry service resource. The function converts an array of xy-coordinates into well-known strings based on the conversion type and SpatialReference supplied by the User. Optional parameters are available for some conversion types. See from_geo_coordinate_strings for more information on the opposite conversion.

Note

If an optional parameter is not applicable for a particular conversion type, but a value is supplied for that parameter, the value will be ignored.

Keys	Description
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
coordinates	An array of xy-coordinates in JSON format to be converted. Syntax: [[x1,y2],…[xN,yN]]
conversion-type	The conversion type of the input strings. Note Valid conversion types are: MGRS - Military Grid Reference System USNG - United States National Grid UTM - Universal Transverse Mercator GeoRef - World Geographic Reference System GARS - Global Area Reference System DMS - Degree Minute Second DDM - Degree Decimal Minute DD - Decimal Degree
conversion_mode	Conversion options for MGRS, UTM and GARS conversion types. Note Valid conversion modes for MGRS are: mgrsDefault - Default. Uses the spheroid from the given spatial reference. mgrsNewStyle - Treats all spheroids as new, like WGS 1984. The 80 degree longitude falls into Zone 60. mgrsOldStyle - Treats all spheroids as old, like Bessel 1841. The 180 degree longitude falls into Zone 60. mgrsNewWith180InZone01 - Same as mgrsNewStyle except the 180 degree longitude falls into Zone 01 mgrsOldWith180InZone01 - Same as mgrsOldStyle except the 180 degree longitude falls into Zone 01 Note Valid conversion modes for UTM are: utmDefault - Default. No options. utmNorthSouth - Uses north/south latitude indicators instead of zone numbers - Non-standard. Default is recommended
num_of_digits	The number of digits to output for each of the numerical portions in the string. The default value for `num_of_digits` varies depending on `conversion_type`.
rounding	If `True`, then numeric portions of the string are rounded to the nearest whole magnitude as specified by num_of_digits. Otherwise, numeric portions of the string are truncated. The rounding parameter applies only to conversion types MGRS, USNG and GeoRef. The default value is `True`.
addSpaces	If `True`, then spaces are added between components of the string. The `addSpaces` parameter applies only to conversion types MGRS, USNG and UTM. The default value for MGRS is `False`, while the default value for both USNG and UTM is `True`.
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns

An array of Strings, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> strings = from_geo_coordinate_string(spatial_ref = "wkid",
                                         coordinates = [[x1,y1], [x2,y2], [x3,y3]]
                                         conversion_type = "MGRS",
                                         conversion_mode = "mgrs_default",
                                         future = False)
>>> strings
    ["01N AA 66021 00000","11S NT 00000 62155", "31U BT 94071 65288"]

trim_extend¶

arcgis.geometry.trim_extend(spatial_ref, polylines, trim_extend_to, extend_how=0, gis=None, future=False)¶

The trim_extend function is performed on a Geometry service resource. This function trims or extends each Polyline specified in the input array, using the user-specified guide polylines.

Note

When trimming features, the part to the left of the oriented cutting line is preserved in the output, and the other part is discarded. An empty Polyline is added to the output array if the corresponding input polyline is neither cut nor extended.

Keys	Description
polylines	An array of `Polyline` objects to trim or extend
trim_extend_to	A `Polyline` that is used as a guide for trimming or extending input polylines.
extend_how	A flag that is used along with the trimExtend function. `0` - By default, an extension considers both ends of a path. The old ends remain, and new points are added to the extended ends. The new points have attributes that are extrapolated from adjacent existing segments. `1` - If an extension is performed at an end, relocate the end point to the new position instead of leaving the old point and adding a new point at the new position. `2` - If an extension is performed at an end, do not extrapolate the end-segment’s attributes for the new point. Instead, make its attributes the same as the current end. Incompatible with esriNoAttributes. `4` - If an extension is performed at an end, do not extrapolate the end-segment’s attributes for the new point. Instead, make its attributes empty. Incompatible with esriKeepAttributes. `8` - Do not extend the ‘from’ end of any path. `16` - Do not extend the ‘to’ end of any path.
spatial_ref	A `SpatialReference` of the input geometries Well-Known ID or JSON object
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results.

Returns: An array of Polyline objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

>>> polylines_arr = trim_extends(polylines = [polyline1,polyline2, ...],
                                 trim_extend_to = polyline_trimmer
                                 extend_how = 2,
                                 spatial_ref = "wkid",
                                 future = False)
>>> polyline_arr
    [polyline1, polyline2,...]

union¶

arcgis.geometry.union(geometries, spatial_ref=None, gis=None, future=False)¶

The union function is performed on a Geometry service resource. This function constructs the set-theoretic union of the geometries in the input array.

Note

All inputs must be of the same type.

Keys	Description
geometries	Required. An array of `Point`, `MultiPoint`, `Polyline`, or `Polygon` objects. The structure of each geometry in the array is the same as the structure of the JSON geometry objects returned by the ArcGIS REST API.
spatial_ref	An optional String or JSON Dict representing the wkid to be used. The default is the spatial reference found in the geometry or, if None found, then “4326”. Example: “4326” or {“wkid”:”4326”}
future	Optional boolean. If True, a future object will be returned and the process will not wait for the task to complete. The default is False, which means wait for results. If setting future to True there is a limitation of 6500 geometries that can be processed in one call.

Returns: The set-theoretic union of the Geometry objects, or a GeometryJob object. If future = True, then the result is a Future object. Call result() to get the response.

arcgis.geometry module¶

Point¶

MultiPoint¶

Polyline¶

Polygon¶

Envelope¶

SpatialReference¶

Geometry¶

areas_and_lengths¶

auto_complete¶

buffer¶

convex_hull¶

cut¶

densify¶

difference¶

distance¶

find_transformation¶

from_geo_coordinate_string¶

generalize¶

intersect¶

label_points¶

lengths¶

offset¶

project¶

relation¶

reshape¶

to_geo_coordinate_string¶

trim_extend¶

union¶

Submodules¶