hub/venv/lib/python3.7/site-packages/pyproj/transformer.py

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"""
The transformer module is for performing cartographic transformations.
"""
__all__ = [
"transform",
"itransform",
"Transformer",
"TransformerGroup",
"AreaOfInterest",
]
import warnings
from array import array
from itertools import chain, islice
from typing import Any, Iterable, Iterator, List, Optional, Tuple, Union
from pyproj import CRS, Proj
from pyproj._crs import AreaOfUse, CoordinateOperation
from pyproj._transformer import AreaOfInterest, _Transformer, _TransformerGroup # noqa
from pyproj.compat import cstrencode
from pyproj.enums import TransformDirection, WktVersion
from pyproj.exceptions import ProjError
from pyproj.utils import _convertback, _copytobuffer
class TransformerGroup(_TransformerGroup):
"""
The TransformerGroup is a set of possible transformers from one CRS to another.
.. versionadded:: 2.3.0
From PROJ docs::
The operations are sorted with the most relevant ones first: by
descending area (intersection of the transformation area with the
area of interest, or intersection of the transformation with the
area of use of the CRS), and by increasing accuracy. Operations
with unknown accuracy are sorted last, whatever their area.
"""
def __init__(
self,
crs_from: Any,
crs_to: Any,
skip_equivalent: bool = False,
always_xy: bool = False,
area_of_interest: Optional[AreaOfInterest] = None,
) -> None:
"""Get all possible transformations from a :obj:`pyproj.crs.CRS`
or input used to create one.
Parameters
----------
crs_from: pyproj.crs.CRS or input used to create one
Projection of input data.
crs_to: pyproj.crs.CRS or input used to create one
Projection of output data.
skip_equivalent: bool, optional
If true, will skip the transformation operation if input and output
projections are equivalent. Default is false.
always_xy: bool, optional
If true, the transform method will accept as input and return as output
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coordinates using the traditional gis order, that is longitude, latitude
for geographic CRS and easting, northing for most projected CRS.
Default is false.
area_of_interest: :class:`pyproj.transformer.AreaOfInterest`, optional
The area of interest to help order the transformations based on the
best operation for the area.
"""
super().__init__(
CRS.from_user_input(crs_from),
CRS.from_user_input(crs_to),
skip_equivalent=skip_equivalent,
always_xy=always_xy,
area_of_interest=area_of_interest,
)
for iii, transformer in enumerate(self._transformers):
self._transformers[iii] = Transformer(transformer)
@property
def transformers(self) -> List["Transformer"]:
"""
list[:obj:`Transformer`]:
List of available :obj:`Transformer`
associated with the transformation.
"""
return self._transformers
@property
def unavailable_operations(self) -> List[CoordinateOperation]:
"""
list[:obj:`pyproj.crs.CoordinateOperation`]:
List of :obj:`pyproj.crs.CoordinateOperation` that are not
available due to missing grids.
"""
return self._unavailable_operations
@property
def best_available(self) -> bool:
"""
bool: If True, the best possible transformer is available.
"""
return self._best_available
def __repr__(self) -> str:
return (
"<TransformerGroup: best_available={best_available}>\n"
"- transformers: {transformers}\n"
"- unavailable_operations: {unavailable_operations}"
).format(
best_available=self.best_available,
transformers=len(self.transformers),
unavailable_operations=len(self.unavailable_operations),
)
class Transformer:
"""
The Transformer class is for facilitating re-using
transforms without needing to re-create them. The goal
is to make repeated transforms faster.
Additionally, it provides multiple methods for initialization.
.. versionadded:: 2.1.0
"""
def __init__(self, base_transformer: Optional[_Transformer] = None) -> None:
if not isinstance(base_transformer, _Transformer):
ProjError.clear()
raise ProjError(
"Transformer must be initialized using: "
"'from_crs', 'from_pipeline', or 'from_proj'."
)
self._transformer = base_transformer
@property
def name(self) -> str:
"""
str: Name of the projection.
"""
return self._transformer.id
@property
def description(self) -> str:
"""
str: Description of the projection.
"""
return self._transformer.description
@property
def definition(self) -> str:
"""
str: Definition of the projection.
"""
return self._transformer.definition
@property
def has_inverse(self) -> bool:
"""
bool: True if an inverse mapping exists.
"""
return self._transformer.has_inverse
@property
def accuracy(self) -> float:
"""
float: Expected accuracy of the transformation. -1 if unknown.
"""
return self._transformer.accuracy
@property
def area_of_use(self) -> AreaOfUse:
"""
.. versionadded:: 2.3.0
Returns
-------
AreaOfUse:
The area of use object with associated attributes.
"""
return self._transformer.area_of_use
@property
def remarks(self) -> str:
"""
.. versionadded:: 2.4.0
Returns
-------
str:
Remarks about object.
"""
return self._transformer.remarks
@property
def scope(self) -> str:
"""
.. versionadded:: 2.4.0
Returns
-------
str:
Scope of object.
"""
return self._transformer.scope
@property
def operations(self) -> Optional[Tuple[CoordinateOperation]]:
"""
.. versionadded:: 2.4.0
Returns
-------
Tuple[CoordinateOperation]:
The operations in a concatenated operation.
"""
return self._transformer.operations
@staticmethod
def from_proj(
proj_from: Any,
proj_to: Any,
skip_equivalent: bool = False,
always_xy: bool = False,
area_of_interest: Optional[AreaOfInterest] = None,
) -> "Transformer":
"""Make a Transformer from a :obj:`pyproj.proj.Proj` or input used to create one.
.. versionadded:: 2.1.2 skip_equivalent
.. versionadded:: 2.2.0 always_xy
.. versionadded:: 2.3.0 area_of_interest
Parameters
----------
proj_from: :obj:`pyproj.proj.Proj` or input used to create one
Projection of input data.
proj_to: :obj:`pyproj.proj.Proj` or input used to create one
Projection of output data.
skip_equivalent: bool, optional
If true, will skip the transformation operation if input and output
projections are equivalent. Default is false.
always_xy: bool, optional
If true, the transform method will accept as input and return as output
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coordinates using the traditional gis order, that is longitude, latitude
for geographic CRS and easting, northing for most projected CRS.
Default is false.
area_of_interest: :class:`pyproj.transformer.AreaOfInterest`, optional
The area of interest to help select the transformation.
Returns
-------
Transformer
"""
if not isinstance(proj_from, Proj):
proj_from = Proj(proj_from)
if not isinstance(proj_to, Proj):
proj_to = Proj(proj_to)
return Transformer.from_crs(
proj_from.crs,
proj_to.crs,
skip_equivalent=skip_equivalent,
always_xy=always_xy,
area_of_interest=area_of_interest,
)
@staticmethod
def from_crs(
crs_from: Any,
crs_to: Any,
skip_equivalent: bool = False,
always_xy: bool = False,
area_of_interest: Optional[AreaOfInterest] = None,
) -> "Transformer":
"""Make a Transformer from a :obj:`pyproj.crs.CRS` or input used to create one.
.. versionadded:: 2.1.2 skip_equivalent
.. versionadded:: 2.2.0 always_xy
.. versionadded:: 2.3.0 area_of_interest
Parameters
----------
crs_from: pyproj.crs.CRS or input used to create one
Projection of input data.
crs_to: pyproj.crs.CRS or input used to create one
Projection of output data.
skip_equivalent: bool, optional
If true, will skip the transformation operation if input and output
projections are equivalent. Default is false.
always_xy: bool, optional
If true, the transform method will accept as input and return as output
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coordinates using the traditional gis order, that is longitude, latitude
for geographic CRS and easting, northing for most projected CRS.
Default is false.
area_of_interest: :class:`pyproj.transformer.AreaOfInterest`, optional
The area of interest to help select the transformation.
Returns
-------
Transformer
"""
return Transformer(
_Transformer.from_crs(
CRS.from_user_input(crs_from),
CRS.from_user_input(crs_to),
skip_equivalent=skip_equivalent,
always_xy=always_xy,
area_of_interest=area_of_interest,
)
)
@staticmethod
def from_pipeline(proj_pipeline: str) -> "Transformer":
"""Make a Transformer from a PROJ pipeline string.
https://proj.org/operations/pipeline.html
Parameters
----------
proj_pipeline: str
Projection pipeline string.
Returns
-------
Transformer
"""
return Transformer(_Transformer.from_pipeline(cstrencode(proj_pipeline)))
def transform(
self,
xx: Any,
yy: Any,
zz: Any = None,
tt: Any = None,
radians: bool = False,
errcheck: bool = False,
direction: Union[TransformDirection, str] = TransformDirection.FORWARD,
) -> Any:
"""
Transform points between two coordinate systems.
.. versionadded:: 2.1.1 errcheck
.. versionadded:: 2.2.0 direction
Parameters
----------
xx: scalar or array (numpy or python)
Input x coordinate(s).
yy: scalar or array (numpy or python)
Input y coordinate(s).
zz: scalar or array (numpy or python), optional
Input z coordinate(s).
tt: scalar or array (numpy or python), optional
Input time coordinate(s).
radians: boolean, optional
If True, will expect input data to be in radians and will return radians
if the projection is geographic. Default is False (degrees). Ignored for
pipeline transformations with pyproj 2, but will work in pyproj 3.
errcheck: boolean, optional
If True an exception is raised if the transformation is invalid.
By default errcheck=False and an invalid transformation
returns ``inf`` and no exception is raised.
direction: pyproj.enums.TransformDirection, optional
The direction of the transform.
Default is :attr:`pyproj.enums.TransformDirection.FORWARD`.
Example:
>>> from pyproj import Transformer
>>> transformer = Transformer.from_crs("epsg:4326", "epsg:3857")
>>> x3, y3 = transformer.transform(33, 98)
>>> "%.3f %.3f" % (x3, y3)
'10909310.098 3895303.963'
>>> pipeline_str = (
... "+proj=pipeline +step +proj=longlat +ellps=WGS84 "
... "+step +proj=unitconvert +xy_in=rad +xy_out=deg"
... )
>>> pipe_trans = Transformer.from_pipeline(pipeline_str)
>>> xt, yt = pipe_trans.transform(2.1, 0.001)
>>> "%.3f %.3f" % (xt, yt)
'2.100 0.001'
>>> transproj = Transformer.from_crs(
... {"proj":'geocent', "ellps":'WGS84', "datum":'WGS84'},
... "EPSG:4326",
... always_xy=True,
... )
>>> xpj, ypj, zpj = transproj.transform(
... -2704026.010,
... -4253051.810,
... 3895878.820,
... radians=True,
... )
>>> "%.3f %.3f %.3f" % (xpj, ypj, zpj)
'-2.137 0.661 -20.531'
>>> transprojr = Transformer.from_crs(
... "EPSG:4326",
... {"proj":'geocent', "ellps":'WGS84', "datum":'WGS84'},
... always_xy=True,
... )
>>> xpjr, ypjr, zpjr = transprojr.transform(xpj, ypj, zpj, radians=True)
>>> "%.3f %.3f %.3f" % (xpjr, ypjr, zpjr)
'-2704026.010 -4253051.810 3895878.820'
>>> transformer = Transformer.from_proj("epsg:4326", 4326, skip_equivalent=True)
>>> xeq, yeq = transformer.transform(33, 98)
>>> "%.0f %.0f" % (xeq, yeq)
'33 98'
"""
# process inputs, making copies that support buffer API.
inx, xisfloat, xislist, xistuple = _copytobuffer(xx)
iny, yisfloat, yislist, yistuple = _copytobuffer(yy)
if zz is not None:
inz, zisfloat, zislist, zistuple = _copytobuffer(zz)
else:
inz = None
if tt is not None:
intime, tisfloat, tislist, tistuple = _copytobuffer(tt)
else:
intime = None
# call pj_transform. inx,iny,inz buffers modified in place.
self._transformer._transform(
inx,
iny,
inz=inz,
intime=intime,
direction=direction,
radians=radians,
errcheck=errcheck,
)
# if inputs were lists, tuples or floats, convert back.
outx = _convertback(xisfloat, xislist, xistuple, inx)
outy = _convertback(yisfloat, yislist, xistuple, iny)
return_data = (outx, outy)
if inz is not None:
return_data += ( # type: ignore
_convertback(zisfloat, zislist, zistuple, inz),
)
if intime is not None:
return_data += ( # type: ignore
_convertback(tisfloat, tislist, tistuple, intime),
)
return return_data
def itransform(
self,
points: Any,
switch: bool = False,
time_3rd: bool = False,
radians: bool = False,
errcheck: bool = False,
direction: Union[TransformDirection, str] = TransformDirection.FORWARD,
) -> Iterator[Iterable]:
"""
Iterator/generator version of the function pyproj.Transformer.transform.
.. versionadded:: 2.1.1 errcheck
.. versionadded:: 2.2.0 direction
Parameters
----------
points: list
List of point tuples.
switch: boolean, optional
If True x, y or lon,lat coordinates of points are switched to y, x
or lat, lon. Default is False.
time_3rd: boolean, optional
If the input coordinates are 3 dimensional and the 3rd dimension is time.
radians: boolean, optional
If True, will expect input data to be in radians and will return radians
if the projection is geographic. Default is False (degrees). Ignored for
pipeline transformations.
errcheck: boolean, optional
If True an exception is raised if the transformation is invalid.
By default errcheck=False and an invalid transformation
returns ``inf`` and no exception is raised.
direction: pyproj.enums.TransformDirection, optional
The direction of the transform.
Default is :attr:`pyproj.enums.TransformDirection.FORWARD`.
Example:
>>> from pyproj import Transformer
>>> transformer = Transformer.from_crs(4326, 2100)
>>> points = [(22.95, 40.63), (22.81, 40.53), (23.51, 40.86)]
>>> for pt in transformer.itransform(points): '{:.3f} {:.3f}'.format(*pt)
'2221638.801 2637034.372'
'2212924.125 2619851.898'
'2238294.779 2703763.736'
>>> pipeline_str = (
... "+proj=pipeline +step +proj=longlat +ellps=WGS84 "
... "+step +proj=unitconvert +xy_in=rad +xy_out=deg"
... )
>>> pipe_trans = Transformer.from_pipeline(pipeline_str)
>>> for pt in pipe_trans.itransform([(2.1, 0.001)]):
... '{:.3f} {:.3f}'.format(*pt)
'2.100 0.001'
>>> transproj = Transformer.from_crs(
... {"proj":'geocent', "ellps":'WGS84', "datum":'WGS84'},
... "EPSG:4326",
... always_xy=True,
... )
>>> for pt in transproj.itransform(
... [(-2704026.010, -4253051.810, 3895878.820)],
... radians=True,
... ):
... '{:.3f} {:.3f} {:.3f}'.format(*pt)
'-2.137 0.661 -20.531'
>>> transprojr = Transformer.from_crs(
... "EPSG:4326",
... {"proj":'geocent', "ellps":'WGS84', "datum":'WGS84'},
... always_xy=True,
... )
>>> for pt in transprojr.itransform(
... [(-2.137, 0.661, -20.531)],
... radians=True
... ):
... '{:.3f} {:.3f} {:.3f}'.format(*pt)
'-2704214.394 -4254414.478 3894270.731'
>>> transproj_eq = Transformer.from_proj(
... 'EPSG:4326',
... '+proj=longlat +datum=WGS84 +no_defs +type=crs',
... always_xy=True,
... skip_equivalent=True
... )
>>> for pt in transproj_eq.itransform([(-2.137, 0.661)]):
... '{:.3f} {:.3f}'.format(*pt)
'-2.137 0.661'
"""
it = iter(points) # point iterator
# get first point to check stride
try:
fst_pt = next(it)
except StopIteration:
raise ValueError("iterable must contain at least one point")
stride = len(fst_pt)
if stride not in (2, 3, 4):
raise ValueError("points can contain up to 4 coordinates")
if time_3rd and stride != 3:
raise ValueError("'time_3rd' is only valid for 3 coordinates.")
# create a coordinate sequence generator etc. x1,y1,z1,x2,y2,z2,....
# chain so the generator returns the first point that was already acquired
coord_gen = chain(fst_pt, (coords[c] for coords in it for c in range(stride)))
while True:
# create a temporary buffer storage for
# the next 64 points (64*stride*8 bytes)
buff = array("d", islice(coord_gen, 0, 64 * stride))
if len(buff) == 0:
break
self._transformer._transform_sequence(
stride,
buff,
switch=switch,
direction=direction,
time_3rd=time_3rd,
radians=radians,
errcheck=errcheck,
)
for pt in zip(*([iter(buff)] * stride)):
yield pt
def to_wkt(
self,
version: Union[WktVersion, str] = WktVersion.WKT2_2019,
pretty: bool = False,
):
"""
Convert the projection to a WKT string.
Version options:
- WKT2_2015
- WKT2_2015_SIMPLIFIED
- WKT2_2019
- WKT2_2019_SIMPLIFIED
- WKT1_GDAL
- WKT1_ESRI
Parameters
----------
version: pyproj.enums.WktVersion
The version of the WKT output.
Default is :attr:`pyproj.enums.WktVersion.WKT2_2019`.
pretty: bool
If True, it will set the output to be a multiline string. Defaults to False.
Returns
-------
str:
The WKT string.
"""
return self._transformer.to_wkt(version=version, pretty=pretty)
def to_json(self, pretty: bool = False, indentation: int = 2) -> str:
"""
Convert the projection to a JSON string.
.. versionadded:: 2.4.0
Parameters
----------
pretty: bool
If True, it will set the output to be a multiline string. Defaults to False.
indentation: int
If pretty is True, it will set the width of the indentation. Default is 2.
Returns
-------
str:
The JSON string.
"""
return self._transformer.to_json(pretty=pretty, indentation=indentation)
def to_json_dict(self) -> dict:
"""
Convert the projection to a JSON dictionary.
.. versionadded:: 2.4.0
Returns
-------
dict:
The JSON dictionary.
"""
return self._transformer.to_json_dict()
def __str__(self) -> str:
return self.definition
def __repr__(self) -> str:
return (
"<{type_name}: {name}>\nDescription: {description}\n"
"Area of Use:\n{area_of_use}"
).format(
type_name=self._transformer.type_name,
name=self.name,
description=self.description,
area_of_use=self.area_of_use or "- undefined",
)
def __eq__(self, other: Any) -> bool:
if not isinstance(other, Transformer):
return False
return self._transformer.__eq__(other._transformer)
def transform(
p1: Any,
p2: Any,
x: Any,
y: Any,
z: Any = None,
tt: Any = None,
radians: bool = False,
errcheck: bool = False,
skip_equivalent: bool = False,
always_xy: bool = False,
):
"""
.. versionadded:: 2.1.2 skip_equivalent
.. versionadded:: 2.2.0 always_xy
.. warning:: This function is deprecated. See: :ref:`upgrade_transformer`
x2, y2, z2 = transform(p1, p2, x1, y1, z1)
Transform points between two coordinate systems defined by the
Proj instances p1 and p2.
The points x1,y1,z1 in the coordinate system defined by p1 are
transformed to x2,y2,z2 in the coordinate system defined by p2.
z1 is optional, if it is not set it is assumed to be zero (and
only x2 and y2 are returned). If the optional keyword
'radians' is True (default is False), then all input and
output coordinates will be in radians instead of the default
of degrees for geographic input/output projections.
If the optional keyword 'errcheck' is set to True an
exception is raised if the transformation is
invalid. By default errcheck=False and ``inf`` is returned for an
invalid transformation (and no exception is raised).
If the optional kwarg skip_equivalent is true (default is False),
it will skip the transformation operation if input and output
projections are equivalent. If `always_xy` is toggled, the
transform method will accept as input and return as output
2020-06-22 13:26:50 -04:00
coordinates using the traditional gis order, that is longitude, latitude
for geographic CRS and easting, northing for most projected CRS.
In addition to converting between cartographic and geographic
projection coordinates, this function can take care of datum
shifts (which cannot be done using the __call__ method of the
Proj instances). It also allows for one of the coordinate
systems to be geographic (proj = 'latlong').
x,y and z can be numpy or regular python arrays, python
lists/tuples or scalars. Arrays are fastest. For projections in
geocentric coordinates, values of x and y are given in meters.
z is always meters.
Example usage:
>>> from pyproj import Proj, transform
>>> # projection 1: UTM zone 15, grs80 ellipse, NAD83 datum
>>> # (defined by epsg code 26915)
>>> p1 = Proj('epsg:26915', preserve_units=False)
>>> # projection 2: UTM zone 15, clrk66 ellipse, NAD27 datum
>>> p2 = Proj('epsg:26715', preserve_units=False)
>>> # find x,y of Jefferson City, MO.
>>> x1, y1 = p1(-92.199881,38.56694)
>>> # transform this point to projection 2 coordinates.
>>> x2, y2 = transform(p1,p2,x1,y1)
>>> '%9.3f %11.3f' % (x1,y1)
'569704.566 4269024.671'
>>> '%9.3f %11.3f' % (x2,y2)
'569722.342 4268814.028'
>>> '%8.3f %5.3f' % p2(x2,y2,inverse=True)
' -92.200 38.567'
>>> # process 3 points at a time in a tuple
>>> lats = (38.83,39.32,38.75) # Columbia, KC and StL Missouri
>>> lons = (-92.22,-94.72,-90.37)
>>> x1, y1 = p1(lons,lats)
>>> x2, y2 = transform(p1,p2,x1,y1)
>>> xy = x1+y1
>>> '%9.3f %9.3f %9.3f %11.3f %11.3f %11.3f' % xy
'567703.344 351730.944 728553.093 4298200.739 4353698.725 4292319.005'
>>> xy = x2+y2
>>> '%9.3f %9.3f %9.3f %11.3f %11.3f %11.3f' % xy
'567721.149 351747.558 728569.133 4297989.112 4353489.645 4292106.305'
>>> lons, lats = p2(x2,y2,inverse=True)
>>> xy = lons+lats
>>> '%8.3f %8.3f %8.3f %5.3f %5.3f %5.3f' % xy
' -92.220 -94.720 -90.370 38.830 39.320 38.750'
"""
warnings.warn(
(
"This function is deprecated. "
"See: https://pyproj4.github.io/pyproj/stable/"
"gotchas.html#upgrading-to-pyproj-2-from-pyproj-1"
),
DeprecationWarning,
stacklevel=2,
)
return Transformer.from_proj(
p1, p2, skip_equivalent=skip_equivalent, always_xy=always_xy
).transform(xx=x, yy=y, zz=z, tt=tt, radians=radians, errcheck=errcheck)
def itransform(
p1: Any,
p2: Any,
points: Iterable[Iterable],
switch: bool = False,
time_3rd: bool = False,
radians: bool = False,
errcheck: bool = False,
skip_equivalent: bool = False,
always_xy: bool = False,
):
"""
.. versionadded:: 2.1.2 skip_equivalent
.. versionadded:: 2.2.0 always_xy
.. warning:: This function is deprecated. See: :ref:`upgrade_transformer`
points2 = itransform(p1, p2, points1)
Iterator/generator version of the function pyproj.transform.
Transform points between two coordinate systems defined by the
Proj instances p1 and p2. This function can be used as an alternative
to pyproj.transform when there is a need to transform a big number of
coordinates lazily, for example when reading and processing from a file.
Points1 is an iterable/generator of coordinates x1,y1(,z1) or lon1,lat1(,z1)
in the coordinate system defined by p1. Points2 is an iterator that returns tuples
of x2,y2(,z2) or lon2,lat2(,z2) coordinates in the coordinate system defined by p2.
z are provided optionally.
Points1 can be:
- a tuple/list of tuples/lists i.e. for 2d points: [(xi,yi),(xj,yj),....(xn,yn)]
- a Nx3 or Nx2 2d numpy array where N is the point number
- a generator of coordinates (xi,yi) for 2d points or (xi,yi,zi) for 3d
If optional keyword 'switch' is True (default is False) then x, y or lon,lat
coordinates of points are switched to y, x or lat, lon.
If the optional keyword 'radians' is True (default is False),
then all input and output coordinates will be in radians instead
of the default of degrees for geographic input/output projections.
If the optional keyword 'errcheck' is set to True an
exception is raised if the transformation is
invalid. By default errcheck=False and ``inf`` is returned for an
invalid transformation (and no exception is raised).
If the optional kwarg skip_equivalent is true (default is False),
it will skip the transformation operation if input and output
projections are equivalent. If `always_xy` is toggled, the
transform method will accept as input and return as output
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coordinates using the traditional gis order, that is longitude, latitude
for geographic CRS and easting, northing for most projected CRS.
Example usage:
>>> from pyproj import Proj, itransform
>>> # projection 1: WGS84
>>> # (defined by epsg code 4326)
>>> p1 = Proj('epsg:4326', preserve_units=False)
>>> # projection 2: GGRS87 / Greek Grid
>>> p2 = Proj('epsg:2100', preserve_units=False)
>>> # Three points with coordinates lon, lat in p1
>>> points = [(22.95, 40.63), (22.81, 40.53), (23.51, 40.86)]
>>> # transform this point to projection 2 coordinates.
>>> for pt in itransform(p1,p2,points, always_xy=True): '%6.3f %7.3f' % pt
'411050.470 4497928.574'
'399060.236 4486978.710'
'458553.243 4523045.485'
>>> for pt in itransform(4326, 4326, [(30, 60)], skip_equivalent=True):
... '{:.0f} {:.0f}'.format(*pt)
'30 60'
"""
warnings.warn(
(
"This function is deprecated. "
"See: https://pyproj4.github.io/pyproj/stable/"
"gotchas.html#upgrading-to-pyproj-2-from-pyproj-1"
),
DeprecationWarning,
stacklevel=2,
)
return Transformer.from_proj(
p1, p2, skip_equivalent=skip_equivalent, always_xy=always_xy
).itransform(
points, switch=switch, time_3rd=time_3rd, radians=radians, errcheck=errcheck
)