python3-rasterio 0.36.0-2build5 / usr / lib / python3 / dist-packages / rasterio / warp.py

"""Raster warping and reprojection."""

from __future__ import absolute_import
from __future__ import division

from math import ceil
import warnings

from affine import Affine
import numpy as np

from rasterio._base import _transform
from rasterio._warp import (
    _transform_geom, _reproject, _calculate_default_transform)
from rasterio.enums import Resampling
from rasterio.env import ensure_env
from rasterio.transform import guard_transform


RESAMPLING = Resampling
warnings.warn(
    "RESAMPLING is deprecated, use Resampling instead.", DeprecationWarning)


@ensure_env
def transform(src_crs, dst_crs, xs, ys, zs=None):
    """Transform vectors from source to target coordinate reference system.

    Transform vectors of x, y and optionally z from source
    coordinate reference system into target.

    Parameters
    ------------
    src_crs: CRS or dict
        Source coordinate reference system, as a rasterio CRS object.
        Example: CRS({'init': 'EPSG:4326'})
    dst_crs: CRS or dict
        Target coordinate reference system.
    xs: array_like
        Contains x values.  Will be cast to double floating point values.
    ys:  array_like
        Contains y values.
    zs: array_like, optional
        Contains z values.  Assumed to be all 0 if absent.

    Returns
    ---------
    out: tuple of array_like, (xs, ys, [zs])
    Tuple of x, y, and optionally z vectors, transformed into the target
    coordinate reference system.
    """
    return _transform(src_crs, dst_crs, xs, ys, zs)


@ensure_env
def transform_geom(
        src_crs,
        dst_crs,
        geom,
        antimeridian_cutting=False,
        antimeridian_offset=10.0,
        precision=-1):
    """Transform geometry from source coordinate reference system into target.

    Parameters
    ------------
    src_crs: CRS or dict
        Source coordinate reference system, in rasterio dict format.
        Example: CRS({'init': 'EPSG:4326'})
    dst_crs: CRS or dict
        Target coordinate reference system.
    geom: GeoJSON like dict object
    antimeridian_cutting: bool, optional
        If True, cut geometries at the antimeridian, otherwise geometries will
        not be cut (default).
    antimeridian_offset: float
        Offset from the antimeridian in degrees (default: 10) within which
        any geometries will be split.
    precision: float
        If >= 0, geometry coordinates will be rounded to this number of decimal
        places after the transform operation, otherwise original coordinate
        values will be preserved (default).

    Returns
    ---------

    out: GeoJSON like dict object
        Transformed geometry in GeoJSON dict format
    """
    return _transform_geom(
        src_crs,
        dst_crs,
        geom,
        antimeridian_cutting,
        antimeridian_offset,
        precision)


@ensure_env
def transform_bounds(
        src_crs,
        dst_crs,
        left,
        bottom,
        right,
        top,
        densify_pts=21):
    """Transform bounds from src_crs to dst_crs.

    Optionally densifying the edges (to account for nonlinear transformations
    along these edges) and extracting the outermost bounds.

    Note: this does not account for the antimeridian.

    Parameters
    ----------
    src_crs: CRS or dict
        Source coordinate reference system, in rasterio dict format.
        Example: CRS({'init': 'EPSG:4326'})
    dst_crs: CRS or dict
        Target coordinate reference system.
    left, bottom, right, top: float
        Bounding coordinates in src_crs, from the bounds property of a raster.
    densify_pts: uint, optional
        Number of points to add to each edge to account for nonlinear
        edges produced by the transform process.  Large numbers will produce
        worse performance.  Default: 21 (gdal default).

    Returns
    -------
    left, bottom, right, top: float
        Outermost coordinates in target coordinate reference system.
    """
    if densify_pts < 0:
        raise ValueError('densify parameter must be >= 0')

    in_xs = []
    in_ys = []

    if densify_pts > 0:
        densify_factor = 1.0 / float(densify_pts + 1)

        # Add points along outer edges.
        for x in (left, right):
            in_xs.extend([x] * (densify_pts + 2))
            in_ys.extend(
                bottom + np.arange(0, densify_pts + 2, dtype=np.float32) *
                ((top - bottom) * densify_factor)
            )

        for y in (bottom, top):
            in_xs.extend(
                left + np.arange(1, densify_pts + 1, dtype=np.float32) *
                ((right - left) * densify_factor)
            )
            in_ys.extend([y] * densify_pts)

    else:
        in_xs = [left, left, right, right]
        in_ys = [bottom, top, bottom, top]

    xs, ys = transform(src_crs, dst_crs, in_xs, in_ys)
    return (min(xs), min(ys), max(xs), max(ys))


@ensure_env
def reproject(
        source,
        destination,
        src_transform=None,
        src_crs=None,
        src_nodata=None,
        dst_transform=None,
        dst_crs=None,
        dst_nodata=None,
        resampling=Resampling.nearest,
        **kwargs):
    """
    Reproject a source raster to a destination raster.

    If the source and destination are ndarrays, coordinate reference
    system definitions and affine transformation parameters are required
    for reprojection.

    If the source and destination are rasterio Bands, shorthand for
    bands of datasets on disk, the coordinate reference systems and
    transforms will be read from the appropriate datasets.

    Parameters
    ------------
    source: ndarray or rasterio Band
        Source raster.
    destination: ndarray or rasterio Band
        Target raster.
    src_transform: affine transform object, optional
        Source affine transformation.  Required if source and destination
        are ndarrays.  Will be derived from source if it is a rasterio Band.
    src_crs: CRS or dict, optional
        Source coordinate reference system, in rasterio dict format.
        Required if source and destination are ndarrays.
        Will be derived from source if it is a rasterio Band.
        Example: CRS({'init': 'EPSG:4326'})
    src_nodata: int or float, optional
        The source nodata value.  Pixels with this value will not be used
        for interpolation.  If not set, it will be default to the
        nodata value of the source image if a masked ndarray or rasterio band,
        if available.  Must be provided if dst_nodata is not None.
    dst_transform: affine transform object, optional
        Target affine transformation.  Required if source and destination
        are ndarrays.  Will be derived from target if it is a rasterio Band.
    dst_crs: CRS or dict, optional
        Target coordinate reference system.  Required if source and destination
        are ndarrays.  Will be derived from target if it is a rasterio Band.
    dst_nodata: int or float, optional
        The nodata value used to initialize the destination; it will remain
        in all areas not covered by the reprojected source.  Defaults to the
        nodata value of the destination image (if set), the value of
        src_nodata, or 0 (GDAL default).
    resampling: int
        Resampling method to use.  One of the following:
            Resampling.nearest,
            Resampling.bilinear,
            Resampling.cubic,
            Resampling.cubic_spline,
            Resampling.lanczos,
            Resampling.average,
            Resampling.mode
    kwargs:  dict, optional
        Additional arguments passed to transformation function.

    Returns
    ---------
    out: None
        Output is written to destination.
    """
    # Resampling guard.
    try:
        Resampling(resampling)
        if resampling == 7:
            raise ValueError
    except ValueError:
        raise ValueError(
            "resampling must be one of: {0}".format(", ".join(
                ['Resampling.{0}'.format(k) for k in
                 Resampling.__members__.keys() if k != 'gauss'])))

    # If working with identity transform, assume it is crs-less data
    # and that translating the matrix very slightly will avoid #674
    eps = 1e-100
    if src_transform and guard_transform(src_transform).is_identity:
        src_transform = src_transform.translation(eps, eps)
    if dst_transform and guard_transform(dst_transform).is_identity:
        dst_transform = dst_transform.translation(eps, eps)

    if src_transform:
        src_transform = guard_transform(src_transform).to_gdal()
    if dst_transform:
        dst_transform = guard_transform(dst_transform).to_gdal()

    # Passing None can cause segfault, use empty dict
    if src_crs is None:
        src_crs = {}
    if dst_crs is None:
        dst_crs = {}

    _reproject(
        source,
        destination,
        src_transform,
        src_crs,
        src_nodata,
        dst_transform,
        dst_crs,
        dst_nodata,
        resampling,
        **kwargs)


@ensure_env
def calculate_default_transform(
        src_crs,
        dst_crs,
        width,
        height,
        left,
        bottom,
        right,
        top,
        resolution=None):
    """Calculate parameters for reproject function.

    Transforms bounds to destination coordinate system, calculates resolution
    if not provided, and returns destination transform and dimensions.
    Intended to be used to calculate parameters for reproject function.

    Destination transform is anchored from the left, top coordinate.

    Destination width and height (and resolution if not provided), are
    calculated using GDAL's method for suggest warp output.

    Parameters
    ----------
    src_crs: CRS or dict
        Source coordinate reference system, in rasterio dict format.
        Example: CRS({'init': 'EPSG:4326'})
    dst_crs: CRS or dict
        Target coordinate reference system.
    width: int
        Source raster width.
    height: int
        Source raster height.
    left, bottom, right, top: float
        Bounding coordinates in src_crs, from the bounds property of a raster.
    resolution: tuple (x resolution, y resolution) or float, optional
        Target resolution, in units of target coordinate reference system.

    Returns
    -------
    tuple of destination affine transform, width, and height

    Note
    ----
    Should be called within a rasterio.Env() context

    Some behavior of this function is determined by the
    CHECK_WITH_INVERT_PROJ environment variable
        YES: constrain output raster to extents that can be inverted
             avoids visual artifacts and coordinate discontinuties.
        NO:  reproject coordinates beyond valid bound limits
    """
    dst_affine, dst_width, dst_height = _calculate_default_transform(
        src_crs, dst_crs,
        width, height,
        left, bottom, right, top)

    # If resolution is specified, Keep upper-left anchored
    # adjust the transform resolutions
    # adjust the width/height by the ratio of estimated:specified res (ceil'd)
    if resolution:

        # resolutions argument into tuple
        try:
            res = (float(resolution), float(resolution))
        except TypeError:
            res = (resolution[0], resolution[0]) \
                if len(resolution) == 1 else resolution[0:2]

        # Assume yres is provided as positive,
        # needs to be negative for north-up affine
        xres = res[0]
        yres = -res[1]

        xratio = dst_affine.a / xres
        yratio = dst_affine.e / yres

        dst_affine = Affine(xres, dst_affine.b, dst_affine.c,
                            dst_affine.d, yres, dst_affine.f)

        dst_width = ceil(dst_width * xratio)
        dst_height = ceil(dst_height * yratio)

    return dst_affine, dst_width, dst_height