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468 lines
16 KiB
Python
468 lines
16 KiB
Python
5 years ago
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import json
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import os
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import sys
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import uuid
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from ctypes import (
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addressof, byref, c_buffer, c_char_p, c_double, c_int, c_void_p, string_at,
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)
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from django.contrib.gis.gdal.driver import Driver
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from django.contrib.gis.gdal.error import GDALException
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from django.contrib.gis.gdal.prototypes import raster as capi
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from django.contrib.gis.gdal.raster.band import BandList
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from django.contrib.gis.gdal.raster.base import GDALRasterBase
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from django.contrib.gis.gdal.raster.const import (
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GDAL_RESAMPLE_ALGORITHMS, VSI_DELETE_BUFFER_ON_READ,
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VSI_FILESYSTEM_BASE_PATH, VSI_TAKE_BUFFER_OWNERSHIP,
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)
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from django.contrib.gis.gdal.srs import SpatialReference, SRSException
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from django.contrib.gis.geometry import json_regex
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from django.utils.encoding import force_bytes, force_str
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from django.utils.functional import cached_property
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class TransformPoint(list):
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indices = {
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'origin': (0, 3),
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'scale': (1, 5),
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'skew': (2, 4),
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}
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def __init__(self, raster, prop):
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x = raster.geotransform[self.indices[prop][0]]
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y = raster.geotransform[self.indices[prop][1]]
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super().__init__([x, y])
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self._raster = raster
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self._prop = prop
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@property
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def x(self):
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return self[0]
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@x.setter
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def x(self, value):
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gtf = self._raster.geotransform
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gtf[self.indices[self._prop][0]] = value
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self._raster.geotransform = gtf
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@property
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def y(self):
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return self[1]
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@y.setter
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def y(self, value):
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gtf = self._raster.geotransform
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gtf[self.indices[self._prop][1]] = value
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self._raster.geotransform = gtf
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class GDALRaster(GDALRasterBase):
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"""
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Wrap a raster GDAL Data Source object.
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"""
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destructor = capi.close_ds
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def __init__(self, ds_input, write=False):
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self._write = 1 if write else 0
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Driver.ensure_registered()
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# Preprocess json inputs. This converts json strings to dictionaries,
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# which are parsed below the same way as direct dictionary inputs.
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if isinstance(ds_input, str) and json_regex.match(ds_input):
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ds_input = json.loads(ds_input)
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# If input is a valid file path, try setting file as source.
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if isinstance(ds_input, str):
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try:
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# GDALOpen will auto-detect the data source type.
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self._ptr = capi.open_ds(force_bytes(ds_input), self._write)
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except GDALException as err:
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raise GDALException('Could not open the datasource at "{}" ({}).'.format(ds_input, err))
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elif isinstance(ds_input, bytes):
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# Create a new raster in write mode.
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self._write = 1
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# Get size of buffer.
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size = sys.getsizeof(ds_input)
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# Pass data to ctypes, keeping a reference to the ctypes object so
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# that the vsimem file remains available until the GDALRaster is
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# deleted.
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self._ds_input = c_buffer(ds_input)
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# Create random name to reference in vsimem filesystem.
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vsi_path = os.path.join(VSI_FILESYSTEM_BASE_PATH, str(uuid.uuid4()))
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# Create vsimem file from buffer.
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capi.create_vsi_file_from_mem_buffer(
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force_bytes(vsi_path),
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byref(self._ds_input),
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size,
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VSI_TAKE_BUFFER_OWNERSHIP,
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)
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# Open the new vsimem file as a GDALRaster.
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try:
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self._ptr = capi.open_ds(force_bytes(vsi_path), self._write)
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except GDALException:
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# Remove the broken file from the VSI filesystem.
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capi.unlink_vsi_file(force_bytes(vsi_path))
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raise GDALException('Failed creating VSI raster from the input buffer.')
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elif isinstance(ds_input, dict):
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# A new raster needs to be created in write mode
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self._write = 1
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# Create driver (in memory by default)
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driver = Driver(ds_input.get('driver', 'MEM'))
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# For out of memory drivers, check filename argument
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if driver.name != 'MEM' and 'name' not in ds_input:
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raise GDALException('Specify name for creation of raster with driver "{}".'.format(driver.name))
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# Check if width and height where specified
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if 'width' not in ds_input or 'height' not in ds_input:
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raise GDALException('Specify width and height attributes for JSON or dict input.')
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# Check if srid was specified
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if 'srid' not in ds_input:
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raise GDALException('Specify srid for JSON or dict input.')
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# Create null terminated gdal options array.
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papsz_options = []
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for key, val in ds_input.get('papsz_options', {}).items():
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option = '{}={}'.format(key, val)
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papsz_options.append(option.upper().encode())
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papsz_options.append(None)
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# Convert papszlist to ctypes array.
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papsz_options = (c_char_p * len(papsz_options))(*papsz_options)
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# Create GDAL Raster
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self._ptr = capi.create_ds(
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driver._ptr,
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force_bytes(ds_input.get('name', '')),
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ds_input['width'],
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ds_input['height'],
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ds_input.get('nr_of_bands', len(ds_input.get('bands', []))),
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ds_input.get('datatype', 6),
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byref(papsz_options),
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)
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# Set band data if provided
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for i, band_input in enumerate(ds_input.get('bands', [])):
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band = self.bands[i]
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if 'nodata_value' in band_input:
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band.nodata_value = band_input['nodata_value']
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# Instantiate band filled with nodata values if only
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# partial input data has been provided.
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if band.nodata_value is not None and (
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'data' not in band_input or
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'size' in band_input or
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'shape' in band_input):
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band.data(data=(band.nodata_value,), shape=(1, 1))
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# Set band data values from input.
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band.data(
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data=band_input.get('data'),
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size=band_input.get('size'),
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shape=band_input.get('shape'),
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offset=band_input.get('offset'),
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)
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# Set SRID
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self.srs = ds_input.get('srid')
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# Set additional properties if provided
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if 'origin' in ds_input:
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self.origin.x, self.origin.y = ds_input['origin']
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if 'scale' in ds_input:
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self.scale.x, self.scale.y = ds_input['scale']
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if 'skew' in ds_input:
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self.skew.x, self.skew.y = ds_input['skew']
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elif isinstance(ds_input, c_void_p):
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# Instantiate the object using an existing pointer to a gdal raster.
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self._ptr = ds_input
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else:
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raise GDALException('Invalid data source input type: "{}".'.format(type(ds_input)))
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def __del__(self):
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if self.is_vsi_based:
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# Remove the temporary file from the VSI in-memory filesystem.
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capi.unlink_vsi_file(force_bytes(self.name))
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super().__del__()
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def __str__(self):
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return self.name
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def __repr__(self):
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"""
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Short-hand representation because WKB may be very large.
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"""
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return '<Raster object at %s>' % hex(addressof(self._ptr))
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def _flush(self):
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"""
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Flush all data from memory into the source file if it exists.
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The data that needs flushing are geotransforms, coordinate systems,
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nodata_values and pixel values. This function will be called
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automatically wherever it is needed.
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"""
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# Raise an Exception if the value is being changed in read mode.
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if not self._write:
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raise GDALException('Raster needs to be opened in write mode to change values.')
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capi.flush_ds(self._ptr)
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@property
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def vsi_buffer(self):
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if not self.is_vsi_based:
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return None
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# Prepare an integer that will contain the buffer length.
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out_length = c_int()
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# Get the data using the vsi file name.
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dat = capi.get_mem_buffer_from_vsi_file(
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force_bytes(self.name),
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byref(out_length),
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VSI_DELETE_BUFFER_ON_READ,
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)
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# Read the full buffer pointer.
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return string_at(dat, out_length.value)
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@cached_property
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def is_vsi_based(self):
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return self.name.startswith(VSI_FILESYSTEM_BASE_PATH)
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@property
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def name(self):
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"""
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Return the name of this raster. Corresponds to filename
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for file-based rasters.
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"""
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return force_str(capi.get_ds_description(self._ptr))
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@cached_property
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def driver(self):
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"""
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Return the GDAL Driver used for this raster.
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"""
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ds_driver = capi.get_ds_driver(self._ptr)
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return Driver(ds_driver)
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@property
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def width(self):
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"""
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Width (X axis) in pixels.
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"""
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return capi.get_ds_xsize(self._ptr)
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@property
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def height(self):
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"""
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Height (Y axis) in pixels.
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"""
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return capi.get_ds_ysize(self._ptr)
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@property
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def srs(self):
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"""
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Return the SpatialReference used in this GDALRaster.
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"""
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try:
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wkt = capi.get_ds_projection_ref(self._ptr)
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if not wkt:
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return None
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return SpatialReference(wkt, srs_type='wkt')
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except SRSException:
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return None
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@srs.setter
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def srs(self, value):
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"""
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Set the spatial reference used in this GDALRaster. The input can be
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a SpatialReference or any parameter accepted by the SpatialReference
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constructor.
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"""
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if isinstance(value, SpatialReference):
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srs = value
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elif isinstance(value, (int, str)):
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srs = SpatialReference(value)
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else:
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raise ValueError('Could not create a SpatialReference from input.')
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capi.set_ds_projection_ref(self._ptr, srs.wkt.encode())
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self._flush()
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@property
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def srid(self):
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"""
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Shortcut to access the srid of this GDALRaster.
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"""
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return self.srs.srid
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@srid.setter
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def srid(self, value):
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"""
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Shortcut to set this GDALRaster's srs from an srid.
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"""
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self.srs = value
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@property
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def geotransform(self):
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"""
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Return the geotransform of the data source.
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Return the default geotransform if it does not exist or has not been
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set previously. The default is [0.0, 1.0, 0.0, 0.0, 0.0, -1.0].
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"""
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# Create empty ctypes double array for data
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gtf = (c_double * 6)()
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capi.get_ds_geotransform(self._ptr, byref(gtf))
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return list(gtf)
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@geotransform.setter
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def geotransform(self, values):
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"Set the geotransform for the data source."
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if len(values) != 6 or not all(isinstance(x, (int, float)) for x in values):
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raise ValueError('Geotransform must consist of 6 numeric values.')
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# Create ctypes double array with input and write data
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values = (c_double * 6)(*values)
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capi.set_ds_geotransform(self._ptr, byref(values))
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self._flush()
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@property
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def origin(self):
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"""
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Coordinates of the raster origin.
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"""
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return TransformPoint(self, 'origin')
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@property
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def scale(self):
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"""
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Pixel scale in units of the raster projection.
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"""
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return TransformPoint(self, 'scale')
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@property
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def skew(self):
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"""
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Skew of pixels (rotation parameters).
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"""
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return TransformPoint(self, 'skew')
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@property
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def extent(self):
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"""
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Return the extent as a 4-tuple (xmin, ymin, xmax, ymax).
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"""
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# Calculate boundary values based on scale and size
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xval = self.origin.x + self.scale.x * self.width
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yval = self.origin.y + self.scale.y * self.height
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# Calculate min and max values
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xmin = min(xval, self.origin.x)
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xmax = max(xval, self.origin.x)
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ymin = min(yval, self.origin.y)
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ymax = max(yval, self.origin.y)
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return xmin, ymin, xmax, ymax
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@property
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def bands(self):
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return BandList(self)
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def warp(self, ds_input, resampling='NearestNeighbour', max_error=0.0):
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"""
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Return a warped GDALRaster with the given input characteristics.
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The input is expected to be a dictionary containing the parameters
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of the target raster. Allowed values are width, height, SRID, origin,
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scale, skew, datatype, driver, and name (filename).
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By default, the warp functions keeps all parameters equal to the values
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of the original source raster. For the name of the target raster, the
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name of the source raster will be used and appended with
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_copy. + source_driver_name.
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In addition, the resampling algorithm can be specified with the "resampling"
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input parameter. The default is NearestNeighbor. For a list of all options
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consult the GDAL_RESAMPLE_ALGORITHMS constant.
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"""
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# Get the parameters defining the geotransform, srid, and size of the raster
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ds_input.setdefault('width', self.width)
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ds_input.setdefault('height', self.height)
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ds_input.setdefault('srid', self.srs.srid)
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ds_input.setdefault('origin', self.origin)
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ds_input.setdefault('scale', self.scale)
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ds_input.setdefault('skew', self.skew)
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# Get the driver, name, and datatype of the target raster
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ds_input.setdefault('driver', self.driver.name)
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if 'name' not in ds_input:
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ds_input['name'] = self.name + '_copy.' + self.driver.name
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if 'datatype' not in ds_input:
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ds_input['datatype'] = self.bands[0].datatype()
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# Instantiate raster bands filled with nodata values.
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ds_input['bands'] = [{'nodata_value': bnd.nodata_value} for bnd in self.bands]
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# Create target raster
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target = GDALRaster(ds_input, write=True)
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# Select resampling algorithm
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algorithm = GDAL_RESAMPLE_ALGORITHMS[resampling]
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# Reproject image
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capi.reproject_image(
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self._ptr, self.srs.wkt.encode(),
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target._ptr, target.srs.wkt.encode(),
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algorithm, 0.0, max_error,
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c_void_p(), c_void_p(), c_void_p()
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)
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# Make sure all data is written to file
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target._flush()
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return target
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def transform(self, srid, driver=None, name=None, resampling='NearestNeighbour',
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max_error=0.0):
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||
|
"""
|
||
|
Return a copy of this raster reprojected into the given SRID.
|
||
|
"""
|
||
|
# Convert the resampling algorithm name into an algorithm id
|
||
|
algorithm = GDAL_RESAMPLE_ALGORITHMS[resampling]
|
||
|
|
||
|
# Instantiate target spatial reference system
|
||
|
target_srs = SpatialReference(srid)
|
||
|
|
||
|
# Create warped virtual dataset in the target reference system
|
||
|
target = capi.auto_create_warped_vrt(
|
||
|
self._ptr, self.srs.wkt.encode(), target_srs.wkt.encode(),
|
||
|
algorithm, max_error, c_void_p()
|
||
|
)
|
||
|
target = GDALRaster(target)
|
||
|
|
||
|
# Construct the target warp dictionary from the virtual raster
|
||
|
data = {
|
||
|
'srid': srid,
|
||
|
'width': target.width,
|
||
|
'height': target.height,
|
||
|
'origin': [target.origin.x, target.origin.y],
|
||
|
'scale': [target.scale.x, target.scale.y],
|
||
|
'skew': [target.skew.x, target.skew.y],
|
||
|
}
|
||
|
|
||
|
# Set the driver and filepath if provided
|
||
|
if driver:
|
||
|
data['driver'] = driver
|
||
|
|
||
|
if name:
|
||
|
data['name'] = name
|
||
|
|
||
|
# Warp the raster into new srid
|
||
|
return self.warp(data, resampling=resampling, max_error=max_error)
|
||
|
|
||
|
@property
|
||
|
def info(self):
|
||
|
"""
|
||
|
Return information about this raster in a string format equivalent
|
||
|
to the output of the gdalinfo command line utility.
|
||
|
"""
|
||
|
if not capi.get_ds_info:
|
||
|
raise ValueError('GDAL ≥ 2.1 is required for using the info property.')
|
||
|
return capi.get_ds_info(self.ptr, None).decode()
|