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GeoArrays

Simple geographical raster interaction built on top of ArchGDAL, GDAL and CoordinateTransformations.

A GeoArray is an AbstractArray, an AffineMap for calculating coordinates based on the axes and a CRS definition to interpret these coordinates into in the real world. It's three dimensional and can be seen as a stack (3D) of 2D geospatial rasters (bands), the dimensions are :x, :y, and :bands. The AffineMap and CRS (coordinates) only operate on the :x and :y dimensions.

This packages takes its inspiration from Python's rasterio.

Installation

(v1.10) pkg> add GeoArrays

Examples

Basic Usage

Load the GeoArrays package.

julia> using GeoArrays

Read a GeoTIFF file and display its information, i.e. AffineMap and projection (CRS).

# Read TIF file
julia> fn = download("https://github.com/yeesian/ArchGDALDatasets/blob/master/data/utmsmall.tif?raw=true")
julia> geoarray = GeoArrays.read(fn)
100x100 Matrix{UInt8} with AffineMap([60.0 0.0; 0.0 -60.0], [440720.0, 3.75132e6]) and CRS PROJCS["NAD27 / UTM zone 11N"...

# Affinemap containing offset and scaling
julia> geoarray.f
AffineMap([60.0 0.0; 0.0 -60.0], [440720.0, 3.75132e6])

# WKT projection string
julia> geoarray.crs
GeoFormatTypes.WellKnownText{GeoFormatTypes.CRS}(GeoFormatTypes.CRS(), "PROJCS[\"NAD27 / UTM zone 11N\",GEOGCS[\"NAD27\",DATUM[\"North_American_Datum_1927\",SPHEROID[\"Clarke 1866\",6378206.4,294.978698213898,AUTHORITY[\"EPSG\",\"7008\"]],AUTHORITY[\"EPSG\",\"6267\"]],PRIMEM[\"Greenwich\",0],UNIT[\"degree\",0.0174532925199433,AUTHORITY[\"EPSG\",\"9122\"]],AUTHORITY[\"EPSG\",\"4267\"]],PROJECTION[\"Transverse_Mercator\"],PARAMETER[\"latitude_of_origin\",0],PARAMETER[\"central_meridian\",-117],PARAMETER[\"scale_factor\",0.9996],PARAMETER[\"false_easting\",500000],PARAMETER[\"false_northing\",0],UNIT[\"metre\",1,AUTHORITY[\"EPSG\",\"9001\"]],AXIS[\"Easting\",EAST],AXIS[\"Northing\",NORTH],AUTHORITY[\"EPSG\",\"26711\"]]")

Writing to GeoTIFF

Create a random GeoArray and write it to a GeoTIFF file.

# Create, reference and write a TIFF
julia> ga = GeoArray(rand(100,200))
julia> bbox!(ga, (min_x=2., min_y=51., max_x=5., max_y=54.))  # roughly the Netherlands
julia> epsg!(ga, 4326)  # in WGS84
julia> GeoArrays.write("test.tif", ga)
# Or write it with compression and tiling
julia> GeoArrays.write("test_compressed.tif", ga; options=Dict("TILED"=>"YES", "COMPRESS"=>"ZSTD"))

Streaming support

The package supports streaming reading.

# Read in 39774x60559x1 raster (AHN3), but without masking (missing) support
julia> @time ga = GeoArrays.read(fn, masked=false)
  0.001917 seconds (46 allocations: 2.938 KiB)
39774x60559x1 ArchGDAL.RasterDataset{Float32,ArchGDAL.IDataset} with AffineMap([1.0433425614165472e-6 0.0; 0.0 -1.0433425614165472e-6], [0.8932098305563291, 0.11903776654646055]) and CRS PROJCS["Amersfoort / RD New",GEOGCS["Amersfoort",DATUM["Amersfoort",SPHEROID["Bessel 1841",6377397.155,299.1528128,AUTHORITY["EPSG","7004"]],AUTHORITY["EPSG","6289"]],PRIMEM["Greenwich",0,AUTHORITY["EPSG","8901"]],UNIT["degree",0.0174532925199433,AUTHORITY["EPSG","9122"]],AUTHORITY["EPSG","4289"]],PROJECTION["Oblique_Stereographic"],PARAMETER["latitude_of_origin",52.1561605555556],PARAMETER["central_meridian",5.38763888888889],PARAMETER["scale_factor",0.9999079],PARAMETER["false_easting",155000],PARAMETER["false_northing",463000],UNIT["metre",1,AUTHORITY["EPSG","9001"]],AXIS["Easting",EAST],AXIS["Northing",NORTH],AUTHORITY["EPSG","28992"]]

Reading bands

GeoTIFFs can be large, with several bands, one can read.

When working with large rasters, e.g. with satellite images that can be GB in size, it is useful to be able to read only one band (or a selection of them) to GeoArray. When using read, one can specify the band.

# Get file
julia> fn = download("https://github.com/yeesian/ArchGDALDatasets/blob/master/pyrasterio/RGB.byte.tif?raw=true")

# Read band 2
julia> ga_band = GeoArrays.read(fn, masked=false, band=2)
791x718x1 Array{UInt8, 3} with AffineMap([300.0379266750948 0.0; 0.0 -300.041782729805], [101985.0, 2.826915e6]) and CRS PROJCS["UTM Zone 18, Northern Hemisphere",GEOGCS["Unknown datum based upon the WGS 84 ellipsoid",DATUM["Not_specified_based_on_WGS_84_spheroid",SPHEROID["WGS 84",6378137,298.257223563,AUTHORITY["EPSG","7030"]]],PRIMEM["Greenwich",0],UNIT["degree",0.0174532925199433,AUTHORITY["EPSG","9122"]]],PROJECTION["Transverse_Mercator"],PARAMETER["latitude_of_origin",0],PARAMETER["central_meridian",-75],PARAMETER["scale_factor",0.9996],PARAMETER["false_easting",500000],PARAMETER["false_northing",0],UNIT["metre",1,AUTHORITY["EPSG","9001"]],AXIS["Easting",EAST],AXIS["Northing",NORTH]]

In case there is missing data, the type will be a Union{Missing, T}. To convert to a GeoArray without missing, you can call coalesce(ga, value_to_replace_missing).

Reading NetCDFs

GeoArrays uses ArchGDAL.readraster to open geo raster datasets, and therefor supports reading formats other than geotiffs

To read a netcdf, the file name must include the prefix NETCDF: and the suffix :var, where var is the name of the NetCDF variable to be opened

# Get file
julia> fn = download("https://github.com/OSGeo/gdal/raw/master/autotest/gdrivers/data/netcdf/sentinel5p_fake.nc")

# variable to read 
julia> var = "my_var";
julia> ga_nc = GeoArrays.read("NETCDF:$fn:$var", masked=false)
61x89x1 ArchGDAL.RasterDataset{Float32, ArchGDAL.IDataset} with AffineMap([1.0 0.0; 0.0 1.0], [0.0, 0.0]) and undefined CRS

Using coordinates

GeoArrays have geographical coordinates for all array elements (pixels). They can be retrieved with the GeoArrays.coords function.

# Find coordinates by index
julia> GeoArrays.coords(geoarray, (1,1))
2-element StaticArrays.SArray{Tuple{2},Float64,1,2}:
 440720.0
      3.75132e6

All coordinates (tuples) are obtained as generator when omitting the index parameter.

# Find all coordinates
julia> collect(GeoArrays.coords(geoarray))
101×101 Matrix{StaticArraysCore.SVector{2, Float64}}:
 [440720.0, 3.75132e6]  [440720.0, 3.75126e6]  [440720.0, 3.7512e6] ...
 ...

Similarly, one can find the coordinates ranges of a GeoArray

julia> x, y = GeoArrays.ranges(geoarray)
(440750.0:60.0:446690.0, 3.75129e6:-60.0:3.74535e6)

The operation can be reversed, i.e. row and column index can be computed from coordinates with the indices function.

# Find index by coordinates
julia> indices(geoarray, [440720.0, 3.75132e6])
CartesianIndex(1, 1)

Manipulation

Basic GeoArray manipulation is implemented, e.g. translation.

# Translate complete raster by x + 100
julia> trans = Translation(100, 0)
julia> compose!(ga, trans)

When GeoArrays have the same dimensions, AffineMap and CRS, addition, subtraction, multiplication and division can be used.

# Math with GeoArrays (- + * /)
julia> GeoArray(rand(5,5,1)) - GeoArray(rand(5,5,1))
5x5x1 Array{Float64,3} with AffineMap([1.0 0.0; 0.0 1.0], [0.0, 0.0]) and undefined CRS

One can also warp an array, using GDAL behind the scenes. For example, we can vertically transform from the ellipsoid to the EGM2008 geoid using EPSG code 3855. Note that the underlying PROJ library needs to find the geoidgrids, so if they're not available locally, one needs to set ENV["PROJ_NETWORK"] = "ON" as early as possible, ideally before loading GeoArrays, or use enable_online_warp.

enable_online_warp()  # If you don't have PROJ grids locally
ga = GeoArray(zeros((360, 180)))
bbox!(ga, Extent(X(-180, 180), Y(-90, 90)))
crs!(ga, GeoFormatTypes.EPSG(4979))  # WGS83 in 3D (reference to ellipsoid)
ga2 = GeoArrays.warp(ga, Dict("t_srs" => "EPSG:4326+3855"))

Nodata filling

GeoArrays with missing data can be filled with the fill! function.

julia> using GeoStatsSolvers  # or any estimation solver from the GeoStats ecosystem
julia> ga = GeoArray(Array{Union{Missing, Float64}}(rand(5, 1)))
julia> ga.A[2,1] = missing
[:, :, 1] =
 0.6760718768442127
  missing
 0.852882193026649
 0.7137410453351622
 0.5949409082233854
julia> GeoArrays.fill!(ga, IDW(:band => (neighbors=3,)))  # band is the hardcoded variable
[:, :, 1] =
 0.6760718768442127
 0.7543298370153771
 0.852882193026649
 0.7137410453351622
 0.5949409082233854

Plotting

Individual bands from a GeoArray can be plotted with the plot function. By default the first band is used.

# Plot a GeoArray
julia> using Plots
julia> fn = download("https://github.com/yeesian/ArchGDALDatasets/blob/master/pyrasterio/RGB.byte.tif?raw=true")
julia> ga = GeoArrays.read(fn)
julia> plot(ga)

# or plot a band other than the first one
julia> plot(ga, band=2)

example plot

Note that for larger GeoArrays, only a sample of the data is plotted for performance. By default the sample size is twice figure size. You can control this factor by calling plot(ga, scalefactor=2), where higher scalefactor yields higher sizes, up to the original GeoArray size.

Subsetting arrays

GeoArrays can be subset by row, column and band using the array subsetting notation, e.g. ga[100:200, 200:300, 1:2].

# Get file
julia> fn = download("https://github.com/yeesian/ArchGDALDatasets/blob/master/pyrasterio/RGB.byte.tif?raw=true")

# Read the entire file
julia> ga = GeoArrays.read(fn);

julia> ga.f
AffineMap([300.0379266750948 0.0; 0.0 -300.041782729805], [101985.0, 2.826915e6])

julia> ga_sub = ga[200:500,200:400,begin:end]
301x201x3 Array{Union{Missing, UInt8}, 3} with AffineMap([300.0379266750948 0.0; 0.0 -300.041782729805], [161692.54740834387, 2.767206685236769e6]) and CRS PROJCS["UTM Zone 18, Northern Hemisphere",GEOGCS["Unknown datum based upon the WGS 84 ellipsoid",DATUM["Not_specified_based_on_WGS_84_spheroid",SPHEROID["WGS 84",6378137,298.257223563,AUTHORITY["EPSG","7030"]]],PRIMEM["Greenwich",0],UNIT["degree",0.0174532925199433,AUTHORITY["EPSG","9122"]]],PROJECTION["Transverse_Mercator"],PARAMETER["latitude_of_origin",0],PARAMETER["central_meridian",-75],PARAMETER["scale_factor",0.9996],PARAMETER["false_easting",500000],PARAMETER["false_northing",0],UNIT["metre",1,AUTHORITY["EPSG","9001"]],AXIS["Easting",EAST],AXIS["Northing",NORTH]]

julia> ga_sub.f
AffineMap([300.0379266750948 0.0; 0.0 -300.041782729805], [161692.54740834387, 2.767206685236769e6])

julia> plot(ga_sub)

example plot

Profile

You can sample the values along a line in a GeoArray with profile(ga, linestring). The linestring can be any geometry that supports GeoInterface.jl.

Alternatives

GeoArrays.jl was written to quickly save a geospatial Array to disk. Its functionality mimics rasterio in Python. If one requires more features---such as rasterization or zonal stats---which also work on NetCDF files, Rasters.jl is a good alternative. Its functionality is more like (rio)xarray in Python. NCDatasets is a great Julia package if working exclusively with NetCDF files.