qgisprocess

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The goal of qgisprocess is to provide an R interface to the geoprocessing algorithms of QGIS, a popular and open source desktop geographic information system (GIS) program. The package is a re-implementation of functionality provided by the archived RQGIS package, which was partially revived in the RQGIS3 package.

Installation

qgisprocess

To install the latest CRAN release, just run:

install.packages("qgisprocess")

You can install the development version from GitHub with:

# install.packages("remotes")
remotes::install_github("r-spatial/qgisprocess")

QGIS

The qgisprocess package wraps the standalone qgis_process command-line utility, which is available in QGIS >= 3.16.

The package is meant to support current QGIS releases, i.e. both the latest and the long-term release. Although older QGIS releases are not officially supported, it may work since QGIS 3.16. Installation instructions for all platforms are available at https://download.qgis.org/.

If a recent version of QGIS isn’t available for your OS, you can use the Geocomputation with R Docker image with QGIS installed (docker pull ghcr.io/geocompx/docker:qgis). See the vignette on ‘getting started’ for more information.

Package configuration

If the automatic configuration fails (or if you have more than one QGIS installation and would like to choose which one is used), you can set options(qgisprocess.path = "path/to/qgis_process"). Specify the qgisprocess.path option in your .Rprofile, to make your choices persistent between sessions. You can run qgis_configure() to reconfigure the package, or just qgis_configure(use_cached_data = TRUE) to see the gritty details!

library(qgisprocess)
#> Attempting to load the package cache ... Success!
#> QGIS version: 3.38.0-Grenoble
#> Having access to 2059 algorithms from 18 QGIS processing providers.
#> Run `qgis_configure(use_cached_data = TRUE)` to reload cache and get more details.

Functionality

Most functions start with the qgis_ prefix, so that functions can be found more easily using tab completion.

The main function is qgis_run_algorithm(algorithm = , ...). It specifies the geoprocessing algorithm to be called with a "provider:algorithm" formatted identifier, e.g. "native:convexhull" or "gdal:hillshade", and it passes the algorithm arguments as R function arguments.

Additional functions are provided to discover available geoprocessing algorithms, retrieve their documentation, handle processing results, manage QGIS plugins, and more.

Spatial layers can be passed to qgis_run_algorithm() as file paths but also as sf, stars, terra or raster objects.

A structured overview of functions is available at https://r-spatial.github.io/qgisprocess/reference/index.html. To get started, read the ‘getting started’ vignette and use the cheat sheets!

Note that R package qgis extends on qgisprocess by providing a separate R function for each geoprocessing algorithm. In addition, it makes the QGIS algorithm documentation available in the corresponding R function documentation.

Example

The following example demonstrates the buffer algorithm in action.

input <- sf::read_sf(system.file("shape/nc.shp", package = "sf"))

result <- qgis_run_algorithm(
  "native:buffer",
  INPUT = input,
  DISTANCE = 1,
  DISSOLVE = TRUE
)
#> Argument `SEGMENTS` is unspecified (using QGIS default value).
#> Using `END_CAP_STYLE = "Round"`
#> Using `JOIN_STYLE = "Round"`
#> Argument `MITER_LIMIT` is unspecified (using QGIS default value).
#> Argument `SEPARATE_DISJOINT` is unspecified (using QGIS default value).
#> Using `OUTPUT = qgis_tmp_vector()`
#> Using non-preferred coordinate operation between EPSG:4267 and EPSG:4326. Using +proj=pipeline +step +proj=unitconvert +xy_in=deg +xy_out=rad +step +proj=push +v_3 +step +proj=cart +ellps=clrk66 +step +proj=helmert +x=-10 +y=158 +z=187 +step +inv +proj=cart +ellps=WGS84 +step +proj=pop +v_3 +step +proj=unitconvert +xy_in=rad +xy_out=deg, preferred +proj=pipeline +step +proj=unitconvert +xy_in=deg +xy_out=rad +step +proj=hgridshift +grids=ca_nrc_ntv2_0.tif +step +proj=unitconvert +xy_in=rad +xy_out=deg.

result
#> <Result of `qgis_run_algorithm("native:buffer", ...)`>
#> List of 1
#>  $ OUTPUT: 'qgis_outputVector' chr "/tmp/RtmphNqw6p/file1d6937316438/file1d6950ffc83a.gpkg"

output_sf <- sf::st_as_sf(result)
plot(sf::st_geometry(output_sf))

Some tips

You can search for algorithms with qgis_search_algorithms() (string matching with regex).

qgis_search_algorithms(algorithm = "buffer", group = "[Vv]ector")
#> # A tibble: 10 × 5
#>    provider provider_title    group                algorithm     algorithm_title
#>    <chr>    <chr>             <chr>                <chr>         <chr>          
#>  1 gdal     GDAL              Vector geoprocessing gdal:bufferv… Buffer vectors 
#>  2 gdal     GDAL              Vector geoprocessing gdal:oneside… One side buffer
#>  3 grass    GRASS             Vector (v.*)         grass:v.buff… v.buffer       
#>  4 native   QGIS (native c++) Vector geometry      native:buffer Buffer         
#>  5 native   QGIS (native c++) Vector geometry      native:buffe… Variable width…
#>  6 native   QGIS (native c++) Vector geometry      native:multi… Multi-ring buf…
#>  7 native   QGIS (native c++) Vector geometry      native:singl… Single sided b…
#>  8 native   QGIS (native c++) Vector geometry      native:taper… Tapered buffers
#>  9 native   QGIS (native c++) Vector geometry      native:wedge… Create wedge b…
#> 10 sagang   SAGA Next Gen     Vector general       sagang:shape… Shapes buffer

You can read the help associated with an algorithm using qgis_show_help().

qgis_show_help("native:buffer")

A full list of available algorithms is returned by qgis_algorithms().

qgis_algorithms()
#> # A tibble: 2,059 × 24
#>    provider  provider_title algorithm               algorithm_id algorithm_title
#>    <chr>     <chr>          <chr>                   <chr>        <chr>          
#>  1 3d        QGIS (3D)      3d:tessellate           tessellate   Tessellate     
#>  2 NetworkGT NetworkGT      NetworkGT:1D Flow       1D Flow      1D Flow        
#>  3 NetworkGT NetworkGT      NetworkGT:2D Flow       2D Flow      2D Flow        
#>  4 NetworkGT NetworkGT      NetworkGT:Aperture      Aperture     Aperture       
#>  5 NetworkGT NetworkGT      NetworkGT:Branches and… Branches an… Branches and N…
#>  6 NetworkGT NetworkGT      NetworkGT:Clusters      Clusters     Define Clusters
#>  7 NetworkGT NetworkGT      NetworkGT:Configure     Configure    Configure Netw…
#>  8 NetworkGT NetworkGT      NetworkGT:Connect Y No… Connect Y N… Connect Y Nodes
#>  9 NetworkGT NetworkGT      NetworkGT:Contour Grid  Contour Grid Contour Grid   
#> 10 NetworkGT NetworkGT      NetworkGT:Define Fract… Define Frac… Define Fractur…
#> # ℹ 2,049 more rows
#> # ℹ 19 more variables: provider_can_be_activated <lgl>,
#> #   provider_is_active <lgl>, provider_long_name <chr>, provider_version <chr>,
#> #   provider_warning <chr>, can_cancel <lgl>, deprecated <lgl>, group <chr>,
#> #   has_known_issues <lgl>, help_url <chr>, requires_matching_crs <lgl>,
#> #   short_description <chr>, tags <list>, default_raster_file_extension <chr>,
#> #   default_vector_file_extension <chr>, …

It may also be useful to run an algorithm in the QGIS GUI to determine how the various input values are translated to string processing arguments. This can be done using the ‘Advanced’ dropdown, by copying either the qgis_process command string or the JSON string:

Note that the JSON string can be passed directly to qgis_run_algorithm()!

Code of Conduct

Please note that the qgisprocess project is released with a Contributor Code of Conduct. By contributing to this project, you agree to abide by its terms.

More information

Presentations

In the wild

(Draft)

Following case studies have used the package:

If you used the package in your work and would like to see it referenced here, then give a shout in issue #211 or make a pull request!

Further reading