Automatic search and find of the installed GIS software binaries is performed by the
find functions. Depending of you OS and the number of installed versions you will get a dataframe providing the binary and module folders.
# find all SAGA GIS installations at the default search location require(link2GI) saga <- link2GI::findSAGA() saga
# find all SAGA GIS installations at the default search location require(link2GI) grass <- link2GI::findGRASS() grass otb <- link2GI::findOTB() otb
find functions are providing an overview of the installed software. This functions are not establishing any linkages or changing settings.
If you just call link2GI on the fly , that means for a single temporary operation, there will be no need for setting up folders and project structures. If you work on a more complex project it is seems to be helpful to support this by a fixed structure. Same with existing
GRASS projects wich need to be in specific mapsets and locations.
A straightforward (you may call it also dirty) approach is the ìnitProjfunction that creates folder structures (if not existing) and establishes (if wanted) global variables containing the pathes as strings.
# find all SAGA GIS installations at the default search location require(link2GI) link2GI::initProj(projRootDir = tempdir(), projFolders = c("data/", "data/level0/", "data/level1/", "output/", "run/", "fun/"), path_prefix = "path_to_" , global =TRUE)
In earlier times it has been pretty cumbersome to link the correct
SAGA GIS version. Since the version 1.x.x of
RSAGA things turned much better. The new
RSAGA::rsaga.env() function is at getting the first
RSAGA version in the search path. For using
link2GI it is strongly recommended to call
RSAGA.env() with the preferred path as provided by a '
findSAGA() call. It is also possible to provide the version number as shown below. Storing the result in adequate variables will then even give the opportunity to easyly switch between different
SAGA GIS installations.
saga1<-link2GI::linkSAGA(ver_select = 1) saga1 sagaEnv1<- RSAGA::rsaga.env(path = saga1$sagaPath)
linkGRASS7 Initializes the session environment and the system paths for an easy access to
GRASS GIS 7.x. The correct setup of the spatial and projection parameters is automatically performed by using either an existing and valid
sf object, or manually by providing a list containing the minimum parameters needed. These properties are used to initialize either a temporary or a permanent
rgrass7 environment including the correct
GRASS 7 database structure. If you provide none of the before mentioned objects
linkGRASS will create a EPSG:4326 world wide location.
The most time consuming part on 'Windows' Systems is the search process. This can easily take 10 or more minutes. To speed up this process you can also provide a correct parameter set. Best way to do so is to call manually
findGRASS. Then call
linkGRASS7 with the returned version arguments of your choice.
linkGRASS7 tries to find all valid
GRASS GIS binaries by analyzing the startup script files of
GRASS GIS. After identifying the
GRASS GIS binaries all necessary system variables and settings will be generated and passed to a temporary
If you have more than one valid installation and run
linkGRASS7 with the arguments
select_ver = TRUE, then you will be ask to select one.
The most common way to use
GRASS is just for one call or algorithm. So the user is not interested in the cumbersome setting up of all parameters.
linGRASS7(georeferenced-dataset) does an automatic search and find all
GRASS binaries using the georeferenced-dataset object for spatial referencing and the necessary other settings.
NOTE: This is the highly recommended linking procedure for all on the fly calls of
GRASS. Please note also: If more than one
GRASS installation is found the one with the highest version number is selected automatically.
Have a look at the following examples which show a typical call for the well known
sf vector data objects.
# get meuse data as sp object and link it temporary to GRASS require(link2GI) require(sp) # get data data(meuse) # add georeference coordinates(meuse) <- ~x+y proj4string(meuse) <-CRS("+init=epsg:28992") # Automatic search and find of GRASS binaries # using the meuse sp data object for spatial referencing # This is the highly recommended linking procedure for on the fly jobs # NOTE: if more than one GRASS installation is found the highest version will be choosed linkGRASS7(meuse)
Now do the same with
sf based data.
require(link2GI) require(sf) # get data nc <- st_read(system.file("shape/nc.shp", package="sf")) # Automatic search and find of GRASS binaries # using the nc sf data object for spatial referencing # This is the highly recommended linking procedure for on the fly jobs # NOTE: if more than one GRASS installation is found the highest version will be choosed grass<-linkGRASS7(nc,returnPaths = TRUE)
The second most common situation is the usage of an existing
GRASS location and project either with existing data sets or manually provided parameters.
library(link2GI) require(sf) # proj folders projRootDir<-tempdir() paths<-link2GI::initProj(projRootDir = projRootDir, projFolders = c("project1/")) # get data nc <- st_read(system.file("shape/nc.shp", package="sf")) # CREATE and link to a permanent GRASS folder at "projRootDir", location named "project1" linkGRASS7(nc, gisdbase = projRootDir, location = "project1") # ONLY LINK to a permanent GRASS folder at "projRootDir", location named "project1" linkGRASS7(gisdbase = projRootDir, location = "project1", gisdbase_exist = TRUE ) # setting up GRASS manually with spatial parameters of the nc data proj4_string <- as.character(sp::CRS("+init=epsg:28992")) linkGRASS7(spatial_params = c(178605,329714,181390,333611,proj4_string)) # creating a GRASS gisdbase manually with spatial parameters of the nc data # additionally using a peramanent directory "projRootDir" and the location "nc_spatial_params " proj4_string <- as.character(sp::CRS("+init=epsg:4267")) linkGRASS7(gisdbase = projRootDir, location = "nc_spatial_params", spatial_params = c(-84.32385, 33.88199,-75.45698,36.58965,proj4_string))
The full disk search can be cumbersome especially running Windos it can easily take 10 minutes and more. So it is helpful to provide a searchpath for narrowing down the search. Searching for
GRASS installations in the home directory you may use the following command.
# Link the GRASS installation and define the search location linkGRASS7(nc, search_path = "~")
If you already did a full search and kow your installation fo example using the command
findGRASS you can use the result directly for linking.
findGRASS() instDir version installation_type 1 /opt/grass 7.8.1 grass78 # now linking it linkGRASS7(nc,c("/opt/grass","7.8.15","grass78")) # corresponding linkage running windows linkGRASS7(nc,c("C:/Program Files/GRASS GIS7.0.5","GRASS GIS 7.0.5","NSIS"))
Finally some more specific examples related to interactive selection or OS specific settings.
Choose manually the
GRASS installation additionally using the meuse
sf object for spatial referencing
linkGRASS7(nc, ver_select = TRUE)
Creating and linking a permanent
GRASS gisdbase (folder structure) at “~/temp3” with the standard mapset “PERMANENT”“ and the location named "project1”. For all spatial attributes use the the meuse
linkGRASS7(x = nc, gisdbase = "~/temp3", location = "project1")
Link to the permanent
GRASS gisdbase (folder structure) at “~/temp3” with the standard mapset “PERMANENT” and the location named “project1”. For all spatial attributes use the formerly referencend nc
sf object parameter.
linkGRASS7(gisdbase = "~/temp3", location = "project1", gisdbase_exist = TRUE)
GRASS manually with spatial parameters of the meuse data
linkGRASS7(spatial_params = c(178605,329714,181390,333611, "+proj=sterea +lat_0=52.15616055555555 +lon_0=5.38763888888889 +k=0.9999079 +x_0=155000 +y_0=463000 +no_defs +a=6377397.155 +rf=299.1528128 +towgs84=565.4171,50.3319,465.5524, -0.398957,0.343988,-1.8774,4.0725 +to_meter=1"))
link2GI supports the use of the Orfeo Toolbox with a listbased simple wrapper function. Actually two functions parse the modules and functions syntax dumps and generate a command list that is easy to modify with the necessary arguments.
Usually you have to get the module list first:
# link to the installed OTB otblink<-link2GI::linkOTB() # get the list of modules from the linked version algo<-parseOTBAlgorithms(gili = otblink)
Based on the modules of the current version of
OTB you can then choose the module(s) you want to use.
## for the example we use the edge detection, algoKeyword<- "EdgeExtraction" ## extract the command list for the choosen algorithm cmd<-parseOTBFunction(algo = algoKeyword, gili = otblink) ## print the current command print(cmd)
Admittedly this is a very straightforward and preliminary approach. Nevertheless it provids you a valid list of all
OTB API calls that can easily manipulated for your needs. The following working example will give you an idea how to use it.
require(link2GI) require(raster) require(listviewer) otblink<-link2GI::linkOTB() projRootDir<-tempdir() data('rgb', package = 'link2GI') raster::plotRGB(rgb) r<-raster::writeRaster(rgb, filename=file.path(projRootDir,"test.tif"), format="GTiff", overwrite=TRUE) ## for the example we use the edge detection, algoKeyword<- "EdgeExtraction" ## extract the command list for the choosen algorithm cmd<-parseOTBFunction(algo = algoKeyword, gili = otblink) ## get help using the convenient listviewer listviewer::jsonedit(cmd$help) ## define the mandantory arguments all other will be default cmd$input <- file.path(projRootDir,"test.tif") cmd$filter <- "touzi" cmd$channel <- 2 cmd$out <- file.path(projRootDir,paste0("out",cmd$filter,".tif")) ## run algorithm retStack<-runOTB(cmd,gili = otblink) ## plot filter raster on the green channel plot(retStack)