gstlearn
gstlearn Team
Introduction¶
The gstlearn Python package is a cross-platform Python package wrapping the gstlearn C++ Library. It offers to Python users all famous Geostatistical methodologies developed and/or invented by the Geostatistic Team of the Geosciences Research Center! It is the successor of the RGeostats R package, but in Python :-).
To install the gstlearn Python Package, you need Python 3.8 (or higher) and execute the following command:
# Uncomment next line for installing last release of gstlearn package (remove '#' character)
#!pip install gstlearn
Loading the package¶
import gstlearn as gl
import gstlearn.plot as gp
import gstlearn.document as gdoc
import matplotlib.pyplot as plt
gdoc.setNoScroll()
Calling the next function (acknowledge_gstlearn) at startup is a good practice in order to check the version of gstlearn you are currently running:
# Uncomment and execute if needed
#gl.acknowledge_gstlearn()
First code: Create and display a database¶
We create a regular 2-D grid and simulate a variable using a geostatistical Model
grid = gl.DbGrid.create(nx=[100,100])
model = gl.Model.createFromParam(type = gl.ECov.CUBIC, range = 30)
err = gl.simtub(None, grid, model, None, nbsimu=1, seed=13126, nbtuba = 1000)
The simulated result is plotted
ax = grid.plot()
plt.show()
If you obtain a nice looking image corresponding to the simulation result on the grid ... the installation of gstlearn is successfull. Here is the description of your grid database content:
grid.display()
Data Base Grid Characteristics ============================== Data Base Summary ----------------- File is organized as a regular grid Space dimension = 2 Number of Columns = 4 Total number of samples = 10000 Grid characteristics: --------------------- Origin : 0.000 0.000 Mesh : 1.000 1.000 Number : 100 100 Variables --------- Column = 0 - Name = rank - Locator = NA Column = 1 - Name = x1 - Locator = x1 Column = 2 - Name = x2 - Locator = x2 Column = 3 - Name = Simu - Locator = z1
About C++ & Python¶
The gstlearn Python package is generated using SWIG See here. We have chosen SWIG in order to mutualize the wrapper code of gstlearn C++ library for several different target languages.
The classes and functions documentation is provided with the gstlearn C++ library as html files generated by Doxygen. Please, refer to gstlearn C++ library API See here for more details. Only the public methods are exported by SWIG and must be considered in the Python package.
Their is currently poor Python documentation for the gstlearn Python package. The user can refer to the C++ documentation and have to learn how to adapt the code into Python language following these "conversion rules":
C++ classes are automatically converted into Python classes. After creating an instance of a class, methods (i.e. class function) must be called using
.
applied to the instance (i.e. an object) of that class (seegrid.display()
in the example below).Static C++ methods (e.g.
createFromNF
method inDbGrid
class) defined in a class (e.g.DbGrid
) are renamed by joining the class name and the method name (e.g.DbGrid.createFromNF
). Note: Static methods do not apply to object instances (e.g.mygrid.createFromNF()
has no sense)Static C++ variables (e.g.
X
locator) defined in a class (e.g.ELoc
'enum' class) must be accessed in Python using the same rules as static methods (e.g.ELoc.X
)All basic C++ types (
double
,int
,bool
, etc...) are automatically converted to/from Python native types (float
,int
,bool
,...)The C++ classes
VectorDouble
,VectorInt
, etc... are automatically converted to/from Python/numpy nd.arrayThe C++ classes
VectorVectorDouble
,VectorVectorInt
, etc... are automatically converted to/from Python/numpy nd.array of nd.array(s)Some classes of the gstlearn C++ library have been extended in Python:
- Almost all classes are 'stringable' (those which inherit from
AStringable
), that means that you can type the object name in the Python console prompt and hit 'Enter' key to obtain a detailed description of the object content. The same output text is obtained using thedisplay
method (e.g.mygrid.display()
) - Some classes have an additional Python method named
toTL
(i.e. 'to Target Language') that permits to convert an object into the corresponding Python type. For example, the instructiondf = mygrid.toTL()
permits to create a pandasDataFrame
from aDb
object. In that case, the newly createdDataFrame
will contain all variables from the Db (but locators and grid parameters (for DbGrid) will be lost)
- Almost all classes are 'stringable' (those which inherit from