Difference between revisions of "2013 Summer Project Week:Python Embedding"

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==Delivery Mechanism==
 
==Delivery Mechanism==
 
PythonCppAPI is a stand alone library. To use it within Slicer, similar to SlicerExecutionModel and other external libraries, an External_PythonCppAPI.cmake is needed in SuperBuild. During superbuild,
 
PythonCppAPI is a stand alone library. To use it within Slicer, similar to SlicerExecutionModel and other external libraries, an External_PythonCppAPI.cmake is needed in SuperBuild. During superbuild,
it will be checked out and built as a library.
+
it will be checked out and built as a library. The sample usage of the library is shown in the following code snippet:
  
 
   // Ok. Now we can create an instance of the interprter itself.
 
   // Ok. Now we can create an instance of the interprter itself.

Revision as of 18:37, 20 June 2013

Home < 2013 Summer Project Week:Python Embedding

Key Investigators

  • GRC: Rui Li, Jim Miller
  • Kitware: Jean-Christophe Fillion-Robin
  • Isomics: Steve Pieper

Objective

Python embedding library to manage calling python functions from C++. This will eliminate the code duplication in Slicer.


Approach, Plan

Discuss with Jc and Steve regarding how to incorporate into Slicer. Currently it is used as a downloadable library during superbuild, similar to SlicerExecutionModel.

Progress

Eliminate all the compile time warnings and fixed some stylistic issues. The updated code is pushed on to github at https://github.com/grclirui/PythonCppAPI.git and ready to use.

Delivery Mechanism

PythonCppAPI is a stand alone library. To use it within Slicer, similar to SlicerExecutionModel and other external libraries, an External_PythonCppAPI.cmake is needed in SuperBuild. During superbuild, it will be checked out and built as a library. The sample usage of the library is shown in the following code snippet:

 // Ok. Now we can create an instance of the interprter itself.
 PythonCppApiCallFunction pyCppApiCallFunction(argc, argv);
 // to check if the python interpreter is available and working,
 // execute a simple python statement.
 pyCppApiCallFunction.ExecuteString("print 'hello'");
 // execute the script in a file
 pyCppApiCallFunction.ExecuteFile("hello.py");
 // Load the test module into the interpreter
 pyCppApiCallFunction.ImportModule("test");


 ArgMap args; // our argument list that maps string values 
 bool ok;
 // Call a simple function, that takes no arguments
 // and returns nothing     
 args.clear();
 pyCppApiCallFunction.CallFunction("simple", args);
 // Call a function that takes two long arguments and returns
 // a long      
 {
 PythonCppApiVariant ret(0); // value returned by python is stored here
 args["10"] = PythonLong;
 args["20"] = PythonLong;
 ret = pyCppApiCallFunction.CallFunction("multiply", args);
 std::cout << ret.toLong(&ok, 0) << '\n';
 args.clear();
 }