// @(#)root/pyroot:$Id$ // Author: Wim Lavrijsen, Apr 2004 // Bindings #include "PyROOT.h" #include "PyStrings.h" #include "TPython.h" #include "ObjectProxy.h" #include "MethodProxy.h" #include "RootWrapper.h" #include "TPyClassGenerator.h" // ROOT #include "TROOT.h" #include "TObject.h" // Standard #include #include #include //______________________________________________________________________________ // Python interpreter access // ========================= // // The TPython class allows for access to python objects from CINT. The current // functionality is only basic: ROOT objects and builtin types can freely cross // the boundary between the two interpreters, python objects can be instantiated // and their methods can be called. All other cross-coding is based on strings // that are run on the python interpreter. // // Examples: // // $ cat MyPyClass.py // print 'creating class MyPyClass ... ' // // class MyPyClass: // def __init__( self ): // print 'in MyPyClass.__init__' // // def gime( self, what ): // return what // // $ root -l // // Execute a string of python code. // root [0] TPython::Exec( "print \'Hello World!\'" ); // Hello World! // // // Create a TBrowser on the python side, and transfer it back and forth. // // Note the required explicit (void*) cast! // root [1] TBrowser* b = (void*)TPython::Eval( "ROOT.TBrowser()" ); // root [2] TPython::Bind( b, "b" ); // root [3] b == (void*) TPython::Eval( "b" ) // (int)1 // // // Builtin variables can cross-over by using implicit casts. // root [4] int i = TPython::Eval( "1 + 1" ); // root [5] i // (int)2 // // // Load a python module with a class definition, and use it. Casts are // // necessary as the type information can not be otherwise derived. // root [6] TPython::LoadMacro( "MyPyClass.py" ); // creating class MyPyClass ... // root [7] MyPyClass m; // in MyPyClass.__init__ // root [8] std::string s = (char*)m.gime( "aap" ); // root [9] s // (class TString)"aap" // // It is possible to switch between interpreters by calling "TPython::Prompt()" // on the CINT side, while returning with ^D (EOF). State is preserved between // successive switches. // // The API part provides (direct) C++ access to the bindings functionality of // PyROOT. It allows verifying that you deal with a PyROOT python object in the // first place (ObjectProxy_Check for ObjectProxy and any derived types, as well // as ObjectProxy_CheckExact for ObjectProxy's only); and it allows conversions // of void* to an ObjectProxy and vice versa. //- data --------------------------------------------------------------------- ClassImp(TPython) static PyObject* gMainDict = 0; //- static public members ---------------------------------------------------- Bool_t TPython::Initialize() { // Private initialization method: setup the python interpreter and load the // ROOT module. static Bool_t isInitialized = kFALSE; if ( isInitialized ) return kTRUE; if ( ! Py_IsInitialized() ) { // this happens if CINT comes in first PyEval_InitThreads(); Py_Initialize(); // try again to see if the interpreter is initialized if ( ! Py_IsInitialized() ) { // give up ... std::cerr << "Error: python has not been intialized; returning." << std::endl; return kFALSE; } // set the command line arguments on python's sys.argv #if PY_VERSION_HEX < 0x03000000 char* argv[] = { const_cast< char* >( "root" ) }; #else wchar_t* argv[] = { const_cast< wchar_t* >( L"root" ) }; #endif PySys_SetArgv( sizeof(argv)/sizeof(argv[0]), argv ); // force loading of the ROOT module PyRun_SimpleString( const_cast< char* >( "import ROOT" ) ); } if ( ! gMainDict ) { // retrieve the main dictionary gMainDict = PyModule_GetDict( PyImport_AddModule( const_cast< char* >( "__main__" ) ) ); Py_INCREF( gMainDict ); } // python side class construction, managed by ROOT gROOT->AddClassGenerator( new TPyClassGenerator ); // declare success ... isInitialized = kTRUE; return kTRUE; } //____________________________________________________________________________ void TPython::LoadMacro( const char* name ) { // Execute the give python script as if it were a macro (effectively an // execfile in __main__), and create CINT equivalents for any newly available // python classes. // setup if ( ! Initialize() ) return; // obtain a reference to look for new classes later PyObject* old = PyDict_Values( gMainDict ); // actual execution Exec( (std::string( "execfile(\"" ) + name + "\")").c_str() ); // obtain new __main__ contents PyObject* current = PyDict_Values( gMainDict ); // create CINT classes for all new python classes for ( int i = 0; i < PyList_GET_SIZE( current ); ++i ) { PyObject* value = PyList_GET_ITEM( current, i ); Py_INCREF( value ); if ( ! PySequence_Contains( old, value ) ) { // collect classes if ( PyClass_Check( value ) || PyObject_HasAttr( value, PyROOT::PyStrings::gBases ) ) { // get full class name (including module) PyObject* pyModName = PyObject_GetAttr( value, PyROOT::PyStrings::gModule ); PyObject* pyClName = PyObject_GetAttr( value, PyROOT::PyStrings::gName ); if ( PyErr_Occurred() ) PyErr_Clear(); // need to check for both exact and derived (differences exist between older and newer // versions of python ... bug?) if ( (pyModName && pyClName) &&\ ( (PyBytes_CheckExact( pyModName ) && PyBytes_CheckExact( pyClName )) ||\ (PyBytes_Check( pyModName ) && PyBytes_Check( pyClName ))\ ) ) { // build full, qualified name std::string fullname = PyROOT_PyUnicode_AsString( pyModName ); fullname += '.'; fullname += PyROOT_PyUnicode_AsString( pyClName ); // force class creation (this will eventually call TPyClassGenerator) TClass::GetClass( fullname.c_str(), kTRUE ); } Py_XDECREF( pyClName ); Py_XDECREF( pyModName ); } } Py_DECREF( value ); } Py_DECREF( current ); Py_DECREF( old ); } //____________________________________________________________________________ void TPython::ExecScript( const char* name, int argc, const char** argv ) { // Execute a python stand-alone script, with argv CLI arguments. // // example of use: // const char* argv[] = { "1", "2", "3" }; // TPython::ExecScript( "test.py", sizeof(argv)/sizeof(argv[0]), argv ); // setup if ( ! Initialize() ) return; // verify arguments if ( ! name ) { std::cerr << "Error: no file name specified." << std::endl; return; } FILE* fp = fopen( name, "r" ); if ( ! fp ) { std::cerr << "Error: could not open file \"" << name << "\"." << std::endl; return; } // store a copy of the old cli for restoration PyObject* oldargv = PySys_GetObject( const_cast< char* >( "argv" ) ); // borrowed if ( ! oldargv ) // e.g. apache PyErr_Clear(); else { PyObject* l = PyList_New( PyList_GET_SIZE( oldargv ) ); for ( int i = 0; i < PyList_GET_SIZE( oldargv ); ++i ) { PyObject* item = PyList_GET_ITEM( oldargv, i ); Py_INCREF( item ); PyList_SET_ITEM( l, i, item ); // steals ref } oldargv = l; } // create and set (add progam name) the new command line argc += 1; #if PY_VERSION_HEX < 0x03000000 const char** argv2 = new const char*[ argc ]; for ( int i = 1; i < argc; ++i ) argv2[ i ] = argv[ i-1 ]; argv2[ 0 ] = Py_GetProgramName(); PySys_SetArgv( argc, const_cast< char** >( argv2 ) ); delete [] argv2; #else // TODO: fix this to work like above ... argv = 0; #endif // actual script execution PyObject* gbl = PyDict_Copy( gMainDict ); PyObject* result = // PyRun_FileEx closes fp (b/c of last argument "1") PyRun_FileEx( fp, const_cast< char* >( name ), Py_file_input, gbl, gbl, 1 ); if ( ! result ) PyErr_Print(); Py_XDECREF( result ); Py_DECREF( gbl ); // restore original command line if ( oldargv ) { PySys_SetObject( const_cast< char* >( "argv" ), oldargv ); Py_DECREF( oldargv ); } } //____________________________________________________________________________ Bool_t TPython::Exec( const char* cmd ) { // Execute a python statement (e.g. "import ROOT"). // setup if ( ! Initialize() ) return kFALSE; // execute the command PyObject* result = PyRun_String( const_cast< char* >( cmd ), Py_file_input, gMainDict, gMainDict ); // test for error if ( result ) { Py_DECREF( result ); return kTRUE; } else { PyErr_Print(); return kFALSE; } } //____________________________________________________________________________ const TPyReturn TPython::Eval( const char* expr ) { // Evaluate a python expression (e.g. "ROOT.TBrowser()"). // // Caution: do not hold on to the return value: either store it in a builtin // type (implicit casting will work), or in a pointer to a ROOT object (explicit // casting to a void* is required). // setup if ( ! Initialize() ) return TPyReturn(); // evaluate the expression PyObject* result = PyRun_String( const_cast< char* >( expr ), Py_eval_input, gMainDict, gMainDict ); // report errors as appropriate; return void if ( ! result ) { PyErr_Print(); return TPyReturn(); } // results that require no convserion if ( result == Py_None || PyROOT::ObjectProxy_Check( result ) || PyBytes_Check( result ) || PyFloat_Check( result ) || PyLong_Check( result ) || PyInt_Check( result ) ) return TPyReturn( result ); // explicit conversion for python type required PyObject* pyclass = PyObject_GetAttr( result, PyROOT::PyStrings::gClass ); if ( pyclass != 0 ) { // retrieve class name and the module in which it resides PyObject* name = PyObject_GetAttr( pyclass, PyROOT::PyStrings::gName ); PyObject* module = PyObject_GetAttr( pyclass, PyROOT::PyStrings::gModule ); // concat name std::string qname = std::string( PyROOT_PyUnicode_AsString( module ) ) + '.' + PyROOT_PyUnicode_AsString( name ); Py_DECREF( module ); Py_DECREF( name ); Py_DECREF( pyclass ); // locate ROOT style class with this name TClass* klass = TClass::GetClass( qname.c_str() ); // construct general ROOT python object that pretends to be of class 'klass' if ( klass != 0 ) return TPyReturn( result ); } else PyErr_Clear(); // no conversion, return null pointer object Py_DECREF( result ); return TPyReturn(); } //____________________________________________________________________________ Bool_t TPython::Bind( TObject* object, const char* label ) { // Bind a ROOT object with, at the python side, the name "label". // check given address and setup if ( ! ( object && Initialize() ) ) return kFALSE; // bind object in the main namespace TClass* klass = object->IsA(); if ( klass != 0 ) { PyObject* bound = PyROOT::BindRootObject( (void*)object, klass ); if ( bound ) { Bool_t bOk = PyDict_SetItemString( gMainDict, const_cast< char* >( label ), bound ) == 0; Py_DECREF( bound ); return bOk; } } return kFALSE; } //____________________________________________________________________________ void TPython::Prompt() { // Enter an interactive python session (exit with ^D). State is preserved // between successive calls. // setup if ( ! Initialize() ) { return; } // enter i/o interactive mode PyRun_InteractiveLoop( stdin, const_cast< char* >( "\0" ) ); } //____________________________________________________________________________ Bool_t TPython::ObjectProxy_Check( PyObject* pyobject ) { // Test whether the type of the given pyobject is of ObjectProxy type or any // derived type. // setup if ( ! Initialize() ) return kFALSE; // detailed walk through inheritance hierarchy return PyROOT::ObjectProxy_Check( pyobject ); } //____________________________________________________________________________ Bool_t TPython::ObjectProxy_CheckExact( PyObject* pyobject ) { // Test whether the type of the given pyobject is ObjectProxy type. // setup if ( ! Initialize() ) return kFALSE; // direct pointer comparison of type member return PyROOT::ObjectProxy_CheckExact( pyobject ); } //____________________________________________________________________________ Bool_t TPython::MethodProxy_Check( PyObject* pyobject ) { // Test whether the type of the given pyobject is of MethodProxy type or any // derived type. // setup if ( ! Initialize() ) return kFALSE; // detailed walk through inheritance hierarchy return PyROOT::MethodProxy_Check( pyobject ); } //____________________________________________________________________________ Bool_t TPython::MethodProxy_CheckExact( PyObject* pyobject ) { // Test whether the type of the given pyobject is MethodProxy type. // setup if ( ! Initialize() ) return kFALSE; // direct pointer comparison of type member return PyROOT::MethodProxy_CheckExact( pyobject ); } //____________________________________________________________________________ void* TPython::ObjectProxy_AsVoidPtr( PyObject* pyobject ) { // Extract the object pointer held by the ObjectProxy pyobject. // setup if ( ! Initialize() ) return 0; // check validity of cast if ( ! PyROOT::ObjectProxy_Check( pyobject ) ) return 0; // get held object (may be null) return ((PyROOT::ObjectProxy*)pyobject)->GetObject(); } //____________________________________________________________________________ PyObject* TPython::ObjectProxy_FromVoidPtr( void* addr, const char* classname, Bool_t python_owns ) { // Bind the addr to a python object of class defined by classname. // setup if ( ! Initialize() ) return 0; // perform cast (the call will check TClass and addr, and set python errors) PyObject* pyobject = PyROOT::BindRootObjectNoCast( addr, TClass::GetClass( classname ), kFALSE ); // give ownership, for ref-counting, to the python side, if so requested if ( python_owns && PyROOT::ObjectProxy_Check( pyobject ) ) ((PyROOT::ObjectProxy*)pyobject)->HoldOn(); return pyobject; }