//=================================================================== // Return the clr python module (new reference) //=================================================================== public static IntPtr GetCLRModule(IntPtr?fromList = null) { root.InitializePreload(); #if (PYTHON32 || PYTHON33 || PYTHON34 || PYTHON35) // update the module dictionary with the contents of the root dictionary root.LoadNames(); IntPtr py_mod_dict = Runtime.PyModule_GetDict(py_clr_module); IntPtr clr_dict = Runtime._PyObject_GetDictPtr(root.pyHandle); // PyObject** clr_dict = (IntPtr)Marshal.PtrToStructure(clr_dict, typeof(IntPtr)); Runtime.PyDict_Update(py_mod_dict, clr_dict); // find any items from the fromlist and get them from the root if they're not // aleady in the module dictionary if (fromList != null && fromList != IntPtr.Zero) { if (Runtime.PyTuple_Check(fromList.GetValueOrDefault())) { Runtime.Incref(py_mod_dict); using (PyDict mod_dict = new PyDict(py_mod_dict)) { Runtime.Incref(fromList.GetValueOrDefault()); using (PyTuple from = new PyTuple(fromList.GetValueOrDefault())) { foreach (PyObject item in from) { if (mod_dict.HasKey(item)) { continue; } string s = item.AsManagedObject(typeof(string)) as string; if (null == s) { continue; } ManagedType attr = root.GetAttribute(s, true); if (null == attr) { continue; } Runtime.Incref(attr.pyHandle); using (PyObject obj = new PyObject(attr.pyHandle)) { mod_dict.SetItem(s, obj); } } } } } } Runtime.Incref(py_clr_module); return(py_clr_module); #else Runtime.Incref(root.pyHandle); return(root.pyHandle); #endif }
//=================================================================== // Return the clr python module (new reference) //=================================================================== public static IntPtr GetCLRModule() { root.InitializePreload(); #if (PYTHON32 || PYTHON33 || PYTHON34) Runtime.Incref(py_clr_module); return(py_clr_module); #else Runtime.Incref(root.pyHandle); return(root.pyHandle); #endif }
/// <summary> /// Return the clr python module (new reference) /// </summary> public static unsafe NewReference GetCLRModule(BorrowedReference fromList = default) { root.InitializePreload(); // update the module dictionary with the contents of the root dictionary root.LoadNames(); BorrowedReference py_mod_dict = Runtime.PyModule_GetDict(ClrModuleReference); using (var clr_dict = Runtime.PyObject_GenericGetDict(root.ObjectReference)) { Runtime.PyDict_Update(py_mod_dict, clr_dict); } // find any items from the from list and get them from the root if they're not // already in the module dictionary if (fromList != null) { if (Runtime.PyTuple_Check(fromList)) { using var mod_dict = new PyDict(py_mod_dict); using var from = new PyTuple(fromList); foreach (PyObject item in from) { if (mod_dict.HasKey(item)) { continue; } var s = item.AsManagedObject(typeof(string)) as string; if (s == null) { continue; } ManagedType attr = root.GetAttribute(s, true); if (attr == null) { continue; } Runtime.XIncref(attr.pyHandle); using (var obj = new PyObject(attr.pyHandle)) { mod_dict.SetItem(s, obj); } } } } Runtime.XIncref(py_clr_module); return(NewReference.DangerousFromPointer(py_clr_module)); }
//=================================================================== // The actual import hook that ties Python to the managed world. //=================================================================== public static IntPtr __import__(IntPtr self, IntPtr args, IntPtr kw) { // Replacement for the builtin __import__. The original import // hook is saved as this.py_import. This version handles CLR // import and defers to the normal builtin for everything else. int num_args = Runtime.PyTuple_Size(args); if (num_args < 1) { return(Exceptions.RaiseTypeError( "__import__() takes at least 1 argument (0 given)" )); } // borrowed reference IntPtr py_mod_name = Runtime.PyTuple_GetItem(args, 0); if ((py_mod_name == IntPtr.Zero) || (!Runtime.IsStringType(py_mod_name))) { return(Exceptions.RaiseTypeError("string expected")); } // Check whether the import is of the form 'from x import y'. // This determines whether we return the head or tail module. IntPtr fromList = IntPtr.Zero; bool fromlist = false; if (num_args >= 4) { fromList = Runtime.PyTuple_GetItem(args, 3); if ((fromList != IntPtr.Zero) && (Runtime.PyObject_IsTrue(fromList) == 1)) { fromlist = true; } } string mod_name = Runtime.GetManagedString(py_mod_name); // Check these BEFORE the built-in import runs; may as well // do the Incref()ed return here, since we've already found // the module. if (mod_name == "clr") { root.InitializePreload(); Runtime.Incref(root.pyHandle); return(root.pyHandle); } if (mod_name == "CLR") { Exceptions.deprecation("The CLR module is deprecated. " + "Please use 'clr'."); root.InitializePreload(); Runtime.Incref(root.pyHandle); return(root.pyHandle); } string realname = mod_name; if (mod_name.StartsWith("CLR.")) { realname = mod_name.Substring(4); string msg = String.Format("Importing from the CLR.* namespace " + "is deprecated. Please import '{0}' directly.", realname); Exceptions.deprecation(msg); } else { // 2010-08-15: Always seemed smart to let python try first... // This shaves off a few tenths of a second on test_module.py // and works around a quirk where 'sys' is found by the // LoadImplicit() deprecation logic. // Turns out that the AssemblyManager.ResolveHandler() checks to see if any // Assembly's FullName.ToLower().StartsWith(name.ToLower()), which makes very // little sense to me. IntPtr res = Runtime.PyObject_Call(py_import, args, kw); if (res != IntPtr.Zero) { // There was no error. return(res); } // There was an error if (!Exceptions.ExceptionMatches(Exceptions.ImportError)) { // and it was NOT an ImportError; bail out here. return(IntPtr.Zero); } // Otherwise, just clear the it. Exceptions.Clear(); } string[] names = realname.Split('.'); // Now we need to decide if the name refers to a CLR module, // and may have to do an implicit load (for b/w compatibility) // using the AssemblyManager. The assembly manager tries // really hard not to use Python objects or APIs, because // parts of it can run recursively and on strange threads. // // It does need an opportunity from time to time to check to // see if sys.path has changed, in a context that is safe. Here // we know we have the GIL, so we'll let it update if needed. AssemblyManager.UpdatePath(); if (!AssemblyManager.IsValidNamespace(realname)) { bool fromFile = false; if (AssemblyManager.LoadImplicit(realname, out fromFile)) { if (true == fromFile) { string deprWarning = String.Format("\nThe module was found, but not in a referenced namespace.\n" + "Implicit loading is deprecated. Please use clr.AddReference(\"{0}\").", realname); Exceptions.deprecation(deprWarning); } } else { // May be called when a module being imported imports a module. // In particular, I've seen decimal import copy import org.python.core return(Runtime.PyObject_Call(py_import, args, kw)); } } // See if sys.modules for this interpreter already has the // requested module. If so, just return the exising module. IntPtr modules = Runtime.PyImport_GetModuleDict(); IntPtr module = Runtime.PyDict_GetItem(modules, py_mod_name); if (module != IntPtr.Zero) { if (fromlist) { Runtime.Incref(module); return(module); } module = Runtime.PyDict_GetItemString(modules, names[0]); Runtime.Incref(module); return(module); } Exceptions.Clear(); // Traverse the qualified module name to get the named module // and place references in sys.modules as we go. Note that if // we are running in interactive mode we pre-load the names in // each module, which is often useful for introspection. If we // are not interactive, we stick to just-in-time creation of // objects at lookup time, which is much more efficient. // NEW: The clr got a new module variable preload. You can // enable preloading in a non-interactive python processing by // setting clr.preload = True ModuleObject head = (mod_name == realname) ? null : root; ModuleObject tail = root; root.InitializePreload(); for (int i = 0; i < names.Length; i++) { string name = names[i]; ManagedType mt = tail.GetAttribute(name, true); if (!(mt is ModuleObject)) { string error = String.Format("No module named {0}", name); Exceptions.SetError(Exceptions.ImportError, error); return(IntPtr.Zero); } if (head == null) { head = (ModuleObject)mt; } tail = (ModuleObject)mt; if (CLRModule.preload) { tail.LoadNames(); } Runtime.PyDict_SetItemString(modules, tail.moduleName, tail.pyHandle ); } ModuleObject mod = fromlist ? tail : head; if (fromlist && Runtime.PySequence_Size(fromList) == 1) { IntPtr fp = Runtime.PySequence_GetItem(fromList, 0); if ((!CLRModule.preload) && Runtime.GetManagedString(fp) == "*") { mod.LoadNames(); } Runtime.Decref(fp); } Runtime.Incref(mod.pyHandle); return(mod.pyHandle); }
//=================================================================== // The actual import hook that ties Python to the managed world. //=================================================================== public static IntPtr __import__(IntPtr self, IntPtr args, IntPtr kw) { // Replacement for the builtin __import__. The original import // hook is saved as this.py_import. This version handles CLR // import and defers to the normal builtin for everything else. int num_args = Runtime.PyTuple_Size(args); if (num_args < 1) { return(Exceptions.RaiseTypeError( "__import__() takes at least 1 argument (0 given)" )); } // borrowed reference IntPtr py_mod_name = Runtime.PyTuple_GetItem(args, 0); if ((py_mod_name == IntPtr.Zero) || (!Runtime.IsStringType(py_mod_name))) { return(Exceptions.RaiseTypeError("string expected")); } // Check whether the import is of the form 'from x import y'. // This determines whether we return the head or tail module. IntPtr fromList = IntPtr.Zero; bool fromlist = false; if (num_args >= 4) { fromList = Runtime.PyTuple_GetItem(args, 3); if ((fromList != IntPtr.Zero) && (Runtime.PyObject_IsTrue(fromList) == 1)) { fromlist = true; } } string mod_name = Runtime.GetManagedString(py_mod_name); if (mod_name == "CLR") { Exceptions.deprecation("The CLR module is deprecated. " + "Please use 'clr'."); root.InitializePreload(); Runtime.Incref(root.pyHandle); return(root.pyHandle); } if (mod_name == "clr") { root.InitializePreload(); Runtime.Incref(root.pyHandle); return(root.pyHandle); } string realname = mod_name; if (mod_name.StartsWith("CLR.")) { realname = mod_name.Substring(4); string msg = String.Format("Importing from the CLR.* namespace " + "is deprecated. Please import '{0}' directly.", realname); Exceptions.deprecation(msg); } string[] names = realname.Split('.'); // Now we need to decide if the name refers to a CLR module, // and may have to do an implicit load (for b/w compatibility) // using the AssemblyManager. The assembly manager tries // really hard not to use Python objects or APIs, because // parts of it can run recursively and on strange threads. // // It does need an opportunity from time to time to check to // see if sys.path has changed, in a context that is safe. Here // we know we have the GIL, so we'll let it update if needed. AssemblyManager.UpdatePath(); AssemblyManager.LoadImplicit(realname); if (!AssemblyManager.IsValidNamespace(realname)) { return(Runtime.PyObject_Call(py_import, args, kw)); } // See if sys.modules for this interpreter already has the // requested module. If so, just return the exising module. IntPtr modules = Runtime.PyImport_GetModuleDict(); IntPtr module = Runtime.PyDict_GetItem(modules, py_mod_name); if (module != IntPtr.Zero) { if (fromlist) { Runtime.Incref(module); return(module); } module = Runtime.PyDict_GetItemString(modules, names[0]); Runtime.Incref(module); return(module); } Exceptions.Clear(); // Traverse the qualified module name to get the named module // and place references in sys.modules as we go. Note that if // we are running in interactive mode we pre-load the names in // each module, which is often useful for introspection. If we // are not interactive, we stick to just-in-time creation of // objects at lookup time, which is much more efficient. // NEW: The clr got a new module variable preload. You can // enable preloading in a non-interactive python processing by // setting clr.preload = True ModuleObject head = (mod_name == realname) ? null : root; ModuleObject tail = root; root.InitializePreload(); for (int i = 0; i < names.Length; i++) { string name = names[i]; ManagedType mt = tail.GetAttribute(name, true); if (!(mt is ModuleObject)) { string error = String.Format("No module named {0}", name); Exceptions.SetError(Exceptions.ImportError, error); return(IntPtr.Zero); } if (head == null) { head = (ModuleObject)mt; } tail = (ModuleObject)mt; if (CLRModule.preload) { tail.LoadNames(); } Runtime.PyDict_SetItemString(modules, tail.moduleName, tail.pyHandle ); } ModuleObject mod = fromlist ? tail : head; if (fromlist && Runtime.PySequence_Size(fromList) == 1) { IntPtr fp = Runtime.PySequence_GetItem(fromList, 0); if ((!CLRModule.preload) && Runtime.GetManagedString(fp) == "*") { mod.LoadNames(); } Runtime.Decref(fp); } Runtime.Incref(mod.pyHandle); return(mod.pyHandle); }