/* This module provides the suite of standard class-based exceptions for * Python's builtin module. This is a complete C implementation of what, * in Python 1.5.2, was contained in the exceptions.py module. The problem * there was that if exceptions.py could not be imported for some reason, * the entire interpreter would abort. * * By moving the exceptions into C and statically linking, we can guarantee * that the standard exceptions will always be available. * * history: * 98-08-19 fl created (for pyexe) * 00-02-08 fl updated for 1.5.2 * 26-May-2000 baw vetted for Python 1.6 * * written by Fredrik Lundh * modifications, additions, cleanups, and proofreading by Barry Warsaw * * Copyright (c) 1998-2000 by Secret Labs AB. All rights reserved. */ #include "Python.h" #include "osdefs.h" /* Caution: MS Visual C++ 6 errors if a single string literal exceeds * 2Kb. So the module docstring has been broken roughly in half, using * compile-time literal concatenation. */ static char module__doc__[] = "Python's standard exception class hierarchy.\n\ \n\ Before Python 1.5, the standard exceptions were all simple string objects.\n\ In Python 1.5, the standard exceptions were converted to classes organized\n\ into a relatively flat hierarchy. String-based standard exceptions were\n\ optional, or used as a fallback if some problem occurred while importing\n\ the exception module. With Python 1.6, optional string-based standard\n\ exceptions were removed (along with the -X command line flag).\n\ \n\ The class exceptions were implemented in such a way as to be almost\n\ completely backward compatible. Some tricky uses of IOError could\n\ potentially have broken, but by Python 1.6, all of these should have\n\ been fixed. As of Python 1.6, the class-based standard exceptions are\n\ now implemented in C, and are guaranteed to exist in the Python\n\ interpreter.\n\ \n\ Here is a rundown of the class hierarchy. The classes found here are\n\ inserted into both the exceptions module and the `built-in' module. It is\n\ recommended that user defined class based exceptions be derived from the\n\ `Exception' class, although this is currently not enforced.\n" /* keep string pieces "small" */ "\n\ Exception\n\ |\n\ +-- SystemExit\n\ +-- StandardError\n\ |\n\ +-- KeyboardInterrupt\n\ +-- ImportError\n\ +-- EnvironmentError\n\ | |\n\ | +-- IOError\n\ | +-- OSError\n\ | |\n\ | +-- WindowsError\n\ |\n\ +-- EOFError\n\ +-- RuntimeError\n\ | |\n\ | +-- NotImplementedError\n\ |\n\ +-- NameError\n\ | |\n\ | +-- UnboundLocalError\n\ |\n\ +-- AttributeError\n\ +-- SyntaxError\n\ | |\n\ | +-- IndentationError\n\ | |\n\ | +-- TabError\n\ |\n\ +-- TypeError\n\ +-- AssertionError\n\ +-- LookupError\n\ | |\n\ | +-- IndexError\n\ | +-- KeyError\n\ |\n\ +-- ArithmeticError\n\ | |\n\ | +-- OverflowError\n\ | +-- ZeroDivisionError\n\ | +-- FloatingPointError\n\ |\n\ +-- ValueError\n\ | |\n\ | +-- UnicodeError\n\ |\n\ +-- SystemError\n\ +-- MemoryError"; /* Helper function for populating a dictionary with method wrappers. */ static int populate_methods(PyObject *klass, PyObject *dict, PyMethodDef *methods) { if (!methods) return 0; while (methods->ml_name) { /* get a wrapper for the built-in function */ PyObject *func = PyCFunction_New(methods, NULL); PyObject *meth; int status; if (!func) return -1; /* turn the function into an unbound method */ if (!(meth = PyMethod_New(func, NULL, klass))) { Py_DECREF(func); return -1; } /* add method to dictionary */ status = PyDict_SetItemString(dict, methods->ml_name, meth); Py_DECREF(meth); Py_DECREF(func); /* stop now if an error occurred, otherwise do the next method */ if (status) return status; methods++; } return 0; } /* This function is used to create all subsequent exception classes. */ static int make_class(PyObject **klass, PyObject *base, char *name, PyMethodDef *methods, char *docstr) { PyObject *dict = PyDict_New(); PyObject *str = NULL; int status = -1; if (!dict) return -1; /* If an error occurs from here on, goto finally instead of explicitly * returning NULL. */ if (docstr) { if (!(str = PyString_FromString(docstr))) goto finally; if (PyDict_SetItemString(dict, "__doc__", str)) goto finally; } if (!(*klass = PyErr_NewException(name, base, dict))) goto finally; if (populate_methods(*klass, dict, methods)) { Py_DECREF(*klass); *klass = NULL; } status = 0; finally: Py_XDECREF(dict); Py_XDECREF(str); return status; } /* Use this for *args signatures, otherwise just use PyArg_ParseTuple() */ static PyObject * get_self(PyObject *args) { PyObject *self = PyTuple_GetItem(args, 0); if (!self) { /* Watch out for being called to early in the bootstrapping process */ if (PyExc_TypeError) { PyErr_SetString(PyExc_TypeError, "unbound method must be called with class instance 1st argument"); } return NULL; } return self; } /* Notes on bootstrapping the exception classes. * * First thing we create is the base class for all exceptions, called * appropriately enough: Exception. Creation of this class makes no * assumptions about the existence of any other exception class -- except * for TypeError, which can conditionally exist. * * Next, StandardError is created (which is quite simple) followed by * TypeError, because the instantiation of other exceptions can potentially * throw a TypeError. Once these exceptions are created, all the others * can be created in any order. See the static exctable below for the * explicit bootstrap order. * * All classes after Exception can be created using PyErr_NewException(). */ static char Exception__doc__[] = "Common base class for all exceptions."; static PyObject * Exception__init__(PyObject *self, PyObject *args) { int status; if (!(self = get_self(args))) return NULL; /* set args attribute */ /* XXX size is only a hint */ args = PySequence_GetSlice(args, 1, PySequence_Size(args)); if (!args) return NULL; status = PyObject_SetAttrString(self, "args", args); Py_DECREF(args); if (status < 0) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * Exception__str__(PyObject *self, PyObject *args) { PyObject *out; if (!PyArg_ParseTuple(args, "O:__str__", &self)) return NULL; args = PyObject_GetAttrString(self, "args"); if (!args) return NULL; switch (PySequence_Size(args)) { case 0: out = PyString_FromString(""); break; case 1: { PyObject *tmp = PySequence_GetItem(args, 0); if (tmp) { out = PyObject_Str(tmp); Py_DECREF(tmp); } else out = NULL; break; } default: out = PyObject_Str(args); break; } Py_DECREF(args); return out; } static PyObject * Exception__getitem__(PyObject *self, PyObject *args) { PyObject *out; PyObject *index; if (!PyArg_ParseTuple(args, "OO:__getitem__", &self, &index)) return NULL; args = PyObject_GetAttrString(self, "args"); if (!args) return NULL; out = PyObject_GetItem(args, index); Py_DECREF(args); return out; } static PyMethodDef Exception_methods[] = { /* methods for the Exception class */ { "__getitem__", Exception__getitem__, METH_VARARGS}, { "__str__", Exception__str__, METH_VARARGS}, { "__init__", Exception__init__, METH_VARARGS}, { NULL, NULL } }; static int make_Exception(char *modulename) { PyObject *dict = PyDict_New(); PyObject *str = NULL; PyObject *name = NULL; int status = -1; if (!dict) return -1; /* If an error occurs from here on, goto finally instead of explicitly * returning NULL. */ if (!(str = PyString_FromString(modulename))) goto finally; if (PyDict_SetItemString(dict, "__module__", str)) goto finally; Py_DECREF(str); if (!(str = PyString_FromString(Exception__doc__))) goto finally; if (PyDict_SetItemString(dict, "__doc__", str)) goto finally; if (!(name = PyString_FromString("Exception"))) goto finally; if (!(PyExc_Exception = PyClass_New(NULL, dict, name))) goto finally; /* Now populate the dictionary with the method suite */ if (populate_methods(PyExc_Exception, dict, Exception_methods)) /* Don't need to reclaim PyExc_Exception here because that'll * happen during interpreter shutdown. */ goto finally; status = 0; finally: Py_XDECREF(dict); Py_XDECREF(str); Py_XDECREF(name); return status; } static char StandardError__doc__[] = "Base class for all standard Python exceptions."; static char TypeError__doc__[] = "Inappropriate argument type."; static char SystemExit__doc__[] = "Request to exit from the interpreter."; static PyObject * SystemExit__init__(PyObject *self, PyObject *args) { PyObject *code; int status; if (!(self = get_self(args))) return NULL; /* Set args attribute. */ if (!(args = PySequence_GetSlice(args, 1, PySequence_Size(args)))) return NULL; status = PyObject_SetAttrString(self, "args", args); if (status < 0) { Py_DECREF(args); return NULL; } /* set code attribute */ switch (PySequence_Size(args)) { case 0: Py_INCREF(Py_None); code = Py_None; break; case 1: code = PySequence_GetItem(args, 0); break; default: Py_INCREF(args); code = args; break; } status = PyObject_SetAttrString(self, "code", code); Py_DECREF(code); Py_DECREF(args); if (status < 0) return NULL; Py_INCREF(Py_None); return Py_None; } PyMethodDef SystemExit_methods[] = { { "__init__", SystemExit__init__, METH_VARARGS}, {NULL, NULL} }; static char KeyboardInterrupt__doc__[] = "Program interrupted by user."; static char ImportError__doc__[] = "Import can't find module, or can't find name in module."; static char EnvironmentError__doc__[] = "Base class for I/O related errors."; static PyObject * EnvironmentError__init__(PyObject *self, PyObject *args) { PyObject *item0 = NULL; PyObject *item1 = NULL; PyObject *item2 = NULL; PyObject *subslice = NULL; PyObject *rtnval = NULL; if (!(self = get_self(args))) return NULL; if (!(args = PySequence_GetSlice(args, 1, PySequence_Size(args)))) return NULL; if (PyObject_SetAttrString(self, "args", args) || PyObject_SetAttrString(self, "errno", Py_None) || PyObject_SetAttrString(self, "strerror", Py_None) || PyObject_SetAttrString(self, "filename", Py_None)) { goto finally; } switch (PySequence_Size(args)) { case 3: /* Where a function has a single filename, such as open() or some * of the os module functions, PyErr_SetFromErrnoWithFilename() is * called, giving a third argument which is the filename. But, so * that old code using in-place unpacking doesn't break, e.g.: * * except IOError, (errno, strerror): * * we hack args so that it only contains two items. This also * means we need our own __str__() which prints out the filename * when it was supplied. */ item0 = PySequence_GetItem(args, 0); item1 = PySequence_GetItem(args, 1); item2 = PySequence_GetItem(args, 2); if (!item0 || !item1 || !item2) goto finally; if (PyObject_SetAttrString(self, "errno", item0) || PyObject_SetAttrString(self, "strerror", item1) || PyObject_SetAttrString(self, "filename", item2)) { goto finally; } subslice = PySequence_GetSlice(args, 0, 2); if (!subslice || PyObject_SetAttrString(self, "args", subslice)) goto finally; break; case 2: /* Used when PyErr_SetFromErrno() is called and no filename * argument is given. */ item0 = PySequence_GetItem(args, 0); item1 = PySequence_GetItem(args, 1); if (!item0 || !item1) goto finally; if (PyObject_SetAttrString(self, "errno", item0) || PyObject_SetAttrString(self, "strerror", item1)) { goto finally; } break; } Py_INCREF(Py_None); rtnval = Py_None; finally: Py_DECREF(args); Py_XDECREF(item0); Py_XDECREF(item1); Py_XDECREF(item2); Py_XDECREF(subslice); return rtnval; } static PyObject * EnvironmentError__str__(PyObject *self, PyObject *args) { PyObject *originalself = self; PyObject *filename; PyObject *serrno; PyObject *strerror; PyObject *rtnval = NULL; if (!PyArg_ParseTuple(args, "O:__str__", &self)) return NULL; filename = PyObject_GetAttrString(self, "filename"); serrno = PyObject_GetAttrString(self, "errno"); strerror = PyObject_GetAttrString(self, "strerror"); if (!filename || !serrno || !strerror) goto finally; if (filename != Py_None) { PyObject *fmt = PyString_FromString("[Errno %s] %s: %s"); PyObject *repr = PyObject_Repr(filename); PyObject *tuple = PyTuple_New(3); if (!fmt || !repr || !tuple) { Py_XDECREF(fmt); Py_XDECREF(repr); Py_XDECREF(tuple); goto finally; } PyTuple_SET_ITEM(tuple, 0, serrno); PyTuple_SET_ITEM(tuple, 1, strerror); PyTuple_SET_ITEM(tuple, 2, repr); rtnval = PyString_Format(fmt, tuple); Py_DECREF(fmt); Py_DECREF(tuple); /* already freed because tuple owned only reference */ serrno = NULL; strerror = NULL; } else if (PyObject_IsTrue(serrno) && PyObject_IsTrue(strerror)) { PyObject *fmt = PyString_FromString("[Errno %s] %s"); PyObject *tuple = PyTuple_New(2); if (!fmt || !tuple) { Py_XDECREF(fmt); Py_XDECREF(tuple); goto finally; } PyTuple_SET_ITEM(tuple, 0, serrno); PyTuple_SET_ITEM(tuple, 1, strerror); rtnval = PyString_Format(fmt, tuple); Py_DECREF(fmt); Py_DECREF(tuple); /* already freed because tuple owned only reference */ serrno = NULL; strerror = NULL; } else /* The original Python code said: * * return StandardError.__str__(self) * * but there is no StandardError__str__() function; we happen to * know that's just a pass through to Exception__str__(). */ rtnval = Exception__str__(originalself, args); finally: Py_XDECREF(filename); Py_XDECREF(serrno); Py_XDECREF(strerror); return rtnval; } static PyMethodDef EnvironmentError_methods[] = { {"__init__", EnvironmentError__init__, METH_VARARGS}, {"__str__", EnvironmentError__str__, METH_VARARGS}, {NULL, NULL} }; static char IOError__doc__[] = "I/O operation failed."; static char OSError__doc__[] = "OS system call failed."; #ifdef MS_WINDOWS static char WindowsError__doc__[] = "MS-Windows OS system call failed."; #endif /* MS_WINDOWS */ static char EOFError__doc__[] = "Read beyond end of file."; static char RuntimeError__doc__[] = "Unspecified run-time error."; static char NotImplementedError__doc__[] = "Method or function hasn't been implemented yet."; static char NameError__doc__[] = "Name not found globally."; static char UnboundLocalError__doc__[] = "Local name referenced but not bound to a value."; static char AttributeError__doc__[] = "Attribute not found."; static char SyntaxError__doc__[] = "Invalid syntax."; static int SyntaxError__classinit__(PyObject *klass) { PyObject *emptystring = PyString_FromString(""); /* Additional class-creation time initializations */ if (!emptystring || PyObject_SetAttrString(klass, "msg", emptystring) || PyObject_SetAttrString(klass, "filename", Py_None) || PyObject_SetAttrString(klass, "lineno", Py_None) || PyObject_SetAttrString(klass, "offset", Py_None) || PyObject_SetAttrString(klass, "text", Py_None)) { Py_XDECREF(emptystring); return -1; } Py_DECREF(emptystring); return 0; } static PyObject * SyntaxError__init__(PyObject *self, PyObject *args) { PyObject *rtnval = NULL; int lenargs; if (!(self = get_self(args))) return NULL; if (!(args = PySequence_GetSlice(args, 1, PySequence_Size(args)))) return NULL; if (PyObject_SetAttrString(self, "args", args)) goto finally; lenargs = PySequence_Size(args); if (lenargs >= 1) { PyObject *item0 = PySequence_GetItem(args, 0); int status; if (!item0) goto finally; status = PyObject_SetAttrString(self, "msg", item0); Py_DECREF(item0); if (status) goto finally; } if (lenargs == 2) { PyObject *info = PySequence_GetItem(args, 1); PyObject *filename, *lineno, *offset, *text; int status = 1; if (!info) goto finally; filename = PySequence_GetItem(info, 0); lineno = PySequence_GetItem(info, 1); offset = PySequence_GetItem(info, 2); text = PySequence_GetItem(info, 3); Py_DECREF(info); if (filename && lineno && offset && text) { status = PyObject_SetAttrString(self, "filename", filename) || PyObject_SetAttrString(self, "lineno", lineno) || PyObject_SetAttrString(self, "offset", offset) || PyObject_SetAttrString(self, "text", text); } Py_XDECREF(filename); Py_XDECREF(lineno); Py_XDECREF(offset); Py_XDECREF(text); if (status) goto finally; } Py_INCREF(Py_None); rtnval = Py_None; finally: Py_DECREF(args); return rtnval; } /* This is called "my_basename" instead of just "basename" to avoid name conflicts with glibc; basename is already prototyped if _GNU_SOURCE is defined, and Python does define that. */ static char * my_basename(char *name) { char *cp = name; char *result = name; if (name == NULL) return "???"; while (*cp != '\0') { if (*cp == SEP) result = cp + 1; ++cp; } return result; } static PyObject * SyntaxError__str__(PyObject *self, PyObject *args) { PyObject *msg; PyObject *str; PyObject *filename, *lineno, *result; if (!PyArg_ParseTuple(args, "O:__str__", &self)) return NULL; if (!(msg = PyObject_GetAttrString(self, "msg"))) return NULL; str = PyObject_Str(msg); Py_DECREF(msg); result = str; /* XXX -- do all the additional formatting with filename and lineno here */ if (PyString_Check(str)) { int have_filename = 0; int have_lineno = 0; char *buffer = NULL; if ((filename = PyObject_GetAttrString(self, "filename")) != NULL) have_filename = PyString_Check(filename); else PyErr_Clear(); if ((lineno = PyObject_GetAttrString(self, "lineno")) != NULL) have_lineno = PyInt_Check(lineno); else PyErr_Clear(); if (have_filename || have_lineno) { int bufsize = PyString_GET_SIZE(str) + 64; if (have_filename) bufsize += PyString_GET_SIZE(filename); buffer = PyMem_Malloc(bufsize); if (buffer != NULL) { if (have_filename && have_lineno) sprintf(buffer, "%s (%s, line %d)", PyString_AS_STRING(str), my_basename(PyString_AS_STRING(filename)), PyInt_AsLong(lineno)); else if (have_filename) sprintf(buffer, "%s (%s)", PyString_AS_STRING(str), my_basename(PyString_AS_STRING(filename))); else if (have_lineno) sprintf(buffer, "%s (line %d)", PyString_AS_STRING(str), PyInt_AsLong(lineno)); result = PyString_FromString(buffer); PyMem_FREE(buffer); if (result == NULL) result = str; else Py_DECREF(str); } } Py_XDECREF(filename); Py_XDECREF(lineno); } return result; } PyMethodDef SyntaxError_methods[] = { {"__init__", SyntaxError__init__, METH_VARARGS}, {"__str__", SyntaxError__str__, METH_VARARGS}, {NULL, NULL} }; static char AssertionError__doc__[] = "Assertion failed."; static char LookupError__doc__[] = "Base class for lookup errors."; static char IndexError__doc__[] = "Sequence index out of range."; static char KeyError__doc__[] = "Mapping key not found."; static char ArithmeticError__doc__[] = "Base class for arithmetic errors."; static char OverflowError__doc__[] = "Result too large to be represented."; static char ZeroDivisionError__doc__[] = "Second argument to a division or modulo operation was zero."; static char FloatingPointError__doc__[] = "Floating point operation failed."; static char ValueError__doc__[] = "Inappropriate argument value (of correct type)."; static char UnicodeError__doc__[] = "Unicode related error."; static char SystemError__doc__[] = "Internal error in the Python interpreter.\n\ \n\ Please report this to the Python maintainer, along with the traceback,\n\ the Python version, and the hardware/OS platform and version."; static char MemoryError__doc__[] = "Out of memory."; static char IndentationError__doc__[] = "Improper indentation."; static char TabError__doc__[] = "Improper mixture of spaces and tabs."; /* module global functions */ static PyMethodDef functions[] = { /* Sentinel */ {NULL, NULL} }; /* Global C API defined exceptions */ PyObject *PyExc_Exception; PyObject *PyExc_StandardError; PyObject *PyExc_ArithmeticError; PyObject *PyExc_LookupError; PyObject *PyExc_AssertionError; PyObject *PyExc_AttributeError; PyObject *PyExc_EOFError; PyObject *PyExc_FloatingPointError; PyObject *PyExc_EnvironmentError; PyObject *PyExc_IOError; PyObject *PyExc_OSError; PyObject *PyExc_ImportError; PyObject *PyExc_IndexError; PyObject *PyExc_KeyError; PyObject *PyExc_KeyboardInterrupt; PyObject *PyExc_MemoryError; PyObject *PyExc_NameError; PyObject *PyExc_OverflowError; PyObject *PyExc_RuntimeError; PyObject *PyExc_NotImplementedError; PyObject *PyExc_SyntaxError; PyObject *PyExc_IndentationError; PyObject *PyExc_TabError; PyObject *PyExc_SystemError; PyObject *PyExc_SystemExit; PyObject *PyExc_UnboundLocalError; PyObject *PyExc_UnicodeError; PyObject *PyExc_TypeError; PyObject *PyExc_ValueError; PyObject *PyExc_ZeroDivisionError; #ifdef MS_WINDOWS PyObject *PyExc_WindowsError; #endif /* Pre-computed MemoryError instance. Best to create this as early as * possibly and not wait until a MemoryError is actually raised! */ PyObject *PyExc_MemoryErrorInst; /* mapping between exception names and their PyObject ** */ static struct { char *name; PyObject **exc; PyObject **base; /* NULL == PyExc_StandardError */ char *docstr; PyMethodDef *methods; int (*classinit)(PyObject *); } exctable[] = { /* * The first three classes MUST appear in exactly this order */ {"Exception", &PyExc_Exception}, {"StandardError", &PyExc_StandardError, &PyExc_Exception, StandardError__doc__}, {"TypeError", &PyExc_TypeError, 0, TypeError__doc__}, /* * The rest appear in depth-first order of the hierarchy */ {"SystemExit", &PyExc_SystemExit, &PyExc_Exception, SystemExit__doc__, SystemExit_methods}, {"KeyboardInterrupt", &PyExc_KeyboardInterrupt, 0, KeyboardInterrupt__doc__}, {"ImportError", &PyExc_ImportError, 0, ImportError__doc__}, {"EnvironmentError", &PyExc_EnvironmentError, 0, EnvironmentError__doc__, EnvironmentError_methods}, {"IOError", &PyExc_IOError, &PyExc_EnvironmentError, IOError__doc__}, {"OSError", &PyExc_OSError, &PyExc_EnvironmentError, OSError__doc__}, #ifdef MS_WINDOWS {"WindowsError", &PyExc_WindowsError, &PyExc_OSError, WindowsError__doc__}, #endif /* MS_WINDOWS */ {"EOFError", &PyExc_EOFError, 0, EOFError__doc__}, {"RuntimeError", &PyExc_RuntimeError, 0, RuntimeError__doc__}, {"NotImplementedError", &PyExc_NotImplementedError, &PyExc_RuntimeError, NotImplementedError__doc__}, {"NameError", &PyExc_NameError, 0, NameError__doc__}, {"UnboundLocalError", &PyExc_UnboundLocalError, &PyExc_NameError, UnboundLocalError__doc__}, {"AttributeError", &PyExc_AttributeError, 0, AttributeError__doc__}, {"SyntaxError", &PyExc_SyntaxError, 0, SyntaxError__doc__, SyntaxError_methods, SyntaxError__classinit__}, {"IndentationError", &PyExc_IndentationError, &PyExc_SyntaxError, IndentationError__doc__}, {"TabError", &PyExc_TabError, &PyExc_IndentationError, TabError__doc__}, {"AssertionError", &PyExc_AssertionError, 0, AssertionError__doc__}, {"LookupError", &PyExc_LookupError, 0, LookupError__doc__}, {"IndexError", &PyExc_IndexError, &PyExc_LookupError, IndexError__doc__}, {"KeyError", &PyExc_KeyError, &PyExc_LookupError, KeyError__doc__}, {"ArithmeticError", &PyExc_ArithmeticError, 0, ArithmeticError__doc__}, {"OverflowError", &PyExc_OverflowError, &PyExc_ArithmeticError, OverflowError__doc__}, {"ZeroDivisionError", &PyExc_ZeroDivisionError, &PyExc_ArithmeticError, ZeroDivisionError__doc__}, {"FloatingPointError", &PyExc_FloatingPointError, &PyExc_ArithmeticError, FloatingPointError__doc__}, {"ValueError", &PyExc_ValueError, 0, ValueError__doc__}, {"UnicodeError", &PyExc_UnicodeError, &PyExc_ValueError, UnicodeError__doc__}, {"SystemError", &PyExc_SystemError, 0, SystemError__doc__}, {"MemoryError", &PyExc_MemoryError, 0, MemoryError__doc__}, /* Sentinel */ {NULL} }; void #ifdef WIN32 __declspec(dllexport) #endif /* WIN32 */ init_exceptions(void) { char *modulename = "exceptions"; int modnamesz = strlen(modulename); int i; PyObject *me = Py_InitModule(modulename, functions); PyObject *mydict = PyModule_GetDict(me); PyObject *bltinmod = PyImport_ImportModule("__builtin__"); PyObject *bdict = PyModule_GetDict(bltinmod); PyObject *doc = PyString_FromString(module__doc__); PyObject *args; PyDict_SetItemString(mydict, "__doc__", doc); Py_DECREF(doc); if (PyErr_Occurred()) Py_FatalError("exceptions bootstrapping error."); /* This is the base class of all exceptions, so make it first. */ if (make_Exception(modulename) || PyDict_SetItemString(mydict, "Exception", PyExc_Exception) || PyDict_SetItemString(bdict, "Exception", PyExc_Exception)) { Py_FatalError("Base class `Exception' could not be created."); } /* Now we can programmatically create all the remaining exceptions. * Remember to start the loop at 1 to skip Exceptions. */ for (i=1; exctable[i].name; i++) { int status; char *cname = PyMem_NEW(char, modnamesz+strlen(exctable[i].name)+2); PyObject *base; (void)strcpy(cname, modulename); (void)strcat(cname, "."); (void)strcat(cname, exctable[i].name); if (exctable[i].base == 0) base = PyExc_StandardError; else base = *exctable[i].base; status = make_class(exctable[i].exc, base, cname, exctable[i].methods, exctable[i].docstr); PyMem_DEL(cname); if (status) Py_FatalError("Standard exception classes could not be created."); if (exctable[i].classinit) { status = (*exctable[i].classinit)(*exctable[i].exc); if (status) Py_FatalError("An exception class could not be initialized."); } /* Now insert the class into both this module and the __builtin__ * module. */ if (PyDict_SetItemString(mydict, exctable[i].name, *exctable[i].exc) || PyDict_SetItemString(bdict, exctable[i].name, *exctable[i].exc)) { Py_FatalError("Module dictionary insertion problem."); } } /* Now we need to pre-allocate a MemoryError instance */ args = Py_BuildValue("()"); if (!args || !(PyExc_MemoryErrorInst = PyEval_CallObject(PyExc_MemoryError, args))) { Py_FatalError("Cannot pre-allocate MemoryError instance\n"); } Py_DECREF(args); /* We're done with __builtin__ */ Py_DECREF(bltinmod); } void #ifdef WIN32 __declspec(dllexport) #endif /* WIN32 */ fini_exceptions(void) { int i; Py_XDECREF(PyExc_MemoryErrorInst); PyExc_MemoryErrorInst = NULL; for (i=0; exctable[i].name; i++) { Py_XDECREF(*exctable[i].exc); *exctable[i].exc = NULL; } }