/* New getargs implementation */ /* XXX There are several unchecked sprintf or strcat calls in this file. XXX The only way these can become a danger is if some C code in the XXX Python source (or in an extension) uses ridiculously long names XXX or ridiculously deep nesting in format strings. */ #include "Python.h" #include int PyArg_Parse(PyObject *, char *, ...); int PyArg_ParseTuple(PyObject *, char *, ...); int PyArg_VaParse(PyObject *, char *, va_list); int PyArg_ParseTupleAndKeywords(PyObject *, PyObject *, char *, char **, ...); /* Forward */ static int vgetargs1(PyObject *, char *, va_list *, int); static void seterror(int, char *, int *, char *, char *); static char *convertitem(PyObject *, char **, va_list *, int *, char *); static char *converttuple(PyObject *, char **, va_list *, int *, char *, int); static char *convertsimple(PyObject *, char **, va_list *, char *); static int convertbuffer(PyObject *, void **p, char **); static int vgetargskeywords(PyObject *, PyObject *, char *, char **, va_list *); static char *skipitem(char **, va_list *); int PyArg_Parse(PyObject *args, char *format, ...) { int retval; va_list va; va_start(va, format); retval = vgetargs1(args, format, &va, 1); va_end(va); return retval; } int PyArg_ParseTuple(PyObject *args, char *format, ...) { int retval; va_list va; va_start(va, format); retval = vgetargs1(args, format, &va, 0); va_end(va); return retval; } int PyArg_VaParse(PyObject *args, char *format, va_list va) { va_list lva; #ifdef VA_LIST_IS_ARRAY memcpy(lva, va, sizeof(va_list)); #else lva = va; #endif return vgetargs1(args, format, &lva, 0); } static int vgetargs1(PyObject *args, char *format, va_list *p_va, int compat) { char msgbuf[256]; int levels[32]; char *fname = NULL; char *message = NULL; int min = -1; int max = 0; int level = 0; int endfmt = 0; char *formatsave = format; int i, len; char *msg; assert(compat || (args != (PyObject*)NULL)); while (endfmt == 0) { int c = *format++; switch (c) { case '(': if (level == 0) max++; level++; break; case ')': if (level == 0) Py_FatalError("excess ')' in getargs format"); else level--; break; case '\0': endfmt = 1; break; case ':': fname = format; endfmt = 1; break; case ';': message = format; endfmt = 1; break; default: if (level == 0) { if (c == 'O') max++; else if (isalpha(c)) { if (c != 'e') /* skip encoded */ max++; } else if (c == '|') min = max; } break; } } if (level != 0) Py_FatalError(/* '(' */ "missing ')' in getargs format"); if (min < 0) min = max; format = formatsave; if (compat) { if (max == 0) { if (args == NULL) return 1; sprintf(msgbuf, "%s%s takes no arguments", fname==NULL ? "function" : fname, fname==NULL ? "" : "()"); PyErr_SetString(PyExc_TypeError, msgbuf); return 0; } else if (min == 1 && max == 1) { if (args == NULL) { sprintf(msgbuf, "%s%s takes at least one argument", fname==NULL ? "function" : fname, fname==NULL ? "" : "()"); PyErr_SetString(PyExc_TypeError, msgbuf); return 0; } msg = convertitem(args, &format, p_va, levels, msgbuf); if (msg == NULL) return 1; seterror(levels[0], msg, levels+1, fname, message); return 0; } else { PyErr_SetString(PyExc_SystemError, "old style getargs format uses new features"); return 0; } } if (!PyTuple_Check(args)) { PyErr_SetString(PyExc_SystemError, "new style getargs format but argument is not a tuple"); return 0; } len = PyTuple_GET_SIZE(args); if (len < min || max < len) { if (message == NULL) { sprintf(msgbuf, "%s%s takes %s %d argument%s (%d given)", fname==NULL ? "function" : fname, fname==NULL ? "" : "()", min==max ? "exactly" : len < min ? "at least" : "at most", len < min ? min : max, (len < min ? min : max) == 1 ? "" : "s", len); message = msgbuf; } PyErr_SetString(PyExc_TypeError, message); return 0; } for (i = 0; i < len; i++) { if (*format == '|') format++; msg = convertitem(PyTuple_GET_ITEM(args, i), &format, p_va, levels, msgbuf); if (msg) { seterror(i+1, msg, levels, fname, message); return 0; } } if (*format != '\0' && !isalpha((int)(*format)) && *format != '(' && *format != '|' && *format != ':' && *format != ';') { PyErr_Format(PyExc_SystemError, "bad format string: %.200s", formatsave); return 0; } return 1; } static void seterror(int iarg, char *msg, int *levels, char *fname, char *message) { char buf[256]; int i; char *p = buf; if (PyErr_Occurred()) return; else if (message == NULL) { if (fname != NULL) { sprintf(p, "%s() ", fname); p += strlen(p); } if (iarg != 0) { sprintf(p, "argument %d", iarg); i = 0; p += strlen(p); while (levels[i] > 0) { sprintf(p, ", item %d", levels[i]-1); p += strlen(p); i++; } } else { sprintf(p, "argument"); p += strlen(p); } sprintf(p, " %s", msg); message = buf; } PyErr_SetString(PyExc_TypeError, message); } /* Convert a tuple argument. On entry, *p_format points to the character _after_ the opening '('. On successful exit, *p_format points to the closing ')'. If successful: *p_format and *p_va are updated, *levels and *msgbuf are untouched, and NULL is returned. If the argument is invalid: *p_format is unchanged, *p_va is undefined, *levels is a 0-terminated list of item numbers, *msgbuf contains an error message, whose format is: "must be , not ", where: is the name of the expected type, and is the name of the actual type, and msgbuf is returned. */ static char * converttuple(PyObject *arg, char **p_format, va_list *p_va, int *levels, char *msgbuf, int toplevel) { int level = 0; int n = 0; char *format = *p_format; int i; for (;;) { int c = *format++; if (c == '(') { if (level == 0) n++; level++; } else if (c == ')') { if (level == 0) break; level--; } else if (c == ':' || c == ';' || c == '\0') break; else if (level == 0 && isalpha(c)) n++; } if (!PySequence_Check(arg) || PyString_Check(arg)) { levels[0] = 0; sprintf(msgbuf, toplevel ? "expected %d arguments, not %s" : "must be %d-item sequence, not %s", n, arg == Py_None ? "None" : arg->ob_type->tp_name); return msgbuf; } if ((i = PySequence_Size(arg)) != n) { levels[0] = 0; sprintf(msgbuf, toplevel ? "expected %d arguments, not %d" : "must be sequence of length %d, not %d", n, i); return msgbuf; } format = *p_format; for (i = 0; i < n; i++) { char *msg; PyObject *item; item = PySequence_GetItem(arg, i); msg = convertitem(item, &format, p_va, levels+1, msgbuf); /* PySequence_GetItem calls tp->sq_item, which INCREFs */ Py_XDECREF(item); if (msg != NULL) { levels[0] = i+1; return msg; } } *p_format = format; return NULL; } /* Convert a single item. */ static char * convertitem(PyObject *arg, char **p_format, va_list *p_va, int *levels, char *msgbuf) { char *msg; char *format = *p_format; if (*format == '(' /* ')' */) { format++; msg = converttuple(arg, &format, p_va, levels, msgbuf, 0); if (msg == NULL) format++; } else { msg = convertsimple(arg, &format, p_va, msgbuf); if (msg != NULL) levels[0] = 0; } if (msg == NULL) *p_format = format; return msg; } #define UNICODE_DEFAULT_ENCODING(arg) \ _PyUnicode_AsDefaultEncodedString(arg, NULL) /* Format an error message generated by convertsimple(). */ static char * converterr(char *expected, PyObject *arg, char *msgbuf) { assert(expected != NULL); assert(arg != NULL); sprintf(msgbuf, "must be %.50s, not %.50s", expected, arg == Py_None ? "None" : arg->ob_type->tp_name); return msgbuf; } #define CONV_UNICODE "(unicode conversion error)" /* Convert a non-tuple argument. Return NULL if conversion went OK, or a string with a message describing the failure. The message is formatted as "must be , not ". When failing, an exception may or may not have been raised. Don't call if a tuple is expected. */ static char * convertsimple(PyObject *arg, char **p_format, va_list *p_va, char *msgbuf) { char *format = *p_format; char c = *format++; PyObject *uarg; switch (c) { case 'b': { /* unsigned byte -- very short int */ char *p = va_arg(*p_va, char *); long ival = PyInt_AsLong(arg); if (ival == -1 && PyErr_Occurred()) return converterr("integer", arg, msgbuf); else if (ival < 0) { PyErr_SetString(PyExc_OverflowError, "unsigned byte integer is less than minimum"); return converterr("integer", arg, msgbuf); } else if (ival > UCHAR_MAX) { PyErr_SetString(PyExc_OverflowError, "unsigned byte integer is greater than maximum"); return converterr("integer", arg, msgbuf); } else *p = (unsigned char) ival; break; } case 'B': {/* byte sized bitfield - both signed and unsigned values allowed */ char *p = va_arg(*p_va, char *); long ival = PyInt_AsLong(arg); if (ival == -1 && PyErr_Occurred()) return converterr("integer", arg, msgbuf); else if (ival < SCHAR_MIN) { PyErr_SetString(PyExc_OverflowError, "byte-sized integer bitfield is less than minimum"); return converterr("integer", arg, msgbuf); } else if (ival > (int)UCHAR_MAX) { PyErr_SetString(PyExc_OverflowError, "byte-sized integer bitfield is greater than maximum"); return converterr("integer", arg, msgbuf); } else *p = (unsigned char) ival; break; } case 'h': {/* signed short int */ short *p = va_arg(*p_va, short *); long ival = PyInt_AsLong(arg); if (ival == -1 && PyErr_Occurred()) return converterr("integer", arg, msgbuf); else if (ival < SHRT_MIN) { PyErr_SetString(PyExc_OverflowError, "signed short integer is less than minimum"); return converterr("integer", arg, msgbuf); } else if (ival > SHRT_MAX) { PyErr_SetString(PyExc_OverflowError, "signed short integer is greater than maximum"); return converterr("integer", arg, msgbuf); } else *p = (short) ival; break; } case 'H': { /* short int sized bitfield, both signed and unsigned allowed */ unsigned short *p = va_arg(*p_va, unsigned short *); long ival = PyInt_AsLong(arg); if (ival == -1 && PyErr_Occurred()) return converterr("integer", arg, msgbuf); else if (ival < SHRT_MIN) { PyErr_SetString(PyExc_OverflowError, "short integer bitfield is less than minimum"); return converterr("integer", arg, msgbuf); } else if (ival > USHRT_MAX) { PyErr_SetString(PyExc_OverflowError, "short integer bitfield is greater than maximum"); return converterr("integer", arg, msgbuf); } else *p = (unsigned short) ival; break; } case 'i': {/* signed int */ int *p = va_arg(*p_va, int *); long ival = PyInt_AsLong(arg); if (ival == -1 && PyErr_Occurred()) return converterr("integer", arg, msgbuf); else if (ival > INT_MAX) { PyErr_SetString(PyExc_OverflowError, "signed integer is greater than maximum"); return converterr("integer", arg, msgbuf); } else if (ival < INT_MIN) { PyErr_SetString(PyExc_OverflowError, "signed integer is less than minimum"); return converterr("integer", arg, msgbuf); } else *p = ival; break; } case 'l': {/* long int */ long *p = va_arg(*p_va, long *); long ival = PyInt_AsLong(arg); if (ival == -1 && PyErr_Occurred()) return converterr("integer", arg, msgbuf); else *p = ival; break; } #ifdef HAVE_LONG_LONG case 'L': {/* LONG_LONG */ LONG_LONG *p = va_arg( *p_va, LONG_LONG * ); LONG_LONG ival = PyLong_AsLongLong( arg ); if( ival == (LONG_LONG)-1 && PyErr_Occurred() ) { return converterr("long", arg, msgbuf); } else { *p = ival; } break; } #endif case 'f': {/* float */ float *p = va_arg(*p_va, float *); double dval = PyFloat_AsDouble(arg); if (PyErr_Occurred()) return converterr("float", arg, msgbuf); else *p = (float) dval; break; } case 'd': {/* double */ double *p = va_arg(*p_va, double *); double dval = PyFloat_AsDouble(arg); if (PyErr_Occurred()) return converterr("float", arg, msgbuf); else *p = dval; break; } #ifndef WITHOUT_COMPLEX case 'D': {/* complex double */ Py_complex *p = va_arg(*p_va, Py_complex *); Py_complex cval; cval = PyComplex_AsCComplex(arg); if (PyErr_Occurred()) return converterr("complex", arg, msgbuf); else *p = cval; break; } #endif /* WITHOUT_COMPLEX */ case 'c': {/* char */ char *p = va_arg(*p_va, char *); if (PyString_Check(arg) && PyString_Size(arg) == 1) *p = PyString_AS_STRING(arg)[0]; else return converterr("char", arg, msgbuf); break; } case 's': {/* string */ if (*format == '#') { void **p = (void **)va_arg(*p_va, char **); int *q = va_arg(*p_va, int *); if (PyString_Check(arg)) { *p = PyString_AS_STRING(arg); *q = PyString_GET_SIZE(arg); } #ifdef Py_USING_UNICODE else if (PyUnicode_Check(arg)) { uarg = UNICODE_DEFAULT_ENCODING(arg); if (uarg == NULL) return converterr(CONV_UNICODE, arg, msgbuf); *p = PyString_AS_STRING(uarg); *q = PyString_GET_SIZE(uarg); } #endif else { /* any buffer-like object */ char *buf; int count = convertbuffer(arg, p, &buf); if (count < 0) return converterr(buf, arg, msgbuf); *q = count; } format++; } else { char **p = va_arg(*p_va, char **); if (PyString_Check(arg)) *p = PyString_AS_STRING(arg); #ifdef Py_USING_UNICODE else if (PyUnicode_Check(arg)) { uarg = UNICODE_DEFAULT_ENCODING(arg); if (uarg == NULL) return converterr(CONV_UNICODE, arg, msgbuf); *p = PyString_AS_STRING(uarg); } #endif else return converterr("string", arg, msgbuf); if ((int)strlen(*p) != PyString_Size(arg)) return converterr("string without null bytes", arg, msgbuf); } break; } case 'z': {/* string, may be NULL (None) */ if (*format == '#') { /* any buffer-like object */ void **p = (void **)va_arg(*p_va, char **); int *q = va_arg(*p_va, int *); if (arg == Py_None) { *p = 0; *q = 0; } else if (PyString_Check(arg)) { *p = PyString_AS_STRING(arg); *q = PyString_GET_SIZE(arg); } #ifdef Py_USING_UNICODE else if (PyUnicode_Check(arg)) { uarg = UNICODE_DEFAULT_ENCODING(arg); if (uarg == NULL) return converterr(CONV_UNICODE, arg, msgbuf); *p = PyString_AS_STRING(uarg); *q = PyString_GET_SIZE(uarg); } #endif else { /* any buffer-like object */ char *buf; int count = convertbuffer(arg, p, &buf); if (count < 0) return converterr(buf, arg, msgbuf); *q = count; } format++; } else { char **p = va_arg(*p_va, char **); if (arg == Py_None) *p = 0; else if (PyString_Check(arg)) *p = PyString_AS_STRING(arg); #ifdef Py_USING_UNICODE else if (PyUnicode_Check(arg)) { uarg = UNICODE_DEFAULT_ENCODING(arg); if (uarg == NULL) return converterr(CONV_UNICODE, arg, msgbuf); *p = PyString_AS_STRING(uarg); } #endif else return converterr("string or None", arg, msgbuf); if (*format == '#') { int *q = va_arg(*p_va, int *); if (arg == Py_None) *q = 0; else *q = PyString_Size(arg); format++; } else if (*p != NULL && (int)strlen(*p) != PyString_Size(arg)) return converterr( "string without null bytes or None", arg, msgbuf); } break; } case 'e': {/* encoded string */ char **buffer; const char *encoding; PyObject *s; int size, recode_strings; /* Get 'e' parameter: the encoding name */ encoding = (const char *)va_arg(*p_va, const char *); #ifdef Py_USING_UNICODE if (encoding == NULL) encoding = PyUnicode_GetDefaultEncoding(); #endif /* Get output buffer parameter: 's' (recode all objects via Unicode) or 't' (only recode non-string objects) */ if (*format == 's') recode_strings = 1; else if (*format == 't') recode_strings = 0; else return converterr( "(unknown parser marker combination)", arg, msgbuf); buffer = (char **)va_arg(*p_va, char **); format++; if (buffer == NULL) return converterr("(buffer is NULL)", arg, msgbuf); /* Encode object */ if (!recode_strings && PyString_Check(arg)) { s = arg; Py_INCREF(s); } else { #ifdef Py_USING_UNICODE PyObject *u; /* Convert object to Unicode */ u = PyUnicode_FromObject(arg); if (u == NULL) return converterr( "string or unicode or text buffer", arg, msgbuf); /* Encode object; use default error handling */ s = PyUnicode_AsEncodedString(u, encoding, NULL); Py_DECREF(u); if (s == NULL) return converterr("(encoding failed)", arg, msgbuf); if (!PyString_Check(s)) { Py_DECREF(s); return converterr( "(encoder failed to return a string)", arg, msgbuf); } #else return converterr("string", arg, msgbuf); #endif } size = PyString_GET_SIZE(s); /* Write output; output is guaranteed to be 0-terminated */ if (*format == '#') { /* Using buffer length parameter '#': - if *buffer is NULL, a new buffer of the needed size is allocated and the data copied into it; *buffer is updated to point to the new buffer; the caller is responsible for PyMem_Free()ing it after usage - if *buffer is not NULL, the data is copied to *buffer; *buffer_len has to be set to the size of the buffer on input; buffer overflow is signalled with an error; buffer has to provide enough room for the encoded string plus the trailing 0-byte - in both cases, *buffer_len is updated to the size of the buffer /excluding/ the trailing 0-byte */ int *buffer_len = va_arg(*p_va, int *); format++; if (buffer_len == NULL) return converterr( "(buffer_len is NULL)", arg, msgbuf); if (*buffer == NULL) { *buffer = PyMem_NEW(char, size + 1); if (*buffer == NULL) { Py_DECREF(s); return converterr( "(memory error)", arg, msgbuf); } } else { if (size + 1 > *buffer_len) { Py_DECREF(s); return converterr( "(buffer overflow)", arg, msgbuf); } } memcpy(*buffer, PyString_AS_STRING(s), size + 1); *buffer_len = size; } else { /* Using a 0-terminated buffer: - the encoded string has to be 0-terminated for this variant to work; if it is not, an error raised - a new buffer of the needed size is allocated and the data copied into it; *buffer is updated to point to the new buffer; the caller is responsible for PyMem_Free()ing it after usage */ if ((int)strlen(PyString_AS_STRING(s)) != size) return converterr( "(encoded string without NULL bytes)", arg, msgbuf); *buffer = PyMem_NEW(char, size + 1); if (*buffer == NULL) { Py_DECREF(s); return converterr("(memory error)", arg, msgbuf); } memcpy(*buffer, PyString_AS_STRING(s), size + 1); } Py_DECREF(s); break; } #ifdef Py_USING_UNICODE case 'u': {/* raw unicode buffer (Py_UNICODE *) */ if (*format == '#') { /* any buffer-like object */ void **p = (void **)va_arg(*p_va, char **); int *q = va_arg(*p_va, int *); char *buf; int count = convertbuffer(arg, p, &buf); if (count < 0) return converterr(buf, arg, msgbuf); *q = count/(sizeof(Py_UNICODE)); format++; } else { Py_UNICODE **p = va_arg(*p_va, Py_UNICODE **); if (PyUnicode_Check(arg)) *p = PyUnicode_AS_UNICODE(arg); else return converterr("unicode", arg, msgbuf); } break; } #endif case 'S': { /* string object */ PyObject **p = va_arg(*p_va, PyObject **); if (PyString_Check(arg)) *p = arg; else return converterr("string", arg, msgbuf); break; } #ifdef Py_USING_UNICODE case 'U': { /* Unicode object */ PyObject **p = va_arg(*p_va, PyObject **); if (PyUnicode_Check(arg)) *p = arg; else return converterr("unicode", arg, msgbuf); break; } #endif case 'O': { /* object */ PyTypeObject *type; PyObject **p; if (*format == '!') { type = va_arg(*p_va, PyTypeObject*); p = va_arg(*p_va, PyObject **); format++; if (PyType_IsSubtype(arg->ob_type, type)) *p = arg; else return converterr(type->tp_name, arg, msgbuf); } else if (*format == '?') { inquiry pred = va_arg(*p_va, inquiry); p = va_arg(*p_va, PyObject **); format++; if ((*pred)(arg)) *p = arg; else return converterr("(unspecified)", arg, msgbuf); } else if (*format == '&') { typedef int (*converter)(PyObject *, void *); converter convert = va_arg(*p_va, converter); void *addr = va_arg(*p_va, void *); format++; if (! (*convert)(arg, addr)) return converterr("(unspecified)", arg, msgbuf); } else { p = va_arg(*p_va, PyObject **); *p = arg; } break; } case 'w': { /* memory buffer, read-write access */ void **p = va_arg(*p_va, void **); PyBufferProcs *pb = arg->ob_type->tp_as_buffer; int count; if (pb == NULL || pb->bf_getwritebuffer == NULL || pb->bf_getsegcount == NULL) return converterr("read-write buffer", arg, msgbuf); if ((*pb->bf_getsegcount)(arg, NULL) != 1) return converterr("single-segment read-write buffer", arg, msgbuf); if ((count = pb->bf_getwritebuffer(arg, 0, p)) < 0) return converterr("(unspecified)", arg, msgbuf); if (*format == '#') { int *q = va_arg(*p_va, int *); *q = count; format++; } break; } case 't': { /* 8-bit character buffer, read-only access */ const char **p = va_arg(*p_va, const char **); PyBufferProcs *pb = arg->ob_type->tp_as_buffer; int count; if (*format++ != '#') return converterr( "invalid use of 't' format character", arg, msgbuf); if (!PyType_HasFeature(arg->ob_type, Py_TPFLAGS_HAVE_GETCHARBUFFER) || pb == NULL || pb->bf_getcharbuffer == NULL || pb->bf_getsegcount == NULL) return converterr( "string or read-only character buffer", arg, msgbuf); if (pb->bf_getsegcount(arg, NULL) != 1) return converterr( "string or single-segment read-only buffer", arg, msgbuf); count = pb->bf_getcharbuffer(arg, 0, p); if (count < 0) return converterr("(unspecified)", arg, msgbuf); *va_arg(*p_va, int *) = count; break; } default: return converterr("impossible", arg, msgbuf); } *p_format = format; return NULL; } static int convertbuffer(PyObject *arg, void **p, char **errmsg) { PyBufferProcs *pb = arg->ob_type->tp_as_buffer; int count; if (pb == NULL || pb->bf_getreadbuffer == NULL || pb->bf_getsegcount == NULL) { *errmsg = "string or read-only buffer"; return -1; } if ((*pb->bf_getsegcount)(arg, NULL) != 1) { *errmsg = "string or single-segment read-only buffer"; return -1; } if ((count = (*pb->bf_getreadbuffer)(arg, 0, p)) < 0) { *errmsg = "(unspecified)"; } return count; } /* Support for keyword arguments donated by Geoff Philbrick */ /* Return false (0) for error, else true. */ int PyArg_ParseTupleAndKeywords(PyObject *args, PyObject *keywords, char *format, char **kwlist, ...) { int retval; va_list va; if ((args == NULL || !PyTuple_Check(args)) || (keywords != NULL && !PyDict_Check(keywords)) || format == NULL || kwlist == NULL) { PyErr_BadInternalCall(); return 0; } va_start(va, kwlist); retval = vgetargskeywords(args, keywords, format, kwlist, &va); va_end(va); return retval; } static int vgetargskeywords(PyObject *args, PyObject *keywords, char *format, char **kwlist, va_list *p_va) { char msgbuf[256]; int levels[32]; char *fname, *message; int min, max; char *formatsave; int i, len, nargs, nkeywords; char *msg, *ks, **p; int nkwlist, pos, match, converted; PyObject *key, *value; assert(args != NULL && PyTuple_Check(args)); assert(keywords == NULL || PyDict_Check(keywords)); assert(format != NULL); assert(kwlist != NULL); assert(p_va != NULL); /* Search the format: message <- error msg, if any (else NULL). name <- routine name, if any (else NULL). min <- # of required arguments, or -1 if all are required. max <- most arguments (required + optional). Raise error if a tuple arg spec is found. */ fname = message = NULL; formatsave = format; min = -1; max = 0; while ((i = *format++) != '\0') { if (isalpha(i) && i != 'e') max++; else if (i == '|') min = max; else if (i == ':') { fname = format; break; } else if (i == ';') { message = format; break; } else if (i == '(') { PyErr_SetString(PyExc_SystemError, "tuple found in format when using keyword arguments"); return 0; } } if (min < 0) { /* All arguments are required. */ min = max; } format = formatsave; nargs = PyTuple_GET_SIZE(args); nkeywords = keywords == NULL ? 0 : PyDict_Size(keywords); /* make sure there are no duplicate values for an argument; its not clear when to use the term "keyword argument vs. keyword parameter in messages */ if (nkeywords > 0) { for (i = 0; i < nargs; i++) { char *thiskw = kwlist[i]; if (thiskw == NULL) break; if (PyMapping_HasKeyString(keywords, thiskw)) { PyErr_Format(PyExc_TypeError, "keyword parameter '%s' was given " "by position and by name", thiskw); return 0; } } } /* required arguments missing from args can be supplied by keyword arguments */ len = nargs; if (keywords && nargs < min) { for (i = nargs; i < min; i++) { if (PyMapping_HasKeyString(keywords, kwlist[i])) { len++; } } } PyErr_Clear(); /* make sure we got an acceptable number of arguments; the message is a little confusing with keywords since keyword arguments which are supplied, but don't match the required arguments are not included in the "%d given" part of the message */ if (len < min || max < len) { if (message == NULL) { sprintf(msgbuf, "%s%s takes %s %d argument%s (%d given)", fname==NULL ? "function" : fname, fname==NULL ? "" : "()", min==max ? "exactly" : len < min ? "at least" : "at most", len < min ? min : max, (len < min ? min : max) == 1 ? "" : "s", len); message = msgbuf; } PyErr_SetString(PyExc_TypeError, message); return 0; } for (i = 0; i < nargs; i++) { if (*format == '|') format++; msg = convertitem(PyTuple_GET_ITEM(args, i), &format, p_va, levels, msgbuf); if (msg) { seterror(i+1, msg, levels, fname, message); return 0; } } /* handle no keyword parameters in call */ if (nkeywords == 0) return 1; /* make sure the number of keywords in the keyword list matches the number of items in the format string */ nkwlist = 0; p = kwlist; while (*p++) nkwlist++; if (nkwlist != max) { PyErr_SetString(PyExc_SystemError, "number of items in format string and keyword list do not match"); return 0; } /* convert the keyword arguments; this uses the format string where it was left after processing args */ converted = 0; for (i = nargs; i < nkwlist; i++) { PyObject *item; if (*format == '|') format++; item = PyMapping_GetItemString(keywords, kwlist[i]); if (item != NULL) { msg = convertitem(item, &format, p_va, levels, msgbuf); if (msg) { seterror(i+1, msg, levels, fname, message); return 0; } converted++; Py_DECREF(item); } else { PyErr_Clear(); msg = skipitem(&format, p_va); if (msg) { seterror(i+1, msg, levels, fname, message); return 0; } } } /* make sure there are no extraneous keyword arguments */ pos = 0; if (converted < nkeywords) { while (PyDict_Next(keywords, &pos, &key, &value)) { match = 0; ks = PyString_AsString(key); for (i = 0; i < nkwlist; i++) { if (!strcmp(ks, kwlist[i])) { match = 1; break; } } if (!match) { sprintf(msgbuf, "%s is an invalid keyword argument for this function", ks); PyErr_SetString(PyExc_TypeError, msgbuf); return 0; } } } return 1; } static char * skipitem(char **p_format, va_list *p_va) { char *format = *p_format; char c = *format++; switch (c) { case 'b': /* byte -- very short int */ case 'B': /* byte as bitfield */ { (void) va_arg(*p_va, char *); break; } case 'h': /* short int */ { (void) va_arg(*p_va, short *); break; } case 'H': /* short int as bitfield */ { (void) va_arg(*p_va, unsigned short *); break; } case 'i': /* int */ { (void) va_arg(*p_va, int *); break; } case 'l': /* long int */ { (void) va_arg(*p_va, long *); break; } #ifdef HAVE_LONG_LONG case 'L': /* LONG_LONG int */ { (void) va_arg(*p_va, LONG_LONG *); break; } #endif case 'f': /* float */ { (void) va_arg(*p_va, float *); break; } case 'd': /* double */ { (void) va_arg(*p_va, double *); break; } #ifndef WITHOUT_COMPLEX case 'D': /* complex double */ { (void) va_arg(*p_va, Py_complex *); break; } #endif /* WITHOUT_COMPLEX */ case 'c': /* char */ { (void) va_arg(*p_va, char *); break; } case 's': /* string */ { (void) va_arg(*p_va, char **); if (*format == '#') { (void) va_arg(*p_va, int *); format++; } break; } case 'z': /* string */ { (void) va_arg(*p_va, char **); if (*format == '#') { (void) va_arg(*p_va, int *); format++; } break; } case 'S': /* string object */ { (void) va_arg(*p_va, PyObject **); break; } case 'O': /* object */ { if (*format == '!') { format++; (void) va_arg(*p_va, PyTypeObject*); (void) va_arg(*p_va, PyObject **); } #if 0 /* I don't know what this is for */ else if (*format == '?') { inquiry pred = va_arg(*p_va, inquiry); format++; if ((*pred)(arg)) { (void) va_arg(*p_va, PyObject **); } } #endif else if (*format == '&') { typedef int (*converter)(PyObject *, void *); (void) va_arg(*p_va, converter); (void) va_arg(*p_va, void *); format++; } else { (void) va_arg(*p_va, PyObject **); } break; } default: return "impossible"; } *p_format = format; return NULL; } int PyArg_UnpackTuple(PyObject *args, char *name, int min, int max, ...) { int i, l; PyObject **o; va_list vargs; #ifdef HAVE_STDARG_PROTOTYPES va_start(vargs, max); #else va_start(vargs); #endif assert(min >= 0); assert(min <= max); if (!PyTuple_Check(args)) { PyErr_SetString(PyExc_SystemError, "PyArg_UnpackTuple() argument list is not a tuple"); return 0; } l = PyTuple_GET_SIZE(args); if (l < min) { if (name != NULL) PyErr_Format( PyExc_TypeError, "%s expected %s%d arguments, got %d", name, (min == max ? "" : "at least "), min, l); else PyErr_Format( PyExc_TypeError, "unpacked tuple should have %s%d elements," " but has %d", (min == max ? "" : "at least "), min, l); va_end(vargs); return 0; } if (l > max) { if (name != NULL) PyErr_Format( PyExc_TypeError, "%s expected %s%d arguments, got %d", name, (min == max ? "" : "at most "), max, l); else PyErr_Format( PyExc_TypeError, "unpacked tuple should have %s%d elements," " but has %d", (min == max ? "" : "at most "), max, l); va_end(vargs); return 0; } for (i = 0; i < l; i++) { o = va_arg(vargs, PyObject **); *o = PyTuple_GET_ITEM(args, i); } va_end(vargs); return 1; }