/* struct module -- pack values into and (out of) strings */ /* New version supporting byte order, alignment and size options, character strings, and unsigned numbers */ static char struct__doc__[] = "\ Functions to convert between Python values and C structs.\n\ Python strings are used to hold the data representing the C struct\n\ and also as format strings to describe the layout of data in the C struct.\n\ \n\ The optional first format char indicates byte ordering and alignment:\n\ @: native w/native alignment(default)\n\ =: native w/standard alignment\n\ <: little-endian, std. alignment\n\ >: big-endian, std. alignment\n\ !: network, std (same as >)\n\ \n\ The remaining chars indicate types of args and must match exactly;\n\ these can be preceded by a decimal repeat count:\n\ x: pad byte (no data); c:char; b:signed byte; B:unsigned byte;\n\ h:short; H:unsigned short; i:int; I:unsigned int;\n\ l:long; L:unsigned long; f:float; d:double.\n\ Special cases (preceding decimal count indicates length):\n\ s:string (array of char); p: pascal string (w. count byte).\n\ Special case (only available in native format):\n\ P:an integer type that is wide enough to hold a pointer.\n\ Whitespace between formats is ignored.\n\ \n\ The variable struct.error is an exception raised on errors."; #include "Python.h" #include #include /* Exception */ static PyObject *StructError; /* Define various structs to figure out the alignments of types */ #ifdef __MWERKS__ /* ** XXXX We have a problem here. There are no unique alignment rules ** on the PowerPC mac. */ #ifdef __powerc #pragma options align=mac68k #endif #endif /* __MWERKS__ */ typedef struct { char c; short x; } s_short; typedef struct { char c; int x; } s_int; typedef struct { char c; long x; } s_long; typedef struct { char c; float x; } s_float; typedef struct { char c; double x; } s_double; typedef struct { char c; void *x; } s_void_p; #define SHORT_ALIGN (sizeof(s_short) - sizeof(short)) #define INT_ALIGN (sizeof(s_int) - sizeof(int)) #define LONG_ALIGN (sizeof(s_long) - sizeof(long)) #define FLOAT_ALIGN (sizeof(s_float) - sizeof(float)) #define DOUBLE_ALIGN (sizeof(s_double) - sizeof(double)) #define VOID_P_ALIGN (sizeof(s_void_p) - sizeof(void *)) #ifdef __powerc #pragma options align=reset #endif /* Helper routine to get a Python integer and raise the appropriate error if it isn't one */ static int get_long(PyObject *v, long *p) { long x = PyInt_AsLong(v); if (x == -1 && PyErr_Occurred()) { if (PyErr_ExceptionMatches(PyExc_TypeError)) PyErr_SetString(StructError, "required argument is not an integer"); return -1; } *p = x; return 0; } /* Same, but handling unsigned long */ static int get_ulong(PyObject *v, unsigned long *p) { if (PyLong_Check(v)) { unsigned long x = PyLong_AsUnsignedLong(v); if (x == (unsigned long)(-1) && PyErr_Occurred()) return -1; *p = x; return 0; } else { return get_long(v, (long *)p); } } /* Floating point helpers */ /* These use ANSI/IEEE Standard 754-1985 (Standard for Binary Floating Point Arithmetic). See the following URL: http://www.psc.edu/general/software/packages/ieee/ieee.html */ /* XXX Inf/NaN are not handled quite right (but underflow is!) */ static int pack_float(double x, /* The number to pack */ char *p, /* Where to pack the high order byte */ int incr) /* 1 for big-endian; -1 for little-endian */ { int s; int e; double f; long fbits; if (x < 0) { s = 1; x = -x; } else s = 0; f = frexp(x, &e); /* Normalize f to be in the range [1.0, 2.0) */ if (0.5 <= f && f < 1.0) { f *= 2.0; e--; } else if (f == 0.0) { e = 0; } else { PyErr_SetString(PyExc_SystemError, "frexp() result out of range"); return -1; } if (e >= 128) { /* XXX 128 itself is reserved for Inf/NaN */ PyErr_SetString(PyExc_OverflowError, "float too large to pack with f format"); return -1; } else if (e < -126) { /* Gradual underflow */ f = ldexp(f, 126 + e); e = 0; } else if (!(e == 0 && f == 0.0)) { e += 127; f -= 1.0; /* Get rid of leading 1 */ } f *= 8388608.0; /* 2**23 */ fbits = (long) floor(f + 0.5); /* Round */ /* First byte */ *p = (s<<7) | (e>>1); p += incr; /* Second byte */ *p = (char) (((e&1)<<7) | (fbits>>16)); p += incr; /* Third byte */ *p = (fbits>>8) & 0xFF; p += incr; /* Fourth byte */ *p = fbits&0xFF; /* Done */ return 0; } static int pack_double(double x, /* The number to pack */ char *p, /* Where to pack the high order byte */ int incr) /* 1 for big-endian; -1 for little-endian */ { int s; int e; double f; long fhi, flo; if (x < 0) { s = 1; x = -x; } else s = 0; f = frexp(x, &e); /* Normalize f to be in the range [1.0, 2.0) */ if (0.5 <= f && f < 1.0) { f *= 2.0; e--; } else if (f == 0.0) { e = 0; } else { PyErr_SetString(PyExc_SystemError, "frexp() result out of range"); return -1; } if (e >= 1024) { /* XXX 1024 itself is reserved for Inf/NaN */ PyErr_SetString(PyExc_OverflowError, "float too large to pack with d format"); return -1; } else if (e < -1022) { /* Gradual underflow */ f = ldexp(f, 1022 + e); e = 0; } else if (!(e == 0 && f == 0.0)) { e += 1023; f -= 1.0; /* Get rid of leading 1 */ } /* fhi receives the high 28 bits; flo the low 24 bits (== 52 bits) */ f *= 268435456.0; /* 2**28 */ fhi = (long) floor(f); /* Truncate */ f -= (double)fhi; f *= 16777216.0; /* 2**24 */ flo = (long) floor(f + 0.5); /* Round */ /* First byte */ *p = (s<<7) | (e>>4); p += incr; /* Second byte */ *p = (char) (((e&0xF)<<4) | (fhi>>24)); p += incr; /* Third byte */ *p = (fhi>>16) & 0xFF; p += incr; /* Fourth byte */ *p = (fhi>>8) & 0xFF; p += incr; /* Fifth byte */ *p = fhi & 0xFF; p += incr; /* Sixth byte */ *p = (flo>>16) & 0xFF; p += incr; /* Seventh byte */ *p = (flo>>8) & 0xFF; p += incr; /* Eighth byte */ *p = flo & 0xFF; p += incr; /* Done */ return 0; } static PyObject * unpack_float(const char *p, /* Where the high order byte is */ int incr) /* 1 for big-endian; -1 for little-endian */ { int s; int e; long f; double x; /* First byte */ s = (*p>>7) & 1; e = (*p & 0x7F) << 1; p += incr; /* Second byte */ e |= (*p>>7) & 1; f = (*p & 0x7F) << 16; p += incr; /* Third byte */ f |= (*p & 0xFF) << 8; p += incr; /* Fourth byte */ f |= *p & 0xFF; x = (double)f / 8388608.0; /* XXX This sadly ignores Inf/NaN issues */ if (e == 0) e = -126; else { x += 1.0; e -= 127; } x = ldexp(x, e); if (s) x = -x; return PyFloat_FromDouble(x); } static PyObject * unpack_double(const char *p, /* Where the high order byte is */ int incr) /* 1 for big-endian; -1 for little-endian */ { int s; int e; long fhi, flo; double x; /* First byte */ s = (*p>>7) & 1; e = (*p & 0x7F) << 4; p += incr; /* Second byte */ e |= (*p>>4) & 0xF; fhi = (*p & 0xF) << 24; p += incr; /* Third byte */ fhi |= (*p & 0xFF) << 16; p += incr; /* Fourth byte */ fhi |= (*p & 0xFF) << 8; p += incr; /* Fifth byte */ fhi |= *p & 0xFF; p += incr; /* Sixth byte */ flo = (*p & 0xFF) << 16; p += incr; /* Seventh byte */ flo |= (*p & 0xFF) << 8; p += incr; /* Eighth byte */ flo |= *p & 0xFF; p += incr; x = (double)fhi + (double)flo / 16777216.0; /* 2**24 */ x /= 268435456.0; /* 2**28 */ /* XXX This sadly ignores Inf/NaN */ if (e == 0) e = -1022; else { x += 1.0; e -= 1023; } x = ldexp(x, e); if (s) x = -x; return PyFloat_FromDouble(x); } /* The translation function for each format character is table driven */ typedef struct _formatdef { char format; int size; int alignment; PyObject* (*unpack)(const char *, const struct _formatdef *); int (*pack)(char *, PyObject *, const struct _formatdef *); } formatdef; static PyObject * nu_char(const char *p, const formatdef *f) { return PyString_FromStringAndSize(p, 1); } static PyObject * nu_byte(const char *p, const formatdef *f) { return PyInt_FromLong((long) *(signed char *)p); } static PyObject * nu_ubyte(const char *p, const formatdef *f) { return PyInt_FromLong((long) *(unsigned char *)p); } static PyObject * nu_short(const char *p, const formatdef *f) { return PyInt_FromLong((long) *(short *)p); } static PyObject * nu_ushort(const char *p, const formatdef *f) { return PyInt_FromLong((long) *(unsigned short *)p); } static PyObject * nu_int(const char *p, const formatdef *f) { return PyInt_FromLong((long) *(int *)p); } static PyObject * nu_uint(const char *p, const formatdef *f) { unsigned int x = *(unsigned int *)p; return PyLong_FromUnsignedLong((unsigned long)x); } static PyObject * nu_long(const char *p, const formatdef *f) { return PyInt_FromLong(*(long *)p); } static PyObject * nu_ulong(const char *p, const formatdef *f) { return PyLong_FromUnsignedLong(*(unsigned long *)p); } static PyObject * nu_float(const char *p, const formatdef *f) { float x; memcpy((char *)&x, p, sizeof(float)); return PyFloat_FromDouble((double)x); } static PyObject * nu_double(const char *p, const formatdef *f) { double x; memcpy((char *)&x, p, sizeof(double)); return PyFloat_FromDouble(x); } static PyObject * nu_void_p(const char *p, const formatdef *f) { return PyLong_FromVoidPtr(*(void **)p); } static int np_byte(char *p, PyObject *v, const formatdef *f) { long x; if (get_long(v, &x) < 0) return -1; *p = (char)x; return 0; } static int np_char(char *p, PyObject *v, const formatdef *f) { if (!PyString_Check(v) || PyString_Size(v) != 1) { PyErr_SetString(StructError, "char format require string of length 1"); return -1; } *p = *PyString_AsString(v); return 0; } static int np_short(char *p, PyObject *v, const formatdef *f) { long x; if (get_long(v, &x) < 0) return -1; * (short *)p = (short)x; return 0; } static int np_int(char *p, PyObject *v, const formatdef *f) { long x; if (get_long(v, &x) < 0) return -1; * (int *)p = x; return 0; } static int np_uint(char *p, PyObject *v, const formatdef *f) { unsigned long x; if (get_ulong(v, &x) < 0) return -1; * (unsigned int *)p = x; return 0; } static int np_long(char *p, PyObject *v, const formatdef *f) { long x; if (get_long(v, &x) < 0) return -1; * (long *)p = x; return 0; } static int np_ulong(char *p, PyObject *v, const formatdef *f) { unsigned long x; if (get_ulong(v, &x) < 0) return -1; * (unsigned long *)p = x; return 0; } static int np_float(char *p, PyObject *v, const formatdef *f) { float x = (float)PyFloat_AsDouble(v); if (x == -1 && PyErr_Occurred()) { PyErr_SetString(StructError, "required argument is not a float"); return -1; } memcpy(p, (char *)&x, sizeof(float)); return 0; } static int np_double(char *p, PyObject *v, const formatdef *f) { double x = PyFloat_AsDouble(v); if (x == -1 && PyErr_Occurred()) { PyErr_SetString(StructError, "required argument is not a float"); return -1; } memcpy(p, (char *)&x, sizeof(double)); return 0; } static int np_void_p(char *p, PyObject *v, const formatdef *f) { void *x = PyLong_AsVoidPtr(v); if (x == NULL && PyErr_Occurred()) { /* ### hrm. PyLong_AsVoidPtr raises SystemError */ if (PyErr_ExceptionMatches(PyExc_TypeError)) PyErr_SetString(StructError, "required argument is not an integer"); return -1; } *(void **)p = x; return 0; } static formatdef native_table[] = { {'x', sizeof(char), 0, NULL}, {'b', sizeof(char), 0, nu_byte, np_byte}, {'B', sizeof(char), 0, nu_ubyte, np_byte}, {'c', sizeof(char), 0, nu_char, np_char}, {'s', sizeof(char), 0, NULL}, {'p', sizeof(char), 0, NULL}, {'h', sizeof(short), SHORT_ALIGN, nu_short, np_short}, {'H', sizeof(short), SHORT_ALIGN, nu_ushort, np_short}, {'i', sizeof(int), INT_ALIGN, nu_int, np_int}, {'I', sizeof(int), INT_ALIGN, nu_uint, np_uint}, {'l', sizeof(long), LONG_ALIGN, nu_long, np_long}, {'L', sizeof(long), LONG_ALIGN, nu_ulong, np_ulong}, {'f', sizeof(float), FLOAT_ALIGN, nu_float, np_float}, {'d', sizeof(double), DOUBLE_ALIGN, nu_double, np_double}, {'P', sizeof(void *), VOID_P_ALIGN, nu_void_p, np_void_p}, {0} }; static PyObject * bu_int(const char *p, const formatdef *f) { long x = 0; int i = f->size; do { x = (x<<8) | (*p++ & 0xFF); } while (--i > 0); i = 8*(sizeof(long) - f->size); if (i) { x <<= i; x >>= i; } return PyInt_FromLong(x); } static PyObject * bu_uint(const char *p, const formatdef *f) { unsigned long x = 0; int i = f->size; do { x = (x<<8) | (*p++ & 0xFF); } while (--i > 0); if (f->size >= 4) return PyLong_FromUnsignedLong(x); else return PyInt_FromLong((long)x); } static PyObject * bu_float(const char *p, const formatdef *f) { return unpack_float(p, 1); } static PyObject * bu_double(const char *p, const formatdef *f) { return unpack_double(p, 1); } static int bp_int(char *p, PyObject *v, const formatdef *f) { long x; int i; if (get_long(v, &x) < 0) return -1; i = f->size; do { p[--i] = (char)x; x >>= 8; } while (i > 0); return 0; } static int bp_uint(char *p, PyObject *v, const formatdef *f) { unsigned long x; int i; if (get_ulong(v, &x) < 0) return -1; i = f->size; do { p[--i] = (char)x; x >>= 8; } while (i > 0); return 0; } static int bp_float(char *p, PyObject *v, const formatdef *f) { double x = PyFloat_AsDouble(v); if (x == -1 && PyErr_Occurred()) { PyErr_SetString(StructError, "required argument is not a float"); return -1; } return pack_float(x, p, 1); } static int bp_double(char *p, PyObject *v, const formatdef *f) { double x = PyFloat_AsDouble(v); if (x == -1 && PyErr_Occurred()) { PyErr_SetString(StructError, "required argument is not a float"); return -1; } return pack_double(x, p, 1); } static formatdef bigendian_table[] = { {'x', 1, 0, NULL}, {'b', 1, 0, bu_int, bp_int}, {'B', 1, 0, bu_uint, bp_int}, {'c', 1, 0, nu_char, np_char}, {'s', 1, 0, NULL}, {'p', 1, 0, NULL}, {'h', 2, 0, bu_int, bp_int}, {'H', 2, 0, bu_uint, bp_uint}, {'i', 4, 0, bu_int, bp_int}, {'I', 4, 0, bu_uint, bp_uint}, {'l', 4, 0, bu_int, bp_int}, {'L', 4, 0, bu_uint, bp_uint}, {'f', 4, 0, bu_float, bp_float}, {'d', 8, 0, bu_double, bp_double}, {0} }; static PyObject * lu_int(const char *p, const formatdef *f) { long x = 0; int i = f->size; do { x = (x<<8) | (p[--i] & 0xFF); } while (i > 0); i = 8*(sizeof(long) - f->size); if (i) { x <<= i; x >>= i; } return PyInt_FromLong(x); } static PyObject * lu_uint(const char *p, const formatdef *f) { unsigned long x = 0; int i = f->size; do { x = (x<<8) | (p[--i] & 0xFF); } while (i > 0); if (f->size >= 4) return PyLong_FromUnsignedLong(x); else return PyInt_FromLong((long)x); } static PyObject * lu_float(const char *p, const formatdef *f) { return unpack_float(p+3, -1); } static PyObject * lu_double(const char *p, const formatdef *f) { return unpack_double(p+7, -1); } static int lp_int(char *p, PyObject *v, const formatdef *f) { long x; int i; if (get_long(v, &x) < 0) return -1; i = f->size; do { *p++ = (char)x; x >>= 8; } while (--i > 0); return 0; } static int lp_uint(char *p, PyObject *v, const formatdef *f) { unsigned long x; int i; if (get_ulong(v, &x) < 0) return -1; i = f->size; do { *p++ = (char)x; x >>= 8; } while (--i > 0); return 0; } static int lp_float(char *p, PyObject *v, const formatdef *f) { double x = PyFloat_AsDouble(v); if (x == -1 && PyErr_Occurred()) { PyErr_SetString(StructError, "required argument is not a float"); return -1; } return pack_float(x, p+3, -1); } static int lp_double(char *p, PyObject *v, const formatdef *f) { double x = PyFloat_AsDouble(v); if (x == -1 && PyErr_Occurred()) { PyErr_SetString(StructError, "required argument is not a float"); return -1; } return pack_double(x, p+7, -1); } static formatdef lilendian_table[] = { {'x', 1, 0, NULL}, {'b', 1, 0, lu_int, lp_int}, {'B', 1, 0, lu_uint, lp_int}, {'c', 1, 0, nu_char, np_char}, {'s', 1, 0, NULL}, {'p', 1, 0, NULL}, {'h', 2, 0, lu_int, lp_int}, {'H', 2, 0, lu_uint, lp_uint}, {'i', 4, 0, lu_int, lp_int}, {'I', 4, 0, lu_uint, lp_uint}, {'l', 4, 0, lu_int, lp_int}, {'L', 4, 0, lu_uint, lp_uint}, {'f', 4, 0, lu_float, lp_float}, {'d', 8, 0, lu_double, lp_double}, {0} }; static const formatdef * whichtable(char **pfmt) { const char *fmt = (*pfmt)++; /* May be backed out of later */ switch (*fmt) { case '<': return lilendian_table; case '>': case '!': /* Network byte order is big-endian */ return bigendian_table; case '=': { /* Host byte order -- different from native in aligment! */ int n = 1; char *p = (char *) &n; if (*p == 1) return lilendian_table; else return bigendian_table; } default: --*pfmt; /* Back out of pointer increment */ /* Fall through */ case '@': return native_table; } } /* Get the table entry for a format code */ static const formatdef * getentry(int c, const formatdef *f) { for (; f->format != '\0'; f++) { if (f->format == c) { return f; } } PyErr_SetString(StructError, "bad char in struct format"); return NULL; } /* Align a size according to a format code */ static int align(int size, int c, const formatdef *e) { if (e->format == c) { if (e->alignment) { size = ((size + e->alignment - 1) / e->alignment) * e->alignment; } } return size; } /* calculate the size of a format string */ static int calcsize(const char *fmt, const formatdef *f) { const formatdef *e; const char *s; char c; int size, num, itemsize, x; s = fmt; size = 0; while ((c = *s++) != '\0') { if (isspace((int)c)) continue; if ('0' <= c && c <= '9') { num = c - '0'; while ('0' <= (c = *s++) && c <= '9') { x = num*10 + (c - '0'); if (x/10 != num) { PyErr_SetString( StructError, "overflow in item count"); return -1; } num = x; } if (c == '\0') break; } else num = 1; e = getentry(c, f); if (e == NULL) return -1; itemsize = e->size; size = align(size, c, e); x = num * itemsize; size += x; if (x/itemsize != num || size < 0) { PyErr_SetString(StructError, "total struct size too long"); return -1; } } return size; } static char calcsize__doc__[] = "\ calcsize(fmt) -> int\n\ Return size of C struct described by format string fmt.\n\ See struct.__doc__ for more on format strings."; static PyObject * struct_calcsize(PyObject *self, PyObject *args) { char *fmt; const formatdef *f; int size; if (!PyArg_ParseTuple(args, "s:calcsize", &fmt)) return NULL; f = whichtable(&fmt); size = calcsize(fmt, f); if (size < 0) return NULL; return PyInt_FromLong((long)size); } static char pack__doc__[] = "\ pack(fmt, v1, v2, ...) -> string\n\ Return string containing values v1, v2, ... packed according to fmt.\n\ See struct.__doc__ for more on format strings."; static PyObject * struct_pack(PyObject *self, PyObject *args) { const formatdef *f, *e; PyObject *format, *result, *v; char *fmt; int size, num; int i, n; char *s, *res, *restart, *nres; char c; if (args == NULL || !PyTuple_Check(args) || (n = PyTuple_Size(args)) < 1) { PyErr_SetString(PyExc_TypeError, "struct.pack requires at least one argument"); return NULL; } format = PyTuple_GetItem(args, 0); if (!PyArg_Parse(format, "s", &fmt)) return NULL; f = whichtable(&fmt); size = calcsize(fmt, f); if (size < 0) return NULL; result = PyString_FromStringAndSize((char *)NULL, size); if (result == NULL) return NULL; s = fmt; i = 1; res = restart = PyString_AsString(result); while ((c = *s++) != '\0') { if (isspace((int)c)) continue; if ('0' <= c && c <= '9') { num = c - '0'; while ('0' <= (c = *s++) && c <= '9') num = num*10 + (c - '0'); if (c == '\0') break; } else num = 1; e = getentry(c, f); if (e == NULL) goto fail; nres = restart + align((int)(res-restart), c, e); /* Fill padd bytes with zeros */ while (res < nres) *res++ = '\0'; if (num == 0 && c != 's') continue; do { if (c == 'x') { /* doesn't consume arguments */ memset(res, '\0', num); res += num; break; } if (i >= n) { PyErr_SetString(StructError, "insufficient arguments to pack"); goto fail; } v = PyTuple_GetItem(args, i++); if (v == NULL) goto fail; if (c == 's') { /* num is string size, not repeat count */ int n; if (!PyString_Check(v)) { PyErr_SetString(StructError, "argument for 's' must be a string"); goto fail; } n = PyString_Size(v); if (n > num) n = num; if (n > 0) memcpy(res, PyString_AsString(v), n); if (n < num) memset(res+n, '\0', num-n); res += num; break; } else if (c == 'p') { /* num is string size + 1, to fit in the count byte */ int n; num--; /* now num is max string size */ if (!PyString_Check(v)) { PyErr_SetString(StructError, "argument for 'p' must be a string"); goto fail; } n = PyString_Size(v); if (n > num) n = num; if (n > 0) memcpy(res+1, PyString_AsString(v), n); if (n < num) /* no real need, just to be nice */ memset(res+1+n, '\0', num-n); *res++ = n; /* store the length byte */ res += num; break; } else { if (e->pack(res, v, e) < 0) goto fail; res += e->size; } } while (--num > 0); } if (i < n) { PyErr_SetString(StructError, "too many arguments for pack format"); goto fail; } return result; fail: Py_DECREF(result); return NULL; } static char unpack__doc__[] = "\ unpack(fmt, string) -> (v1, v2, ...)\n\ Unpack the string, containing packed C structure data, according\n\ to fmt. Requires len(string)==calcsize(fmt).\n\ See struct.__doc__ for more on format strings."; static PyObject * struct_unpack(PyObject *self, PyObject *args) { const formatdef *f, *e; char *str, *start, *fmt, *s; char c; int len, size, num; PyObject *res, *v; if (!PyArg_ParseTuple(args, "ss#:unpack", &fmt, &start, &len)) return NULL; f = whichtable(&fmt); size = calcsize(fmt, f); if (size < 0) return NULL; if (size != len) { PyErr_SetString(StructError, "unpack str size does not match format"); return NULL; } res = PyList_New(0); if (res == NULL) return NULL; str = start; s = fmt; while ((c = *s++) != '\0') { if (isspace((int)c)) continue; if ('0' <= c && c <= '9') { num = c - '0'; while ('0' <= (c = *s++) && c <= '9') num = num*10 + (c - '0'); if (c == '\0') break; } else num = 1; e = getentry(c, f); if (e == NULL) goto fail; str = start + align((int)(str-start), c, e); if (num == 0 && c != 's') continue; do { if (c == 'x') { str += num; break; } if (c == 's') { /* num is string size, not repeat count */ v = PyString_FromStringAndSize(str, num); if (v == NULL) goto fail; str += num; num = 0; } else if (c == 'p') { /* num is string buffer size, not repeat count */ int n = *(unsigned char*)str; /* first byte (unsigned) is string size */ if (n >= num) n = num-1; v = PyString_FromStringAndSize(str+1, n); if (v == NULL) goto fail; str += num; num = 0; } else { v = e->unpack(str, e); if (v == NULL) goto fail; str += e->size; } if (v == NULL || PyList_Append(res, v) < 0) goto fail; Py_DECREF(v); } while (--num > 0); } v = PyList_AsTuple(res); Py_DECREF(res); return v; fail: Py_DECREF(res); return NULL; } /* List of functions */ static PyMethodDef struct_methods[] = { {"calcsize", struct_calcsize, METH_VARARGS, calcsize__doc__}, {"pack", struct_pack, METH_VARARGS, pack__doc__}, {"unpack", struct_unpack, METH_VARARGS, unpack__doc__}, {NULL, NULL} /* sentinel */ }; /* Module initialization */ DL_EXPORT(void) initstruct(void) { PyObject *m, *d; /* Create the module and add the functions */ m = Py_InitModule4("struct", struct_methods, struct__doc__, (PyObject*)NULL, PYTHON_API_VERSION); /* Add some symbolic constants to the module */ d = PyModule_GetDict(m); StructError = PyErr_NewException("struct.error", NULL, NULL); if (StructError == NULL) return; PyDict_SetItemString(d, "error", StructError); }