/* +----------------------------------------------------------------------+ | PHP Version 7 | +----------------------------------------------------------------------+ | Copyright (c) The PHP Group | +----------------------------------------------------------------------+ | This source file is subject to version 3.01 of the PHP license, | | that is bundled with this package in the file LICENSE, and is | | available through the world-wide-web at the following url: | | http://www.php.net/license/3_01.txt | | If you did not receive a copy of the PHP license and are unable to | | obtain it through the world-wide-web, please send a note to | | license@php.net so we can mail you a copy immediately. | +----------------------------------------------------------------------+ | Author: Chris Schneider | +----------------------------------------------------------------------+ */ #include "php.h" #include #include #include #include #include #include #ifdef PHP_WIN32 #define O_RDONLY _O_RDONLY #include "win32/param.h" #else #include #endif #include "ext/standard/head.h" #include "php_string.h" #include "pack.h" #if HAVE_PWD_H #ifdef PHP_WIN32 #include "win32/pwd.h" #else #include #endif #endif #include "fsock.h" #if HAVE_NETINET_IN_H #include #endif #define INC_OUTPUTPOS(a,b) \ if ((a) < 0 || ((INT_MAX - outputpos)/((int)b)) < (a)) { \ efree(formatcodes); \ efree(formatargs); \ php_error_docref(NULL, E_WARNING, "Type %c: integer overflow in format string", code); \ RETURN_FALSE; \ } \ outputpos += (a)*(b); /* Whether machine is little endian */ char machine_little_endian; /* Mapping of byte from char (8bit) to long for machine endian */ static int byte_map[1]; /* Mappings of bytes from int (machine dependent) to int for machine endian */ static int int_map[sizeof(int)]; /* Mappings of bytes from shorts (16bit) for all endian environments */ static int machine_endian_short_map[2]; static int big_endian_short_map[2]; static int little_endian_short_map[2]; /* Mappings of bytes from longs (32bit) for all endian environments */ static int machine_endian_long_map[4]; static int big_endian_long_map[4]; static int little_endian_long_map[4]; #if SIZEOF_ZEND_LONG > 4 /* Mappings of bytes from quads (64bit) for all endian environments */ static int machine_endian_longlong_map[8]; static int big_endian_longlong_map[8]; static int little_endian_longlong_map[8]; #endif /* {{{ php_pack */ static void php_pack(zval *val, size_t size, int *map, char *output) { size_t i; char *v; convert_to_long_ex(val); v = (char *) &Z_LVAL_P(val); for (i = 0; i < size; i++) { *output++ = v[map[i]]; } } /* }}} */ /* {{{ php_pack_reverse_int32 */ static inline uint32_t php_pack_reverse_int32(uint32_t arg) { uint32_t result; result = ((arg & 0xFF) << 24) | ((arg & 0xFF00) << 8) | ((arg >> 8) & 0xFF00) | ((arg >> 24) & 0xFF); return result; } /* }}} */ /* {{{ php_pack */ static inline uint64_t php_pack_reverse_int64(uint64_t arg) { union Swap64 { uint64_t i; uint32_t ul[2]; } tmp, result; tmp.i = arg; result.ul[0] = php_pack_reverse_int32(tmp.ul[1]); result.ul[1] = php_pack_reverse_int32(tmp.ul[0]); return result.i; } /* }}} */ /* {{{ php_pack_copy_float */ static void php_pack_copy_float(int is_little_endian, void * dst, float f) { union Copy32 { float f; uint32_t i; } m; m.f = f; #ifdef WORDS_BIGENDIAN if (is_little_endian) { m.i = php_pack_reverse_int32(m.i); } #else /* WORDS_BIGENDIAN */ if (!is_little_endian) { m.i = php_pack_reverse_int32(m.i); } #endif /* WORDS_BIGENDIAN */ memcpy(dst, &m.f, sizeof(float)); } /* }}} */ /* {{{ php_pack_copy_double */ static void php_pack_copy_double(int is_little_endian, void * dst, double d) { union Copy64 { double d; uint64_t i; } m; m.d = d; #ifdef WORDS_BIGENDIAN if (is_little_endian) { m.i = php_pack_reverse_int64(m.i); } #else /* WORDS_BIGENDIAN */ if (!is_little_endian) { m.i = php_pack_reverse_int64(m.i); } #endif /* WORDS_BIGENDIAN */ memcpy(dst, &m.d, sizeof(double)); } /* }}} */ /* {{{ php_pack_parse_float */ static float php_pack_parse_float(int is_little_endian, void * src) { union Copy32 { float f; uint32_t i; } m; memcpy(&m.i, src, sizeof(float)); #ifdef WORDS_BIGENDIAN if (is_little_endian) { m.i = php_pack_reverse_int32(m.i); } #else /* WORDS_BIGENDIAN */ if (!is_little_endian) { m.i = php_pack_reverse_int32(m.i); } #endif /* WORDS_BIGENDIAN */ return m.f; } /* }}} */ /* {{{ php_pack_parse_double */ static double php_pack_parse_double(int is_little_endian, void * src) { union Copy64 { double d; uint64_t i; } m; memcpy(&m.i, src, sizeof(double)); #ifdef WORDS_BIGENDIAN if (is_little_endian) { m.i = php_pack_reverse_int64(m.i); } #else /* WORDS_BIGENDIAN */ if (!is_little_endian) { m.i = php_pack_reverse_int64(m.i); } #endif /* WORDS_BIGENDIAN */ return m.d; } /* }}} */ /* pack() idea stolen from Perl (implemented formats behave the same as there except J and P) * Implemented formats are Z, A, a, h, H, c, C, s, S, i, I, l, L, n, N, q, Q, J, P, f, d, x, X, @. * Added g, G for little endian float and big endian float, added e, E for little endian double and big endian double. */ /* {{{ proto string pack(string format, mixed arg1 [, mixed arg2 [, mixed ...]]) Takes one or more arguments and packs them into a binary string according to the format argument */ PHP_FUNCTION(pack) { zval *argv = NULL; int num_args = 0; size_t i; int currentarg; char *format; size_t formatlen; char *formatcodes; int *formatargs; size_t formatcount = 0; int outputpos = 0, outputsize = 0; zend_string *output; ZEND_PARSE_PARAMETERS_START(1, -1) Z_PARAM_STRING(format, formatlen) Z_PARAM_VARIADIC('*', argv, num_args) ZEND_PARSE_PARAMETERS_END(); /* We have a maximum of format codes to deal with */ formatcodes = safe_emalloc(formatlen, sizeof(*formatcodes), 0); formatargs = safe_emalloc(formatlen, sizeof(*formatargs), 0); currentarg = 0; /* Preprocess format into formatcodes and formatargs */ for (i = 0; i < formatlen; formatcount++) { char code = format[i++]; int arg = 1; /* Handle format arguments if any */ if (i < formatlen) { char c = format[i]; if (c == '*') { arg = -1; i++; } else if (c >= '0' && c <= '9') { arg = atoi(&format[i]); while (format[i] >= '0' && format[i] <= '9' && i < formatlen) { i++; } } } /* Handle special arg '*' for all codes and check argv overflows */ switch ((int) code) { /* Never uses any args */ case 'x': case 'X': case '@': if (arg < 0) { php_error_docref(NULL, E_WARNING, "Type %c: '*' ignored", code); arg = 1; } break; /* Always uses one arg */ case 'a': case 'A': case 'Z': case 'h': case 'H': if (currentarg >= num_args) { efree(formatcodes); efree(formatargs); php_error_docref(NULL, E_WARNING, "Type %c: not enough arguments", code); RETURN_FALSE; } if (arg < 0) { if (!try_convert_to_string(&argv[currentarg])) { efree(formatcodes); efree(formatargs); return; } arg = Z_STRLEN(argv[currentarg]); if (code == 'Z') { /* add one because Z is always NUL-terminated: * pack("Z*", "aa") === "aa\0" * pack("Z2", "aa") === "a\0" */ arg++; } } currentarg++; break; /* Use as many args as specified */ case 'q': case 'Q': case 'J': case 'P': #if SIZEOF_ZEND_LONG < 8 efree(formatcodes); efree(formatargs); php_error_docref(NULL, E_WARNING, "64-bit format codes are not available for 32-bit versions of PHP"); RETURN_FALSE; #endif case 'c': case 'C': case 's': case 'S': case 'i': case 'I': case 'l': case 'L': case 'n': case 'N': case 'v': case 'V': case 'f': /* float */ case 'g': /* little endian float */ case 'G': /* big endian float */ case 'd': /* double */ case 'e': /* little endian double */ case 'E': /* big endian double */ if (arg < 0) { arg = num_args - currentarg; } if (currentarg > INT_MAX - arg) { goto too_few_args; } currentarg += arg; if (currentarg > num_args) { too_few_args: efree(formatcodes); efree(formatargs); php_error_docref(NULL, E_WARNING, "Type %c: too few arguments", code); RETURN_FALSE; } break; default: efree(formatcodes); efree(formatargs); php_error_docref(NULL, E_WARNING, "Type %c: unknown format code", code); RETURN_FALSE; } formatcodes[formatcount] = code; formatargs[formatcount] = arg; } if (currentarg < num_args) { php_error_docref(NULL, E_WARNING, "%d arguments unused", (num_args - currentarg)); } /* Calculate output length and upper bound while processing*/ for (i = 0; i < formatcount; i++) { int code = (int) formatcodes[i]; int arg = formatargs[i]; switch ((int) code) { case 'h': case 'H': INC_OUTPUTPOS((arg + (arg % 2)) / 2,1) /* 4 bit per arg */ break; case 'a': case 'A': case 'Z': case 'c': case 'C': case 'x': INC_OUTPUTPOS(arg,1) /* 8 bit per arg */ break; case 's': case 'S': case 'n': case 'v': INC_OUTPUTPOS(arg,2) /* 16 bit per arg */ break; case 'i': case 'I': INC_OUTPUTPOS(arg,sizeof(int)) break; case 'l': case 'L': case 'N': case 'V': INC_OUTPUTPOS(arg,4) /* 32 bit per arg */ break; #if SIZEOF_ZEND_LONG > 4 case 'q': case 'Q': case 'J': case 'P': INC_OUTPUTPOS(arg,8) /* 32 bit per arg */ break; #endif case 'f': /* float */ case 'g': /* little endian float */ case 'G': /* big endian float */ INC_OUTPUTPOS(arg,sizeof(float)) break; case 'd': /* double */ case 'e': /* little endian double */ case 'E': /* big endian double */ INC_OUTPUTPOS(arg,sizeof(double)) break; case 'X': outputpos -= arg; if (outputpos < 0) { php_error_docref(NULL, E_WARNING, "Type %c: outside of string", code); outputpos = 0; } break; case '@': outputpos = arg; break; } if (outputsize < outputpos) { outputsize = outputpos; } } output = zend_string_alloc(outputsize, 0); outputpos = 0; currentarg = 0; /* Do actual packing */ for (i = 0; i < formatcount; i++) { int code = (int) formatcodes[i]; int arg = formatargs[i]; switch ((int) code) { case 'a': case 'A': case 'Z': { size_t arg_cp = (code != 'Z') ? arg : MAX(0, arg - 1); zend_string *tmp_str; zend_string *str = zval_get_tmp_string(&argv[currentarg++], &tmp_str); memset(&ZSTR_VAL(output)[outputpos], (code == 'a' || code == 'Z') ? '\0' : ' ', arg); memcpy(&ZSTR_VAL(output)[outputpos], ZSTR_VAL(str), (ZSTR_LEN(str) < arg_cp) ? ZSTR_LEN(str) : arg_cp); outputpos += arg; zend_tmp_string_release(tmp_str); break; } case 'h': case 'H': { int nibbleshift = (code == 'h') ? 0 : 4; int first = 1; zend_string *tmp_str; zend_string *str = zval_get_tmp_string(&argv[currentarg++], &tmp_str); char *v = ZSTR_VAL(str); outputpos--; if ((size_t)arg > ZSTR_LEN(str)) { php_error_docref(NULL, E_WARNING, "Type %c: not enough characters in string", code); arg = ZSTR_LEN(str); } while (arg-- > 0) { char n = *v++; if (n >= '0' && n <= '9') { n -= '0'; } else if (n >= 'A' && n <= 'F') { n -= ('A' - 10); } else if (n >= 'a' && n <= 'f') { n -= ('a' - 10); } else { php_error_docref(NULL, E_WARNING, "Type %c: illegal hex digit %c", code, n); n = 0; } if (first--) { ZSTR_VAL(output)[++outputpos] = 0; } else { first = 1; } ZSTR_VAL(output)[outputpos] |= (n << nibbleshift); nibbleshift = (nibbleshift + 4) & 7; } outputpos++; zend_tmp_string_release(tmp_str); break; } case 'c': case 'C': while (arg-- > 0) { php_pack(&argv[currentarg++], 1, byte_map, &ZSTR_VAL(output)[outputpos]); outputpos++; } break; case 's': case 'S': case 'n': case 'v': { int *map = machine_endian_short_map; if (code == 'n') { map = big_endian_short_map; } else if (code == 'v') { map = little_endian_short_map; } while (arg-- > 0) { php_pack(&argv[currentarg++], 2, map, &ZSTR_VAL(output)[outputpos]); outputpos += 2; } break; } case 'i': case 'I': while (arg-- > 0) { php_pack(&argv[currentarg++], sizeof(int), int_map, &ZSTR_VAL(output)[outputpos]); outputpos += sizeof(int); } break; case 'l': case 'L': case 'N': case 'V': { int *map = machine_endian_long_map; if (code == 'N') { map = big_endian_long_map; } else if (code == 'V') { map = little_endian_long_map; } while (arg-- > 0) { php_pack(&argv[currentarg++], 4, map, &ZSTR_VAL(output)[outputpos]); outputpos += 4; } break; } #if SIZEOF_ZEND_LONG > 4 case 'q': case 'Q': case 'J': case 'P': { int *map = machine_endian_longlong_map; if (code == 'J') { map = big_endian_longlong_map; } else if (code == 'P') { map = little_endian_longlong_map; } while (arg-- > 0) { php_pack(&argv[currentarg++], 8, map, &ZSTR_VAL(output)[outputpos]); outputpos += 8; } break; } #endif case 'f': { while (arg-- > 0) { float v = (float) zval_get_double(&argv[currentarg++]); memcpy(&ZSTR_VAL(output)[outputpos], &v, sizeof(v)); outputpos += sizeof(v); } break; } case 'g': { /* pack little endian float */ while (arg-- > 0) { float v = (float) zval_get_double(&argv[currentarg++]); php_pack_copy_float(1, &ZSTR_VAL(output)[outputpos], v); outputpos += sizeof(v); } break; } case 'G': { /* pack big endian float */ while (arg-- > 0) { float v = (float) zval_get_double(&argv[currentarg++]); php_pack_copy_float(0, &ZSTR_VAL(output)[outputpos], v); outputpos += sizeof(v); } break; } case 'd': { while (arg-- > 0) { double v = (double) zval_get_double(&argv[currentarg++]); memcpy(&ZSTR_VAL(output)[outputpos], &v, sizeof(v)); outputpos += sizeof(v); } break; } case 'e': { /* pack little endian double */ while (arg-- > 0) { double v = (double) zval_get_double(&argv[currentarg++]); php_pack_copy_double(1, &ZSTR_VAL(output)[outputpos], v); outputpos += sizeof(v); } break; } case 'E': { /* pack big endian double */ while (arg-- > 0) { double v = (double) zval_get_double(&argv[currentarg++]); php_pack_copy_double(0, &ZSTR_VAL(output)[outputpos], v); outputpos += sizeof(v); } break; } case 'x': memset(&ZSTR_VAL(output)[outputpos], '\0', arg); outputpos += arg; break; case 'X': outputpos -= arg; if (outputpos < 0) { outputpos = 0; } break; case '@': if (arg > outputpos) { memset(&ZSTR_VAL(output)[outputpos], '\0', arg - outputpos); } outputpos = arg; break; } } efree(formatcodes); efree(formatargs); ZSTR_VAL(output)[outputpos] = '\0'; ZSTR_LEN(output) = outputpos; RETURN_NEW_STR(output); } /* }}} */ /* {{{ php_unpack */ static zend_long php_unpack(char *data, size_t size, int issigned, int *map) { zend_long result; char *cresult = (char *) &result; size_t i; result = issigned ? -1 : 0; for (i = 0; i < size; i++) { cresult[map[i]] = *data++; } return result; } /* }}} */ /* unpack() is based on Perl's unpack(), but is modified a bit from there. * Rather than depending on error-prone ordered lists or syntactically * unpleasant pass-by-reference, we return an object with named parameters * (like *_fetch_object()). Syntax is "f[repeat]name/...", where "f" is the * formatter char (like pack()), "[repeat]" is the optional repeater argument, * and "name" is the name of the variable to use. * Example: "c2chars/nints" will return an object with fields * chars1, chars2, and ints. * Numeric pack types will return numbers, a and A will return strings, * f and d will return doubles. * Implemented formats are Z, A, a, h, H, c, C, s, S, i, I, l, L, n, N, q, Q, J, P, f, d, x, X, @. * Added g, G for little endian float and big endian float, added e, E for little endian double and big endian double. */ /* {{{ proto array unpack(string format, string input) Unpack binary string into named array elements according to format argument */ PHP_FUNCTION(unpack) { char *format, *input; zend_string *formatarg, *inputarg; zend_long formatlen, inputpos, inputlen; int i; zend_long offset = 0; ZEND_PARSE_PARAMETERS_START(2, 3) Z_PARAM_STR(formatarg) Z_PARAM_STR(inputarg) Z_PARAM_OPTIONAL Z_PARAM_LONG(offset) ZEND_PARSE_PARAMETERS_END(); format = ZSTR_VAL(formatarg); formatlen = ZSTR_LEN(formatarg); input = ZSTR_VAL(inputarg); inputlen = ZSTR_LEN(inputarg); inputpos = 0; if (offset < 0 || offset > inputlen) { php_error_docref(NULL, E_WARNING, "Offset " ZEND_LONG_FMT " is out of input range" , offset); RETURN_FALSE; } input += offset; inputlen -= offset; array_init(return_value); while (formatlen-- > 0) { char type = *(format++); char c; int arg = 1, argb; char *name; int namelen; int size=0; /* Handle format arguments if any */ if (formatlen > 0) { c = *format; if (c >= '0' && c <= '9') { arg = atoi(format); while (formatlen > 0 && *format >= '0' && *format <= '9') { format++; formatlen--; } } else if (c == '*') { arg = -1; format++; formatlen--; } } /* Get of new value in array */ name = format; argb = arg; while (formatlen > 0 && *format != '/') { formatlen--; format++; } namelen = format - name; if (namelen > 200) namelen = 200; switch ((int) type) { /* Never use any input */ case 'X': size = -1; if (arg < 0) { php_error_docref(NULL, E_WARNING, "Type %c: '*' ignored", type); arg = 1; } break; case '@': size = 0; break; case 'a': case 'A': case 'Z': size = arg; arg = 1; break; case 'h': case 'H': size = (arg > 0) ? (arg + (arg % 2)) / 2 : arg; arg = 1; break; /* Use 1 byte of input */ case 'c': case 'C': case 'x': size = 1; break; /* Use 2 bytes of input */ case 's': case 'S': case 'n': case 'v': size = 2; break; /* Use sizeof(int) bytes of input */ case 'i': case 'I': size = sizeof(int); break; /* Use 4 bytes of input */ case 'l': case 'L': case 'N': case 'V': size = 4; break; /* Use 8 bytes of input */ case 'q': case 'Q': case 'J': case 'P': #if SIZEOF_ZEND_LONG > 4 size = 8; break; #else php_error_docref(NULL, E_WARNING, "64-bit format codes are not available for 32-bit versions of PHP"); zend_array_destroy(Z_ARR_P(return_value)); RETURN_FALSE; #endif /* Use sizeof(float) bytes of input */ case 'f': case 'g': case 'G': size = sizeof(float); break; /* Use sizeof(double) bytes of input */ case 'd': case 'e': case 'E': size = sizeof(double); break; default: php_error_docref(NULL, E_WARNING, "Invalid format type %c", type); zend_array_destroy(Z_ARR_P(return_value)); RETURN_FALSE; break; } if (size != 0 && size != -1 && size < 0) { php_error_docref(NULL, E_WARNING, "Type %c: integer overflow", type); zend_array_destroy(Z_ARR_P(return_value)); RETURN_FALSE; } /* Do actual unpacking */ for (i = 0; i != arg; i++ ) { /* Space for name + number, safe as namelen is ensured <= 200 */ char n[256]; if (arg != 1 || namelen == 0) { /* Need to add element number to name */ snprintf(n, sizeof(n), "%.*s%d", namelen, name, i + 1); } else { /* Truncate name to next format code or end of string */ snprintf(n, sizeof(n), "%.*s", namelen, name); } if (size != 0 && size != -1 && INT_MAX - size + 1 < inputpos) { php_error_docref(NULL, E_WARNING, "Type %c: integer overflow", type); zend_array_destroy(Z_ARR_P(return_value)); RETURN_FALSE; } if ((inputpos + size) <= inputlen) { switch ((int) type) { case 'a': { /* a will not strip any trailing whitespace or null padding */ zend_long len = inputlen - inputpos; /* Remaining string */ /* If size was given take minimum of len and size */ if ((size >= 0) && (len > size)) { len = size; } size = len; add_assoc_stringl(return_value, n, &input[inputpos], len); break; } case 'A': { /* A will strip any trailing whitespace */ char padn = '\0'; char pads = ' '; char padt = '\t'; char padc = '\r'; char padl = '\n'; zend_long len = inputlen - inputpos; /* Remaining string */ /* If size was given take minimum of len and size */ if ((size >= 0) && (len > size)) { len = size; } size = len; /* Remove trailing white space and nulls chars from unpacked data */ while (--len >= 0) { if (input[inputpos + len] != padn && input[inputpos + len] != pads && input[inputpos + len] != padt && input[inputpos + len] != padc && input[inputpos + len] != padl ) break; } add_assoc_stringl(return_value, n, &input[inputpos], len + 1); break; } /* New option added for Z to remain in-line with the Perl implementation */ case 'Z': { /* Z will strip everything after the first null character */ char pad = '\0'; zend_long s, len = inputlen - inputpos; /* Remaining string */ /* If size was given take minimum of len and size */ if ((size >= 0) && (len > size)) { len = size; } size = len; /* Remove everything after the first null */ for (s=0 ; s < len ; s++) { if (input[inputpos + s] == pad) break; } len = s; add_assoc_stringl(return_value, n, &input[inputpos], len); break; } case 'h': case 'H': { zend_long len = (inputlen - inputpos) * 2; /* Remaining */ int nibbleshift = (type == 'h') ? 0 : 4; int first = 1; zend_string *buf; zend_long ipos, opos; /* If size was given take minimum of len and size */ if (size >= 0 && len > (size * 2)) { len = size * 2; } if (len > 0 && argb > 0) { len -= argb % 2; } buf = zend_string_alloc(len, 0); for (ipos = opos = 0; opos < len; opos++) { char cc = (input[inputpos + ipos] >> nibbleshift) & 0xf; if (cc < 10) { cc += '0'; } else { cc += 'a' - 10; } ZSTR_VAL(buf)[opos] = cc; nibbleshift = (nibbleshift + 4) & 7; if (first-- == 0) { ipos++; first = 1; } } ZSTR_VAL(buf)[len] = '\0'; add_assoc_str(return_value, n, buf); break; } case 'c': case 'C': { int issigned = (type == 'c') ? (input[inputpos] & 0x80) : 0; zend_long v = php_unpack(&input[inputpos], 1, issigned, byte_map); add_assoc_long(return_value, n, v); break; } case 's': case 'S': case 'n': case 'v': { zend_long v; int issigned = 0; int *map = machine_endian_short_map; if (type == 's') { issigned = input[inputpos + (machine_little_endian ? 1 : 0)] & 0x80; } else if (type == 'n') { map = big_endian_short_map; } else if (type == 'v') { map = little_endian_short_map; } v = php_unpack(&input[inputpos], 2, issigned, map); add_assoc_long(return_value, n, v); break; } case 'i': case 'I': { zend_long v; int issigned = 0; if (type == 'i') { issigned = input[inputpos + (machine_little_endian ? (sizeof(int) - 1) : 0)] & 0x80; } v = php_unpack(&input[inputpos], sizeof(int), issigned, int_map); add_assoc_long(return_value, n, v); break; } case 'l': case 'L': case 'N': case 'V': { int issigned = 0; int *map = machine_endian_long_map; zend_long v = 0; if (type == 'l' || type == 'L') { issigned = input[inputpos + (machine_little_endian ? 3 : 0)] & 0x80; } else if (type == 'N') { issigned = input[inputpos] & 0x80; map = big_endian_long_map; } else if (type == 'V') { issigned = input[inputpos + 3] & 0x80; map = little_endian_long_map; } if (SIZEOF_ZEND_LONG > 4 && issigned) { v = ~INT_MAX; } v |= php_unpack(&input[inputpos], 4, issigned, map); if (SIZEOF_ZEND_LONG > 4) { if (type == 'l') { v = (signed int) v; } else { v = (unsigned int) v; } } add_assoc_long(return_value, n, v); break; } #if SIZEOF_ZEND_LONG > 4 case 'q': case 'Q': case 'J': case 'P': { int issigned = 0; int *map = machine_endian_longlong_map; zend_long v = 0; if (type == 'q' || type == 'Q') { issigned = input[inputpos + (machine_little_endian ? 7 : 0)] & 0x80; } else if (type == 'J') { issigned = input[inputpos] & 0x80; map = big_endian_longlong_map; } else if (type == 'P') { issigned = input[inputpos + 7] & 0x80; map = little_endian_longlong_map; } v = php_unpack(&input[inputpos], 8, issigned, map); if (type == 'q') { v = (zend_long) v; } else { v = (zend_ulong) v; } add_assoc_long(return_value, n, v); break; } #endif case 'f': /* float */ case 'g': /* little endian float*/ case 'G': /* big endian float*/ { float v; if (type == 'g') { v = php_pack_parse_float(1, &input[inputpos]); } else if (type == 'G') { v = php_pack_parse_float(0, &input[inputpos]); } else { memcpy(&v, &input[inputpos], sizeof(float)); } add_assoc_double(return_value, n, (double)v); break; } case 'd': /* double */ case 'e': /* little endian float */ case 'E': /* big endian float */ { double v; if (type == 'e') { v = php_pack_parse_double(1, &input[inputpos]); } else if (type == 'E') { v = php_pack_parse_double(0, &input[inputpos]); } else { memcpy(&v, &input[inputpos], sizeof(double)); } add_assoc_double(return_value, n, v); break; } case 'x': /* Do nothing with input, just skip it */ break; case 'X': if (inputpos < size) { inputpos = -size; i = arg - 1; /* Break out of for loop */ if (arg >= 0) { php_error_docref(NULL, E_WARNING, "Type %c: outside of string", type); } } break; case '@': if (arg <= inputlen) { inputpos = arg; } else { php_error_docref(NULL, E_WARNING, "Type %c: outside of string", type); } i = arg - 1; /* Done, break out of for loop */ break; } inputpos += size; if (inputpos < 0) { if (size != -1) { /* only print warning if not working with * */ php_error_docref(NULL, E_WARNING, "Type %c: outside of string", type); } inputpos = 0; } } else if (arg < 0) { /* Reached end of input for '*' repeater */ break; } else { php_error_docref(NULL, E_WARNING, "Type %c: not enough input, need %d, have " ZEND_LONG_FMT, type, size, inputlen - inputpos); zend_array_destroy(Z_ARR_P(return_value)); RETURN_FALSE; } } if (formatlen > 0) { formatlen--; /* Skip '/' separator, does no harm if inputlen == 0 */ format++; } } } /* }}} */ /* {{{ PHP_MINIT_FUNCTION */ PHP_MINIT_FUNCTION(pack) { int machine_endian_check = 1; int i; machine_little_endian = ((char *)&machine_endian_check)[0]; if (machine_little_endian) { /* Where to get lo to hi bytes from */ byte_map[0] = 0; for (i = 0; i < (int)sizeof(int); i++) { int_map[i] = i; } machine_endian_short_map[0] = 0; machine_endian_short_map[1] = 1; big_endian_short_map[0] = 1; big_endian_short_map[1] = 0; little_endian_short_map[0] = 0; little_endian_short_map[1] = 1; machine_endian_long_map[0] = 0; machine_endian_long_map[1] = 1; machine_endian_long_map[2] = 2; machine_endian_long_map[3] = 3; big_endian_long_map[0] = 3; big_endian_long_map[1] = 2; big_endian_long_map[2] = 1; big_endian_long_map[3] = 0; little_endian_long_map[0] = 0; little_endian_long_map[1] = 1; little_endian_long_map[2] = 2; little_endian_long_map[3] = 3; #if SIZEOF_ZEND_LONG > 4 machine_endian_longlong_map[0] = 0; machine_endian_longlong_map[1] = 1; machine_endian_longlong_map[2] = 2; machine_endian_longlong_map[3] = 3; machine_endian_longlong_map[4] = 4; machine_endian_longlong_map[5] = 5; machine_endian_longlong_map[6] = 6; machine_endian_longlong_map[7] = 7; big_endian_longlong_map[0] = 7; big_endian_longlong_map[1] = 6; big_endian_longlong_map[2] = 5; big_endian_longlong_map[3] = 4; big_endian_longlong_map[4] = 3; big_endian_longlong_map[5] = 2; big_endian_longlong_map[6] = 1; big_endian_longlong_map[7] = 0; little_endian_longlong_map[0] = 0; little_endian_longlong_map[1] = 1; little_endian_longlong_map[2] = 2; little_endian_longlong_map[3] = 3; little_endian_longlong_map[4] = 4; little_endian_longlong_map[5] = 5; little_endian_longlong_map[6] = 6; little_endian_longlong_map[7] = 7; #endif } else { zval val; int size = sizeof(Z_LVAL(val)); Z_LVAL(val)=0; /*silence a warning*/ /* Where to get hi to lo bytes from */ byte_map[0] = size - 1; for (i = 0; i < (int)sizeof(int); i++) { int_map[i] = size - (sizeof(int) - i); } machine_endian_short_map[0] = size - 2; machine_endian_short_map[1] = size - 1; big_endian_short_map[0] = size - 2; big_endian_short_map[1] = size - 1; little_endian_short_map[0] = size - 1; little_endian_short_map[1] = size - 2; machine_endian_long_map[0] = size - 4; machine_endian_long_map[1] = size - 3; machine_endian_long_map[2] = size - 2; machine_endian_long_map[3] = size - 1; big_endian_long_map[0] = size - 4; big_endian_long_map[1] = size - 3; big_endian_long_map[2] = size - 2; big_endian_long_map[3] = size - 1; little_endian_long_map[0] = size - 1; little_endian_long_map[1] = size - 2; little_endian_long_map[2] = size - 3; little_endian_long_map[3] = size - 4; #if SIZEOF_ZEND_LONG > 4 machine_endian_longlong_map[0] = size - 8; machine_endian_longlong_map[1] = size - 7; machine_endian_longlong_map[2] = size - 6; machine_endian_longlong_map[3] = size - 5; machine_endian_longlong_map[4] = size - 4; machine_endian_longlong_map[5] = size - 3; machine_endian_longlong_map[6] = size - 2; machine_endian_longlong_map[7] = size - 1; big_endian_longlong_map[0] = size - 8; big_endian_longlong_map[1] = size - 7; big_endian_longlong_map[2] = size - 6; big_endian_longlong_map[3] = size - 5; big_endian_longlong_map[4] = size - 4; big_endian_longlong_map[5] = size - 3; big_endian_longlong_map[6] = size - 2; big_endian_longlong_map[7] = size - 1; little_endian_longlong_map[0] = size - 1; little_endian_longlong_map[1] = size - 2; little_endian_longlong_map[2] = size - 3; little_endian_longlong_map[3] = size - 4; little_endian_longlong_map[4] = size - 5; little_endian_longlong_map[5] = size - 6; little_endian_longlong_map[6] = size - 7; little_endian_longlong_map[7] = size - 8; #endif } return SUCCESS; } /* }}} */