/* * conversion functions between pg_wchar and multibyte streams. * Tatsuo Ishii * src/backend/utils/mb/wchar.c * */ /* can be used in either frontend or backend */ #ifdef FRONTEND #include "postgres_fe.h" #else #include "postgres.h" #endif #include "mb/pg_wchar.h" /* * conversion to pg_wchar is done by "table driven." * to add an encoding support, define mb2wchar_with_len(), mblen(), dsplen() * for the particular encoding. Note that if the encoding is only * supported in the client, you don't need to define * mb2wchar_with_len() function (SJIS is the case). * * These functions generally assume that their input is validly formed. * The "verifier" functions, further down in the file, have to be more * paranoid. We expect that mblen() does not need to examine more than * the first byte of the character to discover the correct length. * * Note: for the display output of psql to work properly, the return values * of the dsplen functions must conform to the Unicode standard. In particular * the NUL character is zero width and control characters are generally * width -1. It is recommended that non-ASCII encodings refer their ASCII * subset to the ASCII routines to ensure consistency. */ /* * SQL/ASCII */ static int pg_ascii2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { int cnt = 0; while (len > 0 && *from) { *to++ = *from++; len--; cnt++; } *to = 0; return cnt; } static int pg_ascii_mblen(const unsigned char *s) { return 1; } static int pg_ascii_dsplen(const unsigned char *s) { if (*s == '\0') return 0; if (*s < 0x20 || *s == 0x7f) return -1; return 1; } /* * EUC */ static int pg_euc2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { int cnt = 0; while (len > 0 && *from) { if (*from == SS2 && len >= 2) /* JIS X 0201 (so called "1 byte * KANA") */ { from++; *to = (SS2 << 8) | *from++; len -= 2; } else if (*from == SS3 && len >= 3) /* JIS X 0212 KANJI */ { from++; *to = (SS3 << 16) | (*from++ << 8); *to |= *from++; len -= 3; } else if (IS_HIGHBIT_SET(*from) && len >= 2) /* JIS X 0208 KANJI */ { *to = *from++ << 8; *to |= *from++; len -= 2; } else /* must be ASCII */ { *to = *from++; len--; } to++; cnt++; } *to = 0; return cnt; } static inline int pg_euc_mblen(const unsigned char *s) { int len; if (*s == SS2) len = 2; else if (*s == SS3) len = 3; else if (IS_HIGHBIT_SET(*s)) len = 2; else len = 1; return len; } static inline int pg_euc_dsplen(const unsigned char *s) { int len; if (*s == SS2) len = 2; else if (*s == SS3) len = 2; else if (IS_HIGHBIT_SET(*s)) len = 2; else len = pg_ascii_dsplen(s); return len; } /* * EUC_JP */ static int pg_eucjp2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { return pg_euc2wchar_with_len(from, to, len); } static int pg_eucjp_mblen(const unsigned char *s) { return pg_euc_mblen(s); } static int pg_eucjp_dsplen(const unsigned char *s) { int len; if (*s == SS2) len = 1; else if (*s == SS3) len = 2; else if (IS_HIGHBIT_SET(*s)) len = 2; else len = pg_ascii_dsplen(s); return len; } /* * EUC_KR */ static int pg_euckr2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { return pg_euc2wchar_with_len(from, to, len); } static int pg_euckr_mblen(const unsigned char *s) { return pg_euc_mblen(s); } static int pg_euckr_dsplen(const unsigned char *s) { return pg_euc_dsplen(s); } /* * EUC_CN * */ static int pg_euccn2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { int cnt = 0; while (len > 0 && *from) { if (*from == SS2 && len >= 3) /* code set 2 (unused?) */ { from++; *to = (SS2 << 16) | (*from++ << 8); *to |= *from++; len -= 3; } else if (*from == SS3 && len >= 3) /* code set 3 (unused ?) */ { from++; *to = (SS3 << 16) | (*from++ << 8); *to |= *from++; len -= 3; } else if (IS_HIGHBIT_SET(*from) && len >= 2) /* code set 1 */ { *to = *from++ << 8; *to |= *from++; len -= 2; } else { *to = *from++; len--; } to++; cnt++; } *to = 0; return cnt; } static int pg_euccn_mblen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; else len = 1; return len; } static int pg_euccn_dsplen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; else len = pg_ascii_dsplen(s); return len; } /* * EUC_TW * */ static int pg_euctw2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { int cnt = 0; while (len > 0 && *from) { if (*from == SS2 && len >= 4) /* code set 2 */ { from++; *to = (((uint32) SS2) << 24) | (*from++ << 16); *to |= *from++ << 8; *to |= *from++; len -= 4; } else if (*from == SS3 && len >= 3) /* code set 3 (unused?) */ { from++; *to = (SS3 << 16) | (*from++ << 8); *to |= *from++; len -= 3; } else if (IS_HIGHBIT_SET(*from) && len >= 2) /* code set 2 */ { *to = *from++ << 8; *to |= *from++; len -= 2; } else { *to = *from++; len--; } to++; cnt++; } *to = 0; return cnt; } static int pg_euctw_mblen(const unsigned char *s) { int len; if (*s == SS2) len = 4; else if (*s == SS3) len = 3; else if (IS_HIGHBIT_SET(*s)) len = 2; else len = 1; return len; } static int pg_euctw_dsplen(const unsigned char *s) { int len; if (*s == SS2) len = 2; else if (*s == SS3) len = 2; else if (IS_HIGHBIT_SET(*s)) len = 2; else len = pg_ascii_dsplen(s); return len; } /* * Convert pg_wchar to EUC_* encoding. * caller must allocate enough space for "to", including a trailing zero! * len: length of from. * "from" not necessarily null terminated. */ static int pg_wchar2euc_with_len(const pg_wchar *from, unsigned char *to, int len) { int cnt = 0; while (len > 0 && *from) { unsigned char c; if ((c = (*from >> 24))) { *to++ = c; *to++ = (*from >> 16) & 0xff; *to++ = (*from >> 8) & 0xff; *to++ = *from & 0xff; cnt += 4; } else if ((c = (*from >> 16))) { *to++ = c; *to++ = (*from >> 8) & 0xff; *to++ = *from & 0xff; cnt += 3; } else if ((c = (*from >> 8))) { *to++ = c; *to++ = *from & 0xff; cnt += 2; } else { *to++ = *from; cnt++; } from++; len--; } *to = 0; return cnt; } /* * JOHAB */ static int pg_johab_mblen(const unsigned char *s) { return pg_euc_mblen(s); } static int pg_johab_dsplen(const unsigned char *s) { return pg_euc_dsplen(s); } /* * convert UTF8 string to pg_wchar (UCS-4) * caller must allocate enough space for "to", including a trailing zero! * len: length of from. * "from" not necessarily null terminated. */ static int pg_utf2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { int cnt = 0; uint32 c1, c2, c3, c4; while (len > 0 && *from) { if ((*from & 0x80) == 0) { *to = *from++; len--; } else if ((*from & 0xe0) == 0xc0) { if (len < 2) break; /* drop trailing incomplete char */ c1 = *from++ & 0x1f; c2 = *from++ & 0x3f; *to = (c1 << 6) | c2; len -= 2; } else if ((*from & 0xf0) == 0xe0) { if (len < 3) break; /* drop trailing incomplete char */ c1 = *from++ & 0x0f; c2 = *from++ & 0x3f; c3 = *from++ & 0x3f; *to = (c1 << 12) | (c2 << 6) | c3; len -= 3; } else if ((*from & 0xf8) == 0xf0) { if (len < 4) break; /* drop trailing incomplete char */ c1 = *from++ & 0x07; c2 = *from++ & 0x3f; c3 = *from++ & 0x3f; c4 = *from++ & 0x3f; *to = (c1 << 18) | (c2 << 12) | (c3 << 6) | c4; len -= 4; } else { /* treat a bogus char as length 1; not ours to raise error */ *to = *from++; len--; } to++; cnt++; } *to = 0; return cnt; } /* * Map a Unicode code point to UTF-8. utf8string must have 4 bytes of * space allocated. */ unsigned char * unicode_to_utf8(pg_wchar c, unsigned char *utf8string) { if (c <= 0x7F) { utf8string[0] = c; } else if (c <= 0x7FF) { utf8string[0] = 0xC0 | ((c >> 6) & 0x1F); utf8string[1] = 0x80 | (c & 0x3F); } else if (c <= 0xFFFF) { utf8string[0] = 0xE0 | ((c >> 12) & 0x0F); utf8string[1] = 0x80 | ((c >> 6) & 0x3F); utf8string[2] = 0x80 | (c & 0x3F); } else { utf8string[0] = 0xF0 | ((c >> 18) & 0x07); utf8string[1] = 0x80 | ((c >> 12) & 0x3F); utf8string[2] = 0x80 | ((c >> 6) & 0x3F); utf8string[3] = 0x80 | (c & 0x3F); } return utf8string; } /* * Trivial conversion from pg_wchar to UTF-8. * caller should allocate enough space for "to" * len: length of from. * "from" not necessarily null terminated. */ static int pg_wchar2utf_with_len(const pg_wchar *from, unsigned char *to, int len) { int cnt = 0; while (len > 0 && *from) { int char_len; unicode_to_utf8(*from, to); char_len = pg_utf_mblen(to); cnt += char_len; to += char_len; from++; len--; } *to = 0; return cnt; } /* * Return the byte length of a UTF8 character pointed to by s * * Note: in the current implementation we do not support UTF8 sequences * of more than 4 bytes; hence do NOT return a value larger than 4. * We return "1" for any leading byte that is either flat-out illegal or * indicates a length larger than we support. * * pg_utf2wchar_with_len(), utf8_to_unicode(), pg_utf8_islegal(), and perhaps * other places would need to be fixed to change this. */ int pg_utf_mblen(const unsigned char *s) { int len; if ((*s & 0x80) == 0) len = 1; else if ((*s & 0xe0) == 0xc0) len = 2; else if ((*s & 0xf0) == 0xe0) len = 3; else if ((*s & 0xf8) == 0xf0) len = 4; #ifdef NOT_USED else if ((*s & 0xfc) == 0xf8) len = 5; else if ((*s & 0xfe) == 0xfc) len = 6; #endif else len = 1; return len; } /* * This is an implementation of wcwidth() and wcswidth() as defined in * "The Single UNIX Specification, Version 2, The Open Group, 1997" * * * Markus Kuhn -- 2001-09-08 -- public domain * * customised for PostgreSQL * * original available at : http://www.cl.cam.ac.uk/~mgk25/ucs/wcwidth.c */ struct mbinterval { unsigned short first; unsigned short last; }; /* auxiliary function for binary search in interval table */ static int mbbisearch(pg_wchar ucs, const struct mbinterval * table, int max) { int min = 0; int mid; if (ucs < table[0].first || ucs > table[max].last) return 0; while (max >= min) { mid = (min + max) / 2; if (ucs > table[mid].last) min = mid + 1; else if (ucs < table[mid].first) max = mid - 1; else return 1; } return 0; } /* The following functions define the column width of an ISO 10646 * character as follows: * * - The null character (U+0000) has a column width of 0. * * - Other C0/C1 control characters and DEL will lead to a return * value of -1. * * - Non-spacing and enclosing combining characters (general * category code Mn or Me in the Unicode database) have a * column width of 0. * * - Other format characters (general category code Cf in the Unicode * database) and ZERO WIDTH SPACE (U+200B) have a column width of 0. * * - Hangul Jamo medial vowels and final consonants (U+1160-U+11FF) * have a column width of 0. * * - Spacing characters in the East Asian Wide (W) or East Asian * FullWidth (F) category as defined in Unicode Technical * Report #11 have a column width of 2. * * - All remaining characters (including all printable * ISO 8859-1 and WGL4 characters, Unicode control characters, * etc.) have a column width of 1. * * This implementation assumes that wchar_t characters are encoded * in ISO 10646. */ static int ucs_wcwidth(pg_wchar ucs) { /* sorted list of non-overlapping intervals of non-spacing characters */ static const struct mbinterval combining[] = { {0x0300, 0x034E}, {0x0360, 0x0362}, {0x0483, 0x0486}, {0x0488, 0x0489}, {0x0591, 0x05A1}, {0x05A3, 0x05B9}, {0x05BB, 0x05BD}, {0x05BF, 0x05BF}, {0x05C1, 0x05C2}, {0x05C4, 0x05C4}, {0x064B, 0x0655}, {0x0670, 0x0670}, {0x06D6, 0x06E4}, {0x06E7, 0x06E8}, {0x06EA, 0x06ED}, {0x070F, 0x070F}, {0x0711, 0x0711}, {0x0730, 0x074A}, {0x07A6, 0x07B0}, {0x0901, 0x0902}, {0x093C, 0x093C}, {0x0941, 0x0948}, {0x094D, 0x094D}, {0x0951, 0x0954}, {0x0962, 0x0963}, {0x0981, 0x0981}, {0x09BC, 0x09BC}, {0x09C1, 0x09C4}, {0x09CD, 0x09CD}, {0x09E2, 0x09E3}, {0x0A02, 0x0A02}, {0x0A3C, 0x0A3C}, {0x0A41, 0x0A42}, {0x0A47, 0x0A48}, {0x0A4B, 0x0A4D}, {0x0A70, 0x0A71}, {0x0A81, 0x0A82}, {0x0ABC, 0x0ABC}, {0x0AC1, 0x0AC5}, {0x0AC7, 0x0AC8}, {0x0ACD, 0x0ACD}, {0x0B01, 0x0B01}, {0x0B3C, 0x0B3C}, {0x0B3F, 0x0B3F}, {0x0B41, 0x0B43}, {0x0B4D, 0x0B4D}, {0x0B56, 0x0B56}, {0x0B82, 0x0B82}, {0x0BC0, 0x0BC0}, {0x0BCD, 0x0BCD}, {0x0C3E, 0x0C40}, {0x0C46, 0x0C48}, {0x0C4A, 0x0C4D}, {0x0C55, 0x0C56}, {0x0CBF, 0x0CBF}, {0x0CC6, 0x0CC6}, {0x0CCC, 0x0CCD}, {0x0D41, 0x0D43}, {0x0D4D, 0x0D4D}, {0x0DCA, 0x0DCA}, {0x0DD2, 0x0DD4}, {0x0DD6, 0x0DD6}, {0x0E31, 0x0E31}, {0x0E34, 0x0E3A}, {0x0E47, 0x0E4E}, {0x0EB1, 0x0EB1}, {0x0EB4, 0x0EB9}, {0x0EBB, 0x0EBC}, {0x0EC8, 0x0ECD}, {0x0F18, 0x0F19}, {0x0F35, 0x0F35}, {0x0F37, 0x0F37}, {0x0F39, 0x0F39}, {0x0F71, 0x0F7E}, {0x0F80, 0x0F84}, {0x0F86, 0x0F87}, {0x0F90, 0x0F97}, {0x0F99, 0x0FBC}, {0x0FC6, 0x0FC6}, {0x102D, 0x1030}, {0x1032, 0x1032}, {0x1036, 0x1037}, {0x1039, 0x1039}, {0x1058, 0x1059}, {0x1160, 0x11FF}, {0x17B7, 0x17BD}, {0x17C6, 0x17C6}, {0x17C9, 0x17D3}, {0x180B, 0x180E}, {0x18A9, 0x18A9}, {0x200B, 0x200F}, {0x202A, 0x202E}, {0x206A, 0x206F}, {0x20D0, 0x20E3}, {0x302A, 0x302F}, {0x3099, 0x309A}, {0xFB1E, 0xFB1E}, {0xFE20, 0xFE23}, {0xFEFF, 0xFEFF}, {0xFFF9, 0xFFFB} }; /* test for 8-bit control characters */ if (ucs == 0) return 0; if (ucs < 0x20 || (ucs >= 0x7f && ucs < 0xa0) || ucs > 0x0010ffff) return -1; /* binary search in table of non-spacing characters */ if (mbbisearch(ucs, combining, sizeof(combining) / sizeof(struct mbinterval) - 1)) return 0; /* * if we arrive here, ucs is not a combining or C0/C1 control character */ return 1 + (ucs >= 0x1100 && (ucs <= 0x115f || /* Hangul Jamo init. consonants */ (ucs >= 0x2e80 && ucs <= 0xa4cf && (ucs & ~0x0011) != 0x300a && ucs != 0x303f) || /* CJK ... Yi */ (ucs >= 0xac00 && ucs <= 0xd7a3) || /* Hangul Syllables */ (ucs >= 0xf900 && ucs <= 0xfaff) || /* CJK Compatibility * Ideographs */ (ucs >= 0xfe30 && ucs <= 0xfe6f) || /* CJK Compatibility Forms */ (ucs >= 0xff00 && ucs <= 0xff5f) || /* Fullwidth Forms */ (ucs >= 0xffe0 && ucs <= 0xffe6) || (ucs >= 0x20000 && ucs <= 0x2ffff))); } /* * Convert a UTF-8 character to a Unicode code point. * This is a one-character version of pg_utf2wchar_with_len. * * No error checks here, c must point to a long-enough string. */ pg_wchar utf8_to_unicode(const unsigned char *c) { if ((*c & 0x80) == 0) return (pg_wchar) c[0]; else if ((*c & 0xe0) == 0xc0) return (pg_wchar) (((c[0] & 0x1f) << 6) | (c[1] & 0x3f)); else if ((*c & 0xf0) == 0xe0) return (pg_wchar) (((c[0] & 0x0f) << 12) | ((c[1] & 0x3f) << 6) | (c[2] & 0x3f)); else if ((*c & 0xf8) == 0xf0) return (pg_wchar) (((c[0] & 0x07) << 18) | ((c[1] & 0x3f) << 12) | ((c[2] & 0x3f) << 6) | (c[3] & 0x3f)); else /* that is an invalid code on purpose */ return 0xffffffff; } static int pg_utf_dsplen(const unsigned char *s) { return ucs_wcwidth(utf8_to_unicode(s)); } /* * convert mule internal code to pg_wchar * caller should allocate enough space for "to" * len: length of from. * "from" not necessarily null terminated. */ static int pg_mule2wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { int cnt = 0; while (len > 0 && *from) { if (IS_LC1(*from) && len >= 2) { *to = *from++ << 16; *to |= *from++; len -= 2; } else if (IS_LCPRV1(*from) && len >= 3) { from++; *to = *from++ << 16; *to |= *from++; len -= 3; } else if (IS_LC2(*from) && len >= 3) { *to = *from++ << 16; *to |= *from++ << 8; *to |= *from++; len -= 3; } else if (IS_LCPRV2(*from) && len >= 4) { from++; *to = *from++ << 16; *to |= *from++ << 8; *to |= *from++; len -= 4; } else { /* assume ASCII */ *to = (unsigned char) *from++; len--; } to++; cnt++; } *to = 0; return cnt; } /* * convert pg_wchar to mule internal code * caller should allocate enough space for "to" * len: length of from. * "from" not necessarily null terminated. */ static int pg_wchar2mule_with_len(const pg_wchar *from, unsigned char *to, int len) { int cnt = 0; while (len > 0 && *from) { unsigned char lb; lb = (*from >> 16) & 0xff; if (IS_LC1(lb)) { *to++ = lb; *to++ = *from & 0xff; cnt += 2; } else if (IS_LC2(lb)) { *to++ = lb; *to++ = (*from >> 8) & 0xff; *to++ = *from & 0xff; cnt += 3; } else if (IS_LCPRV1_A_RANGE(lb)) { *to++ = LCPRV1_A; *to++ = lb; *to++ = *from & 0xff; cnt += 3; } else if (IS_LCPRV1_B_RANGE(lb)) { *to++ = LCPRV1_B; *to++ = lb; *to++ = *from & 0xff; cnt += 3; } else if (IS_LCPRV2_A_RANGE(lb)) { *to++ = LCPRV2_A; *to++ = lb; *to++ = (*from >> 8) & 0xff; *to++ = *from & 0xff; cnt += 4; } else if (IS_LCPRV2_B_RANGE(lb)) { *to++ = LCPRV2_B; *to++ = lb; *to++ = (*from >> 8) & 0xff; *to++ = *from & 0xff; cnt += 4; } else { *to++ = *from & 0xff; cnt += 1; } from++; len--; } *to = 0; return cnt; } int pg_mule_mblen(const unsigned char *s) { int len; if (IS_LC1(*s)) len = 2; else if (IS_LCPRV1(*s)) len = 3; else if (IS_LC2(*s)) len = 3; else if (IS_LCPRV2(*s)) len = 4; else len = 1; /* assume ASCII */ return len; } static int pg_mule_dsplen(const unsigned char *s) { int len; /* * Note: it's not really appropriate to assume that all multibyte charsets * are double-wide on screen. But this seems an okay approximation for * the MULE charsets we currently support. */ if (IS_LC1(*s)) len = 1; else if (IS_LCPRV1(*s)) len = 1; else if (IS_LC2(*s)) len = 2; else if (IS_LCPRV2(*s)) len = 2; else len = 1; /* assume ASCII */ return len; } /* * ISO8859-1 */ static int pg_latin12wchar_with_len(const unsigned char *from, pg_wchar *to, int len) { int cnt = 0; while (len > 0 && *from) { *to++ = *from++; len--; cnt++; } *to = 0; return cnt; } /* * Trivial conversion from pg_wchar to single byte encoding. Just ignores * high bits. * caller should allocate enough space for "to" * len: length of from. * "from" not necessarily null terminated. */ static int pg_wchar2single_with_len(const pg_wchar *from, unsigned char *to, int len) { int cnt = 0; while (len > 0 && *from) { *to++ = *from++; len--; cnt++; } *to = 0; return cnt; } static int pg_latin1_mblen(const unsigned char *s) { return 1; } static int pg_latin1_dsplen(const unsigned char *s) { return pg_ascii_dsplen(s); } /* * SJIS */ static int pg_sjis_mblen(const unsigned char *s) { int len; if (*s >= 0xa1 && *s <= 0xdf) len = 1; /* 1 byte kana? */ else if (IS_HIGHBIT_SET(*s)) len = 2; /* kanji? */ else len = 1; /* should be ASCII */ return len; } static int pg_sjis_dsplen(const unsigned char *s) { int len; if (*s >= 0xa1 && *s <= 0xdf) len = 1; /* 1 byte kana? */ else if (IS_HIGHBIT_SET(*s)) len = 2; /* kanji? */ else len = pg_ascii_dsplen(s); /* should be ASCII */ return len; } /* * Big5 */ static int pg_big5_mblen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; /* kanji? */ else len = 1; /* should be ASCII */ return len; } static int pg_big5_dsplen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; /* kanji? */ else len = pg_ascii_dsplen(s); /* should be ASCII */ return len; } /* * GBK */ static int pg_gbk_mblen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; /* kanji? */ else len = 1; /* should be ASCII */ return len; } static int pg_gbk_dsplen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; /* kanji? */ else len = pg_ascii_dsplen(s); /* should be ASCII */ return len; } /* * UHC */ static int pg_uhc_mblen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; /* 2byte? */ else len = 1; /* should be ASCII */ return len; } static int pg_uhc_dsplen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; /* 2byte? */ else len = pg_ascii_dsplen(s); /* should be ASCII */ return len; } /* * GB18030 * Added by Bill Huang , */ static int pg_gb18030_mblen(const unsigned char *s) { int len; if (!IS_HIGHBIT_SET(*s)) len = 1; /* ASCII */ else if (*(s + 1) >= 0x30 && *(s + 1) <= 0x39) len = 4; else len = 2; return len; } static int pg_gb18030_dsplen(const unsigned char *s) { int len; if (IS_HIGHBIT_SET(*s)) len = 2; else len = pg_ascii_dsplen(s); /* ASCII */ return len; } /* *------------------------------------------------------------------- * multibyte sequence validators * * These functions accept "s", a pointer to the first byte of a string, * and "len", the remaining length of the string. If there is a validly * encoded character beginning at *s, return its length in bytes; else * return -1. * * The functions can assume that len > 0 and that *s != '\0', but they must * test for and reject zeroes in any additional bytes of a multibyte character. * * Note that this definition allows the function for a single-byte * encoding to be just "return 1". *------------------------------------------------------------------- */ static int pg_ascii_verifier(const unsigned char *s, int len) { return 1; } #define IS_EUC_RANGE_VALID(c) ((c) >= 0xa1 && (c) <= 0xfe) static int pg_eucjp_verifier(const unsigned char *s, int len) { int l; unsigned char c1, c2; c1 = *s++; switch (c1) { case SS2: /* JIS X 0201 */ l = 2; if (l > len) return -1; c2 = *s++; if (c2 < 0xa1 || c2 > 0xdf) return -1; break; case SS3: /* JIS X 0212 */ l = 3; if (l > len) return -1; c2 = *s++; if (!IS_EUC_RANGE_VALID(c2)) return -1; c2 = *s++; if (!IS_EUC_RANGE_VALID(c2)) return -1; break; default: if (IS_HIGHBIT_SET(c1)) /* JIS X 0208? */ { l = 2; if (l > len) return -1; if (!IS_EUC_RANGE_VALID(c1)) return -1; c2 = *s++; if (!IS_EUC_RANGE_VALID(c2)) return -1; } else /* must be ASCII */ { l = 1; } break; } return l; } static int pg_euckr_verifier(const unsigned char *s, int len) { int l; unsigned char c1, c2; c1 = *s++; if (IS_HIGHBIT_SET(c1)) { l = 2; if (l > len) return -1; if (!IS_EUC_RANGE_VALID(c1)) return -1; c2 = *s++; if (!IS_EUC_RANGE_VALID(c2)) return -1; } else /* must be ASCII */ { l = 1; } return l; } /* EUC-CN byte sequences are exactly same as EUC-KR */ #define pg_euccn_verifier pg_euckr_verifier static int pg_euctw_verifier(const unsigned char *s, int len) { int l; unsigned char c1, c2; c1 = *s++; switch (c1) { case SS2: /* CNS 11643 Plane 1-7 */ l = 4; if (l > len) return -1; c2 = *s++; if (c2 < 0xa1 || c2 > 0xa7) return -1; c2 = *s++; if (!IS_EUC_RANGE_VALID(c2)) return -1; c2 = *s++; if (!IS_EUC_RANGE_VALID(c2)) return -1; break; case SS3: /* unused */ return -1; default: if (IS_HIGHBIT_SET(c1)) /* CNS 11643 Plane 1 */ { l = 2; if (l > len) return -1; /* no further range check on c1? */ c2 = *s++; if (!IS_EUC_RANGE_VALID(c2)) return -1; } else /* must be ASCII */ { l = 1; } break; } return l; } static int pg_johab_verifier(const unsigned char *s, int len) { int l, mbl; unsigned char c; l = mbl = pg_johab_mblen(s); if (len < l) return -1; if (!IS_HIGHBIT_SET(*s)) return mbl; while (--l > 0) { c = *++s; if (!IS_EUC_RANGE_VALID(c)) return -1; } return mbl; } static int pg_mule_verifier(const unsigned char *s, int len) { int l, mbl; unsigned char c; l = mbl = pg_mule_mblen(s); if (len < l) return -1; while (--l > 0) { c = *++s; if (!IS_HIGHBIT_SET(c)) return -1; } return mbl; } static int pg_latin1_verifier(const unsigned char *s, int len) { return 1; } static int pg_sjis_verifier(const unsigned char *s, int len) { int l, mbl; unsigned char c1, c2; l = mbl = pg_sjis_mblen(s); if (len < l) return -1; if (l == 1) /* pg_sjis_mblen already verified it */ return mbl; c1 = *s++; c2 = *s; if (!ISSJISHEAD(c1) || !ISSJISTAIL(c2)) return -1; return mbl; } static int pg_big5_verifier(const unsigned char *s, int len) { int l, mbl; l = mbl = pg_big5_mblen(s); if (len < l) return -1; while (--l > 0) { if (*++s == '\0') return -1; } return mbl; } static int pg_gbk_verifier(const unsigned char *s, int len) { int l, mbl; l = mbl = pg_gbk_mblen(s); if (len < l) return -1; while (--l > 0) { if (*++s == '\0') return -1; } return mbl; } static int pg_uhc_verifier(const unsigned char *s, int len) { int l, mbl; l = mbl = pg_uhc_mblen(s); if (len < l) return -1; while (--l > 0) { if (*++s == '\0') return -1; } return mbl; } static int pg_gb18030_verifier(const unsigned char *s, int len) { int l; if (!IS_HIGHBIT_SET(*s)) l = 1; /* ASCII */ else if (len >= 4 && *(s + 1) >= 0x30 && *(s + 1) <= 0x39) { /* Should be 4-byte, validate remaining bytes */ if (*s >= 0x81 && *s <= 0xfe && *(s + 2) >= 0x81 && *(s + 2) <= 0xfe && *(s + 3) >= 0x30 && *(s + 3) <= 0x39) l = 4; else l = -1; } else if (len >= 2 && *s >= 0x81 && *s <= 0xfe) { /* Should be 2-byte, validate */ if ((*(s + 1) >= 0x40 && *(s + 1) <= 0x7e) || (*(s + 1) >= 0x80 && *(s + 1) <= 0xfe)) l = 2; else l = -1; } else l = -1; return l; } static int pg_utf8_verifier(const unsigned char *s, int len) { int l = pg_utf_mblen(s); if (len < l) return -1; if (!pg_utf8_islegal(s, l)) return -1; return l; } /* * Check for validity of a single UTF-8 encoded character * * This directly implements the rules in RFC3629. The bizarre-looking * restrictions on the second byte are meant to ensure that there isn't * more than one encoding of a given Unicode character point; that is, * you may not use a longer-than-necessary byte sequence with high order * zero bits to represent a character that would fit in fewer bytes. * To do otherwise is to create security hazards (eg, create an apparent * non-ASCII character that decodes to plain ASCII). * * length is assumed to have been obtained by pg_utf_mblen(), and the * caller must have checked that that many bytes are present in the buffer. */ bool pg_utf8_islegal(const unsigned char *source, int length) { unsigned char a; switch (length) { default: /* reject lengths 5 and 6 for now */ return false; case 4: a = source[3]; if (a < 0x80 || a > 0xBF) return false; /* FALL THRU */ case 3: a = source[2]; if (a < 0x80 || a > 0xBF) return false; /* FALL THRU */ case 2: a = source[1]; switch (*source) { case 0xE0: if (a < 0xA0 || a > 0xBF) return false; break; case 0xED: if (a < 0x80 || a > 0x9F) return false; break; case 0xF0: if (a < 0x90 || a > 0xBF) return false; break; case 0xF4: if (a < 0x80 || a > 0x8F) return false; break; default: if (a < 0x80 || a > 0xBF) return false; break; } /* FALL THRU */ case 1: a = *source; if (a >= 0x80 && a < 0xC2) return false; if (a > 0xF4) return false; break; } return true; } #ifndef FRONTEND /* * Generic character incrementer function. * * Not knowing anything about the properties of the encoding in use, we just * keep incrementing the last byte until we get a validly-encoded result, * or we run out of values to try. We don't bother to try incrementing * higher-order bytes, so there's no growth in runtime for wider characters. * (If we did try to do that, we'd need to consider the likelihood that 255 * is not a valid final byte in the encoding.) */ static bool pg_generic_charinc(unsigned char *charptr, int len) { unsigned char *lastbyte = charptr + len - 1; mbverifier mbverify; /* We can just invoke the character verifier directly. */ mbverify = pg_wchar_table[GetDatabaseEncoding()].mbverify; while (*lastbyte < (unsigned char) 255) { (*lastbyte)++; if ((*mbverify) (charptr, len) == len) return true; } return false; } /* * UTF-8 character incrementer function. * * For a one-byte character less than 0x7F, we just increment the byte. * * For a multibyte character, every byte but the first must fall between 0x80 * and 0xBF; and the first byte must be between 0xC0 and 0xF4. We increment * the last byte that's not already at its maximum value. If we can't find a * byte that's less than the maximum allowable value, we simply fail. We also * need some special-case logic to skip regions used for surrogate pair * handling, as those should not occur in valid UTF-8. * * Note that we don't reset lower-order bytes back to their minimums, since * we can't afford to make an exhaustive search (see make_greater_string). */ static bool pg_utf8_increment(unsigned char *charptr, int length) { unsigned char a; unsigned char limit; switch (length) { default: /* reject lengths 5 and 6 for now */ return false; case 4: a = charptr[3]; if (a < 0xBF) { charptr[3]++; break; } /* FALL THRU */ case 3: a = charptr[2]; if (a < 0xBF) { charptr[2]++; break; } /* FALL THRU */ case 2: a = charptr[1]; switch (*charptr) { case 0xED: limit = 0x9F; break; case 0xF4: limit = 0x8F; break; default: limit = 0xBF; break; } if (a < limit) { charptr[1]++; break; } /* FALL THRU */ case 1: a = *charptr; if (a == 0x7F || a == 0xDF || a == 0xEF || a == 0xF4) return false; charptr[0]++; break; } return true; } /* * EUC-JP character incrementer function. * * If the sequence starts with SS2 (0x8e), it must be a two-byte sequence * representing JIS X 0201 characters with the second byte ranging between * 0xa1 and 0xdf. We just increment the last byte if it's less than 0xdf, * and otherwise rewrite the whole sequence to 0xa1 0xa1. * * If the sequence starts with SS3 (0x8f), it must be a three-byte sequence * in which the last two bytes range between 0xa1 and 0xfe. The last byte * is incremented if possible, otherwise the second-to-last byte. * * If the sequence starts with a value other than the above and its MSB * is set, it must be a two-byte sequence representing JIS X 0208 characters * with both bytes ranging between 0xa1 and 0xfe. The last byte is * incremented if possible, otherwise the second-to-last byte. * * Otherwise, the sequence is a single-byte ASCII character. It is * incremented up to 0x7f. */ static bool pg_eucjp_increment(unsigned char *charptr, int length) { unsigned char c1, c2; int i; c1 = *charptr; switch (c1) { case SS2: /* JIS X 0201 */ if (length != 2) return false; c2 = charptr[1]; if (c2 >= 0xdf) charptr[0] = charptr[1] = 0xa1; else if (c2 < 0xa1) charptr[1] = 0xa1; else charptr[1]++; break; case SS3: /* JIS X 0212 */ if (length != 3) return false; for (i = 2; i > 0; i--) { c2 = charptr[i]; if (c2 < 0xa1) { charptr[i] = 0xa1; return true; } else if (c2 < 0xfe) { charptr[i]++; return true; } } /* Out of 3-byte code region */ return false; default: if (IS_HIGHBIT_SET(c1)) /* JIS X 0208? */ { if (length != 2) return false; for (i = 1; i >= 0; i--) { c2 = charptr[i]; if (c2 < 0xa1) { charptr[i] = 0xa1; return true; } else if (c2 < 0xfe) { charptr[i]++; return true; } } /* Out of 2 byte code region */ return false; } else { /* ASCII, single byte */ if (c1 > 0x7e) return false; (*charptr)++; } break; } return true; } #endif /* !FRONTEND */ /* *------------------------------------------------------------------- * encoding info table * XXX must be sorted by the same order as enum pg_enc (in mb/pg_wchar.h) *------------------------------------------------------------------- */ const pg_wchar_tbl pg_wchar_table[] = { {pg_ascii2wchar_with_len, pg_wchar2single_with_len, pg_ascii_mblen, pg_ascii_dsplen, pg_ascii_verifier, 1}, /* PG_SQL_ASCII */ {pg_eucjp2wchar_with_len, pg_wchar2euc_with_len, pg_eucjp_mblen, pg_eucjp_dsplen, pg_eucjp_verifier, 3}, /* PG_EUC_JP */ {pg_euccn2wchar_with_len, pg_wchar2euc_with_len, pg_euccn_mblen, pg_euccn_dsplen, pg_euccn_verifier, 2}, /* PG_EUC_CN */ {pg_euckr2wchar_with_len, pg_wchar2euc_with_len, pg_euckr_mblen, pg_euckr_dsplen, pg_euckr_verifier, 3}, /* PG_EUC_KR */ {pg_euctw2wchar_with_len, pg_wchar2euc_with_len, pg_euctw_mblen, pg_euctw_dsplen, pg_euctw_verifier, 4}, /* PG_EUC_TW */ {pg_eucjp2wchar_with_len, pg_wchar2euc_with_len, pg_eucjp_mblen, pg_eucjp_dsplen, pg_eucjp_verifier, 3}, /* PG_EUC_JIS_2004 */ {pg_utf2wchar_with_len, pg_wchar2utf_with_len, pg_utf_mblen, pg_utf_dsplen, pg_utf8_verifier, 4}, /* PG_UTF8 */ {pg_mule2wchar_with_len, pg_wchar2mule_with_len, pg_mule_mblen, pg_mule_dsplen, pg_mule_verifier, 4}, /* PG_MULE_INTERNAL */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN1 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN2 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN3 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN4 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN5 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN6 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN7 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN8 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN9 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_LATIN10 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1256 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1258 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN866 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN874 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_KOI8R */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1251 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1252 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* ISO-8859-5 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* ISO-8859-6 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* ISO-8859-7 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* ISO-8859-8 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1250 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1253 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1254 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1255 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_WIN1257 */ {pg_latin12wchar_with_len, pg_wchar2single_with_len, pg_latin1_mblen, pg_latin1_dsplen, pg_latin1_verifier, 1}, /* PG_KOI8U */ {0, 0, pg_sjis_mblen, pg_sjis_dsplen, pg_sjis_verifier, 2}, /* PG_SJIS */ {0, 0, pg_big5_mblen, pg_big5_dsplen, pg_big5_verifier, 2}, /* PG_BIG5 */ {0, 0, pg_gbk_mblen, pg_gbk_dsplen, pg_gbk_verifier, 2}, /* PG_GBK */ {0, 0, pg_uhc_mblen, pg_uhc_dsplen, pg_uhc_verifier, 2}, /* PG_UHC */ {0, 0, pg_gb18030_mblen, pg_gb18030_dsplen, pg_gb18030_verifier, 4}, /* PG_GB18030 */ {0, 0, pg_johab_mblen, pg_johab_dsplen, pg_johab_verifier, 3}, /* PG_JOHAB */ {0, 0, pg_sjis_mblen, pg_sjis_dsplen, pg_sjis_verifier, 2} /* PG_SHIFT_JIS_2004 */ }; /* returns the byte length of a word for mule internal code */ int pg_mic_mblen(const unsigned char *mbstr) { return pg_mule_mblen(mbstr); } /* * Returns the byte length of a multibyte character. */ int pg_encoding_mblen(int encoding, const char *mbstr) { return (PG_VALID_ENCODING(encoding) ? ((*pg_wchar_table[encoding].mblen) ((const unsigned char *) mbstr)) : ((*pg_wchar_table[PG_SQL_ASCII].mblen) ((const unsigned char *) mbstr))); } /* * Returns the display length of a multibyte character. */ int pg_encoding_dsplen(int encoding, const char *mbstr) { return (PG_VALID_ENCODING(encoding) ? ((*pg_wchar_table[encoding].dsplen) ((const unsigned char *) mbstr)) : ((*pg_wchar_table[PG_SQL_ASCII].dsplen) ((const unsigned char *) mbstr))); } /* * Verify the first multibyte character of the given string. * Return its byte length if good, -1 if bad. (See comments above for * full details of the mbverify API.) */ int pg_encoding_verifymb(int encoding, const char *mbstr, int len) { return (PG_VALID_ENCODING(encoding) ? ((*pg_wchar_table[encoding].mbverify) ((const unsigned char *) mbstr, len)) : ((*pg_wchar_table[PG_SQL_ASCII].mbverify) ((const unsigned char *) mbstr, len))); } /* * fetch maximum length of a given encoding */ int pg_encoding_max_length(int encoding) { Assert(PG_VALID_ENCODING(encoding)); return pg_wchar_table[encoding].maxmblen; } #ifndef FRONTEND /* * fetch maximum length of the encoding for the current database */ int pg_database_encoding_max_length(void) { return pg_wchar_table[GetDatabaseEncoding()].maxmblen; } /* * get the character incrementer for the encoding for the current database */ mbcharacter_incrementer pg_database_encoding_character_incrementer(void) { /* * Eventually it might be best to add a field to pg_wchar_table[], but for * now we just use a switch. */ switch (GetDatabaseEncoding()) { case PG_UTF8: return pg_utf8_increment; case PG_EUC_JP: return pg_eucjp_increment; default: return pg_generic_charinc; } } /* * Verify mbstr to make sure that it is validly encoded in the current * database encoding. Otherwise same as pg_verify_mbstr(). */ bool pg_verifymbstr(const char *mbstr, int len, bool noError) { return pg_verify_mbstr_len(GetDatabaseEncoding(), mbstr, len, noError) >= 0; } /* * Verify mbstr to make sure that it is validly encoded in the specified * encoding. */ bool pg_verify_mbstr(int encoding, const char *mbstr, int len, bool noError) { return pg_verify_mbstr_len(encoding, mbstr, len, noError) >= 0; } /* * Verify mbstr to make sure that it is validly encoded in the specified * encoding. * * mbstr is not necessarily zero terminated; length of mbstr is * specified by len. * * If OK, return length of string in the encoding. * If a problem is found, return -1 when noError is * true; when noError is false, ereport() a descriptive message. */ int pg_verify_mbstr_len(int encoding, const char *mbstr, int len, bool noError) { mbverifier mbverify; int mb_len; Assert(PG_VALID_ENCODING(encoding)); /* * In single-byte encodings, we need only reject nulls (\0). */ if (pg_encoding_max_length(encoding) <= 1) { const char *nullpos = memchr(mbstr, 0, len); if (nullpos == NULL) return len; if (noError) return -1; report_invalid_encoding(encoding, nullpos, 1); } /* fetch function pointer just once */ mbverify = pg_wchar_table[encoding].mbverify; mb_len = 0; while (len > 0) { int l; /* fast path for ASCII-subset characters */ if (!IS_HIGHBIT_SET(*mbstr)) { if (*mbstr != '\0') { mb_len++; mbstr++; len--; continue; } if (noError) return -1; report_invalid_encoding(encoding, mbstr, len); } l = (*mbverify) ((const unsigned char *) mbstr, len); if (l < 0) { if (noError) return -1; report_invalid_encoding(encoding, mbstr, len); } mbstr += l; len -= l; mb_len++; } return mb_len; } /* * check_encoding_conversion_args: check arguments of a conversion function * * "expected" arguments can be either an encoding ID or -1 to indicate that * the caller will check whether it accepts the ID. * * Note: the errors here are not really user-facing, so elog instead of * ereport seems sufficient. Also, we trust that the "expected" encoding * arguments are valid encoding IDs, but we don't trust the actuals. */ void check_encoding_conversion_args(int src_encoding, int dest_encoding, int len, int expected_src_encoding, int expected_dest_encoding) { if (!PG_VALID_ENCODING(src_encoding)) elog(ERROR, "invalid source encoding ID: %d", src_encoding); if (src_encoding != expected_src_encoding && expected_src_encoding >= 0) elog(ERROR, "expected source encoding \"%s\", but got \"%s\"", pg_enc2name_tbl[expected_src_encoding].name, pg_enc2name_tbl[src_encoding].name); if (!PG_VALID_ENCODING(dest_encoding)) elog(ERROR, "invalid destination encoding ID: %d", dest_encoding); if (dest_encoding != expected_dest_encoding && expected_dest_encoding >= 0) elog(ERROR, "expected destination encoding \"%s\", but got \"%s\"", pg_enc2name_tbl[expected_dest_encoding].name, pg_enc2name_tbl[dest_encoding].name); if (len < 0) elog(ERROR, "encoding conversion length must not be negative"); } /* * report_invalid_encoding: complain about invalid multibyte character * * note: len is remaining length of string, not length of character; * len must be greater than zero, as we always examine the first byte. */ void report_invalid_encoding(int encoding, const char *mbstr, int len) { int l = pg_encoding_mblen(encoding, mbstr); char buf[8 * 5 + 1]; char *p = buf; int j, jlimit; jlimit = Min(l, len); jlimit = Min(jlimit, 8); /* prevent buffer overrun */ for (j = 0; j < jlimit; j++) { p += sprintf(p, "0x%02x", (unsigned char) mbstr[j]); if (j < jlimit - 1) p += sprintf(p, " "); } ereport(ERROR, (errcode(ERRCODE_CHARACTER_NOT_IN_REPERTOIRE), errmsg("invalid byte sequence for encoding \"%s\": %s", pg_enc2name_tbl[encoding].name, buf))); } /* * report_untranslatable_char: complain about untranslatable character * * note: len is remaining length of string, not length of character; * len must be greater than zero, as we always examine the first byte. */ void report_untranslatable_char(int src_encoding, int dest_encoding, const char *mbstr, int len) { int l = pg_encoding_mblen(src_encoding, mbstr); char buf[8 * 5 + 1]; char *p = buf; int j, jlimit; jlimit = Min(l, len); jlimit = Min(jlimit, 8); /* prevent buffer overrun */ for (j = 0; j < jlimit; j++) { p += sprintf(p, "0x%02x", (unsigned char) mbstr[j]); if (j < jlimit - 1) p += sprintf(p, " "); } ereport(ERROR, (errcode(ERRCODE_UNTRANSLATABLE_CHARACTER), errmsg("character with byte sequence %s in encoding \"%s\" has no equivalent in encoding \"%s\"", buf, pg_enc2name_tbl[src_encoding].name, pg_enc2name_tbl[dest_encoding].name))); } #endif /* !FRONTEND */