ref: 176da4977dc28d538b94a9e14967e0515cfa80a7
dir: /DoConfig/fltk/src/xutf8/lcUniConv/big5_emacs.h/
/* $XFree86: xc/lib/X11/lcUniConv/big5_emacs.h,v 1.1 2000/11/28 18:50:06 dawes Exp $ */ /* * BIG5-0 and BIG5-1 */ /* BIG5 with its 13494 characters doesn't fit in a single 94x94 or 96x96 block. Therefore Emacs/Mule developers, in a typically Japanese way of thinking, have developed an alternative encoding of BIG5 in two 94x94 planes, very similar to the SHIFT_JIS encoding for JISX0208. Conversion between BIG5 codes (s1,s2) and BIG5-0 codes (c1,c2): Example. (s1,s2) = 0xA140, (c1,c2) = 0x2121. 0xA1 <= s1 <= 0xC7, 0x40 <= s2 <= 0x7E || 0xA1 <= s2 <= 0xFE, 0x21 <= c1 <= 0x62, 0x21 <= c2 <= 0x7E. Invariant: 157*(s1-0xA1) + (s2 < 0x80 ? s2-0x40 : s2-0x62) = 94*(c1-0x21)+(c2-0x21) Conversion (s1,s2) -> (c1,c2): t := 157*(s1-0xA1) + (s2 < 0x80 ? s2-0x40 : s2-0x62) c1 := (t div 94) + 0x21 c2 := (t mod 94) + 0x21 Conversion (c1,c2) -> (s1,s2): t := 94*(c1-0x21)+(c2-0x21) t2 := t mod 157 s1 := (t div 157) + 0xA1 s2 := (t2 < 0x3F ? t2+0x40 : t2+0x62) Conversion between BIG5 codes (s1,s2) and BIG5-1 codes (c1,c2): Example. (s1,s2) = 0xC940, (c1,c2) = 0x2121. 0xC9 <= s1 <= 0xF9, 0x40 <= s2 <= 0x7E || 0xA1 <= s2 <= 0xFE, 0x21 <= c1 <= 0x72, 0x21 <= c2 <= 0x7E. Invariant: 157*(s1-0xC9) + (s2 < 0x80 ? s2-0x40 : s2-0x62) = 94*(c1-0x21)+(c2-0x21) Conversion (s1,s2) -> (c1,c2): t := 157*(s1-0xC9) + (s2 < 0x80 ? s2-0x40 : s2-0x62) c1 := (t div 94) + 0x21 c2 := (t mod 94) + 0x21 Conversion (c1,c2) -> (s1,s2): t := 94*(c1-0x21)+(c2-0x21) t2 := t mod 157 s1 := (t div 157) + 0xC9 s2 := (t2 < 0x3F ? t2+0x40 : t2+0x62) */ static int big5_0_mbtowc (conv_t conv, ucs4_t *pwc, const unsigned char *s, int n) { unsigned char c1 = s[0]; if (c1 >= 0x21 && c1 <= 0x62) { if (n >= 2) { unsigned char c2 = s[1]; if (c2 >= 0x21 && c2 <= 0x7e) { unsigned int i = 94 * (c1 - 0x21) + (c2 - 0x21); if (0) { /* Unoptimized. */ unsigned char buf[2]; buf[0] = (i / 157) + 0xa1; i = i % 157; buf[1] = i + (i < 0x3f ? 0x40 : 0x62); return big5_mbtowc(conv,pwc,buf,2); } else { /* Inline the implementation of big5_mbtowc. */ if (i < 6121) { unsigned short wc = big5_2uni_pagea1[i]; if (wc != 0xfffd) { *pwc = (ucs4_t) wc; return 2; } } } } return RET_ILSEQ; } return RET_TOOFEW(0); } return RET_ILSEQ; } static int big5_1_mbtowc (conv_t conv, ucs4_t *pwc, const unsigned char *s, int n) { unsigned char c1 = s[0]; if (c1 >= 0x21 && c1 <= 0x72) { if (n >= 2) { unsigned char c2 = s[1]; if (c2 >= 0x21 && c2 <= 0x7e) { unsigned int i = 94 * (c1 - 0x21) + (c2 - 0x21); if (0) { /* Unoptimized. */ unsigned char buf[2]; buf[0] = (i / 157) + 0xc9; i = i % 157; buf[1] = i + (i < 0x3f ? 0x40 : 0x62); return big5_mbtowc(conv,pwc,buf,2); } else { /* Inline the implementation of big5_mbtowc. */ if (i < 7652) { unsigned short wc = big5_2uni_pagec9[i]; if (wc != 0xfffd) { *pwc = (ucs4_t) wc; return 2; } } } } return RET_ILSEQ; } return RET_TOOFEW(0); } return RET_ILSEQ; } static int big5_0_wctomb (conv_t conv, unsigned char *r, ucs4_t wc, int n) { if (n >= 2) { unsigned char buf[2]; int ret = big5_wctomb(conv,buf,wc,2); if (ret != RET_ILSEQ) { unsigned char s1, s2; if (ret != 2) abort(); s1 = buf[0]; s2 = buf[1]; if (!(s1 >= 0xa1)) abort(); if (!((s2 >= 0x40 && s2 <= 0x7e) || (s2 >= 0xa1 && s2 <= 0xfe))) abort(); if (s1 < 0xc9) { unsigned int t = 157 * (s1 - 0xa1) + s2 - (s2 < 0x80 ? 0x40 : 0x62); r[0] = (t / 94) + 0x21; r[1] = (t % 94) + 0x21; return 2; } } return RET_ILSEQ; } return RET_TOOSMALL; } static int big5_1_wctomb (conv_t conv, unsigned char *r, ucs4_t wc, int n) { if (n >= 2) { unsigned char buf[2]; int ret = big5_wctomb(conv,buf,wc,2); if (ret != RET_ILSEQ) { unsigned char s1, s2; if (ret != 2) abort(); s1 = buf[0]; s2 = buf[1]; if (!(s1 <= 0xf9)) abort(); if (!((s2 >= 0x40 && s2 <= 0x7e) || (s2 >= 0xa1 && s2 <= 0xfe))) abort(); if (s1 >= 0xc9) { unsigned int t = 157 * (s1 - 0xc9) + s2 - (s2 < 0x80 ? 0x40 : 0x62); r[0] = (t / 94) + 0x21; r[1] = (t % 94) + 0x21; return 2; } } return RET_ILSEQ; } return RET_TOOSMALL; }