/* * iso2022.c - support for ISO/IEC 2022 (alias ECMA-35). * * This isn't a complete implementation of ISO/IEC 2022, but it's * close. It can decode 8-bit and 7-bit versions, with support for * single-byte and multi-byte character sets, all four containers * (G0, G1, G2, and G3), using both single-shift and locking-shift * sequences. * * The general principle is that any valid ISO/IEC 2022 sequence * should either be correctly decoded or should emit an ERROR. The * only exception to this is that the C0 and C1 sets are fixed as * those of ISO/IEC 6429. Escape sequences for designating control * sets are passed through, so a post-processor could fix them up if * necessary. * * DOCS to UTF-8 works. Other DOCS sequences are ignored, which will * produce surprising results. */ #ifndef ENUM_CHARSETS #include #include #include "charset.h" #include "internal.h" #include "sbcsdat.h" #define LS1 (0x0E) #define LS0 (0x0F) #define ESC (0x1B) #define SS2 (0x8E) #define SS3 (0x8F) enum {S4, S6, M4, M6}; static long int emacs_big5_1_to_unicode(int, int); static long int emacs_big5_2_to_unicode(int, int); static int unicode_to_emacs_big5(long int, int *, int *, int *); static long int cns11643_1_to_unicode(int, int); static long int cns11643_2_to_unicode(int, int); static long int cns11643_3_to_unicode(int, int); static long int cns11643_4_to_unicode(int, int); static long int cns11643_5_to_unicode(int, int); static long int cns11643_6_to_unicode(int, int); static long int cns11643_7_to_unicode(int, int); static long int null_dbcs_to_unicode(int, int); static int unicode_to_null_dbcs(long int, int *, int *); typedef int (*to_dbcs_t)(long int, int *, int *); typedef int (*to_dbcs_planar_t)(long int, int *, int *, int *); /* * These macros cast between to_dbcs_planar_t and to_dbcs_t, in * such a way as to cause a compile-time error if the input is not * of the appropriate type. * * Defining these portably is quite fiddly. My first effort was as * follows: * #define DEPLANARISE(x) ( (x) == (to_dbcs_planar_t)NULL, (to_dbcs_t)(x) ) * * so that the comparison on the left of the comma provokes the * type check error, and the cast on the right is the actual * desired result. * * gcc was entirely happy with this. However, when used in a static * initialiser, MSVC objected - justifiably - that the first half * of the comma expression wasn't constant and thus the expression * as a whole was not a constant expression. We can get round this * by enclosing the comparison in `sizeof', so that it isn't * actually evaluated. * * But then we run into a second problem, which is that C actually * disallows the use of the comma operator within a constant * expression for any purpose at all! Presumably this is on the * basis that its purpose is to have side effects and constant * expressions can't; unfortunately, this specific case is one in * which the desired side effect is a compile-time rather than a * run-time one. * * We are permitted to use ?:, however, and that works quite well * since the actual result of the sizeof expression _is_ evaluable * at compile time. So here's my final answer, with the unfortunate * remaining problem of evaluating its arguments multiple times: */ #define TYPECHECK(x,y) ( sizeof((x)) == sizeof((x)) ? (y) : (y) ) #define DEPLANARISE(x) TYPECHECK((x) == (to_dbcs_planar_t)NULL, (to_dbcs_t)(x)) #define REPLANARISE(x) TYPECHECK((x) == (to_dbcs_t)NULL, (to_dbcs_planar_t)(x)) /* * Values used in the `enable' field. Each of these identifies a * class of character sets; we then have a bitmask indicating which * classes are allowable in a given mode. * * These values are currently only checked on output: for input, * any ISO 2022 we can comprehend at all is considered acceptable. */ #define CCS 1 /* CTEXT standard */ #define COS 2 /* other standard */ #define CPU 3 /* private use */ #define CDC 4 /* DOCS for CTEXT */ #define CDU 5 /* DOCS for UTF-8 */ #define CNU 31 /* never used */ struct iso2022_mode { int enable_mask; char ltype, li, lf, rtype, ri, rf; }; const struct iso2022_subcharset { char type, i, f, enable; int offset; const sbcs_data *sbcs_base; long int (*from_dbcs)(int, int); /* * If to_dbcs_plane < 0, then to_dbcs is used as expected. * However, if to_dbcs_plane >= 0, then to_dbcs is expected to * be cast to a to_dbcs_planar_t before use, and the returned * plane value (the first int *) must equal to_dbcs_plane. * * I'd have preferred to do this by means of a union, but you * can't initialise a selected field of a union at compile * time. Function pointer casts are guaranteed to work sensibly * in ISO C (that is, it's undefined what happens if you call a * function via the wrong type of pointer, but if you cast it * back to the right type before calling it then it must work), * so this is safe if ugly. */ to_dbcs_t to_dbcs; int to_dbcs_plane; /* use to_dbcs_planar iff >= 0 */ } iso2022_subcharsets[] = { /* * We list these subcharsets in preference order for output. * Since the best-defined use of ISO 2022 output is compound * text, we'll use a preference order which matches that. So we * begin with the charsets defined in the compound text spec. */ { S4, 0, 'B', CCS, 0x00, &sbcsdata_CS_ASCII }, { S6, 0, 'A', CCS, 0x80, &sbcsdata_CS_ISO8859_1 }, { S6, 0, 'B', CCS, 0x80, &sbcsdata_CS_ISO8859_2 }, { S6, 0, 'C', CCS, 0x80, &sbcsdata_CS_ISO8859_3 }, { S6, 0, 'D', CCS, 0x80, &sbcsdata_CS_ISO8859_4 }, { S6, 0, 'F', CCS, 0x80, &sbcsdata_CS_ISO8859_7 }, { S6, 0, 'G', CCS, 0x80, &sbcsdata_CS_ISO8859_6 }, { S6, 0, 'H', CCS, 0x80, &sbcsdata_CS_ISO8859_8 }, { S6, 0, 'L', CCS, 0x80, &sbcsdata_CS_ISO8859_5 }, { S6, 0, 'M', CCS, 0x80, &sbcsdata_CS_ISO8859_9 }, { S4, 0, 'I', CCS, 0x80, &sbcsdata_CS_JISX0201 }, { S4, 0, 'J', CCS, 0x00, &sbcsdata_CS_JISX0201 }, { M4, 0, 'A', CCS, -0x21, 0, &gb2312_to_unicode, &unicode_to_gb2312, -1 }, { M4, 0, 'B', CCS, -0x21, 0, &jisx0208_to_unicode, &unicode_to_jisx0208, -1 }, { M4, 0, 'C', CCS, -0x21, 0, &ksx1001_to_unicode, &unicode_to_ksx1001, -1 }, { M4, 0, 'D', CCS, -0x21, 0, &jisx0212_to_unicode, &unicode_to_jisx0212, -1 }, /* * Next, other reasonably standard things: the rest of the ISO * 8859 sets, UK-ASCII, and CNS 11643. */ { S6, 0, 'T', COS, 0x80, &sbcsdata_CS_ISO8859_11 }, { S6, 0, 'V', COS, 0x80, &sbcsdata_CS_ISO8859_10 }, { S6, 0, 'Y', COS, 0x80, &sbcsdata_CS_ISO8859_13 }, { S6, 0, '_', COS, 0x80, &sbcsdata_CS_ISO8859_14 }, { S6, 0, 'b', COS, 0x80, &sbcsdata_CS_ISO8859_15 }, { S6, 0, 'f', COS, 0x80, &sbcsdata_CS_ISO8859_16 }, { S4, 0, 'A', COS, 0x00, &sbcsdata_CS_BS4730 }, { M4, 0, 'G', COS, -0x21, 0, &cns11643_1_to_unicode, DEPLANARISE(&unicode_to_cns11643), 0 }, { M4, 0, 'H', COS, -0x21, 0, &cns11643_2_to_unicode, DEPLANARISE(&unicode_to_cns11643), 1 }, { M4, 0, 'I', COS, -0x21, 0, &cns11643_3_to_unicode, DEPLANARISE(&unicode_to_cns11643), 2 }, { M4, 0, 'J', COS, -0x21, 0, &cns11643_4_to_unicode, DEPLANARISE(&unicode_to_cns11643), 3 }, { M4, 0, 'K', COS, -0x21, 0, &cns11643_5_to_unicode, DEPLANARISE(&unicode_to_cns11643), 4 }, { M4, 0, 'L', COS, -0x21, 0, &cns11643_6_to_unicode, DEPLANARISE(&unicode_to_cns11643), 5 }, { M4, 0, 'M', COS, -0x21, 0, &cns11643_7_to_unicode, DEPLANARISE(&unicode_to_cns11643), 6 }, /* * Private-use designations: DEC private sets and Emacs's Big5 * abomination. */ { S4, 0, '0', CPU, 0x00, &sbcsdata_CS_DEC_GRAPHICS }, { S4, 0, '<', CPU, 0x80, &sbcsdata_CS_DEC_MCS }, { M4, 0, '0', CPU, -0x21, 0, &emacs_big5_1_to_unicode, DEPLANARISE(&unicode_to_emacs_big5), 1 }, { M4, 0, '1', CPU, -0x21, 0, &emacs_big5_2_to_unicode, DEPLANARISE(&unicode_to_emacs_big5), 2 }, /* * Ben left this conditioned out without explanation, * presumably on the grounds that we don't have a translation * table for it. */ #if 0 { M4, 0, '@', CNU }, /* JIS C 6226-1978 */ #endif /* * Finally, fallback entries for null character sets. */ { S4, 0, '~', CNU }, { S6, 0, '~', CNU }, /* empty 96-set */ { M4, 0, '~', CNU, 0, 0, &null_dbcs_to_unicode, &unicode_to_null_dbcs, -1 }, /* empty 94^n-set */ { M6, 0, '~', CNU, 0, 0, &null_dbcs_to_unicode, &unicode_to_null_dbcs, -1 }, /* empty 96^n-set */ }; static long int null_dbcs_to_unicode(int r, int c) { UNUSEDARG(r); UNUSEDARG(c); return ERROR; } static int unicode_to_null_dbcs(long int unicode, int *r, int *c) { UNUSEDARG(unicode); UNUSEDARG(r); UNUSEDARG(c); return 0; /* failed to convert anything */ } /* * Emacs encodes Big5 in COMPOUND_TEXT as two 94x94 character sets. * We treat Big5 as a 94x191 character set with a bunch of undefined * columns in the middle, so we have to mess around a bit to make * things fit. */ static long int emacs_big5_1_to_unicode(int r, int c) { unsigned long s; s = r * 94 + c; r = s / 157; c = s % 157; if (c >= 64) c += 34; /* Skip over the gap */ return big5_to_unicode(r, c); } static long int emacs_big5_2_to_unicode(int r, int c) { unsigned long s; s = r * 94 + c; r = s / 157 + 40; c = s % 157; if (c >= 64) c += 34; /* Skip over the gap */ return big5_to_unicode(r, c); } static int unicode_to_emacs_big5(long int unicode, int *p, int *r, int *c) { int rr, cc, s; if (!unicode_to_big5(unicode, &rr, &cc)) return 0; if (cc >= 64) { cc -= 34; assert(cc >= 64); } s = rr * 157 + cc; if (s >= 40*157) { *p = 2; s -= 40*157; } else { *p = 1; } *r = s / 94; *c = s % 94; return 1; } /* Wrappers for cns11643_to_unicode() */ static long int cns11643_1_to_unicode(int r, int c) { return cns11643_to_unicode(0, r, c); } static long int cns11643_2_to_unicode(int r, int c) { return cns11643_to_unicode(1, r, c); } static long int cns11643_3_to_unicode(int r, int c) { return cns11643_to_unicode(2, r, c); } static long int cns11643_4_to_unicode(int r, int c) { return cns11643_to_unicode(3, r, c); } static long int cns11643_5_to_unicode(int r, int c) { return cns11643_to_unicode(4, r, c); } static long int cns11643_6_to_unicode(int r, int c) { return cns11643_to_unicode(5, r, c); } static long int cns11643_7_to_unicode(int r, int c) { return cns11643_to_unicode(6, r, c); } /* States, or "what we're currently accumulating". */ enum { IDLE, /* None of the below */ SS2CHAR, /* Accumulating a character after SS2 */ SS3CHAR, /* Accumulating a character after SS3 */ ESCSEQ, /* Accumulating an escape sequence */ ESCDROP, /* Discarding an escape sequence */ ESCPASS, /* Passing through an escape sequence */ DOCSUTF8, /* DOCSed into UTF-8 */ DOCSCTEXT /* DOCSed into a COMPOUND_TEXT extended segment */ }; #if 0 #include static void dump_state(charset_state *s) { unsigned s0 = s->s0, s1 = s->s1; char const * const modes[] = { "IDLE", "SS2CHAR", "SS3CHAR", "ESCSEQ", "ESCDROP", "ESCPASS", "DOCSUTF8" }; fprintf(stderr, "s0: %s", modes[s0 >> 29]); fprintf(stderr, " %02x %02x %02x ", (s0 >> 16) & 0xff, (s0 >> 8) & 0xff, s0 & 0xff); fprintf(stderr, "s1: LS%d LS%dR", (s1 >> 30) & 3, (s1 >> 28) & 3); fprintf(stderr, " %d %d %d %d\n", s1 & 0x7f, (s1 >> 7) & 0x7f, (s1 >> 14) & 0x7f, (s1 >> 21) & 0x7f); } #endif static void designate(charset_state *state, int container, int type, int ibyte, int fbyte) { unsigned long i; assert(container >= 0 && container <= 3); assert(type == S4 || type == S6 || type == M4 || type == M6); for (i = 0; i < lenof(iso2022_subcharsets); i++) { if (iso2022_subcharsets[i].type == type && iso2022_subcharsets[i].i == ibyte && iso2022_subcharsets[i].f == fbyte) { state->s1 &= ~(0x7fL << (container * 7)); state->s1 |= (i << (container * 7)); return; } } /* * If we don't find the charset, invoke the empty one, so we * output ERROR rather than garbage. */ designate(state, container, type, 0, '~'); } static void do_utf8(long int input_chr, charset_state *state, void (*emit)(void *ctx, long int output), void *emitctx) { charset_state ustate; ustate.s1 = 0; ustate.s0 = state->s0 & 0x03ffffffL; read_utf8(NULL, input_chr, &ustate, emit, emitctx); state->s0 = (state->s0 & ~0x03ffffffL) | (ustate.s0 & 0x03ffffffL); } static void docs_utf8(long int input_chr, charset_state *state, void (*emit)(void *ctx, long int output), void *emitctx) { int retstate; /* * Bits [25:0] of s0 are reserved for read_utf8(). * Bits [27:26] are a tiny state machine to recognise ESC % @. */ retstate = (state->s0 & 0x0c000000L) >> 26; if (retstate == 1 && input_chr == '%') retstate = 2; else if (retstate == 2 && input_chr == '@') { /* If we've got a partial UTF-8 sequence, complain. */ if (state->s0 & 0x03ffffffL) emit(emitctx, ERROR); state->s0 = 0; return; } else { if (retstate >= 1) do_utf8(ESC, state, emit, emitctx); if (retstate >= 2) do_utf8('%', state, emit, emitctx); retstate = 0; if (input_chr == ESC) retstate = 1; else { do_utf8(input_chr, state, emit, emitctx); } } state->s0 = (state->s0 & ~0x0c000000L) | (retstate << 26); } struct ctext_encoding { char const *name; char octets_per_char, enable; charset_spec const *subcs; }; /* * In theory, this list is in , * but XLib appears to have its own ideas, and encodes these three * (as of X11R6.8.2) */ extern charset_spec const charset_CS_ISO8859_14; extern charset_spec const charset_CS_ISO8859_15; extern charset_spec const charset_CS_BIG5; static struct ctext_encoding const ctext_encodings[] = { { "big5-0\2", 0 /* variable */, CDC, &charset_CS_BIG5 }, { "iso8859-14\2", 1, CDC, &charset_CS_ISO8859_14 }, { "iso8859-15\2", 1, CDC, &charset_CS_ISO8859_15 } }; static void docs_ctext(long int input_chr, charset_state *state, void (*emit)(void *ctx, long int output), void *emitctx) { /* * s0[27:26] = first entry in ctext_encodings that matches * s0[25:22] = number of characters successfully matched, 0xf if all * s0[21:8] count the number of octets left in the segment * s0[7:0] are for sub-charset use */ int n = (state->s0 >> 22) & 0xf, i = (state->s0 >> 26) & 3, oi = i, j; int length = (state->s0 >> 8) & 0x3fff; /* * Note that we do not bother checking the octets-per-character * byte against the selected charset when reading. It's * extremely unlikely that this code will ever have to deal * with two charset identifiers with the same name and * different octets-per-character values! If it ever happens, * we'll have to edit this file anyway so we can modify the * code then... */ if (!length) { /* Haven't read length yet */ if ((state->s0 & 0xff) == 0) /* ... or even the first byte */ state->s0 |= input_chr; else { length = (state->s0 & 0x7f) * 0x80 + (input_chr & 0x7f); if (length == 0) state->s0 = 0; else state->s0 = (state->s0 & 0xf0000000) | (length << 8); } return; } j = i; if (n == 0xe) { /* Skipping unknown encoding. Look out for STX. */ if (input_chr == 2) state->s0 = (state->s0 & 0xf0000000) | (i << 26) | (0xf << 22); } else if (n != 0xf) { while ((unsigned)j < lenof(ctext_encodings) && !memcmp(ctext_encodings[j].name, ctext_encodings[oi].name, n)) { if (ctext_encodings[j].name[n] < input_chr) i = ++j; else break; } if ((unsigned)i >= lenof(ctext_encodings) || memcmp(ctext_encodings[i].name, ctext_encodings[oi].name, n) || ctext_encodings[i].name[n] != input_chr) { /* Doom! We haven't heard of this encoding */ i = lenof(ctext_encodings); n = 0xe; } else { /* * Otherwise, we have found an additional character in our * encoding name. See if we have reached the _end_ of our * name. */ n++; if (!ctext_encodings[i].name[n]) n = 0xf; } /* * Failing _that_, we simply update our encoding-name- * tracking state. */ assert(i < 4 && n < 16); state->s0 = (state->s0 & 0xf0000000) | (i << 26) | (n << 22); } else { if ((unsigned)i >= lenof(ctext_encodings)) emit(emitctx, ERROR); else { charset_state substate; charset_spec const *subcs = ctext_encodings[i].subcs; substate.s1 = 0; substate.s0 = state->s0 & 0xff; subcs->read(subcs, input_chr, &substate, emit, emitctx); state->s0 = (state->s0 & ~0xff) | (substate.s0 & 0xff); } } if (!--length) state->s0 = 0; else state->s0 = (state->s0 &~0x003fff00) | (length << 8); } static void read_iso2022(charset_spec const *charset, long int input_chr, charset_state *state, void (*emit)(void *ctx, long int output), void *emitctx) { struct iso2022_mode const *mode = (struct iso2022_mode *)charset->data; /* dump_state(state); */ /* * We have to make fairly efficient use of the 64 bits of state * available to us. Long-term state goes in s1, and consists of * the identities of the character sets designated as G0/G1/G2/G3 * and the locking-shift states for GL and GR. Short-term state * goes in s0: The bottom half of s0 accumulates characters for an * escape sequence or a multi-byte character, while the top three * bits indicate what they're being accumulated for. After DOCS, * the bottom 29 bits of state are available for the DOCS function * to use -- the UTF-8 one uses the bottom 26 for UTF-8 decoding * and the top two to recognised ESC % @. * * s0[31:29] = state enum * s0[24:0] = accumulated bytes * s1[31:30] = GL locking-shift state * s1[29:28] = GR locking-shift state * s1[27:21] = G3 charset * s1[20:14] = G2 charset * s1[13:7] = G1 charset * s1[6:0] = G0 charset */ #define LEFT 30 #define RIGHT 28 #define LOCKING_SHIFT(n,side) \ (state->s1 = (state->s1 & ~(3UL<<(side))) | ((n ## UL)<<(side))) #define MODE ((state->s0 & 0xe0000000UL) >> 29) #define ENTER_MODE(m) (state->s0 = (state->s0 & ~0xe0000000UL) | ((unsigned long)(m)<<29)) #define SINGLE_SHIFT(n) ENTER_MODE(SS2CHAR - 2 + (n)) #define ASSERT_IDLE do { \ if (state->s0 != 0) emit(emitctx, ERROR); \ state->s0 = 0; \ } while (0) if (state->s1 == 0) { /* * Since there's no LS0R, this means we must just have started. * Set up a sane initial state (LS0, LS1R, ASCII in G0/G1/G2/G3). */ LOCKING_SHIFT(0, LEFT); LOCKING_SHIFT(1, RIGHT); designate(state, 0, mode->ltype, mode->li, mode->lf); designate(state, 1, mode->rtype, mode->ri, mode->rf); designate(state, 2, S4, 0, 'B'); designate(state, 3, S4, 0, 'B'); } if (MODE == DOCSUTF8) { docs_utf8(input_chr, state, emit, emitctx); return; } if (MODE == DOCSCTEXT) { docs_ctext(input_chr, state, emit, emitctx); return; } if ((input_chr & 0x60) == 0x00) { /* C0 or C1 control */ ASSERT_IDLE; switch (input_chr) { case ESC: ENTER_MODE(ESCSEQ); break; case LS0: LOCKING_SHIFT(0, LEFT); break; case LS1: LOCKING_SHIFT(1, LEFT); break; case SS2: SINGLE_SHIFT(2); break; case SS3: SINGLE_SHIFT(3); break; default: emit(emitctx, input_chr); break; } } else if ((input_chr & 0x80) || MODE < ESCSEQ) { int is_gl = 0; struct iso2022_subcharset const *subcs; unsigned container; long input_7bit; /* * Actual data. * Force idle state if we're in mid escape sequence, or in a * multi-byte character with a different top bit. */ if (MODE >= ESCSEQ || ((state->s0 & 0x00ff0000L) != 0 && (((state->s0 >> 16) ^ input_chr) & 0x80))) ASSERT_IDLE; if (MODE == SS2CHAR || MODE == SS3CHAR) /* Single-shift */ container = MODE - SS2CHAR + 2; else if (input_chr >= 0x80) /* GR */ container = (state->s1 >> 28) & 3; else { /* GL */ container = state->s1 >> 30; is_gl = 1; } input_7bit = input_chr & ~0x80; subcs = &iso2022_subcharsets[(state->s1 >> (container * 7)) & 0x7f]; if ((subcs->type == S4 || subcs->type == M4) && (input_7bit == 0x20 || input_7bit == 0x7f)) { /* characters not in 94-char set */ if (is_gl) emit(emitctx, input_7bit); else emit(emitctx, ERROR); } else if (subcs->type == M4 || subcs->type == M6) { if ((state->s0 & 0x00ff0000L) == 0) { state->s0 |= input_chr << 16; return; } else { emit(emitctx, subcs->from_dbcs(((state->s0 >> 16) & 0x7f) + subcs->offset, input_7bit + subcs->offset)); } } else { if ((state->s0 & 0x00ff0000L) != 0) emit(emitctx, ERROR); emit(emitctx, subcs->sbcs_base ? sbcs_to_unicode(subcs->sbcs_base, input_7bit + subcs->offset): ERROR); } state->s0 = 0; } else { unsigned i1, i2; if (MODE == ESCPASS) { emit(emitctx, input_chr); if ((input_chr & 0xf0) != 0x20) ENTER_MODE(IDLE); return; } /* * Intermediate bytes shall be any of the 16 positions of * column 02 of the code table; they are denoted by the symbol * I. */ if ((input_chr & 0xf0) == 0x20) { if (((state->s0 >> 16) & 0xff) == 0) state->s0 |= input_chr << 16; else if (((state->s0 >> 8) & 0xff) == 0) state->s0 |= input_chr << 8; else { /* Long escape sequence. Switch to ESCPASS or ESCDROP. */ i1 = (state->s0 >> 16) & 0xff; i2 = (state->s0 >> 8) & 0xff; switch (i1) { case '(': case ')': case '*': case '+': case '-': case '.': case '/': case '$': ENTER_MODE(ESCDROP); break; default: emit(emitctx, ESC); emit(emitctx, i1); emit(emitctx, i2); emit(emitctx, input_chr); state->s0 = 0; ENTER_MODE(ESCPASS); break; } } return; } /* * Final bytes shall be any of the 79 positions of columns 03 * to 07 of the code table excluding position 07/15; they are * denoted by the symbol F. */ i1 = (state->s0 >> 16) & 0xff; i2 = (state->s0 >> 8) & 0xff; if (MODE == ESCDROP) input_chr = 0; /* Make sure it won't match. */ state->s0 = 0; switch (i1) { case 0: /* No intermediate bytes */ switch (input_chr) { case 'N': /* SS2 */ SINGLE_SHIFT(2); break; case 'O': /* SS3 */ SINGLE_SHIFT(3); break; case 'n': /* LS2 */ LOCKING_SHIFT(2, LEFT); break; case 'o': /* LS3 */ LOCKING_SHIFT(3, LEFT); break; case '|': /* LS3R */ LOCKING_SHIFT(3, RIGHT); break; case '}': /* LS2R */ LOCKING_SHIFT(2, RIGHT); break; case '~': /* LS1R */ LOCKING_SHIFT(1, RIGHT); break; default: /* Unsupported escape sequence. Spit it back out. */ emit(emitctx, ESC); emit(emitctx, input_chr); } break; case ' ': /* ACS */ /* * Various coding structure facilities specify that designating * a code element also invokes it. As far as I can see, invoking * it now will have the same practical effect, since those * facilities also ban the use of locking shifts. */ switch (input_chr) { case 'A': /* G0 element used and invoked into GL */ LOCKING_SHIFT(0, LEFT); break; case 'C': /* G0 in GL, G1 in GR */ case 'D': /* Ditto, at least for 8-bit codes */ case 'L': /* ISO 4873 (ECMA-43) level 1 */ case 'M': /* ISO 4873 (ECMA-43) level 2 */ LOCKING_SHIFT(0, LEFT); LOCKING_SHIFT(1, RIGHT); break; } break; case '&': /* IRR */ /* * IRR (Identify Revised Registration) is ignored here, * since any revised registration must be * upward-compatible with the old one, so either we'll * support the new one or we'll emit ERROR when we run * into a new character. In either case, there's nothing * to be done here. */ break; case '(': /* GZD4 */ case ')': /* G1D4 */ case '*': /* G2D4 */ case '+': /* G3D4 */ designate(state, i1 - '(', S4, i2, input_chr); break; case '-': /* G1D6 */ case '.': /* G2D6 */ case '/': /* G3D6 */ designate(state, i1 - ',', S6, i2, input_chr); break; case '$': /* G?DM? */ switch (i2) { case 0: /* Obsolete version of GZDM4 */ i2 = '('; case '(': /* GZDM4 */ case ')': /* G1DM4 */ case '*': /* G2DM4 */ case '+': /* G3DM4 */ designate(state, i2 - '(', M4, 0, input_chr); break; case '-': /* G1DM6 */ case '.': /* G2DM6 */ case '/': /* G3DM6 */ designate(state, i2 - ',', M6, 0, input_chr); break; default: emit(emitctx, ERROR); break; } case '%': /* DOCS */ /* XXX What's a reasonable way to handle an unrecognised DOCS? */ switch (i2) { case 0: switch (input_chr) { case 'G': ENTER_MODE(DOCSUTF8); break; } break; case '/': switch (input_chr) { case '1': case '2': ENTER_MODE(DOCSCTEXT); break; } break; } break; default: /* Unsupported nF escape sequence. Re-emit it. */ emit(emitctx, ESC); emit(emitctx, i1); if (i2) emit(emitctx, i2); emit(emitctx, input_chr); break; } } } static void oselect(charset_state *state, int i, int right, void (*emit)(void *ctx, long int output), void *emitctx) { int shift = (right ? 31-7 : 31-7-7); struct iso2022_subcharset const *subcs = &iso2022_subcharsets[i]; if (((state->s1 >> shift) & 0x7F) != (unsigned)i) { state->s1 &= ~(0x7FL << shift); state->s1 |= (i << shift); if (emit) { emit(emitctx, ESC); if (subcs->type == M4 || subcs->type == M6) emit(emitctx, '$'); if (subcs->type == S6 || subcs->type == M6) { assert(right); emit(emitctx, '-'); } else if (right) { emit(emitctx, ')'); } else { emit(emitctx, '('); } if (subcs->i) emit(emitctx, subcs->i); emit(emitctx, subcs->f); } } } static void docs_char(charset_state *state, void (*emit)(void *ctx, long int output), void *emitctx, int cset, char *data, int datalen) { int curr_cset, currlen, i; /* * cset is the index into ctext_encodings[]. It can also be -1 * to mean DOCS UTF-8, or -2 to mean no DOCS (ordinary 2022). * In the latter case, `chr' is ignored. */ /* * First, terminate a DOCS segment if necessary. We always have * to terminate a DOCS segment if one is active and we're about * to switch to a different one; we might also have to * terminate a length-encoded DOCS segment if we've run out of * storage space to accumulate characters in it. */ curr_cset = ((state->s1 >> 14) & 7) - 2; currlen = ((state->s1 >> 11) & 7); if ((curr_cset != -2 && curr_cset != cset) || (curr_cset >= 0 && currlen + datalen > 5)) { if (curr_cset == -1) { /* * Terminating DOCS UTF-8 is easy. */ emit(emitctx, ESC); emit(emitctx, '%'); emit(emitctx, '@'); } else { int len; /* * To terminate a length-encoded DOCS segment we must * actually output the whole thing. */ emit(emitctx, ESC); emit(emitctx, '%'); emit(emitctx, '/'); emit(emitctx, '0' + ctext_encodings[curr_cset].octets_per_char); len = currlen + datalen + (int)strlen(ctext_encodings[curr_cset].name); assert(len < (1 << 14)); emit(emitctx, 0x80 | ((len >> 7) & 0x7F)); emit(emitctx, 0x80 | ((len ) & 0x7F)); /* The name stored in ctext_encodings[] includes the trailing \2 */ for (i = 0; ctext_encodings[curr_cset].name[i]; i++) emit(emitctx, ctext_encodings[curr_cset].name[i]); for (i = 0; i < currlen; i++) emit(emitctx, (i == 0 ? state->s1 : state->s0 >> (8*(4-i))) & 0xFF); for (i = 0; i < datalen; i++) emit(emitctx, data[i]); /* * We've now dealt with the input data, so clear it so * we don't try to do so again below. */ datalen = 0; } curr_cset = -2; } /* * Now, start a DOCS segment if necessary. */ if (curr_cset != cset) { assert(cset != -2); if (cset == -1) { /* * Start DOCS UTF-8. */ emit(emitctx, ESC); emit(emitctx, '%'); emit(emitctx, 'G'); } else { /* * Starting a length-encoded DOCS segment is simply a * matter of setting our stored length counter to zero. */ currlen = 0; state->s1 &= ~(7 << 11); state->s1 &= ~0xFF; state->s0 = 0; } } state->s1 &= ~(7 << 14); assert((cset+2) >= 0 && (cset+2) < 8); state->s1 |= ((cset+2) << 14); /* * Now we're in the right DOCS state. Actually deal with the * input data, if we haven't already done so above. */ if (datalen > 0) { assert(cset != 2); if (cset == -1) { /* * In DOCS UTF-8, we output data as soon as we get it. */ for (i = 0; i < datalen; i++) emit(emitctx, data[i]); } else { /* * In length-encoded DOCS, we just store our data and * bide our time. It'll all be output when we fill up * or switch to another character set. */ assert(currlen + datalen <= 5); /* overflow handled already */ for (i = 0; i < datalen; i++) { if (currlen + i == 0) state->s1 |= data[i] & 0xFF; else state->s0 |= (data[i] & 0xFF) << (8*(4-(currlen+i))); } currlen += datalen; assert(currlen >= 0 && currlen < 8); state->s1 &= ~(7 << 11); state->s1 |= (currlen << 11); } } } static void write_to_pointer(void *ctx, long int output) { char **ptr = (char **)ctx; *(*ptr)++ = (char)output; } /* * Writing full ISO-2022 is not useful in very many circumstances. * One of the few situations in which it _is_ useful is generating * X11 COMPOUND_TEXT; therefore, this writing function will obey * the compound text restrictions and hence output the subset of * ISO-2022 that's usable in that context. * * The subset in question is roughly that we use GL/GR for G0/G1 * always, and that the _only_ escape sequences we output (other * than the occasional DOCS) are those which designate different * subcharsets into G0 and G1. There are additional constraints * about which things go in which container; see below. * * FIXME: this wants some decent tests to be written, and also the * exact output policy for compound text wants thinking about more * carefully. */ static int write_iso2022(charset_spec const *charset, long int input_chr, charset_state *state, void (*emit)(void *ctx, long int output), void *emitctx) { int i; struct iso2022_subcharset const *subcs; struct iso2022_mode const *mode = (struct iso2022_mode *)charset->data; to_dbcs_planar_t last_planar_dbcs = NULL; int last_p, last_r, last_c; long int c1, c2; /* * For output, I allocate the state variables as follows: * * s1[31] == 1 if output state has been initialised * s1[30:24] == G1 charset (always in GR) * s1[23:17] == G0 charset (always in GL) * s1[16:14] == DOCS index plus 2 (because -1 and -2 are special) * s1[13:11] == number of DOCS accumulated characters (up to five) * s1[7:0] + s0[31:0] == DOCS collected characters */ if (!state->s1) { state->s0 = 0x00000000UL; state->s1 = 0x80000000UL; /* * Start with US-ASCII in GL and also in GR. */ for (i = 0; (unsigned)i < lenof(iso2022_subcharsets); i++) { subcs = &iso2022_subcharsets[i]; if (subcs->type == mode->ltype && subcs->i == mode->li && subcs->f == mode->lf) oselect(state, i, FALSE, NULL, NULL); if (subcs->type == mode->rtype && subcs->i == mode->ri && subcs->f == mode->rf) oselect(state, i, TRUE, NULL, NULL); } } if (input_chr == -1) { /* * Special case: reset encoding state. */ docs_char(state, emit, emitctx, -2, NULL, 0); /* leave DOCS */ for (i = 0; (unsigned)i < lenof(iso2022_subcharsets); i++) { subcs = &iso2022_subcharsets[i]; if (subcs->type == mode->ltype && subcs->i == mode->li && subcs->f == mode->lf) oselect(state, i, FALSE, emit, emitctx); if (subcs->type == mode->rtype && subcs->i == mode->ri && subcs->f == mode->rf) oselect(state, i, TRUE, emit, emitctx); } return TRUE; } /* * Special-case characters: Space, Delete, and anything in C0 * or C1 are output unchanged. */ if (input_chr <= 0x20 || (input_chr >= 0x7F && input_chr < 0xA0)) { emit(emitctx, input_chr); return TRUE; } /* * Analyse the input character and work out which subcharset it * belongs to. */ for (i = 0; (unsigned)i < lenof(iso2022_subcharsets); i++) { subcs = &iso2022_subcharsets[i]; if (!(mode->enable_mask & (1 << subcs->enable))) continue; /* this charset is disabled */ if (subcs->sbcs_base) { c1 = sbcs_from_unicode(subcs->sbcs_base, input_chr); c1 -= subcs->offset; if (c1 >= 0x20 && c1 <= 0x7f) { c2 = 0; break; } } else if (subcs->to_dbcs) { if (subcs->to_dbcs_plane >= 0) { /* * Since multiplanar DBCSes almost by definition * involve several entries in iso2022_subcharsets * with the same to_dbcs function and different * plane values, we remember the last such function * we called and what its result was, so that we * don't (for example) have to call * unicode_to_cns11643 seven times. */ if (last_planar_dbcs != REPLANARISE(subcs->to_dbcs)) { last_planar_dbcs = REPLANARISE(subcs->to_dbcs); if (!last_planar_dbcs(input_chr, &last_p, &last_r, &last_c)) last_p = -1; } } else { last_p = subcs->to_dbcs_plane; if (!subcs->to_dbcs(input_chr, &last_r, &last_c)) last_p = 0; /* cannot match since to_dbcs_plane<0 */ } if (last_p == subcs->to_dbcs_plane) { c1 = last_r - subcs->offset; c2 = last_c - subcs->offset; assert(c1 >= 0x20 && c1 <= 0x7f); assert(c2 >= 0x20 && c2 <= 0x7f); break; } } } if ((unsigned)i < lenof(iso2022_subcharsets)) { int right; /* * Our character is represented by c1 (and possibly also * c2) in subcharset `subcs'. So now we must decide whether * to designate that character set into G0/GL or G1/GR. * * Any S6 or M6 subcharset has to go in GR because it won't * fit in GL. In addition, the compound text rules state * that any single-byte subcharset defined as the * right-hand half of some SBCS must go in GR. * * M4 subcharsets can go in either half according to the * rules. I choose to put them in GR always because it's a * simple policy with reasonable behaviour (facilitates * switching between them and ASCII). */ right = (subcs->type == S6 || subcs->type == M6 || subcs->type == M4 || (subcs->sbcs_base && subcs->offset == 0x80)); /* * If we're in a DOCS mode, leave it. */ docs_char(state, emit, emitctx, -2, NULL, 0); /* * If this subcharset is not already selected in that * container, select it. */ oselect(state, i, right, emit, emitctx); /* * Now emit the actual characters. */ if (right) { assert(c1 >= 0x20 && c1 <= 0x7f); emit(emitctx, c1 | 0x80); if (c2) { assert(c2 >= 0x20 && c2 <= 0x7f); emit(emitctx, c2 | 0x80); } } else { assert(c1 > 0x20 && c1 < 0x7f); emit(emitctx, c1); if (c2) { assert(c2 > 0x20 && c2 < 0x7f); emit(emitctx, c2); } } return TRUE; } /* * Fall back to DOCS. */ { char data[10]; char *p = data; int i, cs; cs = -2; /* means failure */ for (i = 0; (unsigned)i <= lenof(ctext_encodings); i++) { charset_state substate; charset_spec const *subcs = ctext_encodings[i].subcs; /* * We assume that all character sets dealt with by DOCS * are stateless for output purposes. */ substate.s1 = substate.s0 = 0; p = data; if ((unsigned)i < lenof(ctext_encodings)) { if ((mode->enable_mask & (1 << ctext_encodings[i].enable)) && subcs->write(subcs, input_chr, &substate, write_to_pointer, &p)) { cs = i; break; } } else { if ((mode->enable_mask & (1 << CDU)) && write_utf8(NULL, input_chr, NULL, write_to_pointer, &p)) { cs = -1; break; } } } if (cs != -2) { docs_char(state, emit, emitctx, cs, data, (int)(p - data)); return TRUE; } } return FALSE; } /* * Full ISO 2022 output with all options on. Not entirely sure what * if anything this is useful for, but here it is anyway. All * output character sets and DOCS variants are permitted; all * containers start out with ASCII in them. */ static const struct iso2022_mode iso2022_all = { (1< #include #include int total_errs = 0; void iso2022_emit(void *ctx, long output) { wchar_t **p = (wchar_t **)ctx; *(*p)++ = output; } void iso2022_read_test(int line, char *input, int inlen, ...) { va_list ap; wchar_t *p, str[512]; int i; charset_state state; unsigned long l; state.s0 = state.s1 = 0; p = str; for (i = 0; i < inlen; i++) read_iso2022(NULL, input[i] & 0xFF, &state, iso2022_emit, &p); va_start(ap, inlen); l = 0; for (i = 0; i < p - str; i++) { l = va_arg(ap, long int); if (l == -1) { printf("%d: correct string shorter than output\n", line); total_errs++; break; } if (l != str[i]) { printf("%d: char %d came out as %08x, should be %08lx\n", line, i, str[i], l); total_errs++; } } if (l != -1) { l = va_arg(ap, long int); if (l != -1) { printf("%d: correct string longer than output\n", line); total_errs++; } } va_end(ap); } /* Macro to concoct the first three parameters of iso2022_read_test. */ #define TESTSTR(x) __LINE__, x, lenof(x) int main(void) { printf("read tests beginning\n"); /* Simple test (Emacs sample text for Japanese, in ISO-2022-JP) */ iso2022_read_test(TESTSTR("Japanese (\x1b$BF|K\\8l\x1b(B)\t" "\x1b$B$3$s$K$A$O\x1b(B, " "\x1b$B%3%s%K%A%O\x1b(B\n"), 'J','a','p','a','n','e','s','e',' ','(', 0x65E5, 0x672C, 0x8A9E, ')', '\t', 0x3053, 0x3093, 0x306b, 0x3061, 0x306f, ',', ' ', 0x30b3, 0x30f3, 0x30cb, 0x30c1, 0x30cf, '\n', 0, -1); /* Same thing in EUC-JP (with designations, and half-width katakana) */ iso2022_read_test(TESTSTR("\x1b$)B\x1b*I\x1b$+D" "Japanese (\xc6\xfc\xcb\xdc\xb8\xec)\t" "\xa4\xb3\xa4\xf3\xa4\xcb\xa4\xc1\xa4\xcf, " "\x8e\xba\x8e\xdd\x8e\xc6\x8e\xc1\x8e\xca\n"), 'J','a','p','a','n','e','s','e',' ','(', 0x65E5, 0x672C, 0x8A9E, ')', '\t', 0x3053, 0x3093, 0x306b, 0x3061, 0x306f, ',', ' ', 0xff7a, 0xff9d, 0xff86, 0xff81, 0xff8a, '\n', 0, -1); /* Multibyte single-shift */ iso2022_read_test(TESTSTR("\x1b$)B\x1b*I\x1b$+D\x8f\"/!"), 0x02D8, '!', 0, -1); /* Non-existent SBCS */ iso2022_read_test(TESTSTR("\x1b(!Zfnord\n"), ERROR, ERROR, ERROR, ERROR, ERROR, '\n', 0, -1); /* Pass-through of ordinary escape sequences, including a long one */ iso2022_read_test(TESTSTR("\x1b""b\x1b#5\x1b#!!!5"), 0x1B, 'b', 0x1B, '#', '5', 0x1B, '#', '!', '!', '!', '5', 0, -1); /* Non-existent DBCS (also 5-byte escape sequence) */ iso2022_read_test(TESTSTR("\x1b$(!Bfnord!"), ERROR, ERROR, ERROR, 0, -1); /* Incomplete DB characters */ iso2022_read_test(TESTSTR("\x1b$B(,(\x1b(BHi\x1b$B(,(\n"), 0x2501, ERROR, 'H', 'i', 0x2501, ERROR, '\n', 0, -1); iso2022_read_test(TESTSTR("\x1b$)B\x1b*I\x1b$+D\xa4""B"), ERROR, 'B', 0, -1); iso2022_read_test(TESTSTR("\x1b$)B\x1b*I\x1b$+D\x0e\x1b|$\xa2\xaf"), ERROR, 0x02D8, 0, -1); /* Incomplete escape sequence */ iso2022_read_test(TESTSTR("\x1b\n"), ERROR, '\n', 0, -1); iso2022_read_test(TESTSTR("\x1b-A\x1b~\x1b\xa1"), ERROR, 0xa1, 0, -1); /* Incomplete single-shift */ iso2022_read_test(TESTSTR("\x8e\n"), ERROR, '\n', 0, -1); iso2022_read_test(TESTSTR("\x1b$*B\x8e(\n"), ERROR, '\n', 0, -1); /* Corner cases (02/00 and 07/15) */ iso2022_read_test(TESTSTR("\x1b(B\x20\x7f"), 0x20, 0x7f, 0, -1); iso2022_read_test(TESTSTR("\x1b(I\x20\x7f"), 0x20, 0x7f, 0, -1); iso2022_read_test(TESTSTR("\x1b$B\x20\x7f"), 0x20, 0x7f, 0, -1); iso2022_read_test(TESTSTR("\x1b-A\x0e\x20\x7f"), 0xa0, 0xff, 0, -1); iso2022_read_test(TESTSTR("\x1b$-~\x0e\x20\x7f"), ERROR, 0, -1); iso2022_read_test(TESTSTR("\x1b)B\xa0\xff"), ERROR, ERROR, 0, -1); iso2022_read_test(TESTSTR("\x1b)I\xa0\xff"), ERROR, ERROR, 0, -1); iso2022_read_test(TESTSTR("\x1b$)B\xa0\xff"), ERROR, ERROR, 0, -1); iso2022_read_test(TESTSTR("\x1b-A\x1b~\xa0\xff"), 0xa0, 0xff, 0, -1); iso2022_read_test(TESTSTR("\x1b$-~\x1b~\xa0\xff"), ERROR, 0, -1); /* Designate control sets */ iso2022_read_test(TESTSTR("\x1b!@"), 0x1b, '!', '@', 0, -1); /* Designate other coding system (UTF-8) */ iso2022_read_test(TESTSTR("\x1b%G" "\xCE\xBA\xE1\xBD\xB9\xCF\x83\xCE\xBC\xCE\xB5"), 0x03BA, 0x1F79, 0x03C3, 0x03BC, 0x03B5, 0, -1); iso2022_read_test(TESTSTR("\x1b-A\x1b%G\xCE\xBA\x1b%@\xa0"), 0x03BA, 0xA0, 0, -1); iso2022_read_test(TESTSTR("\x1b%G\xCE\x1b%@"), ERROR, 0, -1); iso2022_read_test(TESTSTR("\x1b%G\xCE\xBA\x1b%\x1b%@"), 0x03BA, 0x1B, '%', 0, -1); /* DOCS (COMPOUND_TEXT extended segment) */ iso2022_read_test(TESTSTR("\x1b%/1\x80\x80"), 0, -1); iso2022_read_test(TESTSTR("\x1b%/1\x80\x8fiso-8859-15\2xyz\x1b(B"), ERROR, ERROR, ERROR, 0, -1); iso2022_read_test(TESTSTR("\x1b%/1\x80\x8eiso8859-15\2xyz\x1b(B"), 'x', 'y', 'z', 0, -1); iso2022_read_test(TESTSTR("\x1b-A\x1b%/2\x80\x89" "big5-0\2\xa1\x40\xa1\x40"), 0x3000, 0xa1, 0x40, 0, -1); /* Emacs Big5-in-ISO-2022 mapping */ iso2022_read_test(TESTSTR("\x1b$(0&x86\x1b(B \x1b$(0DeBv"), 0x5143, 0x6c23, ' ', ' ', 0x958b, 0x767c, 0, -1); /* Test from RFC 1922 (ISO-2022-CN) */ iso2022_read_test(TESTSTR("\x1b$)A\x0e=;;;\x1b$)GG(_P\x0f"), 0x4EA4, 0x6362, 0x4EA4, 0x63db, 0, -1); printf("read tests completed\n"); printf("total: %d errors\n", total_errs); return (total_errs != 0); } #endif /* TESTMODE */ #else /* ENUM_CHARSETS */ ENUM_CHARSET(CS_ISO2022) #endif