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authorJörg Frings-Fürst <debian@jff-webhosting.net>2016-12-28 16:52:56 +0100
committerJörg Frings-Fürst <debian@jff-webhosting.net>2016-12-28 16:52:56 +0100
commit7b358424ebad9349421acd533c2fa1cbf6cf3e3e (patch)
tree686678532eefed525c242fd214d0cfb2914726c5 /app/tools/halibut/charset/iso2022s.c
Initial import of xtrkcad version 1:4.0.2-2
Diffstat (limited to 'app/tools/halibut/charset/iso2022s.c')
-rw-r--r--app/tools/halibut/charset/iso2022s.c544
1 files changed, 544 insertions, 0 deletions
diff --git a/app/tools/halibut/charset/iso2022s.c b/app/tools/halibut/charset/iso2022s.c
new file mode 100644
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+++ b/app/tools/halibut/charset/iso2022s.c
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+/*
+ * iso2022s.c - support for ISO-2022 subset encodings.
+ */
+
+#ifndef ENUM_CHARSETS
+
+#include <stdio.h>
+#include <string.h>
+#include <assert.h>
+
+#include "charset.h"
+#include "internal.h"
+#include "sbcsdat.h"
+
+#define SO (0x0E)
+#define SI (0x0F)
+#define ESC (0x1B)
+
+/* Functional description of a single ISO 2022 escape sequence. */
+struct iso2022_escape {
+ char const *sequence;
+ unsigned long andbits, xorbits;
+ /*
+ * For output, these variables help us figure out which escape
+ * sequences we need to get where we want to be.
+ *
+ * `container' should be in the range 0-3, but can also be ORed
+ * with the bit flag RO to indicate that this is not a
+ * preferred container to use for this charset during output.
+ */
+ int container, subcharset;
+};
+#define RO 0x80
+
+struct iso2022 {
+ /*
+ * List of escape sequences supported in this subset. Must be
+ * in ASCII order, so that we can narrow down the list as
+ * necessary.
+ */
+ const struct iso2022_escape *escapes;/* must be sorted in ASCII order! */
+ int nescapes;
+
+ /*
+ * We assign indices from 0 upwards to the sub-charsets of a
+ * given ISO 2022 subset. nbytes[i] tells us how many bytes per
+ * character are required by sub-charset i. (It's a string
+ * mainly because that makes it easier to declare in C syntax
+ * than an int array.)
+ */
+ char const *nbytes;
+
+ /*
+ * The characters in this string are indices-plus-one (so that
+ * NUL can still terminate) of escape sequences in `escapes'.
+ * These escapes are output in the given sequence to reset the
+ * encoding state, unless it turns out that a given escape
+ * would not change the state at all.
+ */
+ char const *reset;
+
+ /*
+ * Initial value of s1, in case the default container contents
+ * needs to be something other than charset 0 in all cases.
+ * (Note that this must have the top bit set!)
+ */
+ unsigned long s1;
+
+ /*
+ * For output, some ISO 2022 subsets _mandate_ an initial shift
+ * sequence. If so, here it is so we can output it. (For the
+ * sake of basic sanity we won't bother to _require_ it on
+ * input, although it should of course be listed under
+ * `escapes' above so that we ignore it when present.)
+ */
+ char const *initial_sequence;
+
+ /*
+ * Is this an 8-bit ISO 2022 subset?
+ */
+ int eightbit;
+
+ /*
+ * Function calls to do the actual translation.
+ */
+ long int (*to_ucs)(int subcharset, unsigned long bytes);
+ int (*from_ucs)(long int ucs, int *subcharset, unsigned long *bytes);
+};
+
+static void read_iso2022s(charset_spec const *charset, long int input_chr,
+ charset_state *state,
+ void (*emit)(void *ctx, long int output),
+ void *emitctx)
+{
+ struct iso2022 const *iso = (struct iso2022 *)charset->data;
+
+ /*
+ * For reading ISO-2022 subsets, we divide up our state
+ * variables as follows:
+ *
+ * - The top byte of s0 (bits 31:24) indicates, if nonzero,
+ * that we are part-way through a recognised ISO-2022 escape
+ * sequence. Five of those bits (31:27) give the index of
+ * the first member of the escapes list matching what we
+ * have so far; the remaining three (26:24) give the number
+ * of characters we have seen so far.
+ *
+ * - The top bit of s1 (bit 31) is non-zero at all times, to
+ * indicate that we have performed any necessary
+ * initialisation. When we start, we detect a zero s1 and
+ * respond to it by initialising the default container
+ * contents.
+ *
+ * - The next three bits of s1 (bits 30:28) indicate which
+ * _container_ is currently selected. This isn't quite as
+ * simple as it sounds, since we have to preserve memory of
+ * which of the SI/SO containers we came from when we're
+ * temporarily in SS2/SS3. Hence, what happens is:
+ * + bit 28 indicates SI/SO.
+ * + if we're in an SS2/SS3 container, that's indicated by
+ * the two bits above that being nonzero and holding
+ * either 2 or 3.
+ * + Hence: 0 is SI, 1 is SO, 4 is SS2-from-SI, 5 is
+ * SS2-from-SO, 6 is SS3-from-SI, 7 is SS3-from-SO.
+ * + For added fun: in an _8-bit_ ISO 2022 subset, we have
+ * the further special value 2, which means that we're
+ * theoretically in SI but the current character being
+ * accumulated is composed of 8-bit characters and will
+ * therefore be interpreted as if in SO.
+ *
+ * - The next nibble of s1 (27:24) indicates how many bytes
+ * have been accumulated in the current character.
+ *
+ * - The remaining three bytes of s1 are divided into four
+ * six-bit sections, and each section gives the current
+ * sub-charset selected in one of the possible containers.
+ * (Those containers are SI, SO, SS2 and SS3, respectively
+ * and in order from the bottom of s0 to the top.)
+ *
+ * - The bottom 24 bits of s0 give the accumulated character
+ * data so far.
+ *
+ * (Note that this means s1 contains all the parts of the state
+ * which might need to be operated on by escape sequences.
+ * Cunning, eh?)
+ */
+
+ if (!(state->s1 & 0x80000000)) {
+ state->s1 = iso->s1;
+ }
+
+ /*
+ * So. Firstly, we process escape sequences, if we're in the
+ * middle of one or if we see a possible introducer (SI, SO,
+ * ESC).
+ */
+ if ((state->s0 >> 24) ||
+ (input_chr == SO || input_chr == SI || input_chr == ESC)) {
+ int n = (state->s0 >> 24) & 7, i = (state->s0 >> 27), oi = i, j;
+
+ /*
+ * If this is the start of an escape sequence, we might be
+ * in mid-character. If so, clear the character state and
+ * emit an error token for the incomplete character.
+ */
+ if (state->s1 & 0x0F000000) {
+ state->s1 &= ~0x0F000000;
+ state->s0 &= 0xFF000000;
+ /*
+ * If we were in the SS2 or SS3 container, we
+ * automatically exit it.
+ */
+ if (state->s1 & 0x60000000)
+ state->s1 &= 0x9FFFFFFF;
+ emit(emitctx, ERROR);
+ }
+
+ j = i;
+ while (j < iso->nescapes &&
+ !memcmp(iso->escapes[j].sequence,
+ iso->escapes[oi].sequence, n)) {
+ if (iso->escapes[j].sequence[n] < input_chr)
+ i = ++j;
+ else
+ break;
+ }
+ if (i >= iso->nescapes ||
+ memcmp(iso->escapes[i].sequence,
+ iso->escapes[oi].sequence, n) ||
+ iso->escapes[i].sequence[n] != input_chr) {
+ /*
+ * This character does not appear in any valid escape
+ * sequence. Therefore, we must emit all the characters
+ * we had previously swallowed, plus this one, and
+ * return to non-escape-sequence state.
+ */
+ for (j = 0; j < n; j++)
+ emit(emitctx, iso->escapes[oi].sequence[j]);
+ emit(emitctx, input_chr);
+ state->s0 = 0;
+ return;
+ }
+
+ /*
+ * Otherwise, we have found an additional character in our
+ * escape sequence. See if we have reached the _end_ of our
+ * sequence (and therefore must process the sequence).
+ */
+ n++;
+ if (!iso->escapes[i].sequence[n]) {
+ state->s0 = 0;
+ state->s1 &= iso->escapes[i].andbits;
+ state->s1 ^= iso->escapes[i].xorbits;
+ return;
+ }
+
+ /*
+ * Failing _that_, we simply update our escape-sequence-
+ * tracking state.
+ */
+ assert(i < 32 && n < 8);
+ state->s0 = (i << 27) | (n << 24);
+ return;
+ }
+
+ /*
+ * If this isn't an escape sequence, it must be part of a
+ * character. One possibility is that it's a control character
+ * (00-20 or 7F-9F; also in non-8-bit ISO 2022 subsets I'm
+ * going to treat all top-half characters as controls), in
+ * which case we output it verbatim.
+ */
+ if (input_chr < 0x21 ||
+ (input_chr > 0x7E && (!iso->eightbit || input_chr < 0xA0))) {
+ /*
+ * We might be in mid-multibyte-character. If so, clear the
+ * character state and emit an error token for the
+ * incomplete character.
+ */
+ if (state->s1 & 0x0F000000) {
+ state->s1 &= ~0x0F000000;
+ state->s0 &= 0xFF000000;
+ emit(emitctx, ERROR);
+ /*
+ * If we were in the SS2 or SS3 container, we
+ * automatically exit it.
+ */
+ if (state->s1 & 0x60000000)
+ state->s1 &= 0x9FFFFFFF;
+ }
+
+ emit(emitctx, input_chr);
+ return;
+ }
+
+ /*
+ * Otherwise, accumulate character data.
+ */
+ {
+ unsigned long chr;
+ int chrlen, cont, subcharset, bytes;
+
+ /*
+ * Verify that we've seen the right kind of character for
+ * what we're currently doing. This only matters in 8-bit
+ * subsets.
+ */
+ if (iso->eightbit) {
+ cont = (state->s1 >> 28) & 7;
+ /*
+ * If cont==0, we're entitled to see either GL or GR
+ * characters. If cont==2, we expect only GR; otherwise
+ * we expect only GL.
+ *
+ * If we see a GR character while cont==0, we set
+ * cont=2 immediately.
+ */
+ if ((cont == 2 && !(input_chr & 0x80)) ||
+ (cont != 0 && cont != 2 && (input_chr & 0x80))) {
+ /*
+ * Clear the previous character; it was prematurely
+ * terminated by this error.
+ */
+ state->s1 &= ~0x0F000000;
+ state->s0 &= 0xFF000000;
+ emit(emitctx, ERROR);
+ /*
+ * If we were in the SS2 or SS3 container, we
+ * automatically exit it.
+ */
+ if (state->s1 & 0x60000000)
+ state->s1 &= 0x9FFFFFFF;
+ }
+
+ if (cont == 0 && (input_chr & 0x80)) {
+ state->s1 |= 0x20000000;
+ }
+ }
+
+ /* The current character and its length. */
+ chr = ((state->s0 & 0x00FFFFFF) << 8) | (input_chr & 0x7F);
+ chrlen = ((state->s1 >> 24) & 0xF) + 1;
+ /* The current sub-charset. */
+ cont = (state->s1 >> 28) & 7;
+ if (cont > 1) cont >>= 1;
+ subcharset = (state->s1 >> (6*cont)) & 0x3F;
+ /* The number of bytes-per-character in that sub-charset. */
+ bytes = iso->nbytes[subcharset];
+
+ /*
+ * If this character is now complete, we convert and emit
+ * it. Otherwise, we simply update the state and return.
+ */
+ if (chrlen >= bytes) {
+ emit(emitctx, iso->to_ucs(subcharset, chr));
+ chr = chrlen = 0;
+ /*
+ * If we were in the SS2 or SS3 container, we
+ * automatically exit it.
+ */
+ if (state->s1 & 0x60000000)
+ state->s1 &= 0x9FFFFFFF;
+ }
+ state->s0 = (state->s0 & 0xFF000000) | chr;
+ state->s1 = (state->s1 & 0xF0FFFFFF) | (chrlen << 24);
+ }
+}
+
+static int write_iso2022s(charset_spec const *charset, long int input_chr,
+ charset_state *state,
+ void (*emit)(void *ctx, long int output),
+ void *emitctx)
+{
+ struct iso2022 const *iso = (struct iso2022 *)charset->data;
+ int subcharset, len, i, j, cont, topbit = 0;
+ unsigned long bytes;
+
+ /*
+ * For output, our s1 state variable contains most of the same
+ * stuff as it did for input - initial-state indicator bit,
+ * current container, and current subcharset selected in each
+ * container.
+ */
+
+ /*
+ * Analyse the character and find out what subcharset it needs
+ * to go in.
+ */
+ if (input_chr >= 0 && !iso->from_ucs(input_chr, &subcharset, &bytes))
+ return FALSE;
+
+ if (!(state->s1 & 0x80000000)) {
+ state->s1 = iso->s1;
+ if (iso->initial_sequence)
+ for (i = 0; iso->initial_sequence[i]; i++)
+ emit(emitctx, iso->initial_sequence[i]);
+ }
+
+ if (input_chr == -1) {
+ unsigned long oldstate;
+ int k;
+
+ /*
+ * Special case: reset encoding state.
+ */
+ for (i = 0; iso->reset[i]; i++) {
+ j = iso->reset[i] - 1;
+ oldstate = state->s1;
+ state->s1 &= iso->escapes[j].andbits;
+ state->s1 ^= iso->escapes[j].xorbits;
+ if (state->s1 != oldstate) {
+ /* We must actually emit this sequence. */
+ for (k = 0; iso->escapes[j].sequence[k]; k++)
+ emit(emitctx, iso->escapes[j].sequence[k]);
+ }
+ }
+
+ return TRUE;
+ }
+
+ /*
+ * Now begins the fun. We now know what subcharset we want. So
+ * we must find out which container we should select it into,
+ * select it into it if necessary, select that _container_ if
+ * necessary, and then output the given bytes.
+ */
+ for (i = 0; i < iso->nescapes; i++)
+ if (iso->escapes[i].subcharset == subcharset &&
+ !(iso->escapes[i].container & RO))
+ break;
+ assert(i < iso->nescapes);
+
+ /*
+ * We've found the escape sequence which would select this
+ * subcharset into a container. However, that subcharset might
+ * already _be_ selected in that container! Check before we go
+ * to the effort of emitting the sequence.
+ */
+ cont = iso->escapes[i].container &~ RO;
+ if (((state->s1 >> (6*cont)) & 0x3F) != (unsigned)subcharset) {
+ for (j = 0; iso->escapes[i].sequence[j]; j++)
+ emit(emitctx, iso->escapes[i].sequence[j]);
+ state->s1 &= iso->escapes[i].andbits;
+ state->s1 ^= iso->escapes[i].xorbits;
+ }
+
+ /*
+ * Now we know what container our subcharset is in, so we want
+ * to select that container.
+ */
+ if (cont > 1) {
+ /* SS2 or SS3; just output the sequence and be done. */
+ emit(emitctx, ESC);
+ emit(emitctx, 'L' + cont); /* comes out to 'N' or 'O' */
+ } else {
+ /*
+ * Emit SI or SO, but only if the current container isn't already
+ * the right one.
+ *
+ * Also, in an 8-bit subset, we need not do this; we'll
+ * just use 8-bit characters to output SO-container
+ * characters.
+ */
+ if (iso->eightbit && cont == 1 && ((state->s1 >> 28) & 7) == 0) {
+ topbit = 0x80;
+ } else if (((state->s1 >> 28) & 7) != (unsigned)cont) {
+ emit(emitctx, cont ? SO : SI);
+ state->s1 = (state->s1 & 0x8FFFFFFF) | (cont << 28);
+ }
+ }
+
+ /*
+ * We're done. Subcharset is selected in container, container
+ * is selected. All we need now is to write out the bytes.
+ */
+ len = iso->nbytes[subcharset];
+ while (len--)
+ emit(emitctx, ((bytes >> (8*len)) & 0xFF) | topbit);
+
+ return TRUE;
+}
+
+/*
+ * ISO-2022-JP, defined in RFC 1468.
+ */
+static long int iso2022jp_to_ucs(int subcharset, unsigned long bytes)
+{
+ switch (subcharset) {
+ case 1: /* JIS X 0201 bottom half */
+ if (bytes == 0x5C)
+ return 0xA5;
+ else if (bytes == 0x7E)
+ return 0x203E;
+ /* else fall through to ASCII */
+ case 0: return bytes; /* one-byte ASCII */
+ /* (no break needed since all control paths have returned) */
+ case 2: return jisx0208_to_unicode(((bytes >> 8) & 0xFF) - 0x21,
+ ((bytes ) & 0xFF) - 0x21);
+ default: return ERROR;
+ }
+}
+static int iso2022jp_from_ucs(long int ucs, int *subcharset,
+ unsigned long *bytes)
+{
+ int r, c;
+ if (ucs < 0x80) {
+ *subcharset = 0;
+ *bytes = ucs;
+ return 1;
+ } else if (ucs == 0xA5 || ucs == 0x203E) {
+ *subcharset = 1;
+ *bytes = (ucs == 0xA5 ? 0x5C : 0x7E);
+ return 1;
+ } else if (unicode_to_jisx0208(ucs, &r, &c)) {
+ *subcharset = 2;
+ *bytes = ((r+0x21) << 8) | (c+0x21);
+ return 1;
+ } else {
+ return 0;
+ }
+}
+static const struct iso2022_escape iso2022jp_escapes[] = {
+ {"\033$@", 0xFFFFFFC0, 0x00000002, -1, -1}, /* we ignore this one */
+ {"\033$B", 0xFFFFFFC0, 0x00000002, 0, 2},
+ {"\033(B", 0xFFFFFFC0, 0x00000000, 0, 0},
+ {"\033(J", 0xFFFFFFC0, 0x00000001, 0, 1},
+};
+static const struct iso2022 iso2022jp = {
+ iso2022jp_escapes, lenof(iso2022jp_escapes),
+ "\1\1\2", "\3", 0x80000000, NULL, FALSE,
+ iso2022jp_to_ucs, iso2022jp_from_ucs
+};
+const charset_spec charset_CS_ISO2022_JP = {
+ CS_ISO2022_JP, read_iso2022s, write_iso2022s, &iso2022jp
+};
+
+/*
+ * ISO-2022-KR, defined in RFC 1557.
+ */
+static long int iso2022kr_to_ucs(int subcharset, unsigned long bytes)
+{
+ switch (subcharset) {
+ case 0: return bytes; /* one-byte ASCII */
+ case 1: return ksx1001_to_unicode(((bytes >> 8) & 0xFF) - 0x21,
+ ((bytes ) & 0xFF) - 0x21);
+ default: return ERROR;
+ }
+}
+static int iso2022kr_from_ucs(long int ucs, int *subcharset,
+ unsigned long *bytes)
+{
+ int r, c;
+ if (ucs < 0x80) {
+ *subcharset = 0;
+ *bytes = ucs;
+ return 1;
+ } else if (unicode_to_ksx1001(ucs, &r, &c)) {
+ *subcharset = 1;
+ *bytes = ((r+0x21) << 8) | (c+0x21);
+ return 1;
+ } else {
+ return 0;
+ }
+}
+static const struct iso2022_escape iso2022kr_escapes[] = {
+ {"\016", 0x8FFFFFFF, 0x10000000, -1, -1},
+ {"\017", 0x8FFFFFFF, 0x00000000, 0, 0},
+ {"\033$)C", 0xFFFFF03F, 0x00000040, 1, 1}, /* bits[11:6] <- 1 */
+};
+static const struct iso2022 iso2022kr = {
+ iso2022kr_escapes, lenof(iso2022kr_escapes),
+ "\1\2", "\2", 0x80000040, "\033$)C", FALSE,
+ iso2022kr_to_ucs, iso2022kr_from_ucs
+};
+const charset_spec charset_CS_ISO2022_KR = {
+ CS_ISO2022_KR, read_iso2022s, write_iso2022s, &iso2022kr
+};
+
+#else /* ENUM_CHARSETS */
+
+ENUM_CHARSET(CS_ISO2022_JP)
+ENUM_CHARSET(CS_ISO2022_KR)
+
+#endif /* ENUM_CHARSETS */