/* CPP Library - charsets Copyright (C) 1998-2021 Free Software Foundation, Inc. Broken out of c-lex.c Apr 2003, adding valid C99 UCN ranges. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; see the file COPYING3. If not see . */ #include "config.h" #include "system.h" #include "cpplib.h" #include "internal.h" /* Character set handling for C-family languages. Terminological note: In what follows, "charset" or "character set" will be taken to mean both an abstract set of characters and an encoding for that set. The C99 standard discusses two character sets: source and execution. The source character set is used for internal processing in translation phases 1 through 4; the execution character set is used thereafter. Both are required by 5.2.1.2p1 to be multibyte encodings, not wide character encodings (see 3.7.2, 3.7.3 for the standardese meanings of these terms). Furthermore, the "basic character set" (listed in 5.2.1p3) is to be encoded in each with values one byte wide, and is to appear in the initial shift state. It is not explicitly mentioned, but there is also a "wide execution character set" used to encode wide character constants and wide string literals; this is supposed to be the result of applying the standard library function mbstowcs() to an equivalent narrow string (6.4.5p5). However, the behavior of hexadecimal and octal \-escapes is at odds with this; they are supposed to be translated directly to wchar_t values (6.4.4.4p5,6). The source character set is not necessarily the character set used to encode physical source files on disk; translation phase 1 converts from whatever that encoding is to the source character set. The presence of universal character names in C99 (6.4.3 et seq.) forces the source character set to be isomorphic to ISO 10646, that is, Unicode. There is no such constraint on the execution character set; note also that the conversion from source to execution character set does not occur for identifiers (5.1.1.2p1#5). For convenience of implementation, the source character set's encoding of the basic character set should be identical to the execution character set OF THE HOST SYSTEM's encoding of the basic character set, and it should not be a state-dependent encoding. cpplib uses UTF-8 or UTF-EBCDIC for the source character set, depending on whether the host is based on ASCII or EBCDIC (see respectively Unicode section 2.3/ISO10646 Amendment 2, and Unicode Technical Report #16). With limited exceptions, it relies on the system library's iconv() primitive to do charset conversion (specified in SUSv2). */ #if !HAVE_ICONV /* Make certain that the uses of iconv(), iconv_open(), iconv_close() below, which are guarded only by if statements with compile-time constant conditions, do not cause link errors. */ #define iconv_open(x, y) (errno = EINVAL, (iconv_t)-1) #define iconv(a,b,c,d,e) (errno = EINVAL, (size_t)-1) #define iconv_close(x) (void)0 #define ICONV_CONST #endif #if HOST_CHARSET == HOST_CHARSET_ASCII #define SOURCE_CHARSET "UTF-8" #define LAST_POSSIBLY_BASIC_SOURCE_CHAR 0x7e #elif HOST_CHARSET == HOST_CHARSET_EBCDIC #define SOURCE_CHARSET "UTF-EBCDIC" #define LAST_POSSIBLY_BASIC_SOURCE_CHAR 0xFF #else #error "Unrecognized basic host character set" #endif #ifndef EILSEQ #define EILSEQ EINVAL #endif /* This structure is used for a resizable string buffer throughout. */ /* Don't call it strbuf, as that conflicts with unistd.h on systems such as DYNIX/ptx where unistd.h includes stropts.h. */ struct _cpp_strbuf { uchar *text; size_t asize; size_t len; }; /* This is enough to hold any string that fits on a single 80-column line, even if iconv quadruples its size (e.g. conversion from ASCII to UTF-32) rounded up to a power of two. */ #define OUTBUF_BLOCK_SIZE 256 /* Conversions between UTF-8 and UTF-16/32 are implemented by custom logic. This is because a depressing number of systems lack iconv, or have have iconv libraries that do not do these conversions, so we need a fallback implementation for them. To ensure the fallback doesn't break due to neglect, it is used on all systems. UTF-32 encoding is nice and simple: a four-byte binary number, constrained to the range 00000000-7FFFFFFF to avoid questions of signedness. We do have to cope with big- and little-endian variants. UTF-16 encoding uses two-byte binary numbers, again in big- and little-endian variants, for all values in the 00000000-0000FFFF range. Values in the 00010000-0010FFFF range are encoded as pairs of two-byte numbers, called "surrogate pairs": given a number S in this range, it is mapped to a pair (H, L) as follows: H = (S - 0x10000) / 0x400 + 0xD800 L = (S - 0x10000) % 0x400 + 0xDC00 Two-byte values in the D800...DFFF range are ill-formed except as a component of a surrogate pair. Even if the encoding within a two-byte value is little-endian, the H member of the surrogate pair comes first. There is no way to encode values in the 00110000-7FFFFFFF range, which is not currently a problem as there are no assigned code points in that range; however, the author expects that it will eventually become necessary to abandon UTF-16 due to this limitation. Note also that, because of these pairs, UTF-16 does not meet the requirements of the C standard for a wide character encoding (see 3.7.3 and 6.4.4.4p11). UTF-8 encoding looks like this: value range encoded as 00000000-0000007F 0xxxxxxx 00000080-000007FF 110xxxxx 10xxxxxx 00000800-0000FFFF 1110xxxx 10xxxxxx 10xxxxxx 00010000-001FFFFF 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx 00200000-03FFFFFF 111110xx 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx 04000000-7FFFFFFF 1111110x 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx Values in the 0000D800 ... 0000DFFF range (surrogates) are invalid, which means that three-byte sequences ED xx yy, with A0 <= xx <= BF, never occur. Note also that any value that can be encoded by a given row of the table can also be encoded by all successive rows, but this is not done; only the shortest possible encoding for any given value is valid. For instance, the character 07C0 could be encoded as any of DF 80, E0 9F 80, F0 80 9F 80, F8 80 80 9F 80, or FC 80 80 80 9F 80. Only the first is valid. An implementation note: the transformation from UTF-16 to UTF-8, or vice versa, is easiest done by using UTF-32 as an intermediary. */ /* Internal primitives which go from an UTF-8 byte stream to native-endian UTF-32 in a cppchar_t, or vice versa; this avoids an extra marshal/unmarshal operation in several places below. */ static inline int one_utf8_to_cppchar (const uchar **inbufp, size_t *inbytesleftp, cppchar_t *cp) { static const uchar masks[6] = { 0x7F, 0x1F, 0x0F, 0x07, 0x03, 0x01 }; static const uchar patns[6] = { 0x00, 0xC0, 0xE0, 0xF0, 0xF8, 0xFC }; cppchar_t c; const uchar *inbuf = *inbufp; size_t nbytes, i; if (*inbytesleftp < 1) return EINVAL; c = *inbuf; if (c < 0x80) { *cp = c; *inbytesleftp -= 1; *inbufp += 1; return 0; } /* The number of leading 1-bits in the first byte indicates how many bytes follow. */ for (nbytes = 2; nbytes < 7; nbytes++) if ((c & ~masks[nbytes-1]) == patns[nbytes-1]) goto found; return EILSEQ; found: if (*inbytesleftp < nbytes) return EINVAL; c = (c & masks[nbytes-1]); inbuf++; for (i = 1; i < nbytes; i++) { cppchar_t n = *inbuf++; if ((n & 0xC0) != 0x80) return EILSEQ; c = ((c << 6) + (n & 0x3F)); } /* Make sure the shortest possible encoding was used. */ if (c <= 0x7F && nbytes > 1) return EILSEQ; if (c <= 0x7FF && nbytes > 2) return EILSEQ; if (c <= 0xFFFF && nbytes > 3) return EILSEQ; if (c <= 0x1FFFFF && nbytes > 4) return EILSEQ; if (c <= 0x3FFFFFF && nbytes > 5) return EILSEQ; /* Make sure the character is valid. */ if (c > 0x7FFFFFFF || (c >= 0xD800 && c <= 0xDFFF)) return EILSEQ; *cp = c; *inbufp = inbuf; *inbytesleftp -= nbytes; return 0; } static inline int one_cppchar_to_utf8 (cppchar_t c, uchar **outbufp, size_t *outbytesleftp) { static const uchar masks[6] = { 0x00, 0xC0, 0xE0, 0xF0, 0xF8, 0xFC }; static const uchar limits[6] = { 0x80, 0xE0, 0xF0, 0xF8, 0xFC, 0xFE }; size_t nbytes; uchar buf[6], *p = &buf[6]; uchar *outbuf = *outbufp; nbytes = 1; if (c < 0x80) *--p = c; else { do { *--p = ((c & 0x3F) | 0x80); c >>= 6; nbytes++; } while (c >= 0x3F || (c & limits[nbytes-1])); *--p = (c | masks[nbytes-1]); } if (*outbytesleftp < nbytes) return E2BIG; while (p < &buf[6]) *outbuf++ = *p++; *outbytesleftp -= nbytes; *outbufp = outbuf; return 0; } /* The following four functions transform one character between the two encodings named in the function name. All have the signature int (*)(iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, uchar **outbufp, size_t *outbytesleftp) BIGEND must have the value 0 or 1, coerced to (iconv_t); it is interpreted as a boolean indicating whether big-endian or little-endian encoding is to be used for the member of the pair that is not UTF-8. INBUFP, INBYTESLEFTP, OUTBUFP, OUTBYTESLEFTP work exactly as they do for iconv. The return value is either 0 for success, or an errno value for failure, which may be E2BIG (need more space), EILSEQ (ill-formed input sequence), ir EINVAL (incomplete input sequence). */ static inline int one_utf8_to_utf32 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, uchar **outbufp, size_t *outbytesleftp) { uchar *outbuf; cppchar_t s = 0; int rval; /* Check for space first, since we know exactly how much we need. */ if (*outbytesleftp < 4) return E2BIG; rval = one_utf8_to_cppchar (inbufp, inbytesleftp, &s); if (rval) return rval; outbuf = *outbufp; outbuf[bigend ? 3 : 0] = (s & 0x000000FF); outbuf[bigend ? 2 : 1] = (s & 0x0000FF00) >> 8; outbuf[bigend ? 1 : 2] = (s & 0x00FF0000) >> 16; outbuf[bigend ? 0 : 3] = (s & 0xFF000000) >> 24; *outbufp += 4; *outbytesleftp -= 4; return 0; } static inline int one_utf32_to_utf8 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, uchar **outbufp, size_t *outbytesleftp) { cppchar_t s; int rval; const uchar *inbuf; if (*inbytesleftp < 4) return EINVAL; inbuf = *inbufp; s = inbuf[bigend ? 0 : 3] << 24; s += inbuf[bigend ? 1 : 2] << 16; s += inbuf[bigend ? 2 : 1] << 8; s += inbuf[bigend ? 3 : 0]; if (s >= 0x7FFFFFFF || (s >= 0xD800 && s <= 0xDFFF)) return EILSEQ; rval = one_cppchar_to_utf8 (s, outbufp, outbytesleftp); if (rval) return rval; *inbufp += 4; *inbytesleftp -= 4; return 0; } static inline int one_utf8_to_utf16 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, uchar **outbufp, size_t *outbytesleftp) { int rval; cppchar_t s = 0; const uchar *save_inbuf = *inbufp; size_t save_inbytesleft = *inbytesleftp; uchar *outbuf = *outbufp; rval = one_utf8_to_cppchar (inbufp, inbytesleftp, &s); if (rval) return rval; if (s > 0x0010FFFF) { *inbufp = save_inbuf; *inbytesleftp = save_inbytesleft; return EILSEQ; } if (s <= 0xFFFF) { if (*outbytesleftp < 2) { *inbufp = save_inbuf; *inbytesleftp = save_inbytesleft; return E2BIG; } outbuf[bigend ? 1 : 0] = (s & 0x00FF); outbuf[bigend ? 0 : 1] = (s & 0xFF00) >> 8; *outbufp += 2; *outbytesleftp -= 2; return 0; } else { cppchar_t hi, lo; if (*outbytesleftp < 4) { *inbufp = save_inbuf; *inbytesleftp = save_inbytesleft; return E2BIG; } hi = (s - 0x10000) / 0x400 + 0xD800; lo = (s - 0x10000) % 0x400 + 0xDC00; /* Even if we are little-endian, put the high surrogate first. ??? Matches practice? */ outbuf[bigend ? 1 : 0] = (hi & 0x00FF); outbuf[bigend ? 0 : 1] = (hi & 0xFF00) >> 8; outbuf[bigend ? 3 : 2] = (lo & 0x00FF); outbuf[bigend ? 2 : 3] = (lo & 0xFF00) >> 8; *outbufp += 4; *outbytesleftp -= 4; return 0; } } static inline int one_utf16_to_utf8 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, uchar **outbufp, size_t *outbytesleftp) { cppchar_t s; const uchar *inbuf = *inbufp; int rval; if (*inbytesleftp < 2) return EINVAL; s = inbuf[bigend ? 0 : 1] << 8; s += inbuf[bigend ? 1 : 0]; /* Low surrogate without immediately preceding high surrogate is invalid. */ if (s >= 0xDC00 && s <= 0xDFFF) return EILSEQ; /* High surrogate must have a following low surrogate. */ else if (s >= 0xD800 && s <= 0xDBFF) { cppchar_t hi = s, lo; if (*inbytesleftp < 4) return EINVAL; lo = inbuf[bigend ? 2 : 3] << 8; lo += inbuf[bigend ? 3 : 2]; if (lo < 0xDC00 || lo > 0xDFFF) return EILSEQ; s = (hi - 0xD800) * 0x400 + (lo - 0xDC00) + 0x10000; } rval = one_cppchar_to_utf8 (s, outbufp, outbytesleftp); if (rval) return rval; /* Success - update the input pointers (one_cppchar_to_utf8 has done the output pointers for us). */ if (s <= 0xFFFF) { *inbufp += 2; *inbytesleftp -= 2; } else { *inbufp += 4; *inbytesleftp -= 4; } return 0; } /* Helper routine for the next few functions. The 'const' on one_conversion means that we promise not to modify what function is pointed to, which lets the inliner see through it. */ static inline bool conversion_loop (int (*const one_conversion)(iconv_t, const uchar **, size_t *, uchar **, size_t *), iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to) { const uchar *inbuf; uchar *outbuf; size_t inbytesleft, outbytesleft; int rval; inbuf = from; inbytesleft = flen; outbuf = to->text + to->len; outbytesleft = to->asize - to->len; for (;;) { do rval = one_conversion (cd, &inbuf, &inbytesleft, &outbuf, &outbytesleft); while (inbytesleft && !rval); if (__builtin_expect (inbytesleft == 0, 1)) { to->len = to->asize - outbytesleft; return true; } if (rval != E2BIG) { errno = rval; return false; } outbytesleft += OUTBUF_BLOCK_SIZE; to->asize += OUTBUF_BLOCK_SIZE; to->text = XRESIZEVEC (uchar, to->text, to->asize); outbuf = to->text + to->asize - outbytesleft; } } /* These functions convert entire strings between character sets. They all have the signature bool (*)(iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to); The input string FROM is converted as specified by the function name plus the iconv descriptor CD (which may be fake), and the result appended to TO. On any error, false is returned, otherwise true. */ /* These four use the custom conversion code above. */ static bool convert_utf8_utf16 (iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to) { return conversion_loop (one_utf8_to_utf16, cd, from, flen, to); } static bool convert_utf8_utf32 (iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to) { return conversion_loop (one_utf8_to_utf32, cd, from, flen, to); } static bool convert_utf16_utf8 (iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to) { return conversion_loop (one_utf16_to_utf8, cd, from, flen, to); } static bool convert_utf32_utf8 (iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to) { return conversion_loop (one_utf32_to_utf8, cd, from, flen, to); } /* Identity conversion, used when we have no alternative. */ static bool convert_no_conversion (iconv_t cd ATTRIBUTE_UNUSED, const uchar *from, size_t flen, struct _cpp_strbuf *to) { if (to->len + flen > to->asize) { to->asize = to->len + flen; to->asize += to->asize / 4; to->text = XRESIZEVEC (uchar, to->text, to->asize); } memcpy (to->text + to->len, from, flen); to->len += flen; return true; } /* And this one uses the system iconv primitive. It's a little different, since iconv's interface is a little different. */ #if HAVE_ICONV #define CONVERT_ICONV_GROW_BUFFER \ do { \ outbytesleft += OUTBUF_BLOCK_SIZE; \ to->asize += OUTBUF_BLOCK_SIZE; \ to->text = XRESIZEVEC (uchar, to->text, to->asize); \ outbuf = (char *)to->text + to->asize - outbytesleft; \ } while (0) static bool convert_using_iconv (iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to) { ICONV_CONST char *inbuf; char *outbuf; size_t inbytesleft, outbytesleft; /* Reset conversion descriptor and check that it is valid. */ if (iconv (cd, 0, 0, 0, 0) == (size_t)-1) return false; inbuf = (ICONV_CONST char *)from; inbytesleft = flen; outbuf = (char *)to->text + to->len; outbytesleft = to->asize - to->len; for (;;) { iconv (cd, &inbuf, &inbytesleft, &outbuf, &outbytesleft); if (__builtin_expect (inbytesleft == 0, 1)) { /* Close out any shift states, returning to the initial state. */ if (iconv (cd, 0, 0, &outbuf, &outbytesleft) == (size_t)-1) { if (errno != E2BIG) return false; CONVERT_ICONV_GROW_BUFFER; if (iconv (cd, 0, 0, &outbuf, &outbytesleft) == (size_t)-1) return false; } to->len = to->asize - outbytesleft; return true; } if (errno != E2BIG) return false; CONVERT_ICONV_GROW_BUFFER; } } #else #define convert_using_iconv 0 /* prevent undefined symbol error below */ #endif /* Arrange for the above custom conversion logic to be used automatically when conversion between a suitable pair of character sets is requested. */ #define APPLY_CONVERSION(CONVERTER, FROM, FLEN, TO) \ CONVERTER.func (CONVERTER.cd, FROM, FLEN, TO) struct cpp_conversion { const char *pair; convert_f func; iconv_t fake_cd; }; static const struct cpp_conversion conversion_tab[] = { { "UTF-8/UTF-32LE", convert_utf8_utf32, (iconv_t)0 }, { "UTF-8/UTF-32BE", convert_utf8_utf32, (iconv_t)1 }, { "UTF-8/UTF-16LE", convert_utf8_utf16, (iconv_t)0 }, { "UTF-8/UTF-16BE", convert_utf8_utf16, (iconv_t)1 }, { "UTF-32LE/UTF-8", convert_utf32_utf8, (iconv_t)0 }, { "UTF-32BE/UTF-8", convert_utf32_utf8, (iconv_t)1 }, { "UTF-16LE/UTF-8", convert_utf16_utf8, (iconv_t)0 }, { "UTF-16BE/UTF-8", convert_utf16_utf8, (iconv_t)1 }, }; /* Subroutine of cpp_init_iconv: initialize and return a cset_converter structure for conversion from FROM to TO. If iconv_open() fails, issue an error and return an identity converter. Silently return an identity converter if FROM and TO are identical. PFILE is only used for generating diagnostics; setting it to NULL suppresses diagnostics. */ static struct cset_converter init_iconv_desc (cpp_reader *pfile, const char *to, const char *from) { struct cset_converter ret; char *pair; size_t i; ret.to = to; ret.from = from; if (!strcasecmp (to, from)) { ret.func = convert_no_conversion; ret.cd = (iconv_t) -1; ret.width = -1; return ret; } pair = (char *) alloca(strlen(to) + strlen(from) + 2); strcpy(pair, from); strcat(pair, "/"); strcat(pair, to); for (i = 0; i < ARRAY_SIZE (conversion_tab); i++) if (!strcasecmp (pair, conversion_tab[i].pair)) { ret.func = conversion_tab[i].func; ret.cd = conversion_tab[i].fake_cd; ret.width = -1; return ret; } /* No custom converter - try iconv. */ if (HAVE_ICONV) { ret.func = convert_using_iconv; ret.cd = iconv_open (to, from); ret.width = -1; if (ret.cd == (iconv_t) -1) { if (pfile) { if (errno == EINVAL) cpp_error (pfile, CPP_DL_ERROR, /* FIXME should be DL_SORRY */ "conversion from %s to %s not supported by iconv", from, to); else cpp_errno (pfile, CPP_DL_ERROR, "iconv_open"); } ret.func = convert_no_conversion; } } else { if (pfile) { cpp_error (pfile, CPP_DL_ERROR, /* FIXME: should be DL_SORRY */ "no iconv implementation, cannot convert from %s to %s", from, to); } ret.func = convert_no_conversion; ret.cd = (iconv_t) -1; ret.width = -1; } return ret; } /* If charset conversion is requested, initialize iconv(3) descriptors for conversion from the source character set to the execution character sets. If iconv is not present in the C library, and conversion is requested, issue an error. */ void cpp_init_iconv (cpp_reader *pfile) { const char *ncset = CPP_OPTION (pfile, narrow_charset); const char *wcset = CPP_OPTION (pfile, wide_charset); const char *default_wcset; bool be = CPP_OPTION (pfile, bytes_big_endian); if (CPP_OPTION (pfile, wchar_precision) >= 32) default_wcset = be ? "UTF-32BE" : "UTF-32LE"; else if (CPP_OPTION (pfile, wchar_precision) >= 16) default_wcset = be ? "UTF-16BE" : "UTF-16LE"; else /* This effectively means that wide strings are not supported, so don't do any conversion at all. */ default_wcset = SOURCE_CHARSET; if (!ncset) ncset = SOURCE_CHARSET; if (!wcset) wcset = default_wcset; pfile->narrow_cset_desc = init_iconv_desc (pfile, ncset, SOURCE_CHARSET); pfile->narrow_cset_desc.width = CPP_OPTION (pfile, char_precision); pfile->utf8_cset_desc = init_iconv_desc (pfile, "UTF-8", SOURCE_CHARSET); pfile->utf8_cset_desc.width = CPP_OPTION (pfile, char_precision); pfile->char16_cset_desc = init_iconv_desc (pfile, be ? "UTF-16BE" : "UTF-16LE", SOURCE_CHARSET); pfile->char16_cset_desc.width = 16; pfile->char32_cset_desc = init_iconv_desc (pfile, be ? "UTF-32BE" : "UTF-32LE", SOURCE_CHARSET); pfile->char32_cset_desc.width = 32; pfile->wide_cset_desc = init_iconv_desc (pfile, wcset, SOURCE_CHARSET); pfile->wide_cset_desc.width = CPP_OPTION (pfile, wchar_precision); } /* Destroy iconv(3) descriptors set up by cpp_init_iconv, if necessary. */ void _cpp_destroy_iconv (cpp_reader *pfile) { if (HAVE_ICONV) { if (pfile->narrow_cset_desc.func == convert_using_iconv) iconv_close (pfile->narrow_cset_desc.cd); if (pfile->utf8_cset_desc.func == convert_using_iconv) iconv_close (pfile->utf8_cset_desc.cd); if (pfile->char16_cset_desc.func == convert_using_iconv) iconv_close (pfile->char16_cset_desc.cd); if (pfile->char32_cset_desc.func == convert_using_iconv) iconv_close (pfile->char32_cset_desc.cd); if (pfile->wide_cset_desc.func == convert_using_iconv) iconv_close (pfile->wide_cset_desc.cd); } } /* Utility routine for use by a full compiler. C is a character taken from the *basic* source character set, encoded in the host's execution encoding. Convert it to (the target's) execution encoding, and return that value. Issues an internal error if C's representation in the narrow execution character set fails to be a single-byte value (C99 5.2.1p3: "The representation of each member of the source and execution character sets shall fit in a byte.") May also issue an internal error if C fails to be a member of the basic source character set (testing this exactly is too hard, especially when the host character set is EBCDIC). */ cppchar_t cpp_host_to_exec_charset (cpp_reader *pfile, cppchar_t c) { uchar sbuf[1]; struct _cpp_strbuf tbuf; /* This test is merely an approximation, but it suffices to catch the most important thing, which is that we don't get handed a character outside the unibyte range of the host character set. */ if (c > LAST_POSSIBLY_BASIC_SOURCE_CHAR) { cpp_error (pfile, CPP_DL_ICE, "character 0x%lx is not in the basic source character set\n", (unsigned long)c); return 0; } /* Being a character in the unibyte range of the host character set, we can safely splat it into a one-byte buffer and trust that that is a well-formed string. */ sbuf[0] = c; /* This should never need to reallocate, but just in case... */ tbuf.asize = 1; tbuf.text = XNEWVEC (uchar, tbuf.asize); tbuf.len = 0; if (!APPLY_CONVERSION (pfile->narrow_cset_desc, sbuf, 1, &tbuf)) { cpp_errno (pfile, CPP_DL_ICE, "converting to execution character set"); return 0; } if (tbuf.len != 1) { cpp_error (pfile, CPP_DL_ICE, "character 0x%lx is not unibyte in execution character set", (unsigned long)c); return 0; } c = tbuf.text[0]; free(tbuf.text); return c; } /* cpp_substring_ranges's constructor. */ cpp_substring_ranges::cpp_substring_ranges () : m_ranges (NULL), m_num_ranges (0), m_alloc_ranges (8) { m_ranges = XNEWVEC (source_range, m_alloc_ranges); } /* cpp_substring_ranges's destructor. */ cpp_substring_ranges::~cpp_substring_ranges () { free (m_ranges); } /* Add RANGE to the vector of source_range information. */ void cpp_substring_ranges::add_range (source_range range) { if (m_num_ranges >= m_alloc_ranges) { m_alloc_ranges *= 2; m_ranges = (source_range *)xrealloc (m_ranges, sizeof (source_range) * m_alloc_ranges); } m_ranges[m_num_ranges++] = range; } /* Read NUM ranges from LOC_READER, adding them to the vector of source_range information. */ void cpp_substring_ranges::add_n_ranges (int num, cpp_string_location_reader &loc_reader) { for (int i = 0; i < num; i++) add_range (loc_reader.get_next ()); } /* Utility routine that computes a mask of the form 0000...111... with WIDTH 1-bits. */ static inline size_t width_to_mask (size_t width) { width = MIN (width, BITS_PER_CPPCHAR_T); if (width >= CHAR_BIT * sizeof (size_t)) return ~(size_t) 0; else return ((size_t) 1 << width) - 1; } /* A large table of unicode character information. */ enum { /* Valid in a C99 identifier? */ C99 = 1, /* Valid in a C99 identifier, but not as the first character? */ N99 = 2, /* Valid in a C++ identifier? */ CXX = 4, /* Valid in a C11/C++11 identifier? */ C11 = 8, /* Valid in a C11/C++11 identifier, but not as the first character? */ N11 = 16, /* Valid in a C++23 identifier? */ CXX23 = 32, /* Valid in a C++23 identifier, but not as the first character? */ NXX23 = 64, /* NFC representation is not valid in an identifier? */ CID = 128, /* Might be valid NFC form? */ NFC = 256, /* Might be valid NFKC form? */ NKC = 512, /* Certain preceding characters might make it not valid NFC/NKFC form? */ CTX = 1024 }; struct ucnrange { /* Bitmap of flags above. */ unsigned short flags; /* Combining class of the character. */ unsigned char combine; /* Last character in the range described by this entry. */ unsigned int end; }; #include "ucnid.h" /* ISO 10646 defines the UCS codespace as the range 0-0x10FFFF inclusive. */ #define UCS_LIMIT 0x10FFFF /* Returns 1 if C is valid in an identifier, 2 if C is valid except at the start of an identifier, and 0 if C is not valid in an identifier. We assume C has already gone through the checks of _cpp_valid_ucn. Also update NST for C if returning nonzero. The algorithm is a simple binary search on the table defined in ucnid.h. */ static int ucn_valid_in_identifier (cpp_reader *pfile, cppchar_t c, struct normalize_state *nst) { int mn, mx, md; unsigned short valid_flags, invalid_start_flags; if (c > UCS_LIMIT) return 0; mn = 0; mx = ARRAY_SIZE (ucnranges) - 1; while (mx != mn) { md = (mn + mx) / 2; if (c <= ucnranges[md].end) mx = md; else mn = md + 1; } /* When -pedantic, we require the character to have been listed by the standard for the current language. Otherwise, we accept the union of the acceptable sets for all supported language versions. */ valid_flags = C99 | CXX | C11 | CXX23; if (CPP_PEDANTIC (pfile)) { if (CPP_OPTION (pfile, cxx23_identifiers)) valid_flags = CXX23; else if (CPP_OPTION (pfile, c11_identifiers)) valid_flags = C11; else if (CPP_OPTION (pfile, c99)) valid_flags = C99; else if (CPP_OPTION (pfile, cplusplus)) valid_flags = CXX; } if (! (ucnranges[mn].flags & valid_flags)) return 0; /* Update NST. */ if (ucnranges[mn].combine != 0 && ucnranges[mn].combine < nst->prev_class) nst->level = normalized_none; else if (ucnranges[mn].flags & CTX) { bool safe; cppchar_t p = nst->previous; /* For Hangul, characters in the range AC00-D7A3 are NFC/NFKC, and are combined algorithmically from a sequence of the form 1100-1112 1161-1175 11A8-11C2 (if the third is not present, it is treated as 11A7, which is not really a valid character). Unfortunately, C99 allows (only) the NFC form, but C++ allows only the combining characters. */ if (c >= 0x1161 && c <= 0x1175) safe = p < 0x1100 || p > 0x1112; else if (c >= 0x11A8 && c <= 0x11C2) safe = (p < 0xAC00 || p > 0xD7A3 || (p - 0xAC00) % 28 != 0); else safe = check_nfc (pfile, c, p); if (!safe) { if ((c >= 0x1161 && c <= 0x1175) || (c >= 0x11A8 && c <= 0x11C2)) nst->level = MAX (nst->level, normalized_identifier_C); else nst->level = normalized_none; } } else if (ucnranges[mn].flags & NKC) ; else if (ucnranges[mn].flags & NFC) nst->level = MAX (nst->level, normalized_C); else if (ucnranges[mn].flags & CID) nst->level = MAX (nst->level, normalized_identifier_C); else nst->level = normalized_none; if (ucnranges[mn].combine == 0) nst->previous = c; nst->prev_class = ucnranges[mn].combine; if (!CPP_PEDANTIC (pfile)) { /* If not -pedantic, accept as character that may begin an identifier a union of characters allowed at that position in each of the character sets. */ if ((ucnranges[mn].flags & (C99 | N99)) == C99 || (ucnranges[mn].flags & CXX) != 0 || (ucnranges[mn].flags & (C11 | N11)) == C11 || (ucnranges[mn].flags & (CXX23 | NXX23)) == CXX23) return 1; return 2; } if (CPP_OPTION (pfile, cxx23_identifiers)) invalid_start_flags = NXX23; else if (CPP_OPTION (pfile, c11_identifiers)) invalid_start_flags = N11; else if (CPP_OPTION (pfile, c99)) invalid_start_flags = N99; else invalid_start_flags = 0; /* In C99, UCN digits may not begin identifiers. In C11 and C++11, UCN combining characters may not begin identifiers. */ if (ucnranges[mn].flags & invalid_start_flags) return 2; return 1; } /* [lex.charset]: The character designated by the universal character name \UNNNNNNNN is that character whose character short name in ISO/IEC 10646 is NNNNNNNN; the character designated by the universal character name \uNNNN is that character whose character short name in ISO/IEC 10646 is 0000NNNN. If the hexadecimal value for a universal character name corresponds to a surrogate code point (in the range 0xD800-0xDFFF, inclusive), the program is ill-formed. Additionally, if the hexadecimal value for a universal-character-name outside a character or string literal corresponds to a control character (in either of the ranges 0x00-0x1F or 0x7F-0x9F, both inclusive) or to a character in the basic source character set, the program is ill-formed. C99 6.4.3: A universal character name shall not specify a character whose short identifier is less than 00A0 other than 0024 ($), 0040 (@), or 0060 (`), nor one in the range D800 through DFFF inclusive. If the hexadecimal value is larger than the upper bound of the UCS codespace specified in ISO/IEC 10646, a pedantic warning is issued in all versions of C and in the C++20 or later versions of C++. *PSTR must be preceded by "\u" or "\U"; it is assumed that the buffer end is delimited by a non-hex digit. Returns false if the UCN has not been consumed, true otherwise. The value of the UCN, whether valid or invalid, is returned in *CP. Diagnostics are emitted for invalid values. PSTR is updated to point one beyond the UCN, or to the syntactically invalid character. IDENTIFIER_POS is 0 when not in an identifier, 1 for the start of an identifier, or 2 otherwise. If LOC_READER is non-NULL, then position information is read from *LOC_READER and CHAR_RANGE->m_finish is updated accordingly. */ bool _cpp_valid_ucn (cpp_reader *pfile, const uchar **pstr, const uchar *limit, int identifier_pos, struct normalize_state *nst, cppchar_t *cp, source_range *char_range, cpp_string_location_reader *loc_reader) { cppchar_t result, c; unsigned int length; const uchar *str = *pstr; const uchar *base = str - 2; if (!CPP_OPTION (pfile, cplusplus) && !CPP_OPTION (pfile, c99)) cpp_error (pfile, CPP_DL_WARNING, "universal character names are only valid in C++ and C99"); else if (CPP_OPTION (pfile, cpp_warn_c90_c99_compat) > 0 && !CPP_OPTION (pfile, cplusplus)) cpp_error (pfile, CPP_DL_WARNING, "C99's universal character names are incompatible with C90"); else if (CPP_WTRADITIONAL (pfile) && identifier_pos == 0) cpp_warning (pfile, CPP_W_TRADITIONAL, "the meaning of '\\%c' is different in traditional C", (int) str[-1]); if (str[-1] == 'u') length = 4; else if (str[-1] == 'U') length = 8; else { cpp_error (pfile, CPP_DL_ICE, "In _cpp_valid_ucn but not a UCN"); length = 4; } result = 0; do { c = *str; if (!ISXDIGIT (c)) break; str++; if (loc_reader) { gcc_assert (char_range); char_range->m_finish = loc_reader->get_next ().m_finish; } result = (result << 4) + hex_value (c); } while (--length && str < limit); /* Partial UCNs are not valid in strings, but decompose into multiple tokens in identifiers, so we can't give a helpful error message in that case. */ if (length && identifier_pos) { *cp = 0; return false; } *pstr = str; if (length) { cpp_error (pfile, CPP_DL_ERROR, "incomplete universal character name %.*s", (int) (str - base), base); result = 1; } /* The C99 standard permits $, @ and ` to be specified as UCNs. We use hex escapes so that this also works with EBCDIC hosts. C++0x permits everything below 0xa0 within literals; ucn_valid_in_identifier will complain about identifiers. */ else if ((result < 0xa0 && !CPP_OPTION (pfile, cplusplus) && (result != 0x24 && result != 0x40 && result != 0x60)) || (result & 0x80000000) || (result >= 0xD800 && result <= 0xDFFF)) { cpp_error (pfile, CPP_DL_ERROR, "%.*s is not a valid universal character", (int) (str - base), base); result = 1; } else if (identifier_pos && result == 0x24 && CPP_OPTION (pfile, dollars_in_ident)) { if (CPP_OPTION (pfile, warn_dollars) && !pfile->state.skipping) { CPP_OPTION (pfile, warn_dollars) = 0; cpp_error (pfile, CPP_DL_PEDWARN, "'$' in identifier or number"); } NORMALIZE_STATE_UPDATE_IDNUM (nst, result); } else if (identifier_pos) { int validity = ucn_valid_in_identifier (pfile, result, nst); if (validity == 0) cpp_error (pfile, CPP_DL_ERROR, "universal character %.*s is not valid in an identifier", (int) (str - base), base); else if (validity == 2 && identifier_pos == 1) cpp_error (pfile, CPP_DL_ERROR, "universal character %.*s is not valid at the start of an identifier", (int) (str - base), base); } else if (result > UCS_LIMIT && (!CPP_OPTION (pfile, cplusplus) || CPP_OPTION (pfile, lang) > CLK_CXX17)) cpp_error (pfile, CPP_DL_PEDWARN, "%.*s is outside the UCS codespace", (int) (str - base), base); *cp = result; return true; } /* Convert an UCN, pointed to by FROM, to UTF-8 encoding, then translate it to the execution character set and write the result into TBUF, if TBUF is non-NULL. An advanced pointer is returned. Issues all relevant diagnostics. If LOC_READER is non-NULL, then RANGES must be non-NULL and CHAR_RANGE contains the location of the character so far: location information is read from *LOC_READER, and *RANGES is updated accordingly. */ static const uchar * convert_ucn (cpp_reader *pfile, const uchar *from, const uchar *limit, struct _cpp_strbuf *tbuf, struct cset_converter cvt, source_range char_range, cpp_string_location_reader *loc_reader, cpp_substring_ranges *ranges) { cppchar_t ucn; uchar buf[6]; uchar *bufp = buf; size_t bytesleft = 6; int rval; struct normalize_state nst = INITIAL_NORMALIZE_STATE; /* loc_reader and ranges must either be both NULL, or both be non-NULL. */ gcc_assert ((loc_reader != NULL) == (ranges != NULL)); from++; /* Skip u/U. */ if (loc_reader) /* The u/U is part of the spelling of this character. */ char_range.m_finish = loc_reader->get_next ().m_finish; _cpp_valid_ucn (pfile, &from, limit, 0, &nst, &ucn, &char_range, loc_reader); rval = one_cppchar_to_utf8 (ucn, &bufp, &bytesleft); if (rval) { errno = rval; cpp_errno (pfile, CPP_DL_ERROR, "converting UCN to source character set"); } else { if (tbuf) if (!APPLY_CONVERSION (cvt, buf, 6 - bytesleft, tbuf)) cpp_errno (pfile, CPP_DL_ERROR, "converting UCN to execution character set"); if (loc_reader) { int num_encoded_bytes = 6 - bytesleft; for (int i = 0; i < num_encoded_bytes; i++) ranges->add_range (char_range); } } return from; } /* Performs a similar task as _cpp_valid_ucn, but parses UTF-8-encoded extended characters rather than UCNs. If the return value is TRUE, then a character was successfully decoded and stored in *CP; *PSTR has been updated to point one past the valid UTF-8 sequence. Diagnostics may have been emitted if the character parsed is not allowed in the current context. If the return value is FALSE, then *PSTR has not been modified and *CP may equal 0, to indicate that *PSTR does not form a valid UTF-8 sequence, or it may, when processing an identifier in C mode, equal a codepoint that was validly encoded but is not allowed to appear in an identifier. In either case, no diagnostic is emitted, and the return value of FALSE should cause a new token to be formed. Unlike _cpp_valid_ucn, this will never be called when lexing a string; only a potential identifier, or a CPP_OTHER token. NST is unused in the latter case. As in _cpp_valid_ucn, IDENTIFIER_POS is 0 when not in an identifier, 1 for the start of an identifier, or 2 otherwise. */ extern bool _cpp_valid_utf8 (cpp_reader *pfile, const uchar **pstr, const uchar *limit, int identifier_pos, struct normalize_state *nst, cppchar_t *cp) { const uchar *base = *pstr; size_t inbytesleft = limit - base; if (one_utf8_to_cppchar (pstr, &inbytesleft, cp)) { /* No diagnostic here as this byte will rather become a new token. */ *cp = 0; return false; } if (identifier_pos) { switch (ucn_valid_in_identifier (pfile, *cp, nst)) { case 0: /* In C++, this is an error for invalid character in an identifier because logically, the UTF-8 was converted to a UCN during translation phase 1 (even though we don't physically do it that way). In C, this byte rather becomes grammatically a separate token. */ if (CPP_OPTION (pfile, cplusplus)) cpp_error (pfile, CPP_DL_ERROR, "extended character %.*s is not valid in an identifier", (int) (*pstr - base), base); else { *pstr = base; return false; } break; case 2: if (identifier_pos == 1) { /* This is treated the same way in C++ or C99 -- lexed as an identifier which is then invalid because an identifier is not allowed to start with this character. */ cpp_error (pfile, CPP_DL_ERROR, "extended character %.*s is not valid at the start of an identifier", (int) (*pstr - base), base); } break; } } return true; } /* Subroutine of convert_hex and convert_oct. N is the representation in the execution character set of a numeric escape; write it into the string buffer TBUF and update the end-of-string pointer therein. WIDE is true if it's a wide string that's being assembled in TBUF. This function issues no diagnostics and never fails. */ static void emit_numeric_escape (cpp_reader *pfile, cppchar_t n, struct _cpp_strbuf *tbuf, struct cset_converter cvt) { size_t width = cvt.width; if (width != CPP_OPTION (pfile, char_precision)) { /* We have to render this into the target byte order, which may not be our byte order. */ bool bigend = CPP_OPTION (pfile, bytes_big_endian); size_t cwidth = CPP_OPTION (pfile, char_precision); size_t cmask = width_to_mask (cwidth); size_t nbwc = width / cwidth; size_t i; size_t off = tbuf->len; cppchar_t c; if (tbuf->len + nbwc > tbuf->asize) { tbuf->asize += OUTBUF_BLOCK_SIZE; tbuf->text = XRESIZEVEC (uchar, tbuf->text, tbuf->asize); } for (i = 0; i < nbwc; i++) { c = n & cmask; n >>= cwidth; tbuf->text[off + (bigend ? nbwc - i - 1 : i)] = c; } tbuf->len += nbwc; } else { /* Note: this code does not handle the case where the target and host have a different number of bits in a byte. */ if (tbuf->len + 1 > tbuf->asize) { tbuf->asize += OUTBUF_BLOCK_SIZE; tbuf->text = XRESIZEVEC (uchar, tbuf->text, tbuf->asize); } tbuf->text[tbuf->len++] = n; } } /* Convert a hexadecimal escape, pointed to by FROM, to the execution character set and write it into the string buffer TBUF (if non-NULL). Returns an advanced pointer, and issues diagnostics as necessary. No character set translation occurs; this routine always produces the execution-set character with numeric value equal to the given hex number. You can, e.g. generate surrogate pairs this way. If LOC_READER is non-NULL, then RANGES must be non-NULL and CHAR_RANGE contains the location of the character so far: location information is read from *LOC_READER, and *RANGES is updated accordingly. */ static const uchar * convert_hex (cpp_reader *pfile, const uchar *from, const uchar *limit, struct _cpp_strbuf *tbuf, struct cset_converter cvt, source_range char_range, cpp_string_location_reader *loc_reader, cpp_substring_ranges *ranges) { cppchar_t c, n = 0, overflow = 0; int digits_found = 0; size_t width = cvt.width; size_t mask = width_to_mask (width); /* loc_reader and ranges must either be both NULL, or both be non-NULL. */ gcc_assert ((loc_reader != NULL) == (ranges != NULL)); if (CPP_WTRADITIONAL (pfile)) cpp_warning (pfile, CPP_W_TRADITIONAL, "the meaning of '\\x' is different in traditional C"); /* Skip 'x'. */ from++; /* The 'x' is part of the spelling of this character. */ if (loc_reader) char_range.m_finish = loc_reader->get_next ().m_finish; while (from < limit) { c = *from; if (! hex_p (c)) break; from++; if (loc_reader) char_range.m_finish = loc_reader->get_next ().m_finish; overflow |= n ^ (n << 4 >> 4); n = (n << 4) + hex_value (c); digits_found = 1; } if (!digits_found) { cpp_error (pfile, CPP_DL_ERROR, "\\x used with no following hex digits"); return from; } if (overflow | (n != (n & mask))) { cpp_error (pfile, CPP_DL_PEDWARN, "hex escape sequence out of range"); n &= mask; } if (tbuf) emit_numeric_escape (pfile, n, tbuf, cvt); if (ranges) ranges->add_range (char_range); return from; } /* Convert an octal escape, pointed to by FROM, to the execution character set and write it into the string buffer TBUF. Returns an advanced pointer, and issues diagnostics as necessary. No character set translation occurs; this routine always produces the execution-set character with numeric value equal to the given octal number. If LOC_READER is non-NULL, then RANGES must be non-NULL and CHAR_RANGE contains the location of the character so far: location information is read from *LOC_READER, and *RANGES is updated accordingly. */ static const uchar * convert_oct (cpp_reader *pfile, const uchar *from, const uchar *limit, struct _cpp_strbuf *tbuf, struct cset_converter cvt, source_range char_range, cpp_string_location_reader *loc_reader, cpp_substring_ranges *ranges) { size_t count = 0; cppchar_t c, n = 0; size_t width = cvt.width; size_t mask = width_to_mask (width); bool overflow = false; /* loc_reader and ranges must either be both NULL, or both be non-NULL. */ gcc_assert ((loc_reader != NULL) == (ranges != NULL)); while (from < limit && count++ < 3) { c = *from; if (c < '0' || c > '7') break; from++; if (loc_reader) char_range.m_finish = loc_reader->get_next ().m_finish; overflow |= n ^ (n << 3 >> 3); n = (n << 3) + c - '0'; } if (n != (n & mask)) { cpp_error (pfile, CPP_DL_PEDWARN, "octal escape sequence out of range"); n &= mask; } if (tbuf) emit_numeric_escape (pfile, n, tbuf, cvt); if (ranges) ranges->add_range (char_range); return from; } /* Convert an escape sequence (pointed to by FROM) to its value on the target, and to the execution character set. Do not scan past LIMIT. Write the converted value into TBUF, if TBUF is non-NULL. Returns an advanced pointer. Handles all relevant diagnostics. If LOC_READER is non-NULL, then RANGES must be non-NULL: location information is read from *LOC_READER, and *RANGES is updated accordingly. */ static const uchar * convert_escape (cpp_reader *pfile, const uchar *from, const uchar *limit, struct _cpp_strbuf *tbuf, struct cset_converter cvt, cpp_string_location_reader *loc_reader, cpp_substring_ranges *ranges) { /* Values of \a \b \e \f \n \r \t \v respectively. */ #if HOST_CHARSET == HOST_CHARSET_ASCII static const uchar charconsts[] = { 7, 8, 27, 12, 10, 13, 9, 11 }; #elif HOST_CHARSET == HOST_CHARSET_EBCDIC static const uchar charconsts[] = { 47, 22, 39, 12, 21, 13, 5, 11 }; #else #error "unknown host character set" #endif uchar c; /* Record the location of the backslash. */ source_range char_range; if (loc_reader) char_range = loc_reader->get_next (); c = *from; switch (c) { /* UCNs, hex escapes, and octal escapes are processed separately. */ case 'u': case 'U': return convert_ucn (pfile, from, limit, tbuf, cvt, char_range, loc_reader, ranges); case 'x': return convert_hex (pfile, from, limit, tbuf, cvt, char_range, loc_reader, ranges); break; case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': return convert_oct (pfile, from, limit, tbuf, cvt, char_range, loc_reader, ranges); /* Various letter escapes. Get the appropriate host-charset value into C. */ case '\\': case '\'': case '"': case '?': break; case '(': case '{': case '[': case '%': /* '\(', etc, can be used at the beginning of a line in a long string split onto multiple lines with \-newline, to prevent Emacs or other text editors from getting confused. '\%' can be used to prevent SCCS from mangling printf format strings. */ if (CPP_PEDANTIC (pfile)) goto unknown; break; case 'b': c = charconsts[1]; break; case 'f': c = charconsts[3]; break; case 'n': c = charconsts[4]; break; case 'r': c = charconsts[5]; break; case 't': c = charconsts[6]; break; case 'v': c = charconsts[7]; break; case 'a': if (CPP_WTRADITIONAL (pfile)) cpp_warning (pfile, CPP_W_TRADITIONAL, "the meaning of '\\a' is different in traditional C"); c = charconsts[0]; break; case 'e': case 'E': if (CPP_PEDANTIC (pfile)) cpp_error (pfile, CPP_DL_PEDWARN, "non-ISO-standard escape sequence, '\\%c'", (int) c); c = charconsts[2]; break; default: unknown: if (ISGRAPH (c)) cpp_error (pfile, CPP_DL_PEDWARN, "unknown escape sequence: '\\%c'", (int) c); else { /* diagnostic.c does not support "%03o". When it does, this code can use %03o directly in the diagnostic again. */ char buf[32]; sprintf(buf, "%03o", (int) c); cpp_error (pfile, CPP_DL_PEDWARN, "unknown escape sequence: '\\%s'", buf); } } if (tbuf) /* Now convert what we have to the execution character set. */ if (!APPLY_CONVERSION (cvt, &c, 1, tbuf)) cpp_errno (pfile, CPP_DL_ERROR, "converting escape sequence to execution character set"); if (loc_reader) { char_range.m_finish = loc_reader->get_next ().m_finish; ranges->add_range (char_range); } return from + 1; } /* TYPE is a token type. The return value is the conversion needed to convert from source to execution character set for the given type. */ static struct cset_converter converter_for_type (cpp_reader *pfile, enum cpp_ttype type) { switch (type) { default: return pfile->narrow_cset_desc; case CPP_UTF8CHAR: case CPP_UTF8STRING: return pfile->utf8_cset_desc; case CPP_CHAR16: case CPP_STRING16: return pfile->char16_cset_desc; case CPP_CHAR32: case CPP_STRING32: return pfile->char32_cset_desc; case CPP_WCHAR: case CPP_WSTRING: return pfile->wide_cset_desc; } } /* FROM is an array of cpp_string structures of length COUNT. These are to be converted from the source to the execution character set, escape sequences translated, and finally all are to be concatenated. WIDE indicates whether or not to produce a wide string. If TO is non-NULL, the result is written into TO. If LOC_READERS and OUT are non-NULL, then location information is read from LOC_READERS (which must be an array of length COUNT), and location information is written to *RANGES. Returns true for success, false for failure. */ static bool cpp_interpret_string_1 (cpp_reader *pfile, const cpp_string *from, size_t count, cpp_string *to, enum cpp_ttype type, cpp_string_location_reader *loc_readers, cpp_substring_ranges *out) { struct _cpp_strbuf tbuf; const uchar *p, *base, *limit; size_t i; struct cset_converter cvt = converter_for_type (pfile, type); /* loc_readers and out must either be both NULL, or both be non-NULL. */ gcc_assert ((loc_readers != NULL) == (out != NULL)); if (to) { tbuf.asize = MAX (OUTBUF_BLOCK_SIZE, from->len); tbuf.text = XNEWVEC (uchar, tbuf.asize); tbuf.len = 0; } cpp_string_location_reader *loc_reader = NULL; for (i = 0; i < count; i++) { if (loc_readers) loc_reader = &loc_readers[i]; p = from[i].text; if (*p == 'u') { p++; if (loc_reader) loc_reader->get_next (); if (*p == '8') { p++; if (loc_reader) loc_reader->get_next (); } } else if (*p == 'L' || *p == 'U') p++; if (*p == 'R') { const uchar *prefix; /* Skip over 'R"'. */ p += 2; if (loc_reader) { loc_reader->get_next (); loc_reader->get_next (); } prefix = p; while (*p != '(') { p++; if (loc_reader) loc_reader->get_next (); } p++; if (loc_reader) loc_reader->get_next (); limit = from[i].text + from[i].len; if (limit >= p + (p - prefix) + 1) limit -= (p - prefix) + 1; /* Raw strings are all normal characters; these can be fed directly to convert_cset. */ if (to) if (!APPLY_CONVERSION (cvt, p, limit - p, &tbuf)) goto fail; if (loc_reader) { /* If generating source ranges, assume we have a 1:1 correspondence between bytes in the source encoding and bytes in the execution encoding (e.g. if we have a UTF-8 to UTF-8 conversion), so that this run of bytes in the source file corresponds to a run of bytes in the execution string. This requirement is guaranteed by an early-reject in cpp_interpret_string_ranges. */ gcc_assert (cvt.func == convert_no_conversion); out->add_n_ranges (limit - p, *loc_reader); } continue; } /* If we don't now have a leading quote, something has gone wrong. This can occur if cpp_interpret_string_ranges is handling a stringified macro argument, but should not be possible otherwise. */ if (*p != '"' && *p != '\'') { gcc_assert (out != NULL); cpp_error (pfile, CPP_DL_ERROR, "missing open quote"); if (to) free (tbuf.text); return false; } /* Skip leading quote. */ p++; if (loc_reader) loc_reader->get_next (); limit = from[i].text + from[i].len - 1; /* Skip trailing quote. */ for (;;) { base = p; while (p < limit && *p != '\\') p++; if (p > base) { /* We have a run of normal characters; these can be fed directly to convert_cset. */ if (to) if (!APPLY_CONVERSION (cvt, base, p - base, &tbuf)) goto fail; /* Similar to above: assumes we have a 1:1 correspondence between bytes in the source encoding and bytes in the execution encoding. */ if (loc_reader) { gcc_assert (cvt.func == convert_no_conversion); out->add_n_ranges (p - base, *loc_reader); } } if (p >= limit) break; struct _cpp_strbuf *tbuf_ptr = to ? &tbuf : NULL; p = convert_escape (pfile, p + 1, limit, tbuf_ptr, cvt, loc_reader, out); } } if (to) { /* NUL-terminate the 'to' buffer and translate it to a cpp_string structure. */ emit_numeric_escape (pfile, 0, &tbuf, cvt); tbuf.text = XRESIZEVEC (uchar, tbuf.text, tbuf.len); to->text = tbuf.text; to->len = tbuf.len; } /* Use the location of the trailing quote as the location of the NUL-terminator. */ if (loc_reader) { source_range range = loc_reader->get_next (); out->add_range (range); } return true; fail: cpp_errno (pfile, CPP_DL_ERROR, "converting to execution character set"); if (to) free (tbuf.text); return false; } /* FROM is an array of cpp_string structures of length COUNT. These are to be converted from the source to the execution character set, escape sequences translated, and finally all are to be concatenated. WIDE indicates whether or not to produce a wide string. The result is written into TO. Returns true for success, false for failure. */ bool cpp_interpret_string (cpp_reader *pfile, const cpp_string *from, size_t count, cpp_string *to, enum cpp_ttype type) { return cpp_interpret_string_1 (pfile, from, count, to, type, NULL, NULL); } /* A "do nothing" diagnostic-handling callback for use by cpp_interpret_string_ranges, so that it can temporarily suppress diagnostic-handling. */ static bool noop_diagnostic_cb (cpp_reader *, enum cpp_diagnostic_level, enum cpp_warning_reason, rich_location *, const char *, va_list *) { /* no-op. */ return true; } /* This function mimics the behavior of cpp_interpret_string, but rather than generating a string in the execution character set, *OUT is written to with the source code ranges of the characters in such a string. FROM and LOC_READERS should both be arrays of length COUNT. Returns NULL for success, or an error message for failure. */ const char * cpp_interpret_string_ranges (cpp_reader *pfile, const cpp_string *from, cpp_string_location_reader *loc_readers, size_t count, cpp_substring_ranges *out, enum cpp_ttype type) { /* There are a couple of cases in the range-handling in cpp_interpret_string_1 that rely on there being a 1:1 correspondence between bytes in the source encoding and bytes in the execution encoding, so that each byte in the execution string can correspond to the location of a byte in the source string. This holds for the typical case of a UTF-8 to UTF-8 conversion. Enforce this requirement by only attempting to track substring locations if we have source encoding == execution encoding. This is a stronger condition than we need, since we could e.g. have ASCII to EBCDIC (with 1 byte per character before and after), but it seems to be a reasonable restriction. */ struct cset_converter cvt = converter_for_type (pfile, type); if (cvt.func != convert_no_conversion) return "execution character set != source character set"; /* For on-demand strings we have already lexed the strings, so there should be no diagnostics. However, if we have bogus source location data (or stringified macro arguments), the attempt to lex the strings could fail with an diagnostic. Temporarily install an diagnostic-handler to catch the diagnostic, so that it can lead to this call failing, rather than being emitted as a user-visible diagnostic. If an diagnostic does occur, we should see it via the return value of cpp_interpret_string_1. */ bool (*saved_diagnostic_handler) (cpp_reader *, enum cpp_diagnostic_level, enum cpp_warning_reason, rich_location *, const char *, va_list *) ATTRIBUTE_FPTR_PRINTF(5,0); saved_diagnostic_handler = pfile->cb.diagnostic; pfile->cb.diagnostic = noop_diagnostic_cb; bool result = cpp_interpret_string_1 (pfile, from, count, NULL, type, loc_readers, out); /* Restore the saved diagnostic-handler. */ pfile->cb.diagnostic = saved_diagnostic_handler; if (!result) return "cpp_interpret_string_1 failed"; /* Success. */ return NULL; } /* Subroutine of do_line and do_linemarker. Convert escape sequences in a string, but do not perform character set conversion. */ bool cpp_interpret_string_notranslate (cpp_reader *pfile, const cpp_string *from, size_t count, cpp_string *to, enum cpp_ttype type ATTRIBUTE_UNUSED) { struct cset_converter save_narrow_cset_desc = pfile->narrow_cset_desc; bool retval; pfile->narrow_cset_desc.func = convert_no_conversion; pfile->narrow_cset_desc.cd = (iconv_t) -1; pfile->narrow_cset_desc.width = CPP_OPTION (pfile, char_precision); retval = cpp_interpret_string (pfile, from, count, to, CPP_STRING); pfile->narrow_cset_desc = save_narrow_cset_desc; return retval; } /* Subroutine of cpp_interpret_charconst which performs the conversion to a number, for narrow strings. STR is the string structure returned by cpp_interpret_string. PCHARS_SEEN and UNSIGNEDP are as for cpp_interpret_charconst. TYPE is the token type. */ static cppchar_t narrow_str_to_charconst (cpp_reader *pfile, cpp_string str, unsigned int *pchars_seen, int *unsignedp, enum cpp_ttype type) { size_t width = CPP_OPTION (pfile, char_precision); size_t max_chars = CPP_OPTION (pfile, int_precision) / width; size_t mask = width_to_mask (width); size_t i; cppchar_t result, c; bool unsigned_p; /* The value of a multi-character character constant, or a single-character character constant whose representation in the execution character set is more than one byte long, is implementation defined. This implementation defines it to be the number formed by interpreting the byte sequence in memory as a big-endian binary number. If overflow occurs, the high bytes are lost, and a warning is issued. We don't want to process the NUL terminator handed back by cpp_interpret_string. */ result = 0; for (i = 0; i < str.len - 1; i++) { c = str.text[i] & mask; if (width < BITS_PER_CPPCHAR_T) result = (result << width) | c; else result = c; } if (type == CPP_UTF8CHAR) max_chars = 1; if (i > max_chars) { i = max_chars; cpp_error (pfile, type == CPP_UTF8CHAR ? CPP_DL_ERROR : CPP_DL_WARNING, "character constant too long for its type"); } else if (i > 1 && CPP_OPTION (pfile, warn_multichar)) cpp_warning (pfile, CPP_W_MULTICHAR, "multi-character character constant"); /* Multichar constants are of type int and therefore signed. */ if (i > 1) unsigned_p = 0; else if (type == CPP_UTF8CHAR && !CPP_OPTION (pfile, cplusplus)) unsigned_p = 1; else unsigned_p = CPP_OPTION (pfile, unsigned_char); /* Truncate the constant to its natural width, and simultaneously sign- or zero-extend to the full width of cppchar_t. For single-character constants, the value is WIDTH bits wide. For multi-character constants, the value is INT_PRECISION bits wide. */ if (i > 1) width = CPP_OPTION (pfile, int_precision); if (width < BITS_PER_CPPCHAR_T) { mask = ((cppchar_t) 1 << width) - 1; if (unsigned_p || !(result & (1 << (width - 1)))) result &= mask; else result |= ~mask; } *pchars_seen = i; *unsignedp = unsigned_p; return result; } /* Subroutine of cpp_interpret_charconst which performs the conversion to a number, for wide strings. STR is the string structure returned by cpp_interpret_string. PCHARS_SEEN and UNSIGNEDP are as for cpp_interpret_charconst. TYPE is the token type. */ static cppchar_t wide_str_to_charconst (cpp_reader *pfile, cpp_string str, unsigned int *pchars_seen, int *unsignedp, enum cpp_ttype type) { bool bigend = CPP_OPTION (pfile, bytes_big_endian); size_t width = converter_for_type (pfile, type).width; size_t cwidth = CPP_OPTION (pfile, char_precision); size_t mask = width_to_mask (width); size_t cmask = width_to_mask (cwidth); size_t nbwc = width / cwidth; size_t off, i; cppchar_t result = 0, c; if (str.len <= nbwc) { /* Error recovery, if no errors have been diagnosed previously, there should be at least two wide characters. Empty literals are diagnosed earlier and we can get just the zero terminator only if there were errors diagnosed during conversion. */ *pchars_seen = 0; *unsignedp = 0; return 0; } /* This is finicky because the string is in the target's byte order, which may not be our byte order. Only the last character, ignoring the NUL terminator, is relevant. */ off = str.len - (nbwc * 2); result = 0; for (i = 0; i < nbwc; i++) { c = bigend ? str.text[off + i] : str.text[off + nbwc - i - 1]; result = (result << cwidth) | (c & cmask); } /* Wide character constants have type wchar_t, and a single character exactly fills a wchar_t, so a multi-character wide character constant is guaranteed to overflow. */ if (str.len > nbwc * 2) cpp_error (pfile, (CPP_OPTION (pfile, cplusplus) && (type == CPP_CHAR16 || type == CPP_CHAR32)) ? CPP_DL_ERROR : CPP_DL_WARNING, "character constant too long for its type"); /* Truncate the constant to its natural width, and simultaneously sign- or zero-extend to the full width of cppchar_t. */ if (width < BITS_PER_CPPCHAR_T) { if (type == CPP_CHAR16 || type == CPP_CHAR32 || CPP_OPTION (pfile, unsigned_wchar) || !(result & (1 << (width - 1)))) result &= mask; else result |= ~mask; } if (type == CPP_CHAR16 || type == CPP_CHAR32 || CPP_OPTION (pfile, unsigned_wchar)) *unsignedp = 1; else *unsignedp = 0; *pchars_seen = 1; return result; } /* Interpret a (possibly wide) character constant in TOKEN. PCHARS_SEEN points to a variable that is filled in with the number of characters seen, and UNSIGNEDP to a variable that indicates whether the result has signed type. */ cppchar_t cpp_interpret_charconst (cpp_reader *pfile, const cpp_token *token, unsigned int *pchars_seen, int *unsignedp) { cpp_string str = { 0, 0 }; bool wide = (token->type != CPP_CHAR && token->type != CPP_UTF8CHAR); int u8 = 2 * int(token->type == CPP_UTF8CHAR); cppchar_t result; /* An empty constant will appear as L'', u'', U'', u8'', or '' */ if (token->val.str.len == (size_t) (2 + wide + u8)) { cpp_error (pfile, CPP_DL_ERROR, "empty character constant"); *pchars_seen = 0; *unsignedp = 0; return 0; } else if (!cpp_interpret_string (pfile, &token->val.str, 1, &str, token->type)) { *pchars_seen = 0; *unsignedp = 0; return 0; } if (wide) result = wide_str_to_charconst (pfile, str, pchars_seen, unsignedp, token->type); else result = narrow_str_to_charconst (pfile, str, pchars_seen, unsignedp, token->type); if (str.text != token->val.str.text) free ((void *)str.text); return result; } /* Convert an identifier denoted by ID and LEN, which might contain UCN escapes or UTF-8 multibyte chars, to the source character set, either UTF-8 or UTF-EBCDIC. Assumes that the identifier is actually a valid identifier. */ cpp_hashnode * _cpp_interpret_identifier (cpp_reader *pfile, const uchar *id, size_t len) { /* It turns out that a UCN escape always turns into fewer characters than the escape itself, so we can allocate a temporary in advance. */ uchar * buf = (uchar *) alloca (len + 1); uchar * bufp = buf; size_t idp; for (idp = 0; idp < len; idp++) if (id[idp] != '\\') *bufp++ = id[idp]; else { unsigned length = id[idp+1] == 'u' ? 4 : 8; cppchar_t value = 0; size_t bufleft = len - (bufp - buf); int rval; idp += 2; while (length && idp < len && ISXDIGIT (id[idp])) { value = (value << 4) + hex_value (id[idp]); idp++; length--; } idp--; /* Special case for EBCDIC: if the identifier contains a '$' specified using a UCN, translate it to EBCDIC. */ if (value == 0x24) { *bufp++ = '$'; continue; } rval = one_cppchar_to_utf8 (value, &bufp, &bufleft); if (rval) { errno = rval; cpp_errno (pfile, CPP_DL_ERROR, "converting UCN to source character set"); break; } } return CPP_HASHNODE (ht_lookup (pfile->hash_table, buf, bufp - buf, HT_ALLOC)); } /* Utility to strip a UTF-8 byte order marking from the beginning of a buffer. Returns the number of bytes to skip, which currently will be either 0 or 3. */ int cpp_check_utf8_bom (const char *data, size_t data_length) { #if HOST_CHARSET == HOST_CHARSET_ASCII const unsigned char *udata = (const unsigned char *) data; if (data_length >= 3 && udata[0] == 0xef && udata[1] == 0xbb && udata[2] == 0xbf) return 3; #endif return 0; } /* Convert an input buffer (containing the complete contents of one source file) from INPUT_CHARSET to the source character set. INPUT points to the input buffer, SIZE is its allocated size, and LEN is the length of the meaningful data within the buffer. The translated buffer is returned, *ST_SIZE is set to the length of the meaningful data within the translated buffer, and *BUFFER_START is set to the start of the returned buffer. *BUFFER_START may differ from the return value in the case of a BOM or other ignored marker information. INPUT is expected to have been allocated with xmalloc. This function will either set *BUFFER_START to INPUT, or free it and set *BUFFER_START to a pointer to another xmalloc-allocated block of memory. PFILE is only used to generate diagnostics; setting it to NULL suppresses diagnostics, and causes a return of NULL if there was any error instead. */ uchar * _cpp_convert_input (cpp_reader *pfile, const char *input_charset, uchar *input, size_t size, size_t len, const unsigned char **buffer_start, off_t *st_size) { struct cset_converter input_cset; struct _cpp_strbuf to; unsigned char *buffer; input_cset = init_iconv_desc (pfile, SOURCE_CHARSET, input_charset); if (input_cset.func == convert_no_conversion) { to.text = input; to.asize = size; to.len = len; } else { to.asize = MAX (65536, len); to.text = XNEWVEC (uchar, to.asize); to.len = 0; const bool ok = APPLY_CONVERSION (input_cset, input, len, &to); free (input); /* Clean up the mess. */ if (input_cset.func == convert_using_iconv) iconv_close (input_cset.cd); /* Handle conversion failure. */ if (!ok) { if (!pfile) { XDELETEVEC (to.text); *buffer_start = NULL; *st_size = 0; return NULL; } cpp_error (pfile, CPP_DL_ERROR, "failure to convert %s to %s", input_charset, SOURCE_CHARSET); } } /* Resize buffer if we allocated substantially too much, or if we haven't enough space for the \n-terminator or following 15 bytes of padding (used to quiet warnings from valgrind or Address Sanitizer, when the optimized lexer accesses aligned 16-byte memory chunks, including the bytes after the malloced, area, and stops lexing on '\n'). */ if (to.len + 4096 < to.asize || to.len + 16 > to.asize) to.text = XRESIZEVEC (uchar, to.text, to.len + 16); memset (to.text + to.len, '\0', 16); /* If the file is using old-school Mac line endings (\r only), terminate with another \r, not an \n, so that we do not mistake the \r\n sequence for a single DOS line ending and erroneously issue the "No newline at end of file" diagnostic. */ if (to.len && to.text[to.len - 1] == '\r') to.text[to.len] = '\r'; else to.text[to.len] = '\n'; buffer = to.text; *st_size = to.len; /* Ignore a UTF-8 BOM if we see one and the source charset is UTF-8. Note that glib'c UTF-8 iconv() provider (as of glibc 2.7) does not ignore a BOM -- however, even if it did, we would still need this code due to the 'convert_no_conversion' case. */ const int bom_len = cpp_check_utf8_bom ((const char *) to.text, to.len); *st_size -= bom_len; buffer += bom_len; *buffer_start = to.text; return buffer; } /* Decide on the default encoding to assume for input files. */ const char * _cpp_default_encoding (void) { const char *current_encoding = NULL; /* We disable this because the default codeset is 7-bit ASCII on most platforms, and this causes conversion failures on every file in GCC that happens to have one of the upper 128 characters in it -- most likely, as part of the name of a contributor. We should definitely recognize in-band markers of file encoding, like: - the appropriate Unicode byte-order mark (FE FF) to recognize UTF16 and UCS4 (in both big-endian and little-endian flavors) and UTF8 - a "#i", "#d", "/ *", "//", " #p" or "#p" (for #pragma) to distinguish ASCII and EBCDIC. - now we can parse something like "#pragma GCC encoding on the first line, or even Emacs/VIM's mode line tags (there's a problem here in that VIM uses the last line, and Emacs has its more elaborate "local variables" convention). - investigate whether Java has another common convention, which would be friendly to support. (Zack Weinberg and Paolo Bonzini, May 20th 2004) */ #if defined (HAVE_LOCALE_H) && defined (HAVE_LANGINFO_CODESET) && 0 setlocale (LC_CTYPE, ""); current_encoding = nl_langinfo (CODESET); #endif if (current_encoding == NULL || *current_encoding == '\0') current_encoding = SOURCE_CHARSET; return current_encoding; } /* Check if the configured input charset requires no conversion, other than possibly stripping a UTF-8 BOM. */ bool cpp_input_conversion_is_trivial (const char *input_charset) { return !strcasecmp (input_charset, SOURCE_CHARSET); } /* Implementation of class cpp_string_location_reader. */ /* Constructor for cpp_string_location_reader. */ cpp_string_location_reader:: cpp_string_location_reader (location_t src_loc, line_maps *line_table) { src_loc = get_range_from_loc (line_table, src_loc).m_start; /* SRC_LOC might be a macro location. It only makes sense to do column-by-column calculations on ordinary maps, so get the corresponding location in an ordinary map. */ m_loc = linemap_resolve_location (line_table, src_loc, LRK_SPELLING_LOCATION, NULL); const line_map_ordinary *map = linemap_check_ordinary (linemap_lookup (line_table, m_loc)); m_offset_per_column = (1 << map->m_range_bits); } /* Get the range of the next source byte. */ source_range cpp_string_location_reader::get_next () { source_range result; result.m_start = m_loc; result.m_finish = m_loc; if (m_loc <= LINE_MAP_MAX_LOCATION_WITH_COLS) m_loc += m_offset_per_column; return result; } cpp_display_width_computation:: cpp_display_width_computation (const char *data, int data_length, int tabstop) : m_begin (data), m_next (m_begin), m_bytes_left (data_length), m_tabstop (tabstop), m_display_cols (0) { gcc_assert (m_tabstop > 0); } /* The main implementation function for class cpp_display_width_computation. m_next points on entry to the start of the UTF-8 encoding of the next character, and is updated to point just after the last byte of the encoding. m_bytes_left contains on entry the remaining size of the buffer into which m_next points, and this is also updated accordingly. If m_next does not point to a valid UTF-8-encoded sequence, then it will be treated as a single byte with display width 1. m_cur_display_col is the current display column, relative to which tab stops should be expanded. Returns the display width of the codepoint just processed. */ int cpp_display_width_computation::process_next_codepoint () { cppchar_t c; int next_width; if (*m_next == '\t') { ++m_next; --m_bytes_left; next_width = m_tabstop - (m_display_cols % m_tabstop); } else if (one_utf8_to_cppchar ((const uchar **) &m_next, &m_bytes_left, &c) != 0) { /* Input is not convertible to UTF-8. This could be fine, e.g. in a string literal, so don't complain. Just treat it as if it has a width of one. */ ++m_next; --m_bytes_left; next_width = 1; } else { /* one_utf8_to_cppchar() has updated m_next and m_bytes_left for us. */ next_width = cpp_wcwidth (c); } m_display_cols += next_width; return next_width; } /* Utility to advance the byte stream by the minimum amount needed to consume N display columns. Returns the number of display columns that were actually skipped. This could be less than N, if there was not enough data, or more than N, if the last character to be skipped had a sufficiently large display width. */ int cpp_display_width_computation::advance_display_cols (int n) { const int start = m_display_cols; const int target = start + n; while (m_display_cols < target && !done ()) process_next_codepoint (); return m_display_cols - start; } /* For the string of length DATA_LENGTH bytes that begins at DATA, compute how many display columns are occupied by the first COLUMN bytes. COLUMN may exceed DATA_LENGTH, in which case the phantom bytes at the end are treated as if they have display width 1. Tabs are expanded to the next tab stop, relative to the start of DATA. */ int cpp_byte_column_to_display_column (const char *data, int data_length, int column, int tabstop) { const int offset = MAX (0, column - data_length); cpp_display_width_computation dw (data, column - offset, tabstop); while (!dw.done ()) dw.process_next_codepoint (); return dw.display_cols_processed () + offset; } /* For the string of length DATA_LENGTH bytes that begins at DATA, compute the least number of bytes that will result in at least DISPLAY_COL display columns. The return value may exceed DATA_LENGTH if the entire string does not occupy enough display columns. */ int cpp_display_column_to_byte_column (const char *data, int data_length, int display_col, int tabstop) { cpp_display_width_computation dw (data, data_length, tabstop); const int avail_display = dw.advance_display_cols (display_col); return dw.bytes_processed () + MAX (0, display_col - avail_display); } /* Our own version of wcwidth(). We don't use the actual wcwidth() in glibc, because that will inspect the user's locale, and in particular in an ASCII locale, it will not return anything useful for extended characters. But GCC in other respects (see e.g. _cpp_default_encoding()) behaves as if everything is UTF-8. We also make some tweaks that are useful for the way GCC needs to use this data, e.g. tabs and other control characters should be treated as having width 1. The lookup tables are generated from contrib/unicode/gen_wcwidth.py and were made by simply calling glibc wcwidth() on all codepoints, then applying the small tweaks. These tables are not highly optimized, but for the present purpose of outputting diagnostics, they are sufficient. */ #include "generated_cpp_wcwidth.h" int cpp_wcwidth (cppchar_t c) { if (__builtin_expect (c <= wcwidth_range_ends[0], true)) return wcwidth_widths[0]; /* Binary search the tables. */ int begin = 1; static const int end = sizeof wcwidth_range_ends / sizeof (*wcwidth_range_ends); int len = end - begin; do { int half = len/2; int middle = begin + half; if (c > wcwidth_range_ends[middle]) { begin = middle + 1; len -= half + 1; } else len = half; } while (len); if (__builtin_expect (begin != end, true)) return wcwidth_widths[begin]; return 1; }