1 /* CPP Library - charsets 2 Copyright (C) 1998-2018 Free Software Foundation, Inc. 3 4 Broken out of c-lex.c Apr 2003, adding valid C99 UCN ranges. 5 6 This program is free software; you can redistribute it and/or modify it 7 under the terms of the GNU General Public License as published by the 8 Free Software Foundation; either version 3, or (at your option) any 9 later version. 10 11 This program is distributed in the hope that it will be useful, 12 but WITHOUT ANY WARRANTY; without even the implied warranty of 13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 14 GNU General Public License for more details. 15 16 You should have received a copy of the GNU General Public License 17 along with this program; see the file COPYING3. If not see 18 <http://www.gnu.org/licenses/>. */ 19 20 #include "config.h" 21 #include "system.h" 22 #include "cpplib.h" 23 #include "internal.h" 24 25 /* Character set handling for C-family languages. 26 27 Terminological note: In what follows, "charset" or "character set" 28 will be taken to mean both an abstract set of characters and an 29 encoding for that set. 30 31 The C99 standard discusses two character sets: source and execution. 32 The source character set is used for internal processing in translation 33 phases 1 through 4; the execution character set is used thereafter. 34 Both are required by 5.2.1.2p1 to be multibyte encodings, not wide 35 character encodings (see 3.7.2, 3.7.3 for the standardese meanings 36 of these terms). Furthermore, the "basic character set" (listed in 37 5.2.1p3) is to be encoded in each with values one byte wide, and is 38 to appear in the initial shift state. 39 40 It is not explicitly mentioned, but there is also a "wide execution 41 character set" used to encode wide character constants and wide 42 string literals; this is supposed to be the result of applying the 43 standard library function mbstowcs() to an equivalent narrow string 44 (6.4.5p5). However, the behavior of hexadecimal and octal 45 \-escapes is at odds with this; they are supposed to be translated 46 directly to wchar_t values (6.4.4.4p5,6). 47 48 The source character set is not necessarily the character set used 49 to encode physical source files on disk; translation phase 1 converts 50 from whatever that encoding is to the source character set. 51 52 The presence of universal character names in C99 (6.4.3 et seq.) 53 forces the source character set to be isomorphic to ISO 10646, 54 that is, Unicode. There is no such constraint on the execution 55 character set; note also that the conversion from source to 56 execution character set does not occur for identifiers (5.1.1.2p1#5). 57 58 For convenience of implementation, the source character set's 59 encoding of the basic character set should be identical to the 60 execution character set OF THE HOST SYSTEM's encoding of the basic 61 character set, and it should not be a state-dependent encoding. 62 63 cpplib uses UTF-8 or UTF-EBCDIC for the source character set, 64 depending on whether the host is based on ASCII or EBCDIC (see 65 respectively Unicode section 2.3/ISO10646 Amendment 2, and Unicode 66 Technical Report #16). With limited exceptions, it relies on the 67 system library's iconv() primitive to do charset conversion 68 (specified in SUSv2). */ 69 70 #if !HAVE_ICONV 71 /* Make certain that the uses of iconv(), iconv_open(), iconv_close() 72 below, which are guarded only by if statements with compile-time 73 constant conditions, do not cause link errors. */ 74 #define iconv_open(x, y) (errno = EINVAL, (iconv_t)-1) 75 #define iconv(a,b,c,d,e) (errno = EINVAL, (size_t)-1) 76 #define iconv_close(x) (void)0 77 #define ICONV_CONST 78 #endif 79 80 #if HOST_CHARSET == HOST_CHARSET_ASCII 81 #define SOURCE_CHARSET "UTF-8" 82 #define LAST_POSSIBLY_BASIC_SOURCE_CHAR 0x7e 83 #elif HOST_CHARSET == HOST_CHARSET_EBCDIC 84 #define SOURCE_CHARSET "UTF-EBCDIC" 85 #define LAST_POSSIBLY_BASIC_SOURCE_CHAR 0xFF 86 #else 87 #error "Unrecognized basic host character set" 88 #endif 89 90 #ifndef EILSEQ 91 #define EILSEQ EINVAL 92 #endif 93 94 /* This structure is used for a resizable string buffer throughout. */ 95 /* Don't call it strbuf, as that conflicts with unistd.h on systems 96 such as DYNIX/ptx where unistd.h includes stropts.h. */ 97 struct _cpp_strbuf 98 { 99 uchar *text; 100 size_t asize; 101 size_t len; 102 }; 103 104 /* This is enough to hold any string that fits on a single 80-column 105 line, even if iconv quadruples its size (e.g. conversion from 106 ASCII to UTF-32) rounded up to a power of two. */ 107 #define OUTBUF_BLOCK_SIZE 256 108 109 /* Conversions between UTF-8 and UTF-16/32 are implemented by custom 110 logic. This is because a depressing number of systems lack iconv, 111 or have have iconv libraries that do not do these conversions, so 112 we need a fallback implementation for them. To ensure the fallback 113 doesn't break due to neglect, it is used on all systems. 114 115 UTF-32 encoding is nice and simple: a four-byte binary number, 116 constrained to the range 00000000-7FFFFFFF to avoid questions of 117 signedness. We do have to cope with big- and little-endian 118 variants. 119 120 UTF-16 encoding uses two-byte binary numbers, again in big- and 121 little-endian variants, for all values in the 00000000-0000FFFF 122 range. Values in the 00010000-0010FFFF range are encoded as pairs 123 of two-byte numbers, called "surrogate pairs": given a number S in 124 this range, it is mapped to a pair (H, L) as follows: 125 126 H = (S - 0x10000) / 0x400 + 0xD800 127 L = (S - 0x10000) % 0x400 + 0xDC00 128 129 Two-byte values in the D800...DFFF range are ill-formed except as a 130 component of a surrogate pair. Even if the encoding within a 131 two-byte value is little-endian, the H member of the surrogate pair 132 comes first. 133 134 There is no way to encode values in the 00110000-7FFFFFFF range, 135 which is not currently a problem as there are no assigned code 136 points in that range; however, the author expects that it will 137 eventually become necessary to abandon UTF-16 due to this 138 limitation. Note also that, because of these pairs, UTF-16 does 139 not meet the requirements of the C standard for a wide character 140 encoding (see 3.7.3 and 6.4.4.4p11). 141 142 UTF-8 encoding looks like this: 143 144 value range encoded as 145 00000000-0000007F 0xxxxxxx 146 00000080-000007FF 110xxxxx 10xxxxxx 147 00000800-0000FFFF 1110xxxx 10xxxxxx 10xxxxxx 148 00010000-001FFFFF 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx 149 00200000-03FFFFFF 111110xx 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx 150 04000000-7FFFFFFF 1111110x 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx 151 152 Values in the 0000D800 ... 0000DFFF range (surrogates) are invalid, 153 which means that three-byte sequences ED xx yy, with A0 <= xx <= BF, 154 never occur. Note also that any value that can be encoded by a 155 given row of the table can also be encoded by all successive rows, 156 but this is not done; only the shortest possible encoding for any 157 given value is valid. For instance, the character 07C0 could be 158 encoded as any of DF 80, E0 9F 80, F0 80 9F 80, F8 80 80 9F 80, or 159 FC 80 80 80 9F 80. Only the first is valid. 160 161 An implementation note: the transformation from UTF-16 to UTF-8, or 162 vice versa, is easiest done by using UTF-32 as an intermediary. */ 163 164 /* Internal primitives which go from an UTF-8 byte stream to native-endian 165 UTF-32 in a cppchar_t, or vice versa; this avoids an extra marshal/unmarshal 166 operation in several places below. */ 167 static inline int 168 one_utf8_to_cppchar (const uchar **inbufp, size_t *inbytesleftp, 169 cppchar_t *cp) 170 { 171 static const uchar masks[6] = { 0x7F, 0x1F, 0x0F, 0x07, 0x03, 0x01 }; 172 static const uchar patns[6] = { 0x00, 0xC0, 0xE0, 0xF0, 0xF8, 0xFC }; 173 174 cppchar_t c; 175 const uchar *inbuf = *inbufp; 176 size_t nbytes, i; 177 178 if (*inbytesleftp < 1) 179 return EINVAL; 180 181 c = *inbuf; 182 if (c < 0x80) 183 { 184 *cp = c; 185 *inbytesleftp -= 1; 186 *inbufp += 1; 187 return 0; 188 } 189 190 /* The number of leading 1-bits in the first byte indicates how many 191 bytes follow. */ 192 for (nbytes = 2; nbytes < 7; nbytes++) 193 if ((c & ~masks[nbytes-1]) == patns[nbytes-1]) 194 goto found; 195 return EILSEQ; 196 found: 197 198 if (*inbytesleftp < nbytes) 199 return EINVAL; 200 201 c = (c & masks[nbytes-1]); 202 inbuf++; 203 for (i = 1; i < nbytes; i++) 204 { 205 cppchar_t n = *inbuf++; 206 if ((n & 0xC0) != 0x80) 207 return EILSEQ; 208 c = ((c << 6) + (n & 0x3F)); 209 } 210 211 /* Make sure the shortest possible encoding was used. */ 212 if (c <= 0x7F && nbytes > 1) return EILSEQ; 213 if (c <= 0x7FF && nbytes > 2) return EILSEQ; 214 if (c <= 0xFFFF && nbytes > 3) return EILSEQ; 215 if (c <= 0x1FFFFF && nbytes > 4) return EILSEQ; 216 if (c <= 0x3FFFFFF && nbytes > 5) return EILSEQ; 217 218 /* Make sure the character is valid. */ 219 if (c > 0x7FFFFFFF || (c >= 0xD800 && c <= 0xDFFF)) return EILSEQ; 220 221 *cp = c; 222 *inbufp = inbuf; 223 *inbytesleftp -= nbytes; 224 return 0; 225 } 226 227 static inline int 228 one_cppchar_to_utf8 (cppchar_t c, uchar **outbufp, size_t *outbytesleftp) 229 { 230 static const uchar masks[6] = { 0x00, 0xC0, 0xE0, 0xF0, 0xF8, 0xFC }; 231 static const uchar limits[6] = { 0x80, 0xE0, 0xF0, 0xF8, 0xFC, 0xFE }; 232 size_t nbytes; 233 uchar buf[6], *p = &buf[6]; 234 uchar *outbuf = *outbufp; 235 236 nbytes = 1; 237 if (c < 0x80) 238 *--p = c; 239 else 240 { 241 do 242 { 243 *--p = ((c & 0x3F) | 0x80); 244 c >>= 6; 245 nbytes++; 246 } 247 while (c >= 0x3F || (c & limits[nbytes-1])); 248 *--p = (c | masks[nbytes-1]); 249 } 250 251 if (*outbytesleftp < nbytes) 252 return E2BIG; 253 254 while (p < &buf[6]) 255 *outbuf++ = *p++; 256 *outbytesleftp -= nbytes; 257 *outbufp = outbuf; 258 return 0; 259 } 260 261 /* The following four functions transform one character between the two 262 encodings named in the function name. All have the signature 263 int (*)(iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, 264 uchar **outbufp, size_t *outbytesleftp) 265 266 BIGEND must have the value 0 or 1, coerced to (iconv_t); it is 267 interpreted as a boolean indicating whether big-endian or 268 little-endian encoding is to be used for the member of the pair 269 that is not UTF-8. 270 271 INBUFP, INBYTESLEFTP, OUTBUFP, OUTBYTESLEFTP work exactly as they 272 do for iconv. 273 274 The return value is either 0 for success, or an errno value for 275 failure, which may be E2BIG (need more space), EILSEQ (ill-formed 276 input sequence), ir EINVAL (incomplete input sequence). */ 277 278 static inline int 279 one_utf8_to_utf32 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, 280 uchar **outbufp, size_t *outbytesleftp) 281 { 282 uchar *outbuf; 283 cppchar_t s = 0; 284 int rval; 285 286 /* Check for space first, since we know exactly how much we need. */ 287 if (*outbytesleftp < 4) 288 return E2BIG; 289 290 rval = one_utf8_to_cppchar (inbufp, inbytesleftp, &s); 291 if (rval) 292 return rval; 293 294 outbuf = *outbufp; 295 outbuf[bigend ? 3 : 0] = (s & 0x000000FF); 296 outbuf[bigend ? 2 : 1] = (s & 0x0000FF00) >> 8; 297 outbuf[bigend ? 1 : 2] = (s & 0x00FF0000) >> 16; 298 outbuf[bigend ? 0 : 3] = (s & 0xFF000000) >> 24; 299 300 *outbufp += 4; 301 *outbytesleftp -= 4; 302 return 0; 303 } 304 305 static inline int 306 one_utf32_to_utf8 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, 307 uchar **outbufp, size_t *outbytesleftp) 308 { 309 cppchar_t s; 310 int rval; 311 const uchar *inbuf; 312 313 if (*inbytesleftp < 4) 314 return EINVAL; 315 316 inbuf = *inbufp; 317 318 s = inbuf[bigend ? 0 : 3] << 24; 319 s += inbuf[bigend ? 1 : 2] << 16; 320 s += inbuf[bigend ? 2 : 1] << 8; 321 s += inbuf[bigend ? 3 : 0]; 322 323 if (s >= 0x7FFFFFFF || (s >= 0xD800 && s <= 0xDFFF)) 324 return EILSEQ; 325 326 rval = one_cppchar_to_utf8 (s, outbufp, outbytesleftp); 327 if (rval) 328 return rval; 329 330 *inbufp += 4; 331 *inbytesleftp -= 4; 332 return 0; 333 } 334 335 static inline int 336 one_utf8_to_utf16 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, 337 uchar **outbufp, size_t *outbytesleftp) 338 { 339 int rval; 340 cppchar_t s = 0; 341 const uchar *save_inbuf = *inbufp; 342 size_t save_inbytesleft = *inbytesleftp; 343 uchar *outbuf = *outbufp; 344 345 rval = one_utf8_to_cppchar (inbufp, inbytesleftp, &s); 346 if (rval) 347 return rval; 348 349 if (s > 0x0010FFFF) 350 { 351 *inbufp = save_inbuf; 352 *inbytesleftp = save_inbytesleft; 353 return EILSEQ; 354 } 355 356 if (s <= 0xFFFF) 357 { 358 if (*outbytesleftp < 2) 359 { 360 *inbufp = save_inbuf; 361 *inbytesleftp = save_inbytesleft; 362 return E2BIG; 363 } 364 outbuf[bigend ? 1 : 0] = (s & 0x00FF); 365 outbuf[bigend ? 0 : 1] = (s & 0xFF00) >> 8; 366 367 *outbufp += 2; 368 *outbytesleftp -= 2; 369 return 0; 370 } 371 else 372 { 373 cppchar_t hi, lo; 374 375 if (*outbytesleftp < 4) 376 { 377 *inbufp = save_inbuf; 378 *inbytesleftp = save_inbytesleft; 379 return E2BIG; 380 } 381 382 hi = (s - 0x10000) / 0x400 + 0xD800; 383 lo = (s - 0x10000) % 0x400 + 0xDC00; 384 385 /* Even if we are little-endian, put the high surrogate first. 386 ??? Matches practice? */ 387 outbuf[bigend ? 1 : 0] = (hi & 0x00FF); 388 outbuf[bigend ? 0 : 1] = (hi & 0xFF00) >> 8; 389 outbuf[bigend ? 3 : 2] = (lo & 0x00FF); 390 outbuf[bigend ? 2 : 3] = (lo & 0xFF00) >> 8; 391 392 *outbufp += 4; 393 *outbytesleftp -= 4; 394 return 0; 395 } 396 } 397 398 static inline int 399 one_utf16_to_utf8 (iconv_t bigend, const uchar **inbufp, size_t *inbytesleftp, 400 uchar **outbufp, size_t *outbytesleftp) 401 { 402 cppchar_t s; 403 const uchar *inbuf = *inbufp; 404 int rval; 405 406 if (*inbytesleftp < 2) 407 return EINVAL; 408 s = inbuf[bigend ? 0 : 1] << 8; 409 s += inbuf[bigend ? 1 : 0]; 410 411 /* Low surrogate without immediately preceding high surrogate is invalid. */ 412 if (s >= 0xDC00 && s <= 0xDFFF) 413 return EILSEQ; 414 /* High surrogate must have a following low surrogate. */ 415 else if (s >= 0xD800 && s <= 0xDBFF) 416 { 417 cppchar_t hi = s, lo; 418 if (*inbytesleftp < 4) 419 return EINVAL; 420 421 lo = inbuf[bigend ? 2 : 3] << 8; 422 lo += inbuf[bigend ? 3 : 2]; 423 424 if (lo < 0xDC00 || lo > 0xDFFF) 425 return EILSEQ; 426 427 s = (hi - 0xD800) * 0x400 + (lo - 0xDC00) + 0x10000; 428 } 429 430 rval = one_cppchar_to_utf8 (s, outbufp, outbytesleftp); 431 if (rval) 432 return rval; 433 434 /* Success - update the input pointers (one_cppchar_to_utf8 has done 435 the output pointers for us). */ 436 if (s <= 0xFFFF) 437 { 438 *inbufp += 2; 439 *inbytesleftp -= 2; 440 } 441 else 442 { 443 *inbufp += 4; 444 *inbytesleftp -= 4; 445 } 446 return 0; 447 } 448 449 /* Helper routine for the next few functions. The 'const' on 450 one_conversion means that we promise not to modify what function is 451 pointed to, which lets the inliner see through it. */ 452 453 static inline bool 454 conversion_loop (int (*const one_conversion)(iconv_t, const uchar **, size_t *, 455 uchar **, size_t *), 456 iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to) 457 { 458 const uchar *inbuf; 459 uchar *outbuf; 460 size_t inbytesleft, outbytesleft; 461 int rval; 462 463 inbuf = from; 464 inbytesleft = flen; 465 outbuf = to->text + to->len; 466 outbytesleft = to->asize - to->len; 467 468 for (;;) 469 { 470 do 471 rval = one_conversion (cd, &inbuf, &inbytesleft, 472 &outbuf, &outbytesleft); 473 while (inbytesleft && !rval); 474 475 if (__builtin_expect (inbytesleft == 0, 1)) 476 { 477 to->len = to->asize - outbytesleft; 478 return true; 479 } 480 if (rval != E2BIG) 481 { 482 errno = rval; 483 return false; 484 } 485 486 outbytesleft += OUTBUF_BLOCK_SIZE; 487 to->asize += OUTBUF_BLOCK_SIZE; 488 to->text = XRESIZEVEC (uchar, to->text, to->asize); 489 outbuf = to->text + to->asize - outbytesleft; 490 } 491 } 492 493 494 /* These functions convert entire strings between character sets. 495 They all have the signature 496 497 bool (*)(iconv_t cd, const uchar *from, size_t flen, struct _cpp_strbuf *to); 498 499 The input string FROM is converted as specified by the function 500 name plus the iconv descriptor CD (which may be fake), and the 501 result appended to TO. On any error, false is returned, otherwise true. */ 502 503 /* These four use the custom conversion code above. */ 504 static bool 505 convert_utf8_utf16 (iconv_t cd, const uchar *from, size_t flen, 506 struct _cpp_strbuf *to) 507 { 508 return conversion_loop (one_utf8_to_utf16, cd, from, flen, to); 509 } 510 511 static bool 512 convert_utf8_utf32 (iconv_t cd, const uchar *from, size_t flen, 513 struct _cpp_strbuf *to) 514 { 515 return conversion_loop (one_utf8_to_utf32, cd, from, flen, to); 516 } 517 518 static bool 519 convert_utf16_utf8 (iconv_t cd, const uchar *from, size_t flen, 520 struct _cpp_strbuf *to) 521 { 522 return conversion_loop (one_utf16_to_utf8, cd, from, flen, to); 523 } 524 525 static bool 526 convert_utf32_utf8 (iconv_t cd, const uchar *from, size_t flen, 527 struct _cpp_strbuf *to) 528 { 529 return conversion_loop (one_utf32_to_utf8, cd, from, flen, to); 530 } 531 532 /* Identity conversion, used when we have no alternative. */ 533 static bool 534 convert_no_conversion (iconv_t cd ATTRIBUTE_UNUSED, 535 const uchar *from, size_t flen, struct _cpp_strbuf *to) 536 { 537 if (to->len + flen > to->asize) 538 { 539 to->asize = to->len + flen; 540 to->asize += to->asize / 4; 541 to->text = XRESIZEVEC (uchar, to->text, to->asize); 542 } 543 memcpy (to->text + to->len, from, flen); 544 to->len += flen; 545 return true; 546 } 547 548 /* And this one uses the system iconv primitive. It's a little 549 different, since iconv's interface is a little different. */ 550 #if HAVE_ICONV 551 552 #define CONVERT_ICONV_GROW_BUFFER \ 553 do { \ 554 outbytesleft += OUTBUF_BLOCK_SIZE; \ 555 to->asize += OUTBUF_BLOCK_SIZE; \ 556 to->text = XRESIZEVEC (uchar, to->text, to->asize); \ 557 outbuf = (char *)to->text + to->asize - outbytesleft; \ 558 } while (0) 559 560 static bool 561 convert_using_iconv (iconv_t cd, const uchar *from, size_t flen, 562 struct _cpp_strbuf *to) 563 { 564 ICONV_CONST char *inbuf; 565 char *outbuf; 566 size_t inbytesleft, outbytesleft; 567 568 /* Reset conversion descriptor and check that it is valid. */ 569 if (iconv (cd, 0, 0, 0, 0) == (size_t)-1) 570 return false; 571 572 inbuf = (ICONV_CONST char *)from; 573 inbytesleft = flen; 574 outbuf = (char *)to->text + to->len; 575 outbytesleft = to->asize - to->len; 576 577 for (;;) 578 { 579 iconv (cd, &inbuf, &inbytesleft, &outbuf, &outbytesleft); 580 if (__builtin_expect (inbytesleft == 0, 1)) 581 { 582 /* Close out any shift states, returning to the initial state. */ 583 if (iconv (cd, 0, 0, &outbuf, &outbytesleft) == (size_t)-1) 584 { 585 if (errno != E2BIG) 586 return false; 587 588 CONVERT_ICONV_GROW_BUFFER; 589 if (iconv (cd, 0, 0, &outbuf, &outbytesleft) == (size_t)-1) 590 return false; 591 } 592 593 to->len = to->asize - outbytesleft; 594 return true; 595 } 596 if (errno != E2BIG) 597 return false; 598 599 CONVERT_ICONV_GROW_BUFFER; 600 } 601 } 602 #else 603 #define convert_using_iconv 0 /* prevent undefined symbol error below */ 604 #endif 605 606 /* Arrange for the above custom conversion logic to be used automatically 607 when conversion between a suitable pair of character sets is requested. */ 608 609 #define APPLY_CONVERSION(CONVERTER, FROM, FLEN, TO) \ 610 CONVERTER.func (CONVERTER.cd, FROM, FLEN, TO) 611 612 struct cpp_conversion 613 { 614 const char *pair; 615 convert_f func; 616 iconv_t fake_cd; 617 }; 618 static const struct cpp_conversion conversion_tab[] = { 619 { "UTF-8/UTF-32LE", convert_utf8_utf32, (iconv_t)0 }, 620 { "UTF-8/UTF-32BE", convert_utf8_utf32, (iconv_t)1 }, 621 { "UTF-8/UTF-16LE", convert_utf8_utf16, (iconv_t)0 }, 622 { "UTF-8/UTF-16BE", convert_utf8_utf16, (iconv_t)1 }, 623 { "UTF-32LE/UTF-8", convert_utf32_utf8, (iconv_t)0 }, 624 { "UTF-32BE/UTF-8", convert_utf32_utf8, (iconv_t)1 }, 625 { "UTF-16LE/UTF-8", convert_utf16_utf8, (iconv_t)0 }, 626 { "UTF-16BE/UTF-8", convert_utf16_utf8, (iconv_t)1 }, 627 }; 628 629 /* Subroutine of cpp_init_iconv: initialize and return a 630 cset_converter structure for conversion from FROM to TO. If 631 iconv_open() fails, issue an error and return an identity 632 converter. Silently return an identity converter if FROM and TO 633 are identical. */ 634 static struct cset_converter 635 init_iconv_desc (cpp_reader *pfile, const char *to, const char *from) 636 { 637 struct cset_converter ret; 638 char *pair; 639 size_t i; 640 641 if (!strcasecmp (to, from)) 642 { 643 ret.func = convert_no_conversion; 644 ret.cd = (iconv_t) -1; 645 ret.width = -1; 646 return ret; 647 } 648 649 pair = (char *) alloca(strlen(to) + strlen(from) + 2); 650 651 strcpy(pair, from); 652 strcat(pair, "/"); 653 strcat(pair, to); 654 for (i = 0; i < ARRAY_SIZE (conversion_tab); i++) 655 if (!strcasecmp (pair, conversion_tab[i].pair)) 656 { 657 ret.func = conversion_tab[i].func; 658 ret.cd = conversion_tab[i].fake_cd; 659 ret.width = -1; 660 return ret; 661 } 662 663 /* No custom converter - try iconv. */ 664 if (HAVE_ICONV) 665 { 666 ret.func = convert_using_iconv; 667 ret.cd = iconv_open (to, from); 668 ret.width = -1; 669 670 if (ret.cd == (iconv_t) -1) 671 { 672 if (errno == EINVAL) 673 cpp_error (pfile, CPP_DL_ERROR, /* FIXME should be DL_SORRY */ 674 "conversion from %s to %s not supported by iconv", 675 from, to); 676 else 677 cpp_errno (pfile, CPP_DL_ERROR, "iconv_open"); 678 679 ret.func = convert_no_conversion; 680 } 681 } 682 else 683 { 684 cpp_error (pfile, CPP_DL_ERROR, /* FIXME: should be DL_SORRY */ 685 "no iconv implementation, cannot convert from %s to %s", 686 from, to); 687 ret.func = convert_no_conversion; 688 ret.cd = (iconv_t) -1; 689 ret.width = -1; 690 } 691 return ret; 692 } 693 694 /* If charset conversion is requested, initialize iconv(3) descriptors 695 for conversion from the source character set to the execution 696 character sets. If iconv is not present in the C library, and 697 conversion is requested, issue an error. */ 698 699 void 700 cpp_init_iconv (cpp_reader *pfile) 701 { 702 const char *ncset = CPP_OPTION (pfile, narrow_charset); 703 const char *wcset = CPP_OPTION (pfile, wide_charset); 704 const char *default_wcset; 705 706 bool be = CPP_OPTION (pfile, bytes_big_endian); 707 708 if (CPP_OPTION (pfile, wchar_precision) >= 32) 709 default_wcset = be ? "UTF-32BE" : "UTF-32LE"; 710 else if (CPP_OPTION (pfile, wchar_precision) >= 16) 711 default_wcset = be ? "UTF-16BE" : "UTF-16LE"; 712 else 713 /* This effectively means that wide strings are not supported, 714 so don't do any conversion at all. */ 715 default_wcset = SOURCE_CHARSET; 716 717 if (!ncset) 718 ncset = SOURCE_CHARSET; 719 if (!wcset) 720 wcset = default_wcset; 721 722 pfile->narrow_cset_desc = init_iconv_desc (pfile, ncset, SOURCE_CHARSET); 723 pfile->narrow_cset_desc.width = CPP_OPTION (pfile, char_precision); 724 pfile->utf8_cset_desc = init_iconv_desc (pfile, "UTF-8", SOURCE_CHARSET); 725 pfile->utf8_cset_desc.width = CPP_OPTION (pfile, char_precision); 726 pfile->char16_cset_desc = init_iconv_desc (pfile, 727 be ? "UTF-16BE" : "UTF-16LE", 728 SOURCE_CHARSET); 729 pfile->char16_cset_desc.width = 16; 730 pfile->char32_cset_desc = init_iconv_desc (pfile, 731 be ? "UTF-32BE" : "UTF-32LE", 732 SOURCE_CHARSET); 733 pfile->char32_cset_desc.width = 32; 734 pfile->wide_cset_desc = init_iconv_desc (pfile, wcset, SOURCE_CHARSET); 735 pfile->wide_cset_desc.width = CPP_OPTION (pfile, wchar_precision); 736 } 737 738 /* Destroy iconv(3) descriptors set up by cpp_init_iconv, if necessary. */ 739 void 740 _cpp_destroy_iconv (cpp_reader *pfile) 741 { 742 if (HAVE_ICONV) 743 { 744 if (pfile->narrow_cset_desc.func == convert_using_iconv) 745 iconv_close (pfile->narrow_cset_desc.cd); 746 if (pfile->utf8_cset_desc.func == convert_using_iconv) 747 iconv_close (pfile->utf8_cset_desc.cd); 748 if (pfile->char16_cset_desc.func == convert_using_iconv) 749 iconv_close (pfile->char16_cset_desc.cd); 750 if (pfile->char32_cset_desc.func == convert_using_iconv) 751 iconv_close (pfile->char32_cset_desc.cd); 752 if (pfile->wide_cset_desc.func == convert_using_iconv) 753 iconv_close (pfile->wide_cset_desc.cd); 754 } 755 } 756 757 /* Utility routine for use by a full compiler. C is a character taken 758 from the *basic* source character set, encoded in the host's 759 execution encoding. Convert it to (the target's) execution 760 encoding, and return that value. 761 762 Issues an internal error if C's representation in the narrow 763 execution character set fails to be a single-byte value (C99 764 5.2.1p3: "The representation of each member of the source and 765 execution character sets shall fit in a byte.") May also issue an 766 internal error if C fails to be a member of the basic source 767 character set (testing this exactly is too hard, especially when 768 the host character set is EBCDIC). */ 769 cppchar_t 770 cpp_host_to_exec_charset (cpp_reader *pfile, cppchar_t c) 771 { 772 uchar sbuf[1]; 773 struct _cpp_strbuf tbuf; 774 775 /* This test is merely an approximation, but it suffices to catch 776 the most important thing, which is that we don't get handed a 777 character outside the unibyte range of the host character set. */ 778 if (c > LAST_POSSIBLY_BASIC_SOURCE_CHAR) 779 { 780 cpp_error (pfile, CPP_DL_ICE, 781 "character 0x%lx is not in the basic source character set\n", 782 (unsigned long)c); 783 return 0; 784 } 785 786 /* Being a character in the unibyte range of the host character set, 787 we can safely splat it into a one-byte buffer and trust that that 788 is a well-formed string. */ 789 sbuf[0] = c; 790 791 /* This should never need to reallocate, but just in case... */ 792 tbuf.asize = 1; 793 tbuf.text = XNEWVEC (uchar, tbuf.asize); 794 tbuf.len = 0; 795 796 if (!APPLY_CONVERSION (pfile->narrow_cset_desc, sbuf, 1, &tbuf)) 797 { 798 cpp_errno (pfile, CPP_DL_ICE, "converting to execution character set"); 799 return 0; 800 } 801 if (tbuf.len != 1) 802 { 803 cpp_error (pfile, CPP_DL_ICE, 804 "character 0x%lx is not unibyte in execution character set", 805 (unsigned long)c); 806 return 0; 807 } 808 c = tbuf.text[0]; 809 free(tbuf.text); 810 return c; 811 } 812 813 814 815 /* cpp_substring_ranges's constructor. */ 816 817 cpp_substring_ranges::cpp_substring_ranges () : 818 m_ranges (NULL), 819 m_num_ranges (0), 820 m_alloc_ranges (8) 821 { 822 m_ranges = XNEWVEC (source_range, m_alloc_ranges); 823 } 824 825 /* cpp_substring_ranges's destructor. */ 826 827 cpp_substring_ranges::~cpp_substring_ranges () 828 { 829 free (m_ranges); 830 } 831 832 /* Add RANGE to the vector of source_range information. */ 833 834 void 835 cpp_substring_ranges::add_range (source_range range) 836 { 837 if (m_num_ranges >= m_alloc_ranges) 838 { 839 m_alloc_ranges *= 2; 840 m_ranges 841 = (source_range *)xrealloc (m_ranges, 842 sizeof (source_range) * m_alloc_ranges); 843 } 844 m_ranges[m_num_ranges++] = range; 845 } 846 847 /* Read NUM ranges from LOC_READER, adding them to the vector of source_range 848 information. */ 849 850 void 851 cpp_substring_ranges::add_n_ranges (int num, 852 cpp_string_location_reader &loc_reader) 853 { 854 for (int i = 0; i < num; i++) 855 add_range (loc_reader.get_next ()); 856 } 857 858 859 860 /* Utility routine that computes a mask of the form 0000...111... with 861 WIDTH 1-bits. */ 862 static inline size_t 863 width_to_mask (size_t width) 864 { 865 width = MIN (width, BITS_PER_CPPCHAR_T); 866 if (width >= CHAR_BIT * sizeof (size_t)) 867 return ~(size_t) 0; 868 else 869 return ((size_t) 1 << width) - 1; 870 } 871 872 /* A large table of unicode character information. */ 873 enum { 874 /* Valid in a C99 identifier? */ 875 C99 = 1, 876 /* Valid in a C99 identifier, but not as the first character? */ 877 N99 = 2, 878 /* Valid in a C++ identifier? */ 879 CXX = 4, 880 /* Valid in a C11/C++11 identifier? */ 881 C11 = 8, 882 /* Valid in a C11/C++11 identifier, but not as the first character? */ 883 N11 = 16, 884 /* NFC representation is not valid in an identifier? */ 885 CID = 32, 886 /* Might be valid NFC form? */ 887 NFC = 64, 888 /* Might be valid NFKC form? */ 889 NKC = 128, 890 /* Certain preceding characters might make it not valid NFC/NKFC form? */ 891 CTX = 256 892 }; 893 894 struct ucnrange { 895 /* Bitmap of flags above. */ 896 unsigned short flags; 897 /* Combining class of the character. */ 898 unsigned char combine; 899 /* Last character in the range described by this entry. */ 900 unsigned int end; 901 }; 902 #include "ucnid.h" 903 904 /* Returns 1 if C is valid in an identifier, 2 if C is valid except at 905 the start of an identifier, and 0 if C is not valid in an 906 identifier. We assume C has already gone through the checks of 907 _cpp_valid_ucn. Also update NST for C if returning nonzero. The 908 algorithm is a simple binary search on the table defined in 909 ucnid.h. */ 910 911 static int 912 ucn_valid_in_identifier (cpp_reader *pfile, cppchar_t c, 913 struct normalize_state *nst) 914 { 915 int mn, mx, md; 916 unsigned short valid_flags, invalid_start_flags; 917 918 if (c > 0x10FFFF) 919 return 0; 920 921 mn = 0; 922 mx = ARRAY_SIZE (ucnranges) - 1; 923 while (mx != mn) 924 { 925 md = (mn + mx) / 2; 926 if (c <= ucnranges[md].end) 927 mx = md; 928 else 929 mn = md + 1; 930 } 931 932 /* When -pedantic, we require the character to have been listed by 933 the standard for the current language. Otherwise, we accept the 934 union of the acceptable sets for all supported language versions. */ 935 valid_flags = C99 | CXX | C11; 936 if (CPP_PEDANTIC (pfile)) 937 { 938 if (CPP_OPTION (pfile, c11_identifiers)) 939 valid_flags = C11; 940 else if (CPP_OPTION (pfile, c99)) 941 valid_flags = C99; 942 else if (CPP_OPTION (pfile, cplusplus)) 943 valid_flags = CXX; 944 } 945 if (! (ucnranges[mn].flags & valid_flags)) 946 return 0; 947 if (CPP_OPTION (pfile, c11_identifiers)) 948 invalid_start_flags = N11; 949 else if (CPP_OPTION (pfile, c99)) 950 invalid_start_flags = N99; 951 else 952 invalid_start_flags = 0; 953 954 /* Update NST. */ 955 if (ucnranges[mn].combine != 0 && ucnranges[mn].combine < nst->prev_class) 956 nst->level = normalized_none; 957 else if (ucnranges[mn].flags & CTX) 958 { 959 bool safe; 960 cppchar_t p = nst->previous; 961 962 /* For Hangul, characters in the range AC00-D7A3 are NFC/NFKC, 963 and are combined algorithmically from a sequence of the form 964 1100-1112 1161-1175 11A8-11C2 965 (if the third is not present, it is treated as 11A7, which is not 966 really a valid character). 967 Unfortunately, C99 allows (only) the NFC form, but C++ allows 968 only the combining characters. */ 969 if (c >= 0x1161 && c <= 0x1175) 970 safe = p < 0x1100 || p > 0x1112; 971 else if (c >= 0x11A8 && c <= 0x11C2) 972 safe = (p < 0xAC00 || p > 0xD7A3 || (p - 0xAC00) % 28 != 0); 973 else 974 safe = check_nfc (pfile, c, p); 975 if (!safe) 976 { 977 if ((c >= 0x1161 && c <= 0x1175) || (c >= 0x11A8 && c <= 0x11C2)) 978 nst->level = MAX (nst->level, normalized_identifier_C); 979 else 980 nst->level = normalized_none; 981 } 982 } 983 else if (ucnranges[mn].flags & NKC) 984 ; 985 else if (ucnranges[mn].flags & NFC) 986 nst->level = MAX (nst->level, normalized_C); 987 else if (ucnranges[mn].flags & CID) 988 nst->level = MAX (nst->level, normalized_identifier_C); 989 else 990 nst->level = normalized_none; 991 if (ucnranges[mn].combine == 0) 992 nst->previous = c; 993 nst->prev_class = ucnranges[mn].combine; 994 995 /* In C99, UCN digits may not begin identifiers. In C11 and C++11, 996 UCN combining characters may not begin identifiers. */ 997 if (ucnranges[mn].flags & invalid_start_flags) 998 return 2; 999 1000 return 1; 1001 } 1002 1003 /* [lex.charset]: The character designated by the universal character 1004 name \UNNNNNNNN is that character whose character short name in 1005 ISO/IEC 10646 is NNNNNNNN; the character designated by the 1006 universal character name \uNNNN is that character whose character 1007 short name in ISO/IEC 10646 is 0000NNNN. If the hexadecimal value 1008 for a universal character name corresponds to a surrogate code point 1009 (in the range 0xD800-0xDFFF, inclusive), the program is ill-formed. 1010 Additionally, if the hexadecimal value for a universal-character-name 1011 outside a character or string literal corresponds to a control character 1012 (in either of the ranges 0x00-0x1F or 0x7F-0x9F, both inclusive) or to a 1013 character in the basic source character set, the program is ill-formed. 1014 1015 C99 6.4.3: A universal character name shall not specify a character 1016 whose short identifier is less than 00A0 other than 0024 ($), 0040 (@), 1017 or 0060 (`), nor one in the range D800 through DFFF inclusive. 1018 1019 *PSTR must be preceded by "\u" or "\U"; it is assumed that the 1020 buffer end is delimited by a non-hex digit. Returns false if the 1021 UCN has not been consumed, true otherwise. 1022 1023 The value of the UCN, whether valid or invalid, is returned in *CP. 1024 Diagnostics are emitted for invalid values. PSTR is updated to point 1025 one beyond the UCN, or to the syntactically invalid character. 1026 1027 IDENTIFIER_POS is 0 when not in an identifier, 1 for the start of 1028 an identifier, or 2 otherwise. 1029 1030 If LOC_READER is non-NULL, then position information is 1031 read from *LOC_READER and CHAR_RANGE->m_finish is updated accordingly. */ 1032 1033 bool 1034 _cpp_valid_ucn (cpp_reader *pfile, const uchar **pstr, 1035 const uchar *limit, int identifier_pos, 1036 struct normalize_state *nst, cppchar_t *cp, 1037 source_range *char_range, 1038 cpp_string_location_reader *loc_reader) 1039 { 1040 cppchar_t result, c; 1041 unsigned int length; 1042 const uchar *str = *pstr; 1043 const uchar *base = str - 2; 1044 1045 if (!CPP_OPTION (pfile, cplusplus) && !CPP_OPTION (pfile, c99)) 1046 cpp_error (pfile, CPP_DL_WARNING, 1047 "universal character names are only valid in C++ and C99"); 1048 else if (CPP_OPTION (pfile, cpp_warn_c90_c99_compat) > 0 1049 && !CPP_OPTION (pfile, cplusplus)) 1050 cpp_error (pfile, CPP_DL_WARNING, 1051 "C99's universal character names are incompatible with C90"); 1052 else if (CPP_WTRADITIONAL (pfile) && identifier_pos == 0) 1053 cpp_warning (pfile, CPP_W_TRADITIONAL, 1054 "the meaning of '\\%c' is different in traditional C", 1055 (int) str[-1]); 1056 1057 if (str[-1] == 'u') 1058 length = 4; 1059 else if (str[-1] == 'U') 1060 length = 8; 1061 else 1062 { 1063 cpp_error (pfile, CPP_DL_ICE, "In _cpp_valid_ucn but not a UCN"); 1064 length = 4; 1065 } 1066 1067 result = 0; 1068 do 1069 { 1070 c = *str; 1071 if (!ISXDIGIT (c)) 1072 break; 1073 str++; 1074 if (loc_reader) 1075 { 1076 gcc_assert (char_range); 1077 char_range->m_finish = loc_reader->get_next ().m_finish; 1078 } 1079 result = (result << 4) + hex_value (c); 1080 } 1081 while (--length && str < limit); 1082 1083 /* Partial UCNs are not valid in strings, but decompose into 1084 multiple tokens in identifiers, so we can't give a helpful 1085 error message in that case. */ 1086 if (length && identifier_pos) 1087 { 1088 *cp = 0; 1089 return false; 1090 } 1091 1092 *pstr = str; 1093 if (length) 1094 { 1095 cpp_error (pfile, CPP_DL_ERROR, 1096 "incomplete universal character name %.*s", 1097 (int) (str - base), base); 1098 result = 1; 1099 } 1100 /* The C99 standard permits $, @ and ` to be specified as UCNs. We use 1101 hex escapes so that this also works with EBCDIC hosts. 1102 C++0x permits everything below 0xa0 within literals; 1103 ucn_valid_in_identifier will complain about identifiers. */ 1104 else if ((result < 0xa0 1105 && !CPP_OPTION (pfile, cplusplus) 1106 && (result != 0x24 && result != 0x40 && result != 0x60)) 1107 || (result & 0x80000000) 1108 || (result >= 0xD800 && result <= 0xDFFF)) 1109 { 1110 cpp_error (pfile, CPP_DL_ERROR, 1111 "%.*s is not a valid universal character", 1112 (int) (str - base), base); 1113 result = 1; 1114 } 1115 else if (identifier_pos && result == 0x24 1116 && CPP_OPTION (pfile, dollars_in_ident)) 1117 { 1118 if (CPP_OPTION (pfile, warn_dollars) && !pfile->state.skipping) 1119 { 1120 CPP_OPTION (pfile, warn_dollars) = 0; 1121 cpp_error (pfile, CPP_DL_PEDWARN, "'$' in identifier or number"); 1122 } 1123 NORMALIZE_STATE_UPDATE_IDNUM (nst, result); 1124 } 1125 else if (identifier_pos) 1126 { 1127 int validity = ucn_valid_in_identifier (pfile, result, nst); 1128 1129 if (validity == 0) 1130 cpp_error (pfile, CPP_DL_ERROR, 1131 "universal character %.*s is not valid in an identifier", 1132 (int) (str - base), base); 1133 else if (validity == 2 && identifier_pos == 1) 1134 cpp_error (pfile, CPP_DL_ERROR, 1135 "universal character %.*s is not valid at the start of an identifier", 1136 (int) (str - base), base); 1137 } 1138 1139 *cp = result; 1140 return true; 1141 } 1142 1143 /* Convert an UCN, pointed to by FROM, to UTF-8 encoding, then translate 1144 it to the execution character set and write the result into TBUF, 1145 if TBUF is non-NULL. 1146 An advanced pointer is returned. Issues all relevant diagnostics. 1147 If LOC_READER is non-NULL, then RANGES must be non-NULL and CHAR_RANGE 1148 contains the location of the character so far: location information 1149 is read from *LOC_READER, and *RANGES is updated accordingly. */ 1150 static const uchar * 1151 convert_ucn (cpp_reader *pfile, const uchar *from, const uchar *limit, 1152 struct _cpp_strbuf *tbuf, struct cset_converter cvt, 1153 source_range char_range, 1154 cpp_string_location_reader *loc_reader, 1155 cpp_substring_ranges *ranges) 1156 { 1157 cppchar_t ucn; 1158 uchar buf[6]; 1159 uchar *bufp = buf; 1160 size_t bytesleft = 6; 1161 int rval; 1162 struct normalize_state nst = INITIAL_NORMALIZE_STATE; 1163 1164 /* loc_reader and ranges must either be both NULL, or both be non-NULL. */ 1165 gcc_assert ((loc_reader != NULL) == (ranges != NULL)); 1166 1167 from++; /* Skip u/U. */ 1168 1169 if (loc_reader) 1170 /* The u/U is part of the spelling of this character. */ 1171 char_range.m_finish = loc_reader->get_next ().m_finish; 1172 1173 _cpp_valid_ucn (pfile, &from, limit, 0, &nst, 1174 &ucn, &char_range, loc_reader); 1175 1176 rval = one_cppchar_to_utf8 (ucn, &bufp, &bytesleft); 1177 if (rval) 1178 { 1179 errno = rval; 1180 cpp_errno (pfile, CPP_DL_ERROR, 1181 "converting UCN to source character set"); 1182 } 1183 else 1184 { 1185 if (tbuf) 1186 if (!APPLY_CONVERSION (cvt, buf, 6 - bytesleft, tbuf)) 1187 cpp_errno (pfile, CPP_DL_ERROR, 1188 "converting UCN to execution character set"); 1189 1190 if (loc_reader) 1191 { 1192 int num_encoded_bytes = 6 - bytesleft; 1193 for (int i = 0; i < num_encoded_bytes; i++) 1194 ranges->add_range (char_range); 1195 } 1196 } 1197 1198 return from; 1199 } 1200 1201 /* Subroutine of convert_hex and convert_oct. N is the representation 1202 in the execution character set of a numeric escape; write it into the 1203 string buffer TBUF and update the end-of-string pointer therein. WIDE 1204 is true if it's a wide string that's being assembled in TBUF. This 1205 function issues no diagnostics and never fails. */ 1206 static void 1207 emit_numeric_escape (cpp_reader *pfile, cppchar_t n, 1208 struct _cpp_strbuf *tbuf, struct cset_converter cvt) 1209 { 1210 size_t width = cvt.width; 1211 1212 if (width != CPP_OPTION (pfile, char_precision)) 1213 { 1214 /* We have to render this into the target byte order, which may not 1215 be our byte order. */ 1216 bool bigend = CPP_OPTION (pfile, bytes_big_endian); 1217 size_t cwidth = CPP_OPTION (pfile, char_precision); 1218 size_t cmask = width_to_mask (cwidth); 1219 size_t nbwc = width / cwidth; 1220 size_t i; 1221 size_t off = tbuf->len; 1222 cppchar_t c; 1223 1224 if (tbuf->len + nbwc > tbuf->asize) 1225 { 1226 tbuf->asize += OUTBUF_BLOCK_SIZE; 1227 tbuf->text = XRESIZEVEC (uchar, tbuf->text, tbuf->asize); 1228 } 1229 1230 for (i = 0; i < nbwc; i++) 1231 { 1232 c = n & cmask; 1233 n >>= cwidth; 1234 tbuf->text[off + (bigend ? nbwc - i - 1 : i)] = c; 1235 } 1236 tbuf->len += nbwc; 1237 } 1238 else 1239 { 1240 /* Note: this code does not handle the case where the target 1241 and host have a different number of bits in a byte. */ 1242 if (tbuf->len + 1 > tbuf->asize) 1243 { 1244 tbuf->asize += OUTBUF_BLOCK_SIZE; 1245 tbuf->text = XRESIZEVEC (uchar, tbuf->text, tbuf->asize); 1246 } 1247 tbuf->text[tbuf->len++] = n; 1248 } 1249 } 1250 1251 /* Convert a hexadecimal escape, pointed to by FROM, to the execution 1252 character set and write it into the string buffer TBUF (if non-NULL). 1253 Returns an advanced pointer, and issues diagnostics as necessary. 1254 No character set translation occurs; this routine always produces the 1255 execution-set character with numeric value equal to the given hex 1256 number. You can, e.g. generate surrogate pairs this way. 1257 If LOC_READER is non-NULL, then RANGES must be non-NULL and CHAR_RANGE 1258 contains the location of the character so far: location information 1259 is read from *LOC_READER, and *RANGES is updated accordingly. */ 1260 static const uchar * 1261 convert_hex (cpp_reader *pfile, const uchar *from, const uchar *limit, 1262 struct _cpp_strbuf *tbuf, struct cset_converter cvt, 1263 source_range char_range, 1264 cpp_string_location_reader *loc_reader, 1265 cpp_substring_ranges *ranges) 1266 { 1267 cppchar_t c, n = 0, overflow = 0; 1268 int digits_found = 0; 1269 size_t width = cvt.width; 1270 size_t mask = width_to_mask (width); 1271 1272 /* loc_reader and ranges must either be both NULL, or both be non-NULL. */ 1273 gcc_assert ((loc_reader != NULL) == (ranges != NULL)); 1274 1275 if (CPP_WTRADITIONAL (pfile)) 1276 cpp_warning (pfile, CPP_W_TRADITIONAL, 1277 "the meaning of '\\x' is different in traditional C"); 1278 1279 /* Skip 'x'. */ 1280 from++; 1281 1282 /* The 'x' is part of the spelling of this character. */ 1283 if (loc_reader) 1284 char_range.m_finish = loc_reader->get_next ().m_finish; 1285 1286 while (from < limit) 1287 { 1288 c = *from; 1289 if (! hex_p (c)) 1290 break; 1291 from++; 1292 if (loc_reader) 1293 char_range.m_finish = loc_reader->get_next ().m_finish; 1294 overflow |= n ^ (n << 4 >> 4); 1295 n = (n << 4) + hex_value (c); 1296 digits_found = 1; 1297 } 1298 1299 if (!digits_found) 1300 { 1301 cpp_error (pfile, CPP_DL_ERROR, 1302 "\\x used with no following hex digits"); 1303 return from; 1304 } 1305 1306 if (overflow | (n != (n & mask))) 1307 { 1308 cpp_error (pfile, CPP_DL_PEDWARN, 1309 "hex escape sequence out of range"); 1310 n &= mask; 1311 } 1312 1313 if (tbuf) 1314 emit_numeric_escape (pfile, n, tbuf, cvt); 1315 if (ranges) 1316 ranges->add_range (char_range); 1317 1318 return from; 1319 } 1320 1321 /* Convert an octal escape, pointed to by FROM, to the execution 1322 character set and write it into the string buffer TBUF. Returns an 1323 advanced pointer, and issues diagnostics as necessary. 1324 No character set translation occurs; this routine always produces the 1325 execution-set character with numeric value equal to the given octal 1326 number. 1327 If LOC_READER is non-NULL, then RANGES must be non-NULL and CHAR_RANGE 1328 contains the location of the character so far: location information 1329 is read from *LOC_READER, and *RANGES is updated accordingly. */ 1330 static const uchar * 1331 convert_oct (cpp_reader *pfile, const uchar *from, const uchar *limit, 1332 struct _cpp_strbuf *tbuf, struct cset_converter cvt, 1333 source_range char_range, 1334 cpp_string_location_reader *loc_reader, 1335 cpp_substring_ranges *ranges) 1336 { 1337 size_t count = 0; 1338 cppchar_t c, n = 0; 1339 size_t width = cvt.width; 1340 size_t mask = width_to_mask (width); 1341 bool overflow = false; 1342 1343 /* loc_reader and ranges must either be both NULL, or both be non-NULL. */ 1344 gcc_assert ((loc_reader != NULL) == (ranges != NULL)); 1345 1346 while (from < limit && count++ < 3) 1347 { 1348 c = *from; 1349 if (c < '0' || c > '7') 1350 break; 1351 from++; 1352 if (loc_reader) 1353 char_range.m_finish = loc_reader->get_next ().m_finish; 1354 overflow |= n ^ (n << 3 >> 3); 1355 n = (n << 3) + c - '0'; 1356 } 1357 1358 if (n != (n & mask)) 1359 { 1360 cpp_error (pfile, CPP_DL_PEDWARN, 1361 "octal escape sequence out of range"); 1362 n &= mask; 1363 } 1364 1365 if (tbuf) 1366 emit_numeric_escape (pfile, n, tbuf, cvt); 1367 if (ranges) 1368 ranges->add_range (char_range); 1369 1370 return from; 1371 } 1372 1373 /* Convert an escape sequence (pointed to by FROM) to its value on 1374 the target, and to the execution character set. Do not scan past 1375 LIMIT. Write the converted value into TBUF, if TBUF is non-NULL. 1376 Returns an advanced pointer. Handles all relevant diagnostics. 1377 If LOC_READER is non-NULL, then RANGES must be non-NULL: location 1378 information is read from *LOC_READER, and *RANGES is updated 1379 accordingly. */ 1380 static const uchar * 1381 convert_escape (cpp_reader *pfile, const uchar *from, const uchar *limit, 1382 struct _cpp_strbuf *tbuf, struct cset_converter cvt, 1383 cpp_string_location_reader *loc_reader, 1384 cpp_substring_ranges *ranges) 1385 { 1386 /* Values of \a \b \e \f \n \r \t \v respectively. */ 1387 #if HOST_CHARSET == HOST_CHARSET_ASCII 1388 static const uchar charconsts[] = { 7, 8, 27, 12, 10, 13, 9, 11 }; 1389 #elif HOST_CHARSET == HOST_CHARSET_EBCDIC 1390 static const uchar charconsts[] = { 47, 22, 39, 12, 21, 13, 5, 11 }; 1391 #else 1392 #error "unknown host character set" 1393 #endif 1394 1395 uchar c; 1396 1397 /* Record the location of the backslash. */ 1398 source_range char_range; 1399 if (loc_reader) 1400 char_range = loc_reader->get_next (); 1401 1402 c = *from; 1403 switch (c) 1404 { 1405 /* UCNs, hex escapes, and octal escapes are processed separately. */ 1406 case 'u': case 'U': 1407 return convert_ucn (pfile, from, limit, tbuf, cvt, 1408 char_range, loc_reader, ranges); 1409 1410 case 'x': 1411 return convert_hex (pfile, from, limit, tbuf, cvt, 1412 char_range, loc_reader, ranges); 1413 break; 1414 1415 case '0': case '1': case '2': case '3': 1416 case '4': case '5': case '6': case '7': 1417 return convert_oct (pfile, from, limit, tbuf, cvt, 1418 char_range, loc_reader, ranges); 1419 1420 /* Various letter escapes. Get the appropriate host-charset 1421 value into C. */ 1422 case '\\': case '\'': case '"': case '?': break; 1423 1424 case '(': case '{': case '[': case '%': 1425 /* '\(', etc, can be used at the beginning of a line in a long 1426 string split onto multiple lines with \-newline, to prevent 1427 Emacs or other text editors from getting confused. '\%' can 1428 be used to prevent SCCS from mangling printf format strings. */ 1429 if (CPP_PEDANTIC (pfile)) 1430 goto unknown; 1431 break; 1432 1433 case 'b': c = charconsts[1]; break; 1434 case 'f': c = charconsts[3]; break; 1435 case 'n': c = charconsts[4]; break; 1436 case 'r': c = charconsts[5]; break; 1437 case 't': c = charconsts[6]; break; 1438 case 'v': c = charconsts[7]; break; 1439 1440 case 'a': 1441 if (CPP_WTRADITIONAL (pfile)) 1442 cpp_warning (pfile, CPP_W_TRADITIONAL, 1443 "the meaning of '\\a' is different in traditional C"); 1444 c = charconsts[0]; 1445 break; 1446 1447 case 'e': case 'E': 1448 if (CPP_PEDANTIC (pfile)) 1449 cpp_error (pfile, CPP_DL_PEDWARN, 1450 "non-ISO-standard escape sequence, '\\%c'", (int) c); 1451 c = charconsts[2]; 1452 break; 1453 1454 default: 1455 unknown: 1456 if (ISGRAPH (c)) 1457 cpp_error (pfile, CPP_DL_PEDWARN, 1458 "unknown escape sequence: '\\%c'", (int) c); 1459 else 1460 { 1461 /* diagnostic.c does not support "%03o". When it does, this 1462 code can use %03o directly in the diagnostic again. */ 1463 char buf[32]; 1464 sprintf(buf, "%03o", (int) c); 1465 cpp_error (pfile, CPP_DL_PEDWARN, 1466 "unknown escape sequence: '\\%s'", buf); 1467 } 1468 } 1469 1470 if (tbuf) 1471 /* Now convert what we have to the execution character set. */ 1472 if (!APPLY_CONVERSION (cvt, &c, 1, tbuf)) 1473 cpp_errno (pfile, CPP_DL_ERROR, 1474 "converting escape sequence to execution character set"); 1475 1476 if (loc_reader) 1477 { 1478 char_range.m_finish = loc_reader->get_next ().m_finish; 1479 ranges->add_range (char_range); 1480 } 1481 1482 return from + 1; 1483 } 1484 1485 /* TYPE is a token type. The return value is the conversion needed to 1486 convert from source to execution character set for the given type. */ 1487 static struct cset_converter 1488 converter_for_type (cpp_reader *pfile, enum cpp_ttype type) 1489 { 1490 switch (type) 1491 { 1492 default: 1493 return pfile->narrow_cset_desc; 1494 case CPP_UTF8CHAR: 1495 case CPP_UTF8STRING: 1496 return pfile->utf8_cset_desc; 1497 case CPP_CHAR16: 1498 case CPP_STRING16: 1499 return pfile->char16_cset_desc; 1500 case CPP_CHAR32: 1501 case CPP_STRING32: 1502 return pfile->char32_cset_desc; 1503 case CPP_WCHAR: 1504 case CPP_WSTRING: 1505 return pfile->wide_cset_desc; 1506 } 1507 } 1508 1509 /* FROM is an array of cpp_string structures of length COUNT. These 1510 are to be converted from the source to the execution character set, 1511 escape sequences translated, and finally all are to be 1512 concatenated. WIDE indicates whether or not to produce a wide 1513 string. If TO is non-NULL, the result is written into TO. 1514 If LOC_READERS and OUT are non-NULL, then location information 1515 is read from LOC_READERS (which must be an array of length COUNT), 1516 and location information is written to *RANGES. 1517 1518 Returns true for success, false for failure. */ 1519 1520 static bool 1521 cpp_interpret_string_1 (cpp_reader *pfile, const cpp_string *from, size_t count, 1522 cpp_string *to, enum cpp_ttype type, 1523 cpp_string_location_reader *loc_readers, 1524 cpp_substring_ranges *out) 1525 { 1526 struct _cpp_strbuf tbuf; 1527 const uchar *p, *base, *limit; 1528 size_t i; 1529 struct cset_converter cvt = converter_for_type (pfile, type); 1530 1531 /* loc_readers and out must either be both NULL, or both be non-NULL. */ 1532 gcc_assert ((loc_readers != NULL) == (out != NULL)); 1533 1534 if (to) 1535 { 1536 tbuf.asize = MAX (OUTBUF_BLOCK_SIZE, from->len); 1537 tbuf.text = XNEWVEC (uchar, tbuf.asize); 1538 tbuf.len = 0; 1539 } 1540 1541 cpp_string_location_reader *loc_reader = NULL; 1542 for (i = 0; i < count; i++) 1543 { 1544 if (loc_readers) 1545 loc_reader = &loc_readers[i]; 1546 1547 p = from[i].text; 1548 if (*p == 'u') 1549 { 1550 p++; 1551 if (loc_reader) 1552 loc_reader->get_next (); 1553 if (*p == '8') 1554 { 1555 p++; 1556 if (loc_reader) 1557 loc_reader->get_next (); 1558 } 1559 } 1560 else if (*p == 'L' || *p == 'U') p++; 1561 if (*p == 'R') 1562 { 1563 const uchar *prefix; 1564 1565 /* Skip over 'R"'. */ 1566 p += 2; 1567 if (loc_reader) 1568 { 1569 loc_reader->get_next (); 1570 loc_reader->get_next (); 1571 } 1572 prefix = p; 1573 while (*p != '(') 1574 { 1575 p++; 1576 if (loc_reader) 1577 loc_reader->get_next (); 1578 } 1579 p++; 1580 if (loc_reader) 1581 loc_reader->get_next (); 1582 limit = from[i].text + from[i].len; 1583 if (limit >= p + (p - prefix) + 1) 1584 limit -= (p - prefix) + 1; 1585 1586 /* Raw strings are all normal characters; these can be fed 1587 directly to convert_cset. */ 1588 if (to) 1589 if (!APPLY_CONVERSION (cvt, p, limit - p, &tbuf)) 1590 goto fail; 1591 1592 if (loc_reader) 1593 { 1594 /* If generating source ranges, assume we have a 1:1 1595 correspondence between bytes in the source encoding and bytes 1596 in the execution encoding (e.g. if we have a UTF-8 to UTF-8 1597 conversion), so that this run of bytes in the source file 1598 corresponds to a run of bytes in the execution string. 1599 This requirement is guaranteed by an early-reject in 1600 cpp_interpret_string_ranges. */ 1601 gcc_assert (cvt.func == convert_no_conversion); 1602 out->add_n_ranges (limit - p, *loc_reader); 1603 } 1604 1605 continue; 1606 } 1607 1608 /* If we don't now have a leading quote, something has gone wrong. 1609 This can occur if cpp_interpret_string_ranges is handling a 1610 stringified macro argument, but should not be possible otherwise. */ 1611 if (*p != '"' && *p != '\'') 1612 { 1613 gcc_assert (out != NULL); 1614 cpp_error (pfile, CPP_DL_ERROR, "missing open quote"); 1615 if (to) 1616 free (tbuf.text); 1617 return false; 1618 } 1619 1620 /* Skip leading quote. */ 1621 p++; 1622 if (loc_reader) 1623 loc_reader->get_next (); 1624 1625 limit = from[i].text + from[i].len - 1; /* Skip trailing quote. */ 1626 1627 for (;;) 1628 { 1629 base = p; 1630 while (p < limit && *p != '\\') 1631 p++; 1632 if (p > base) 1633 { 1634 /* We have a run of normal characters; these can be fed 1635 directly to convert_cset. */ 1636 if (to) 1637 if (!APPLY_CONVERSION (cvt, base, p - base, &tbuf)) 1638 goto fail; 1639 /* Similar to above: assumes we have a 1:1 correspondence 1640 between bytes in the source encoding and bytes in the 1641 execution encoding. */ 1642 if (loc_reader) 1643 { 1644 gcc_assert (cvt.func == convert_no_conversion); 1645 out->add_n_ranges (p - base, *loc_reader); 1646 } 1647 } 1648 if (p >= limit) 1649 break; 1650 1651 struct _cpp_strbuf *tbuf_ptr = to ? &tbuf : NULL; 1652 p = convert_escape (pfile, p + 1, limit, tbuf_ptr, cvt, 1653 loc_reader, out); 1654 } 1655 } 1656 1657 if (to) 1658 { 1659 /* NUL-terminate the 'to' buffer and translate it to a cpp_string 1660 structure. */ 1661 emit_numeric_escape (pfile, 0, &tbuf, cvt); 1662 tbuf.text = XRESIZEVEC (uchar, tbuf.text, tbuf.len); 1663 to->text = tbuf.text; 1664 to->len = tbuf.len; 1665 } 1666 /* Use the location of the trailing quote as the location of the 1667 NUL-terminator. */ 1668 if (loc_reader) 1669 { 1670 source_range range = loc_reader->get_next (); 1671 out->add_range (range); 1672 } 1673 1674 return true; 1675 1676 fail: 1677 cpp_errno (pfile, CPP_DL_ERROR, "converting to execution character set"); 1678 if (to) 1679 free (tbuf.text); 1680 return false; 1681 } 1682 1683 /* FROM is an array of cpp_string structures of length COUNT. These 1684 are to be converted from the source to the execution character set, 1685 escape sequences translated, and finally all are to be 1686 concatenated. WIDE indicates whether or not to produce a wide 1687 string. The result is written into TO. Returns true for success, 1688 false for failure. */ 1689 bool 1690 cpp_interpret_string (cpp_reader *pfile, const cpp_string *from, size_t count, 1691 cpp_string *to, enum cpp_ttype type) 1692 { 1693 return cpp_interpret_string_1 (pfile, from, count, to, type, NULL, NULL); 1694 } 1695 1696 /* A "do nothing" error-handling callback for use by 1697 cpp_interpret_string_ranges, so that it can temporarily suppress 1698 error-handling. */ 1699 1700 static bool 1701 noop_error_cb (cpp_reader *, int, int, rich_location *, 1702 const char *, va_list *) 1703 { 1704 /* no-op. */ 1705 return true; 1706 } 1707 1708 /* This function mimics the behavior of cpp_interpret_string, but 1709 rather than generating a string in the execution character set, 1710 *OUT is written to with the source code ranges of the characters 1711 in such a string. 1712 FROM and LOC_READERS should both be arrays of length COUNT. 1713 Returns NULL for success, or an error message for failure. */ 1714 1715 const char * 1716 cpp_interpret_string_ranges (cpp_reader *pfile, const cpp_string *from, 1717 cpp_string_location_reader *loc_readers, 1718 size_t count, 1719 cpp_substring_ranges *out, 1720 enum cpp_ttype type) 1721 { 1722 /* There are a couple of cases in the range-handling in 1723 cpp_interpret_string_1 that rely on there being a 1:1 correspondence 1724 between bytes in the source encoding and bytes in the execution 1725 encoding, so that each byte in the execution string can correspond 1726 to the location of a byte in the source string. 1727 1728 This holds for the typical case of a UTF-8 to UTF-8 conversion. 1729 Enforce this requirement by only attempting to track substring 1730 locations if we have source encoding == execution encoding. 1731 1732 This is a stronger condition than we need, since we could e.g. 1733 have ASCII to EBCDIC (with 1 byte per character before and after), 1734 but it seems to be a reasonable restriction. */ 1735 struct cset_converter cvt = converter_for_type (pfile, type); 1736 if (cvt.func != convert_no_conversion) 1737 return "execution character set != source character set"; 1738 1739 /* For on-demand strings we have already lexed the strings, so there 1740 should be no errors. However, if we have bogus source location 1741 data (or stringified macro arguments), the attempt to lex the 1742 strings could fail with an error. Temporarily install an 1743 error-handler to catch the error, so that it can lead to this call 1744 failing, rather than being emitted as a user-visible diagnostic. 1745 If an error does occur, we should see it via the return value of 1746 cpp_interpret_string_1. */ 1747 bool (*saved_error_handler) (cpp_reader *, int, int, rich_location *, 1748 const char *, va_list *) 1749 ATTRIBUTE_FPTR_PRINTF(5,0); 1750 1751 saved_error_handler = pfile->cb.error; 1752 pfile->cb.error = noop_error_cb; 1753 1754 bool result = cpp_interpret_string_1 (pfile, from, count, NULL, type, 1755 loc_readers, out); 1756 1757 /* Restore the saved error-handler. */ 1758 pfile->cb.error = saved_error_handler; 1759 1760 if (!result) 1761 return "cpp_interpret_string_1 failed"; 1762 1763 /* Success. */ 1764 return NULL; 1765 } 1766 1767 /* Subroutine of do_line and do_linemarker. Convert escape sequences 1768 in a string, but do not perform character set conversion. */ 1769 bool 1770 cpp_interpret_string_notranslate (cpp_reader *pfile, const cpp_string *from, 1771 size_t count, cpp_string *to, 1772 enum cpp_ttype type ATTRIBUTE_UNUSED) 1773 { 1774 struct cset_converter save_narrow_cset_desc = pfile->narrow_cset_desc; 1775 bool retval; 1776 1777 pfile->narrow_cset_desc.func = convert_no_conversion; 1778 pfile->narrow_cset_desc.cd = (iconv_t) -1; 1779 pfile->narrow_cset_desc.width = CPP_OPTION (pfile, char_precision); 1780 1781 retval = cpp_interpret_string (pfile, from, count, to, CPP_STRING); 1782 1783 pfile->narrow_cset_desc = save_narrow_cset_desc; 1784 return retval; 1785 } 1786 1787 1788 /* Subroutine of cpp_interpret_charconst which performs the conversion 1789 to a number, for narrow strings. STR is the string structure returned 1790 by cpp_interpret_string. PCHARS_SEEN and UNSIGNEDP are as for 1791 cpp_interpret_charconst. */ 1792 static cppchar_t 1793 narrow_str_to_charconst (cpp_reader *pfile, cpp_string str, 1794 unsigned int *pchars_seen, int *unsignedp) 1795 { 1796 size_t width = CPP_OPTION (pfile, char_precision); 1797 size_t max_chars = CPP_OPTION (pfile, int_precision) / width; 1798 size_t mask = width_to_mask (width); 1799 size_t i; 1800 cppchar_t result, c; 1801 bool unsigned_p; 1802 1803 /* The value of a multi-character character constant, or a 1804 single-character character constant whose representation in the 1805 execution character set is more than one byte long, is 1806 implementation defined. This implementation defines it to be the 1807 number formed by interpreting the byte sequence in memory as a 1808 big-endian binary number. If overflow occurs, the high bytes are 1809 lost, and a warning is issued. 1810 1811 We don't want to process the NUL terminator handed back by 1812 cpp_interpret_string. */ 1813 result = 0; 1814 for (i = 0; i < str.len - 1; i++) 1815 { 1816 c = str.text[i] & mask; 1817 if (width < BITS_PER_CPPCHAR_T) 1818 result = (result << width) | c; 1819 else 1820 result = c; 1821 } 1822 1823 if (i > max_chars) 1824 { 1825 i = max_chars; 1826 cpp_error (pfile, CPP_DL_WARNING, 1827 "character constant too long for its type"); 1828 } 1829 else if (i > 1 && CPP_OPTION (pfile, warn_multichar)) 1830 cpp_warning (pfile, CPP_W_MULTICHAR, "multi-character character constant"); 1831 1832 /* Multichar constants are of type int and therefore signed. */ 1833 if (i > 1) 1834 unsigned_p = 0; 1835 else 1836 unsigned_p = CPP_OPTION (pfile, unsigned_char); 1837 1838 /* Truncate the constant to its natural width, and simultaneously 1839 sign- or zero-extend to the full width of cppchar_t. 1840 For single-character constants, the value is WIDTH bits wide. 1841 For multi-character constants, the value is INT_PRECISION bits wide. */ 1842 if (i > 1) 1843 width = CPP_OPTION (pfile, int_precision); 1844 if (width < BITS_PER_CPPCHAR_T) 1845 { 1846 mask = ((cppchar_t) 1 << width) - 1; 1847 if (unsigned_p || !(result & (1 << (width - 1)))) 1848 result &= mask; 1849 else 1850 result |= ~mask; 1851 } 1852 *pchars_seen = i; 1853 *unsignedp = unsigned_p; 1854 return result; 1855 } 1856 1857 /* Subroutine of cpp_interpret_charconst which performs the conversion 1858 to a number, for wide strings. STR is the string structure returned 1859 by cpp_interpret_string. PCHARS_SEEN and UNSIGNEDP are as for 1860 cpp_interpret_charconst. TYPE is the token type. */ 1861 static cppchar_t 1862 wide_str_to_charconst (cpp_reader *pfile, cpp_string str, 1863 unsigned int *pchars_seen, int *unsignedp, 1864 enum cpp_ttype type) 1865 { 1866 bool bigend = CPP_OPTION (pfile, bytes_big_endian); 1867 size_t width = converter_for_type (pfile, type).width; 1868 size_t cwidth = CPP_OPTION (pfile, char_precision); 1869 size_t mask = width_to_mask (width); 1870 size_t cmask = width_to_mask (cwidth); 1871 size_t nbwc = width / cwidth; 1872 size_t off, i; 1873 cppchar_t result = 0, c; 1874 1875 /* This is finicky because the string is in the target's byte order, 1876 which may not be our byte order. Only the last character, ignoring 1877 the NUL terminator, is relevant. */ 1878 off = str.len - (nbwc * 2); 1879 result = 0; 1880 for (i = 0; i < nbwc; i++) 1881 { 1882 c = bigend ? str.text[off + i] : str.text[off + nbwc - i - 1]; 1883 result = (result << cwidth) | (c & cmask); 1884 } 1885 1886 /* Wide character constants have type wchar_t, and a single 1887 character exactly fills a wchar_t, so a multi-character wide 1888 character constant is guaranteed to overflow. */ 1889 if (str.len > nbwc * 2) 1890 cpp_error (pfile, CPP_DL_WARNING, 1891 "character constant too long for its type"); 1892 1893 /* Truncate the constant to its natural width, and simultaneously 1894 sign- or zero-extend to the full width of cppchar_t. */ 1895 if (width < BITS_PER_CPPCHAR_T) 1896 { 1897 if (type == CPP_CHAR16 || type == CPP_CHAR32 1898 || CPP_OPTION (pfile, unsigned_wchar) 1899 || !(result & (1 << (width - 1)))) 1900 result &= mask; 1901 else 1902 result |= ~mask; 1903 } 1904 1905 if (type == CPP_CHAR16 || type == CPP_CHAR32 1906 || CPP_OPTION (pfile, unsigned_wchar)) 1907 *unsignedp = 1; 1908 else 1909 *unsignedp = 0; 1910 1911 *pchars_seen = 1; 1912 return result; 1913 } 1914 1915 /* Interpret a (possibly wide) character constant in TOKEN. 1916 PCHARS_SEEN points to a variable that is filled in with the number 1917 of characters seen, and UNSIGNEDP to a variable that indicates 1918 whether the result has signed type. */ 1919 cppchar_t 1920 cpp_interpret_charconst (cpp_reader *pfile, const cpp_token *token, 1921 unsigned int *pchars_seen, int *unsignedp) 1922 { 1923 cpp_string str = { 0, 0 }; 1924 bool wide = (token->type != CPP_CHAR && token->type != CPP_UTF8CHAR); 1925 int u8 = 2 * int(token->type == CPP_UTF8CHAR); 1926 cppchar_t result; 1927 1928 /* An empty constant will appear as L'', u'', U'', u8'', or '' */ 1929 if (token->val.str.len == (size_t) (2 + wide + u8)) 1930 { 1931 cpp_error (pfile, CPP_DL_ERROR, "empty character constant"); 1932 *pchars_seen = 0; 1933 *unsignedp = 0; 1934 return 0; 1935 } 1936 else if (!cpp_interpret_string (pfile, &token->val.str, 1, &str, 1937 token->type)) 1938 { 1939 *pchars_seen = 0; 1940 *unsignedp = 0; 1941 return 0; 1942 } 1943 1944 if (wide) 1945 result = wide_str_to_charconst (pfile, str, pchars_seen, unsignedp, 1946 token->type); 1947 else 1948 result = narrow_str_to_charconst (pfile, str, pchars_seen, unsignedp); 1949 1950 if (str.text != token->val.str.text) 1951 free ((void *)str.text); 1952 1953 return result; 1954 } 1955 1956 /* Convert an identifier denoted by ID and LEN, which might contain 1957 UCN escapes, to the source character set, either UTF-8 or 1958 UTF-EBCDIC. Assumes that the identifier is actually a valid identifier. */ 1959 cpp_hashnode * 1960 _cpp_interpret_identifier (cpp_reader *pfile, const uchar *id, size_t len) 1961 { 1962 /* It turns out that a UCN escape always turns into fewer characters 1963 than the escape itself, so we can allocate a temporary in advance. */ 1964 uchar * buf = (uchar *) alloca (len + 1); 1965 uchar * bufp = buf; 1966 size_t idp; 1967 1968 for (idp = 0; idp < len; idp++) 1969 if (id[idp] != '\\') 1970 *bufp++ = id[idp]; 1971 else 1972 { 1973 unsigned length = id[idp+1] == 'u' ? 4 : 8; 1974 cppchar_t value = 0; 1975 size_t bufleft = len - (bufp - buf); 1976 int rval; 1977 1978 idp += 2; 1979 while (length && idp < len && ISXDIGIT (id[idp])) 1980 { 1981 value = (value << 4) + hex_value (id[idp]); 1982 idp++; 1983 length--; 1984 } 1985 idp--; 1986 1987 /* Special case for EBCDIC: if the identifier contains 1988 a '$' specified using a UCN, translate it to EBCDIC. */ 1989 if (value == 0x24) 1990 { 1991 *bufp++ = '$'; 1992 continue; 1993 } 1994 1995 rval = one_cppchar_to_utf8 (value, &bufp, &bufleft); 1996 if (rval) 1997 { 1998 errno = rval; 1999 cpp_errno (pfile, CPP_DL_ERROR, 2000 "converting UCN to source character set"); 2001 break; 2002 } 2003 } 2004 2005 return CPP_HASHNODE (ht_lookup (pfile->hash_table, 2006 buf, bufp - buf, HT_ALLOC)); 2007 } 2008 2009 /* Convert an input buffer (containing the complete contents of one 2010 source file) from INPUT_CHARSET to the source character set. INPUT 2011 points to the input buffer, SIZE is its allocated size, and LEN is 2012 the length of the meaningful data within the buffer. The 2013 translated buffer is returned, *ST_SIZE is set to the length of 2014 the meaningful data within the translated buffer, and *BUFFER_START 2015 is set to the start of the returned buffer. *BUFFER_START may 2016 differ from the return value in the case of a BOM or other ignored 2017 marker information. 2018 2019 INPUT is expected to have been allocated with xmalloc. This 2020 function will either set *BUFFER_START to INPUT, or free it and set 2021 *BUFFER_START to a pointer to another xmalloc-allocated block of 2022 memory. */ 2023 uchar * 2024 _cpp_convert_input (cpp_reader *pfile, const char *input_charset, 2025 uchar *input, size_t size, size_t len, 2026 const unsigned char **buffer_start, off_t *st_size) 2027 { 2028 struct cset_converter input_cset; 2029 struct _cpp_strbuf to; 2030 unsigned char *buffer; 2031 2032 input_cset = init_iconv_desc (pfile, SOURCE_CHARSET, input_charset); 2033 if (input_cset.func == convert_no_conversion) 2034 { 2035 to.text = input; 2036 to.asize = size; 2037 to.len = len; 2038 } 2039 else 2040 { 2041 to.asize = MAX (65536, len); 2042 to.text = XNEWVEC (uchar, to.asize); 2043 to.len = 0; 2044 2045 if (!APPLY_CONVERSION (input_cset, input, len, &to)) 2046 cpp_error (pfile, CPP_DL_ERROR, 2047 "failure to convert %s to %s", 2048 CPP_OPTION (pfile, input_charset), SOURCE_CHARSET); 2049 2050 free (input); 2051 } 2052 2053 /* Clean up the mess. */ 2054 if (input_cset.func == convert_using_iconv) 2055 iconv_close (input_cset.cd); 2056 2057 /* Resize buffer if we allocated substantially too much, or if we 2058 haven't enough space for the \n-terminator or following 2059 15 bytes of padding (used to quiet warnings from valgrind or 2060 Address Sanitizer, when the optimized lexer accesses aligned 2061 16-byte memory chunks, including the bytes after the malloced, 2062 area, and stops lexing on '\n'). */ 2063 if (to.len + 4096 < to.asize || to.len + 16 > to.asize) 2064 to.text = XRESIZEVEC (uchar, to.text, to.len + 16); 2065 2066 memset (to.text + to.len, '\0', 16); 2067 2068 /* If the file is using old-school Mac line endings (\r only), 2069 terminate with another \r, not an \n, so that we do not mistake 2070 the \r\n sequence for a single DOS line ending and erroneously 2071 issue the "No newline at end of file" diagnostic. */ 2072 if (to.len && to.text[to.len - 1] == '\r') 2073 to.text[to.len] = '\r'; 2074 else 2075 to.text[to.len] = '\n'; 2076 2077 buffer = to.text; 2078 *st_size = to.len; 2079 #if HOST_CHARSET == HOST_CHARSET_ASCII 2080 /* The HOST_CHARSET test just above ensures that the source charset 2081 is UTF-8. So, ignore a UTF-8 BOM if we see one. Note that 2082 glib'c UTF-8 iconv() provider (as of glibc 2.7) does not ignore a 2083 BOM -- however, even if it did, we would still need this code due 2084 to the 'convert_no_conversion' case. */ 2085 if (to.len >= 3 && to.text[0] == 0xef && to.text[1] == 0xbb 2086 && to.text[2] == 0xbf) 2087 { 2088 *st_size -= 3; 2089 buffer += 3; 2090 } 2091 #endif 2092 2093 *buffer_start = to.text; 2094 return buffer; 2095 } 2096 2097 /* Decide on the default encoding to assume for input files. */ 2098 const char * 2099 _cpp_default_encoding (void) 2100 { 2101 const char *current_encoding = NULL; 2102 2103 /* We disable this because the default codeset is 7-bit ASCII on 2104 most platforms, and this causes conversion failures on every 2105 file in GCC that happens to have one of the upper 128 characters 2106 in it -- most likely, as part of the name of a contributor. 2107 We should definitely recognize in-band markers of file encoding, 2108 like: 2109 - the appropriate Unicode byte-order mark (FE FF) to recognize 2110 UTF16 and UCS4 (in both big-endian and little-endian flavors) 2111 and UTF8 2112 - a "#i", "#d", "/ *", "//", " #p" or "#p" (for #pragma) to 2113 distinguish ASCII and EBCDIC. 2114 - now we can parse something like "#pragma GCC encoding <xyz> 2115 on the first line, or even Emacs/VIM's mode line tags (there's 2116 a problem here in that VIM uses the last line, and Emacs has 2117 its more elaborate "local variables" convention). 2118 - investigate whether Java has another common convention, which 2119 would be friendly to support. 2120 (Zack Weinberg and Paolo Bonzini, May 20th 2004) */ 2121 #if defined (HAVE_LOCALE_H) && defined (HAVE_LANGINFO_CODESET) && 0 2122 setlocale (LC_CTYPE, ""); 2123 current_encoding = nl_langinfo (CODESET); 2124 #endif 2125 if (current_encoding == NULL || *current_encoding == '\0') 2126 current_encoding = SOURCE_CHARSET; 2127 2128 return current_encoding; 2129 } 2130 2131 /* Implementation of class cpp_string_location_reader. */ 2132 2133 /* Constructor for cpp_string_location_reader. */ 2134 2135 cpp_string_location_reader:: 2136 cpp_string_location_reader (source_location src_loc, 2137 line_maps *line_table) 2138 : m_line_table (line_table) 2139 { 2140 src_loc = get_range_from_loc (line_table, src_loc).m_start; 2141 2142 /* SRC_LOC might be a macro location. It only makes sense to do 2143 column-by-column calculations on ordinary maps, so get the 2144 corresponding location in an ordinary map. */ 2145 m_loc 2146 = linemap_resolve_location (line_table, src_loc, 2147 LRK_SPELLING_LOCATION, NULL); 2148 2149 const line_map_ordinary *map 2150 = linemap_check_ordinary (linemap_lookup (line_table, m_loc)); 2151 m_offset_per_column = (1 << map->m_range_bits); 2152 } 2153 2154 /* Get the range of the next source byte. */ 2155 2156 source_range 2157 cpp_string_location_reader::get_next () 2158 { 2159 source_range result; 2160 result.m_start = m_loc; 2161 result.m_finish = m_loc; 2162 if (m_loc <= LINE_MAP_MAX_LOCATION_WITH_COLS) 2163 m_loc += m_offset_per_column; 2164 return result; 2165 } 2166