github.com/binkynet/BinkyNet@v1.12.1-0.20240421190447-da4e34c20be0/proto_vendor/golang.org/x/text/unicode/norm/composition.go (about) 1 // Copyright 2011 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 package norm 6 7 import "unicode/utf8" 8 9 const ( 10 maxNonStarters = 30 11 // The maximum number of characters needed for a buffer is 12 // maxNonStarters + 1 for the starter + 1 for the GCJ 13 maxBufferSize = maxNonStarters + 2 14 maxNFCExpansion = 3 // NFC(0x1D160) 15 maxNFKCExpansion = 18 // NFKC(0xFDFA) 16 17 maxByteBufferSize = utf8.UTFMax * maxBufferSize // 128 18 ) 19 20 // ssState is used for reporting the segment state after inserting a rune. 21 // It is returned by streamSafe.next. 22 type ssState int 23 24 const ( 25 // Indicates a rune was successfully added to the segment. 26 ssSuccess ssState = iota 27 // Indicates a rune starts a new segment and should not be added. 28 ssStarter 29 // Indicates a rune caused a segment overflow and a CGJ should be inserted. 30 ssOverflow 31 ) 32 33 // streamSafe implements the policy of when a CGJ should be inserted. 34 type streamSafe uint8 35 36 // first inserts the first rune of a segment. It is a faster version of next if 37 // it is known p represents the first rune in a segment. 38 func (ss *streamSafe) first(p Properties) { 39 *ss = streamSafe(p.nTrailingNonStarters()) 40 } 41 42 // insert returns a ssState value to indicate whether a rune represented by p 43 // can be inserted. 44 func (ss *streamSafe) next(p Properties) ssState { 45 if *ss > maxNonStarters { 46 panic("streamSafe was not reset") 47 } 48 n := p.nLeadingNonStarters() 49 if *ss += streamSafe(n); *ss > maxNonStarters { 50 *ss = 0 51 return ssOverflow 52 } 53 // The Stream-Safe Text Processing prescribes that the counting can stop 54 // as soon as a starter is encountered. However, there are some starters, 55 // like Jamo V and T, that can combine with other runes, leaving their 56 // successive non-starters appended to the previous, possibly causing an 57 // overflow. We will therefore consider any rune with a non-zero nLead to 58 // be a non-starter. Note that it always hold that if nLead > 0 then 59 // nLead == nTrail. 60 if n == 0 { 61 *ss = streamSafe(p.nTrailingNonStarters()) 62 return ssStarter 63 } 64 return ssSuccess 65 } 66 67 // backwards is used for checking for overflow and segment starts 68 // when traversing a string backwards. Users do not need to call first 69 // for the first rune. The state of the streamSafe retains the count of 70 // the non-starters loaded. 71 func (ss *streamSafe) backwards(p Properties) ssState { 72 if *ss > maxNonStarters { 73 panic("streamSafe was not reset") 74 } 75 c := *ss + streamSafe(p.nTrailingNonStarters()) 76 if c > maxNonStarters { 77 return ssOverflow 78 } 79 *ss = c 80 if p.nLeadingNonStarters() == 0 { 81 return ssStarter 82 } 83 return ssSuccess 84 } 85 86 func (ss streamSafe) isMax() bool { 87 return ss == maxNonStarters 88 } 89 90 // GraphemeJoiner is inserted after maxNonStarters non-starter runes. 91 const GraphemeJoiner = "\u034F" 92 93 // reorderBuffer is used to normalize a single segment. Characters inserted with 94 // insert are decomposed and reordered based on CCC. The compose method can 95 // be used to recombine characters. Note that the byte buffer does not hold 96 // the UTF-8 characters in order. Only the rune array is maintained in sorted 97 // order. flush writes the resulting segment to a byte array. 98 type reorderBuffer struct { 99 rune [maxBufferSize]Properties // Per character info. 100 byte [maxByteBufferSize]byte // UTF-8 buffer. Referenced by runeInfo.pos. 101 nbyte uint8 // Number or bytes. 102 ss streamSafe // For limiting length of non-starter sequence. 103 nrune int // Number of runeInfos. 104 f formInfo 105 106 src input 107 nsrc int 108 tmpBytes input 109 110 out []byte 111 flushF func(*reorderBuffer) bool 112 } 113 114 func (rb *reorderBuffer) init(f Form, src []byte) { 115 rb.f = *formTable[f] 116 rb.src.setBytes(src) 117 rb.nsrc = len(src) 118 rb.ss = 0 119 } 120 121 func (rb *reorderBuffer) initString(f Form, src string) { 122 rb.f = *formTable[f] 123 rb.src.setString(src) 124 rb.nsrc = len(src) 125 rb.ss = 0 126 } 127 128 func (rb *reorderBuffer) setFlusher(out []byte, f func(*reorderBuffer) bool) { 129 rb.out = out 130 rb.flushF = f 131 } 132 133 // reset discards all characters from the buffer. 134 func (rb *reorderBuffer) reset() { 135 rb.nrune = 0 136 rb.nbyte = 0 137 } 138 139 func (rb *reorderBuffer) doFlush() bool { 140 if rb.f.composing { 141 rb.compose() 142 } 143 res := rb.flushF(rb) 144 rb.reset() 145 return res 146 } 147 148 // appendFlush appends the normalized segment to rb.out. 149 func appendFlush(rb *reorderBuffer) bool { 150 for i := 0; i < rb.nrune; i++ { 151 start := rb.rune[i].pos 152 end := start + rb.rune[i].size 153 rb.out = append(rb.out, rb.byte[start:end]...) 154 } 155 return true 156 } 157 158 // flush appends the normalized segment to out and resets rb. 159 func (rb *reorderBuffer) flush(out []byte) []byte { 160 for i := 0; i < rb.nrune; i++ { 161 start := rb.rune[i].pos 162 end := start + rb.rune[i].size 163 out = append(out, rb.byte[start:end]...) 164 } 165 rb.reset() 166 return out 167 } 168 169 // flushCopy copies the normalized segment to buf and resets rb. 170 // It returns the number of bytes written to buf. 171 func (rb *reorderBuffer) flushCopy(buf []byte) int { 172 p := 0 173 for i := 0; i < rb.nrune; i++ { 174 runep := rb.rune[i] 175 p += copy(buf[p:], rb.byte[runep.pos:runep.pos+runep.size]) 176 } 177 rb.reset() 178 return p 179 } 180 181 // insertOrdered inserts a rune in the buffer, ordered by Canonical Combining Class. 182 // It returns false if the buffer is not large enough to hold the rune. 183 // It is used internally by insert and insertString only. 184 func (rb *reorderBuffer) insertOrdered(info Properties) { 185 n := rb.nrune 186 b := rb.rune[:] 187 cc := info.ccc 188 if cc > 0 { 189 // Find insertion position + move elements to make room. 190 for ; n > 0; n-- { 191 if b[n-1].ccc <= cc { 192 break 193 } 194 b[n] = b[n-1] 195 } 196 } 197 rb.nrune += 1 198 pos := uint8(rb.nbyte) 199 rb.nbyte += utf8.UTFMax 200 info.pos = pos 201 b[n] = info 202 } 203 204 // insertErr is an error code returned by insert. Using this type instead 205 // of error improves performance up to 20% for many of the benchmarks. 206 type insertErr int 207 208 const ( 209 iSuccess insertErr = -iota 210 iShortDst 211 iShortSrc 212 ) 213 214 // insertFlush inserts the given rune in the buffer ordered by CCC. 215 // If a decomposition with multiple segments are encountered, they leading 216 // ones are flushed. 217 // It returns a non-zero error code if the rune was not inserted. 218 func (rb *reorderBuffer) insertFlush(src input, i int, info Properties) insertErr { 219 if rune := src.hangul(i); rune != 0 { 220 rb.decomposeHangul(rune) 221 return iSuccess 222 } 223 if info.hasDecomposition() { 224 return rb.insertDecomposed(info.Decomposition()) 225 } 226 rb.insertSingle(src, i, info) 227 return iSuccess 228 } 229 230 // insertUnsafe inserts the given rune in the buffer ordered by CCC. 231 // It is assumed there is sufficient space to hold the runes. It is the 232 // responsibility of the caller to ensure this. This can be done by checking 233 // the state returned by the streamSafe type. 234 func (rb *reorderBuffer) insertUnsafe(src input, i int, info Properties) { 235 if rune := src.hangul(i); rune != 0 { 236 rb.decomposeHangul(rune) 237 } 238 if info.hasDecomposition() { 239 // TODO: inline. 240 rb.insertDecomposed(info.Decomposition()) 241 } else { 242 rb.insertSingle(src, i, info) 243 } 244 } 245 246 // insertDecomposed inserts an entry in to the reorderBuffer for each rune 247 // in dcomp. dcomp must be a sequence of decomposed UTF-8-encoded runes. 248 // It flushes the buffer on each new segment start. 249 func (rb *reorderBuffer) insertDecomposed(dcomp []byte) insertErr { 250 rb.tmpBytes.setBytes(dcomp) 251 // As the streamSafe accounting already handles the counting for modifiers, 252 // we don't have to call next. However, we do need to keep the accounting 253 // intact when flushing the buffer. 254 for i := 0; i < len(dcomp); { 255 info := rb.f.info(rb.tmpBytes, i) 256 if info.BoundaryBefore() && rb.nrune > 0 && !rb.doFlush() { 257 return iShortDst 258 } 259 i += copy(rb.byte[rb.nbyte:], dcomp[i:i+int(info.size)]) 260 rb.insertOrdered(info) 261 } 262 return iSuccess 263 } 264 265 // insertSingle inserts an entry in the reorderBuffer for the rune at 266 // position i. info is the runeInfo for the rune at position i. 267 func (rb *reorderBuffer) insertSingle(src input, i int, info Properties) { 268 src.copySlice(rb.byte[rb.nbyte:], i, i+int(info.size)) 269 rb.insertOrdered(info) 270 } 271 272 // insertCGJ inserts a Combining Grapheme Joiner (0x034f) into rb. 273 func (rb *reorderBuffer) insertCGJ() { 274 rb.insertSingle(input{str: GraphemeJoiner}, 0, Properties{size: uint8(len(GraphemeJoiner))}) 275 } 276 277 // appendRune inserts a rune at the end of the buffer. It is used for Hangul. 278 func (rb *reorderBuffer) appendRune(r rune) { 279 bn := rb.nbyte 280 sz := utf8.EncodeRune(rb.byte[bn:], rune(r)) 281 rb.nbyte += utf8.UTFMax 282 rb.rune[rb.nrune] = Properties{pos: bn, size: uint8(sz)} 283 rb.nrune++ 284 } 285 286 // assignRune sets a rune at position pos. It is used for Hangul and recomposition. 287 func (rb *reorderBuffer) assignRune(pos int, r rune) { 288 bn := rb.rune[pos].pos 289 sz := utf8.EncodeRune(rb.byte[bn:], rune(r)) 290 rb.rune[pos] = Properties{pos: bn, size: uint8(sz)} 291 } 292 293 // runeAt returns the rune at position n. It is used for Hangul and recomposition. 294 func (rb *reorderBuffer) runeAt(n int) rune { 295 inf := rb.rune[n] 296 r, _ := utf8.DecodeRune(rb.byte[inf.pos : inf.pos+inf.size]) 297 return r 298 } 299 300 // bytesAt returns the UTF-8 encoding of the rune at position n. 301 // It is used for Hangul and recomposition. 302 func (rb *reorderBuffer) bytesAt(n int) []byte { 303 inf := rb.rune[n] 304 return rb.byte[inf.pos : int(inf.pos)+int(inf.size)] 305 } 306 307 // For Hangul we combine algorithmically, instead of using tables. 308 const ( 309 hangulBase = 0xAC00 // UTF-8(hangulBase) -> EA B0 80 310 hangulBase0 = 0xEA 311 hangulBase1 = 0xB0 312 hangulBase2 = 0x80 313 314 hangulEnd = hangulBase + jamoLVTCount // UTF-8(0xD7A4) -> ED 9E A4 315 hangulEnd0 = 0xED 316 hangulEnd1 = 0x9E 317 hangulEnd2 = 0xA4 318 319 jamoLBase = 0x1100 // UTF-8(jamoLBase) -> E1 84 00 320 jamoLBase0 = 0xE1 321 jamoLBase1 = 0x84 322 jamoLEnd = 0x1113 323 jamoVBase = 0x1161 324 jamoVEnd = 0x1176 325 jamoTBase = 0x11A7 326 jamoTEnd = 0x11C3 327 328 jamoTCount = 28 329 jamoVCount = 21 330 jamoVTCount = 21 * 28 331 jamoLVTCount = 19 * 21 * 28 332 ) 333 334 const hangulUTF8Size = 3 335 336 func isHangul(b []byte) bool { 337 if len(b) < hangulUTF8Size { 338 return false 339 } 340 b0 := b[0] 341 if b0 < hangulBase0 { 342 return false 343 } 344 b1 := b[1] 345 switch { 346 case b0 == hangulBase0: 347 return b1 >= hangulBase1 348 case b0 < hangulEnd0: 349 return true 350 case b0 > hangulEnd0: 351 return false 352 case b1 < hangulEnd1: 353 return true 354 } 355 return b1 == hangulEnd1 && b[2] < hangulEnd2 356 } 357 358 func isHangulString(b string) bool { 359 if len(b) < hangulUTF8Size { 360 return false 361 } 362 b0 := b[0] 363 if b0 < hangulBase0 { 364 return false 365 } 366 b1 := b[1] 367 switch { 368 case b0 == hangulBase0: 369 return b1 >= hangulBase1 370 case b0 < hangulEnd0: 371 return true 372 case b0 > hangulEnd0: 373 return false 374 case b1 < hangulEnd1: 375 return true 376 } 377 return b1 == hangulEnd1 && b[2] < hangulEnd2 378 } 379 380 // Caller must ensure len(b) >= 2. 381 func isJamoVT(b []byte) bool { 382 // True if (rune & 0xff00) == jamoLBase 383 return b[0] == jamoLBase0 && (b[1]&0xFC) == jamoLBase1 384 } 385 386 func isHangulWithoutJamoT(b []byte) bool { 387 c, _ := utf8.DecodeRune(b) 388 c -= hangulBase 389 return c < jamoLVTCount && c%jamoTCount == 0 390 } 391 392 // decomposeHangul writes the decomposed Hangul to buf and returns the number 393 // of bytes written. len(buf) should be at least 9. 394 func decomposeHangul(buf []byte, r rune) int { 395 const JamoUTF8Len = 3 396 r -= hangulBase 397 x := r % jamoTCount 398 r /= jamoTCount 399 utf8.EncodeRune(buf, jamoLBase+r/jamoVCount) 400 utf8.EncodeRune(buf[JamoUTF8Len:], jamoVBase+r%jamoVCount) 401 if x != 0 { 402 utf8.EncodeRune(buf[2*JamoUTF8Len:], jamoTBase+x) 403 return 3 * JamoUTF8Len 404 } 405 return 2 * JamoUTF8Len 406 } 407 408 // decomposeHangul algorithmically decomposes a Hangul rune into 409 // its Jamo components. 410 // See http://unicode.org/reports/tr15/#Hangul for details on decomposing Hangul. 411 func (rb *reorderBuffer) decomposeHangul(r rune) { 412 r -= hangulBase 413 x := r % jamoTCount 414 r /= jamoTCount 415 rb.appendRune(jamoLBase + r/jamoVCount) 416 rb.appendRune(jamoVBase + r%jamoVCount) 417 if x != 0 { 418 rb.appendRune(jamoTBase + x) 419 } 420 } 421 422 // combineHangul algorithmically combines Jamo character components into Hangul. 423 // See http://unicode.org/reports/tr15/#Hangul for details on combining Hangul. 424 func (rb *reorderBuffer) combineHangul(s, i, k int) { 425 b := rb.rune[:] 426 bn := rb.nrune 427 for ; i < bn; i++ { 428 cccB := b[k-1].ccc 429 cccC := b[i].ccc 430 if cccB == 0 { 431 s = k - 1 432 } 433 if s != k-1 && cccB >= cccC { 434 // b[i] is blocked by greater-equal cccX below it 435 b[k] = b[i] 436 k++ 437 } else { 438 l := rb.runeAt(s) // also used to compare to hangulBase 439 v := rb.runeAt(i) // also used to compare to jamoT 440 switch { 441 case jamoLBase <= l && l < jamoLEnd && 442 jamoVBase <= v && v < jamoVEnd: 443 // 11xx plus 116x to LV 444 rb.assignRune(s, hangulBase+ 445 (l-jamoLBase)*jamoVTCount+(v-jamoVBase)*jamoTCount) 446 case hangulBase <= l && l < hangulEnd && 447 jamoTBase < v && v < jamoTEnd && 448 ((l-hangulBase)%jamoTCount) == 0: 449 // ACxx plus 11Ax to LVT 450 rb.assignRune(s, l+v-jamoTBase) 451 default: 452 b[k] = b[i] 453 k++ 454 } 455 } 456 } 457 rb.nrune = k 458 } 459 460 // compose recombines the runes in the buffer. 461 // It should only be used to recompose a single segment, as it will not 462 // handle alternations between Hangul and non-Hangul characters correctly. 463 func (rb *reorderBuffer) compose() { 464 // UAX #15, section X5 , including Corrigendum #5 465 // "In any character sequence beginning with starter S, a character C is 466 // blocked from S if and only if there is some character B between S 467 // and C, and either B is a starter or it has the same or higher 468 // combining class as C." 469 bn := rb.nrune 470 if bn == 0 { 471 return 472 } 473 k := 1 474 b := rb.rune[:] 475 for s, i := 0, 1; i < bn; i++ { 476 if isJamoVT(rb.bytesAt(i)) { 477 // Redo from start in Hangul mode. Necessary to support 478 // U+320E..U+321E in NFKC mode. 479 rb.combineHangul(s, i, k) 480 return 481 } 482 ii := b[i] 483 // We can only use combineForward as a filter if we later 484 // get the info for the combined character. This is more 485 // expensive than using the filter. Using combinesBackward() 486 // is safe. 487 if ii.combinesBackward() { 488 cccB := b[k-1].ccc 489 cccC := ii.ccc 490 blocked := false // b[i] blocked by starter or greater or equal CCC? 491 if cccB == 0 { 492 s = k - 1 493 } else { 494 blocked = s != k-1 && cccB >= cccC 495 } 496 if !blocked { 497 combined := combine(rb.runeAt(s), rb.runeAt(i)) 498 if combined != 0 { 499 rb.assignRune(s, combined) 500 continue 501 } 502 } 503 } 504 b[k] = b[i] 505 k++ 506 } 507 rb.nrune = k 508 }