1 /* 2 ** $Id: lcode.c,v 2.112.1.1 2017/04/19 17:20:42 roberto Exp $ 3 ** Code generator for Lua 4 ** See Copyright Notice in lua.h 5 */ 6 7 #define lcode_c 8 #define LUA_CORE 9 10 #include "lprefix.h" 11 12 13 #include <math.h> 14 #include <stdlib.h> 15 16 #include "lua.h" 17 18 #include "lcode.h" 19 #include "ldebug.h" 20 #include "ldo.h" 21 #include "lgc.h" 22 #include "llex.h" 23 #include "lmem.h" 24 #include "lobject.h" 25 #include "lopcodes.h" 26 #include "lparser.h" 27 #include "lstring.h" 28 #include "ltable.h" 29 #include "lvm.h" 30 31 32 /* Maximum number of registers in a Lua function (must fit in 8 bits) */ 33 #define MAXREGS 255 34 35 36 #define hasjumps(e) ((e)->t != (e)->f) 37 38 39 /* 40 ** If expression is a numeric constant, fills 'v' with its value 41 ** and returns 1. Otherwise, returns 0. 42 */ 43 static int tonumeral(const expdesc *e, TValue *v) { 44 if (hasjumps(e)) 45 return 0; /* not a numeral */ 46 switch (e->k) { 47 case VKINT: 48 if (v) setivalue(v, e->u.ival); 49 return 1; 50 case VKFLT: 51 if (v) setfltvalue(v, e->u.nval); 52 return 1; 53 default: return 0; 54 } 55 } 56 57 58 /* 59 ** Create a OP_LOADNIL instruction, but try to optimize: if the previous 60 ** instruction is also OP_LOADNIL and ranges are compatible, adjust 61 ** range of previous instruction instead of emitting a new one. (For 62 ** instance, 'local a; local b' will generate a single opcode.) 63 */ 64 void luaK_nil (FuncState *fs, int from, int n) { 65 Instruction *previous; 66 int l = from + n - 1; /* last register to set nil */ 67 if (fs->pc > fs->lasttarget) { /* no jumps to current position? */ 68 previous = &fs->f->code[fs->pc-1]; 69 if (GET_OPCODE(*previous) == OP_LOADNIL) { /* previous is LOADNIL? */ 70 int pfrom = GETARG_A(*previous); /* get previous range */ 71 int pl = pfrom + GETARG_B(*previous); 72 if ((pfrom <= from && from <= pl + 1) || 73 (from <= pfrom && pfrom <= l + 1)) { /* can connect both? */ 74 if (pfrom < from) from = pfrom; /* from = min(from, pfrom) */ 75 if (pl > l) l = pl; /* l = max(l, pl) */ 76 SETARG_A(*previous, from); 77 SETARG_B(*previous, l - from); 78 return; 79 } 80 } /* else go through */ 81 } 82 luaK_codeABC(fs, OP_LOADNIL, from, n - 1, 0); /* else no optimization */ 83 } 84 85 86 /* 87 ** Gets the destination address of a jump instruction. Used to traverse 88 ** a list of jumps. 89 */ 90 static int getjump (FuncState *fs, int pc) { 91 int offset = GETARG_sBx(fs->f->code[pc]); 92 if (offset == NO_JUMP) /* point to itself represents end of list */ 93 return NO_JUMP; /* end of list */ 94 else 95 return (pc+1)+offset; /* turn offset into absolute position */ 96 } 97 98 99 /* 100 ** Fix jump instruction at position 'pc' to jump to 'dest'. 101 ** (Jump addresses are relative in Lua) 102 */ 103 static void fixjump (FuncState *fs, int pc, int dest) { 104 Instruction *jmp = &fs->f->code[pc]; 105 int offset = dest - (pc + 1); 106 lua_assert(dest != NO_JUMP); 107 if (abs(offset) > MAXARG_sBx) 108 luaX_syntaxerror(fs->ls, "control structure too long"); 109 SETARG_sBx(*jmp, offset); 110 } 111 112 113 /* 114 ** Concatenate jump-list 'l2' into jump-list 'l1' 115 */ 116 void luaK_concat (FuncState *fs, int *l1, int l2) { 117 if (l2 == NO_JUMP) return; /* nothing to concatenate? */ 118 else if (*l1 == NO_JUMP) /* no original list? */ 119 *l1 = l2; /* 'l1' points to 'l2' */ 120 else { 121 int list = *l1; 122 int next; 123 while ((next = getjump(fs, list)) != NO_JUMP) /* find last element */ 124 list = next; 125 fixjump(fs, list, l2); /* last element links to 'l2' */ 126 } 127 } 128 129 130 /* 131 ** Create a jump instruction and return its position, so its destination 132 ** can be fixed later (with 'fixjump'). If there are jumps to 133 ** this position (kept in 'jpc'), link them all together so that 134 ** 'patchlistaux' will fix all them directly to the final destination. 135 */ 136 int luaK_jump (FuncState *fs) { 137 int jpc = fs->jpc; /* save list of jumps to here */ 138 int j; 139 fs->jpc = NO_JUMP; /* no more jumps to here */ 140 j = luaK_codeAsBx(fs, OP_JMP, 0, NO_JUMP); 141 luaK_concat(fs, &j, jpc); /* keep them on hold */ 142 return j; 143 } 144 145 146 /* 147 ** Code a 'return' instruction 148 */ 149 void luaK_ret (FuncState *fs, int first, int nret) { 150 luaK_codeABC(fs, OP_RETURN, first, nret+1, 0); 151 } 152 153 154 /* 155 ** Code a "conditional jump", that is, a test or comparison opcode 156 ** followed by a jump. Return jump position. 157 */ 158 static int condjump (FuncState *fs, OpCode op, int A, int B, int C) { 159 luaK_codeABC(fs, op, A, B, C); 160 return luaK_jump(fs); 161 } 162 163 164 /* 165 ** returns current 'pc' and marks it as a jump target (to avoid wrong 166 ** optimizations with consecutive instructions not in the same basic block). 167 */ 168 int luaK_getlabel (FuncState *fs) { 169 fs->lasttarget = fs->pc; 170 return fs->pc; 171 } 172 173 174 /* 175 ** Returns the position of the instruction "controlling" a given 176 ** jump (that is, its condition), or the jump itself if it is 177 ** unconditional. 178 */ 179 static Instruction *getjumpcontrol (FuncState *fs, int pc) { 180 Instruction *pi = &fs->f->code[pc]; 181 if (pc >= 1 && testTMode(GET_OPCODE(*(pi-1)))) 182 return pi-1; 183 else 184 return pi; 185 } 186 187 188 /* 189 ** Patch destination register for a TESTSET instruction. 190 ** If instruction in position 'node' is not a TESTSET, return 0 ("fails"). 191 ** Otherwise, if 'reg' is not 'NO_REG', set it as the destination 192 ** register. Otherwise, change instruction to a simple 'TEST' (produces 193 ** no register value) 194 */ 195 static int patchtestreg (FuncState *fs, int node, int reg) { 196 Instruction *i = getjumpcontrol(fs, node); 197 if (GET_OPCODE(*i) != OP_TESTSET) 198 return 0; /* cannot patch other instructions */ 199 if (reg != NO_REG && reg != GETARG_B(*i)) 200 SETARG_A(*i, reg); 201 else { 202 /* no register to put value or register already has the value; 203 change instruction to simple test */ 204 *i = CREATE_ABC(OP_TEST, GETARG_B(*i), 0, GETARG_C(*i)); 205 } 206 return 1; 207 } 208 209 210 /* 211 ** Traverse a list of tests ensuring no one produces a value 212 */ 213 static void removevalues (FuncState *fs, int list) { 214 for (; list != NO_JUMP; list = getjump(fs, list)) 215 patchtestreg(fs, list, NO_REG); 216 } 217 218 219 /* 220 ** Traverse a list of tests, patching their destination address and 221 ** registers: tests producing values jump to 'vtarget' (and put their 222 ** values in 'reg'), other tests jump to 'dtarget'. 223 */ 224 static void patchlistaux (FuncState *fs, int list, int vtarget, int reg, 225 int dtarget) { 226 while (list != NO_JUMP) { 227 int next = getjump(fs, list); 228 if (patchtestreg(fs, list, reg)) 229 fixjump(fs, list, vtarget); 230 else 231 fixjump(fs, list, dtarget); /* jump to default target */ 232 list = next; 233 } 234 } 235 236 237 /* 238 ** Ensure all pending jumps to current position are fixed (jumping 239 ** to current position with no values) and reset list of pending 240 ** jumps 241 */ 242 static void dischargejpc (FuncState *fs) { 243 patchlistaux(fs, fs->jpc, fs->pc, NO_REG, fs->pc); 244 fs->jpc = NO_JUMP; 245 } 246 247 248 /* 249 ** Add elements in 'list' to list of pending jumps to "here" 250 ** (current position) 251 */ 252 void luaK_patchtohere (FuncState *fs, int list) { 253 luaK_getlabel(fs); /* mark "here" as a jump target */ 254 luaK_concat(fs, &fs->jpc, list); 255 } 256 257 258 /* 259 ** Path all jumps in 'list' to jump to 'target'. 260 ** (The assert means that we cannot fix a jump to a forward address 261 ** because we only know addresses once code is generated.) 262 */ 263 void luaK_patchlist (FuncState *fs, int list, int target) { 264 if (target == fs->pc) /* 'target' is current position? */ 265 luaK_patchtohere(fs, list); /* add list to pending jumps */ 266 else { 267 lua_assert(target < fs->pc); 268 patchlistaux(fs, list, target, NO_REG, target); 269 } 270 } 271 272 273 /* 274 ** Path all jumps in 'list' to close upvalues up to given 'level' 275 ** (The assertion checks that jumps either were closing nothing 276 ** or were closing higher levels, from inner blocks.) 277 */ 278 void luaK_patchclose (FuncState *fs, int list, int level) { 279 level++; /* argument is +1 to reserve 0 as non-op */ 280 for (; list != NO_JUMP; list = getjump(fs, list)) { 281 lua_assert(GET_OPCODE(fs->f->code[list]) == OP_JMP && 282 (GETARG_A(fs->f->code[list]) == 0 || 283 GETARG_A(fs->f->code[list]) >= level)); 284 SETARG_A(fs->f->code[list], level); 285 } 286 } 287 288 289 /* 290 ** Emit instruction 'i', checking for array sizes and saving also its 291 ** line information. Return 'i' position. 292 */ 293 static int luaK_code (FuncState *fs, Instruction i) { 294 Proto *f = fs->f; 295 dischargejpc(fs); /* 'pc' will change */ 296 /* put new instruction in code array */ 297 luaM_growvector(fs->ls->L, f->code, fs->pc, f->sizecode, Instruction, 298 MAX_INT, "opcodes"); 299 f->code[fs->pc] = i; 300 /* save corresponding line information */ 301 luaM_growvector(fs->ls->L, f->lineinfo, fs->pc, f->sizelineinfo, int, 302 MAX_INT, "opcodes"); 303 f->lineinfo[fs->pc] = fs->ls->lastline; 304 return fs->pc++; 305 } 306 307 308 /* 309 ** Format and emit an 'iABC' instruction. (Assertions check consistency 310 ** of parameters versus opcode.) 311 */ 312 int luaK_codeABC (FuncState *fs, OpCode o, int a, int b, int c) { 313 lua_assert(getOpMode(o) == iABC); 314 lua_assert(getBMode(o) != OpArgN || b == 0); 315 lua_assert(getCMode(o) != OpArgN || c == 0); 316 lua_assert(a <= MAXARG_A && b <= MAXARG_B && c <= MAXARG_C); 317 return luaK_code(fs, CREATE_ABC(o, a, b, c)); 318 } 319 320 321 /* 322 ** Format and emit an 'iABx' instruction. 323 */ 324 int luaK_codeABx (FuncState *fs, OpCode o, int a, unsigned int bc) { 325 lua_assert(getOpMode(o) == iABx || getOpMode(o) == iAsBx); 326 lua_assert(getCMode(o) == OpArgN); 327 lua_assert(a <= MAXARG_A && bc <= MAXARG_Bx); 328 return luaK_code(fs, CREATE_ABx(o, a, bc)); 329 } 330 331 332 /* 333 ** Emit an "extra argument" instruction (format 'iAx') 334 */ 335 static int codeextraarg (FuncState *fs, int a) { 336 lua_assert(a <= MAXARG_Ax); 337 return luaK_code(fs, CREATE_Ax(OP_EXTRAARG, a)); 338 } 339 340 341 /* 342 ** Emit a "load constant" instruction, using either 'OP_LOADK' 343 ** (if constant index 'k' fits in 18 bits) or an 'OP_LOADKX' 344 ** instruction with "extra argument". 345 */ 346 int luaK_codek (FuncState *fs, int reg, int k) { 347 if (k <= MAXARG_Bx) 348 return luaK_codeABx(fs, OP_LOADK, reg, k); 349 else { 350 int p = luaK_codeABx(fs, OP_LOADKX, reg, 0); 351 codeextraarg(fs, k); 352 return p; 353 } 354 } 355 356 357 /* 358 ** Check register-stack level, keeping track of its maximum size 359 ** in field 'maxstacksize' 360 */ 361 void luaK_checkstack (FuncState *fs, int n) { 362 int newstack = fs->freereg + n; 363 if (newstack > fs->f->maxstacksize) { 364 if (newstack >= MAXREGS) 365 luaX_syntaxerror(fs->ls, 366 "function or expression needs too many registers"); 367 fs->f->maxstacksize = cast_byte(newstack); 368 } 369 } 370 371 372 /* 373 ** Reserve 'n' registers in register stack 374 */ 375 void luaK_reserveregs (FuncState *fs, int n) { 376 luaK_checkstack(fs, n); 377 fs->freereg += n; 378 } 379 380 381 /* 382 ** Free register 'reg', if it is neither a constant index nor 383 ** a local variable. 384 ) 385 */ 386 static void freereg (FuncState *fs, int reg) { 387 if (!ISK(reg) && reg >= fs->nactvar) { 388 fs->freereg--; 389 lua_assert(reg == fs->freereg); 390 } 391 } 392 393 394 /* 395 ** Free register used by expression 'e' (if any) 396 */ 397 static void freeexp (FuncState *fs, expdesc *e) { 398 if (e->k == VNONRELOC) 399 freereg(fs, e->u.info); 400 } 401 402 403 /* 404 ** Free registers used by expressions 'e1' and 'e2' (if any) in proper 405 ** order. 406 */ 407 static void freeexps (FuncState *fs, expdesc *e1, expdesc *e2) { 408 int r1 = (e1->k == VNONRELOC) ? e1->u.info : -1; 409 int r2 = (e2->k == VNONRELOC) ? e2->u.info : -1; 410 if (r1 > r2) { 411 freereg(fs, r1); 412 freereg(fs, r2); 413 } 414 else { 415 freereg(fs, r2); 416 freereg(fs, r1); 417 } 418 } 419 420 421 /* 422 ** Add constant 'v' to prototype's list of constants (field 'k'). 423 ** Use scanner's table to cache position of constants in constant list 424 ** and try to reuse constants. Because some values should not be used 425 ** as keys (nil cannot be a key, integer keys can collapse with float 426 ** keys), the caller must provide a useful 'key' for indexing the cache. 427 */ 428 static int addk (FuncState *fs, TValue *key, TValue *v) { 429 lua_State *L = fs->ls->L; 430 Proto *f = fs->f; 431 TValue *idx = luaH_set(L, fs->ls->h, key); /* index scanner table */ 432 int k, oldsize; 433 if (ttisinteger(idx)) { /* is there an index there? */ 434 k = cast_int(ivalue(idx)); 435 /* correct value? (warning: must distinguish floats from integers!) */ 436 if (k < fs->nk && ttype(&f->k[k]) == ttype(v) && 437 luaV_rawequalobj(&f->k[k], v)) 438 return k; /* reuse index */ 439 } 440 /* constant not found; create a new entry */ 441 oldsize = f->sizek; 442 k = fs->nk; 443 /* numerical value does not need GC barrier; 444 table has no metatable, so it does not need to invalidate cache */ 445 setivalue(idx, k); 446 luaM_growvector(L, f->k, k, f->sizek, TValue, MAXARG_Ax, "constants"); 447 while (oldsize < f->sizek) setnilvalue(&f->k[oldsize++]); 448 setobj(L, &f->k[k], v); 449 fs->nk++; 450 luaC_barrier(L, f, v); 451 return k; 452 } 453 454 455 /* 456 ** Add a string to list of constants and return its index. 457 */ 458 int luaK_stringK (FuncState *fs, TString *s) { 459 TValue o; 460 setsvalue(fs->ls->L, &o, s); 461 return addk(fs, &o, &o); /* use string itself as key */ 462 } 463 464 465 /* 466 ** Add an integer to list of constants and return its index. 467 ** Integers use userdata as keys to avoid collision with floats with 468 ** same value; conversion to 'void*' is used only for hashing, so there 469 ** are no "precision" problems. 470 */ 471 int luaK_intK (FuncState *fs, lua_Integer n) { 472 TValue k, o; 473 setpvalue(&k, cast(void*, cast(size_t, n))); 474 setivalue(&o, n); 475 return addk(fs, &k, &o); 476 } 477 478 /* 479 ** Add a float to list of constants and return its index. 480 */ 481 static int luaK_numberK (FuncState *fs, lua_Number r) { 482 TValue o; 483 setfltvalue(&o, r); 484 return addk(fs, &o, &o); /* use number itself as key */ 485 } 486 487 488 /* 489 ** Add a boolean to list of constants and return its index. 490 */ 491 static int boolK (FuncState *fs, int b) { 492 TValue o; 493 setbvalue(&o, b); 494 return addk(fs, &o, &o); /* use boolean itself as key */ 495 } 496 497 498 /* 499 ** Add nil to list of constants and return its index. 500 */ 501 static int nilK (FuncState *fs) { 502 TValue k, v; 503 setnilvalue(&v); 504 /* cannot use nil as key; instead use table itself to represent nil */ 505 sethvalue(fs->ls->L, &k, fs->ls->h); 506 return addk(fs, &k, &v); 507 } 508 509 510 /* 511 ** Fix an expression to return the number of results 'nresults'. 512 ** Either 'e' is a multi-ret expression (function call or vararg) 513 ** or 'nresults' is LUA_MULTRET (as any expression can satisfy that). 514 */ 515 void luaK_setreturns (FuncState *fs, expdesc *e, int nresults) { 516 if (e->k == VCALL) { /* expression is an open function call? */ 517 SETARG_C(getinstruction(fs, e), nresults + 1); 518 } 519 else if (e->k == VVARARG) { 520 Instruction *pc = &getinstruction(fs, e); 521 SETARG_B(*pc, nresults + 1); 522 SETARG_A(*pc, fs->freereg); 523 luaK_reserveregs(fs, 1); 524 } 525 else lua_assert(nresults == LUA_MULTRET); 526 } 527 528 529 /* 530 ** Fix an expression to return one result. 531 ** If expression is not a multi-ret expression (function call or 532 ** vararg), it already returns one result, so nothing needs to be done. 533 ** Function calls become VNONRELOC expressions (as its result comes 534 ** fixed in the base register of the call), while vararg expressions 535 ** become VRELOCABLE (as OP_VARARG puts its results where it wants). 536 ** (Calls are created returning one result, so that does not need 537 ** to be fixed.) 538 */ 539 void luaK_setoneret (FuncState *fs, expdesc *e) { 540 if (e->k == VCALL) { /* expression is an open function call? */ 541 /* already returns 1 value */ 542 lua_assert(GETARG_C(getinstruction(fs, e)) == 2); 543 e->k = VNONRELOC; /* result has fixed position */ 544 e->u.info = GETARG_A(getinstruction(fs, e)); 545 } 546 else if (e->k == VVARARG) { 547 SETARG_B(getinstruction(fs, e), 2); 548 e->k = VRELOCABLE; /* can relocate its simple result */ 549 } 550 } 551 552 553 /* 554 ** Ensure that expression 'e' is not a variable. 555 */ 556 void luaK_dischargevars (FuncState *fs, expdesc *e) { 557 switch (e->k) { 558 case VLOCAL: { /* already in a register */ 559 e->k = VNONRELOC; /* becomes a non-relocatable value */ 560 break; 561 } 562 case VUPVAL: { /* move value to some (pending) register */ 563 e->u.info = luaK_codeABC(fs, OP_GETUPVAL, 0, e->u.info, 0); 564 e->k = VRELOCABLE; 565 break; 566 } 567 case VINDEXED: { 568 OpCode op; 569 freereg(fs, e->u.ind.idx); 570 if (e->u.ind.vt == VLOCAL) { /* is 't' in a register? */ 571 freereg(fs, e->u.ind.t); 572 op = OP_GETTABLE; 573 } 574 else { 575 lua_assert(e->u.ind.vt == VUPVAL); 576 op = OP_GETTABUP; /* 't' is in an upvalue */ 577 } 578 e->u.info = luaK_codeABC(fs, op, 0, e->u.ind.t, e->u.ind.idx); 579 e->k = VRELOCABLE; 580 break; 581 } 582 case VVARARG: case VCALL: { 583 luaK_setoneret(fs, e); 584 break; 585 } 586 default: break; /* there is one value available (somewhere) */ 587 } 588 } 589 590 591 /* 592 ** Ensures expression value is in register 'reg' (and therefore 593 ** 'e' will become a non-relocatable expression). 594 */ 595 static void discharge2reg (FuncState *fs, expdesc *e, int reg) { 596 luaK_dischargevars(fs, e); 597 switch (e->k) { 598 case VNIL: { 599 luaK_nil(fs, reg, 1); 600 break; 601 } 602 case VFALSE: case VTRUE: { 603 luaK_codeABC(fs, OP_LOADBOOL, reg, e->k == VTRUE, 0); 604 break; 605 } 606 case VK: { 607 luaK_codek(fs, reg, e->u.info); 608 break; 609 } 610 case VKFLT: { 611 luaK_codek(fs, reg, luaK_numberK(fs, e->u.nval)); 612 break; 613 } 614 case VKINT: { 615 luaK_codek(fs, reg, luaK_intK(fs, e->u.ival)); 616 break; 617 } 618 case VRELOCABLE: { 619 Instruction *pc = &getinstruction(fs, e); 620 SETARG_A(*pc, reg); /* instruction will put result in 'reg' */ 621 break; 622 } 623 case VNONRELOC: { 624 if (reg != e->u.info) 625 luaK_codeABC(fs, OP_MOVE, reg, e->u.info, 0); 626 break; 627 } 628 default: { 629 lua_assert(e->k == VJMP); 630 return; /* nothing to do... */ 631 } 632 } 633 e->u.info = reg; 634 e->k = VNONRELOC; 635 } 636 637 638 /* 639 ** Ensures expression value is in any register. 640 */ 641 static void discharge2anyreg (FuncState *fs, expdesc *e) { 642 if (e->k != VNONRELOC) { /* no fixed register yet? */ 643 luaK_reserveregs(fs, 1); /* get a register */ 644 discharge2reg(fs, e, fs->freereg-1); /* put value there */ 645 } 646 } 647 648 649 static int code_loadbool (FuncState *fs, int A, int b, int jump) { 650 luaK_getlabel(fs); /* those instructions may be jump targets */ 651 return luaK_codeABC(fs, OP_LOADBOOL, A, b, jump); 652 } 653 654 655 /* 656 ** check whether list has any jump that do not produce a value 657 ** or produce an inverted value 658 */ 659 static int need_value (FuncState *fs, int list) { 660 for (; list != NO_JUMP; list = getjump(fs, list)) { 661 Instruction i = *getjumpcontrol(fs, list); 662 if (GET_OPCODE(i) != OP_TESTSET) return 1; 663 } 664 return 0; /* not found */ 665 } 666 667 668 /* 669 ** Ensures final expression result (including results from its jump 670 ** lists) is in register 'reg'. 671 ** If expression has jumps, need to patch these jumps either to 672 ** its final position or to "load" instructions (for those tests 673 ** that do not produce values). 674 */ 675 static void exp2reg (FuncState *fs, expdesc *e, int reg) { 676 discharge2reg(fs, e, reg); 677 if (e->k == VJMP) /* expression itself is a test? */ 678 luaK_concat(fs, &e->t, e->u.info); /* put this jump in 't' list */ 679 if (hasjumps(e)) { 680 int final; /* position after whole expression */ 681 int p_f = NO_JUMP; /* position of an eventual LOAD false */ 682 int p_t = NO_JUMP; /* position of an eventual LOAD true */ 683 if (need_value(fs, e->t) || need_value(fs, e->f)) { 684 int fj = (e->k == VJMP) ? NO_JUMP : luaK_jump(fs); 685 p_f = code_loadbool(fs, reg, 0, 1); 686 p_t = code_loadbool(fs, reg, 1, 0); 687 luaK_patchtohere(fs, fj); 688 } 689 final = luaK_getlabel(fs); 690 patchlistaux(fs, e->f, final, reg, p_f); 691 patchlistaux(fs, e->t, final, reg, p_t); 692 } 693 e->f = e->t = NO_JUMP; 694 e->u.info = reg; 695 e->k = VNONRELOC; 696 } 697 698 699 /* 700 ** Ensures final expression result (including results from its jump 701 ** lists) is in next available register. 702 */ 703 void luaK_exp2nextreg (FuncState *fs, expdesc *e) { 704 luaK_dischargevars(fs, e); 705 freeexp(fs, e); 706 luaK_reserveregs(fs, 1); 707 exp2reg(fs, e, fs->freereg - 1); 708 } 709 710 711 /* 712 ** Ensures final expression result (including results from its jump 713 ** lists) is in some (any) register and return that register. 714 */ 715 int luaK_exp2anyreg (FuncState *fs, expdesc *e) { 716 luaK_dischargevars(fs, e); 717 if (e->k == VNONRELOC) { /* expression already has a register? */ 718 if (!hasjumps(e)) /* no jumps? */ 719 return e->u.info; /* result is already in a register */ 720 if (e->u.info >= fs->nactvar) { /* reg. is not a local? */ 721 exp2reg(fs, e, e->u.info); /* put final result in it */ 722 return e->u.info; 723 } 724 } 725 luaK_exp2nextreg(fs, e); /* otherwise, use next available register */ 726 return e->u.info; 727 } 728 729 730 /* 731 ** Ensures final expression result is either in a register or in an 732 ** upvalue. 733 */ 734 void luaK_exp2anyregup (FuncState *fs, expdesc *e) { 735 if (e->k != VUPVAL || hasjumps(e)) 736 luaK_exp2anyreg(fs, e); 737 } 738 739 740 /* 741 ** Ensures final expression result is either in a register or it is 742 ** a constant. 743 */ 744 void luaK_exp2val (FuncState *fs, expdesc *e) { 745 if (hasjumps(e)) 746 luaK_exp2anyreg(fs, e); 747 else 748 luaK_dischargevars(fs, e); 749 } 750 751 752 /* 753 ** Ensures final expression result is in a valid R/K index 754 ** (that is, it is either in a register or in 'k' with an index 755 ** in the range of R/K indices). 756 ** Returns R/K index. 757 */ 758 int luaK_exp2RK (FuncState *fs, expdesc *e) { 759 luaK_exp2val(fs, e); 760 switch (e->k) { /* move constants to 'k' */ 761 case VTRUE: e->u.info = boolK(fs, 1); goto vk; 762 case VFALSE: e->u.info = boolK(fs, 0); goto vk; 763 case VNIL: e->u.info = nilK(fs); goto vk; 764 case VKINT: e->u.info = luaK_intK(fs, e->u.ival); goto vk; 765 case VKFLT: e->u.info = luaK_numberK(fs, e->u.nval); goto vk; 766 case VK: 767 vk: 768 e->k = VK; 769 if (e->u.info <= MAXINDEXRK) /* constant fits in 'argC'? */ 770 return RKASK(e->u.info); 771 else break; 772 default: break; 773 } 774 /* not a constant in the right range: put it in a register */ 775 return luaK_exp2anyreg(fs, e); 776 } 777 778 779 /* 780 ** Generate code to store result of expression 'ex' into variable 'var'. 781 */ 782 void luaK_storevar (FuncState *fs, expdesc *var, expdesc *ex) { 783 switch (var->k) { 784 case VLOCAL: { 785 freeexp(fs, ex); 786 exp2reg(fs, ex, var->u.info); /* compute 'ex' into proper place */ 787 return; 788 } 789 case VUPVAL: { 790 int e = luaK_exp2anyreg(fs, ex); 791 luaK_codeABC(fs, OP_SETUPVAL, e, var->u.info, 0); 792 break; 793 } 794 case VINDEXED: { 795 OpCode op = (var->u.ind.vt == VLOCAL) ? OP_SETTABLE : OP_SETTABUP; 796 int e = luaK_exp2RK(fs, ex); 797 luaK_codeABC(fs, op, var->u.ind.t, var->u.ind.idx, e); 798 break; 799 } 800 default: lua_assert(0); /* invalid var kind to store */ 801 } 802 freeexp(fs, ex); 803 } 804 805 806 /* 807 ** Emit SELF instruction (convert expression 'e' into 'e:key(e,'). 808 */ 809 void luaK_self (FuncState *fs, expdesc *e, expdesc *key) { 810 int ereg; 811 luaK_exp2anyreg(fs, e); 812 ereg = e->u.info; /* register where 'e' was placed */ 813 freeexp(fs, e); 814 e->u.info = fs->freereg; /* base register for op_self */ 815 e->k = VNONRELOC; /* self expression has a fixed register */ 816 luaK_reserveregs(fs, 2); /* function and 'self' produced by op_self */ 817 luaK_codeABC(fs, OP_SELF, e->u.info, ereg, luaK_exp2RK(fs, key)); 818 freeexp(fs, key); 819 } 820 821 822 /* 823 ** Negate condition 'e' (where 'e' is a comparison). 824 */ 825 static void negatecondition (FuncState *fs, expdesc *e) { 826 Instruction *pc = getjumpcontrol(fs, e->u.info); 827 lua_assert(testTMode(GET_OPCODE(*pc)) && GET_OPCODE(*pc) != OP_TESTSET && 828 GET_OPCODE(*pc) != OP_TEST); 829 SETARG_A(*pc, !(GETARG_A(*pc))); 830 } 831 832 833 /* 834 ** Emit instruction to jump if 'e' is 'cond' (that is, if 'cond' 835 ** is true, code will jump if 'e' is true.) Return jump position. 836 ** Optimize when 'e' is 'not' something, inverting the condition 837 ** and removing the 'not'. 838 */ 839 static int jumponcond (FuncState *fs, expdesc *e, int cond) { 840 if (e->k == VRELOCABLE) { 841 Instruction ie = getinstruction(fs, e); 842 if (GET_OPCODE(ie) == OP_NOT) { 843 fs->pc--; /* remove previous OP_NOT */ 844 return condjump(fs, OP_TEST, GETARG_B(ie), 0, !cond); 845 } 846 /* else go through */ 847 } 848 discharge2anyreg(fs, e); 849 freeexp(fs, e); 850 return condjump(fs, OP_TESTSET, NO_REG, e->u.info, cond); 851 } 852 853 854 /* 855 ** Emit code to go through if 'e' is true, jump otherwise. 856 */ 857 void luaK_goiftrue (FuncState *fs, expdesc *e) { 858 int pc; /* pc of new jump */ 859 luaK_dischargevars(fs, e); 860 switch (e->k) { 861 case VJMP: { /* condition? */ 862 negatecondition(fs, e); /* jump when it is false */ 863 pc = e->u.info; /* save jump position */ 864 break; 865 } 866 case VK: case VKFLT: case VKINT: case VTRUE: { 867 pc = NO_JUMP; /* always true; do nothing */ 868 break; 869 } 870 default: { 871 pc = jumponcond(fs, e, 0); /* jump when false */ 872 break; 873 } 874 } 875 luaK_concat(fs, &e->f, pc); /* insert new jump in false list */ 876 luaK_patchtohere(fs, e->t); /* true list jumps to here (to go through) */ 877 e->t = NO_JUMP; 878 } 879 880 881 /* 882 ** Emit code to go through if 'e' is false, jump otherwise. 883 */ 884 void luaK_goiffalse (FuncState *fs, expdesc *e) { 885 int pc; /* pc of new jump */ 886 luaK_dischargevars(fs, e); 887 switch (e->k) { 888 case VJMP: { 889 pc = e->u.info; /* already jump if true */ 890 break; 891 } 892 case VNIL: case VFALSE: { 893 pc = NO_JUMP; /* always false; do nothing */ 894 break; 895 } 896 default: { 897 pc = jumponcond(fs, e, 1); /* jump if true */ 898 break; 899 } 900 } 901 luaK_concat(fs, &e->t, pc); /* insert new jump in 't' list */ 902 luaK_patchtohere(fs, e->f); /* false list jumps to here (to go through) */ 903 e->f = NO_JUMP; 904 } 905 906 907 /* 908 ** Code 'not e', doing constant folding. 909 */ 910 static void codenot (FuncState *fs, expdesc *e) { 911 luaK_dischargevars(fs, e); 912 switch (e->k) { 913 case VNIL: case VFALSE: { 914 e->k = VTRUE; /* true == not nil == not false */ 915 break; 916 } 917 case VK: case VKFLT: case VKINT: case VTRUE: { 918 e->k = VFALSE; /* false == not "x" == not 0.5 == not 1 == not true */ 919 break; 920 } 921 case VJMP: { 922 negatecondition(fs, e); 923 break; 924 } 925 case VRELOCABLE: 926 case VNONRELOC: { 927 discharge2anyreg(fs, e); 928 freeexp(fs, e); 929 e->u.info = luaK_codeABC(fs, OP_NOT, 0, e->u.info, 0); 930 e->k = VRELOCABLE; 931 break; 932 } 933 default: lua_assert(0); /* cannot happen */ 934 } 935 /* interchange true and false lists */ 936 { int temp = e->f; e->f = e->t; e->t = temp; } 937 removevalues(fs, e->f); /* values are useless when negated */ 938 removevalues(fs, e->t); 939 } 940 941 942 /* 943 ** Create expression 't[k]'. 't' must have its final result already in a 944 ** register or upvalue. 945 */ 946 void luaK_indexed (FuncState *fs, expdesc *t, expdesc *k) { 947 lua_assert(!hasjumps(t) && (vkisinreg(t->k) || t->k == VUPVAL)); 948 t->u.ind.t = t->u.info; /* register or upvalue index */ 949 t->u.ind.idx = luaK_exp2RK(fs, k); /* R/K index for key */ 950 t->u.ind.vt = (t->k == VUPVAL) ? VUPVAL : VLOCAL; 951 t->k = VINDEXED; 952 } 953 954 955 /* 956 ** Return false if folding can raise an error. 957 ** Bitwise operations need operands convertible to integers; division 958 ** operations cannot have 0 as divisor. 959 */ 960 static int validop (int op, TValue *v1, TValue *v2) { 961 switch (op) { 962 case LUA_OPBAND: case LUA_OPBOR: case LUA_OPBXOR: 963 case LUA_OPSHL: case LUA_OPSHR: case LUA_OPBNOT: { /* conversion errors */ 964 lua_Integer i; 965 return (tointeger(v1, &i) && tointeger(v2, &i)); 966 } 967 case LUA_OPDIV: case LUA_OPIDIV: case LUA_OPMOD: /* division by 0 */ 968 return (nvalue(v2) != 0); 969 default: return 1; /* everything else is valid */ 970 } 971 } 972 973 974 /* 975 ** Try to "constant-fold" an operation; return 1 iff successful. 976 ** (In this case, 'e1' has the final result.) 977 */ 978 static int constfolding (FuncState *fs, int op, expdesc *e1, 979 const expdesc *e2) { 980 TValue v1, v2, res; 981 if (!tonumeral(e1, &v1) || !tonumeral(e2, &v2) || !validop(op, &v1, &v2)) 982 return 0; /* non-numeric operands or not safe to fold */ 983 luaO_arith(fs->ls->L, op, &v1, &v2, &res); /* does operation */ 984 if (ttisinteger(&res)) { 985 e1->k = VKINT; 986 e1->u.ival = ivalue(&res); 987 } 988 else { /* folds neither NaN nor 0.0 (to avoid problems with -0.0) */ 989 lua_Number n = fltvalue(&res); 990 if (luai_numisnan(n) || n == 0) 991 return 0; 992 e1->k = VKFLT; 993 e1->u.nval = n; 994 } 995 return 1; 996 } 997 998 999 /* 1000 ** Emit code for unary expressions that "produce values" 1001 ** (everything but 'not'). 1002 ** Expression to produce final result will be encoded in 'e'. 1003 */ 1004 static void codeunexpval (FuncState *fs, OpCode op, expdesc *e, int line) { 1005 int r = luaK_exp2anyreg(fs, e); /* opcodes operate only on registers */ 1006 freeexp(fs, e); 1007 e->u.info = luaK_codeABC(fs, op, 0, r, 0); /* generate opcode */ 1008 e->k = VRELOCABLE; /* all those operations are relocatable */ 1009 luaK_fixline(fs, line); 1010 } 1011 1012 1013 /* 1014 ** Emit code for binary expressions that "produce values" 1015 ** (everything but logical operators 'and'/'or' and comparison 1016 ** operators). 1017 ** Expression to produce final result will be encoded in 'e1'. 1018 ** Because 'luaK_exp2RK' can free registers, its calls must be 1019 ** in "stack order" (that is, first on 'e2', which may have more 1020 ** recent registers to be released). 1021 */ 1022 static void codebinexpval (FuncState *fs, OpCode op, 1023 expdesc *e1, expdesc *e2, int line) { 1024 int rk2 = luaK_exp2RK(fs, e2); /* both operands are "RK" */ 1025 int rk1 = luaK_exp2RK(fs, e1); 1026 freeexps(fs, e1, e2); 1027 e1->u.info = luaK_codeABC(fs, op, 0, rk1, rk2); /* generate opcode */ 1028 e1->k = VRELOCABLE; /* all those operations are relocatable */ 1029 luaK_fixline(fs, line); 1030 } 1031 1032 1033 /* 1034 ** Emit code for comparisons. 1035 ** 'e1' was already put in R/K form by 'luaK_infix'. 1036 */ 1037 static void codecomp (FuncState *fs, BinOpr opr, expdesc *e1, expdesc *e2) { 1038 int rk1 = (e1->k == VK) ? RKASK(e1->u.info) 1039 : check_exp(e1->k == VNONRELOC, e1->u.info); 1040 int rk2 = luaK_exp2RK(fs, e2); 1041 freeexps(fs, e1, e2); 1042 switch (opr) { 1043 case OPR_NE: { /* '(a ~= b)' ==> 'not (a == b)' */ 1044 e1->u.info = condjump(fs, OP_EQ, 0, rk1, rk2); 1045 break; 1046 } 1047 case OPR_GT: case OPR_GE: { 1048 /* '(a > b)' ==> '(b < a)'; '(a >= b)' ==> '(b <= a)' */ 1049 OpCode op = cast(OpCode, (opr - OPR_NE) + OP_EQ); 1050 e1->u.info = condjump(fs, op, 1, rk2, rk1); /* invert operands */ 1051 break; 1052 } 1053 default: { /* '==', '<', '<=' use their own opcodes */ 1054 OpCode op = cast(OpCode, (opr - OPR_EQ) + OP_EQ); 1055 e1->u.info = condjump(fs, op, 1, rk1, rk2); 1056 break; 1057 } 1058 } 1059 e1->k = VJMP; 1060 } 1061 1062 1063 /* 1064 ** Apply prefix operation 'op' to expression 'e'. 1065 */ 1066 void luaK_prefix (FuncState *fs, UnOpr op, expdesc *e, int line) { 1067 static const expdesc ef = {VKINT, {0}, NO_JUMP, NO_JUMP}; 1068 switch (op) { 1069 case OPR_MINUS: case OPR_BNOT: /* use 'ef' as fake 2nd operand */ 1070 if (constfolding(fs, op + LUA_OPUNM, e, &ef)) 1071 break; 1072 /* FALLTHROUGH */ 1073 case OPR_LEN: 1074 codeunexpval(fs, cast(OpCode, op + OP_UNM), e, line); 1075 break; 1076 case OPR_NOT: codenot(fs, e); break; 1077 default: lua_assert(0); 1078 } 1079 } 1080 1081 1082 /* 1083 ** Process 1st operand 'v' of binary operation 'op' before reading 1084 ** 2nd operand. 1085 */ 1086 void luaK_infix (FuncState *fs, BinOpr op, expdesc *v) { 1087 switch (op) { 1088 case OPR_AND: { 1089 luaK_goiftrue(fs, v); /* go ahead only if 'v' is true */ 1090 break; 1091 } 1092 case OPR_OR: { 1093 luaK_goiffalse(fs, v); /* go ahead only if 'v' is false */ 1094 break; 1095 } 1096 case OPR_CONCAT: { 1097 luaK_exp2nextreg(fs, v); /* operand must be on the 'stack' */ 1098 break; 1099 } 1100 case OPR_ADD: case OPR_SUB: 1101 case OPR_MUL: case OPR_DIV: case OPR_IDIV: 1102 case OPR_MOD: case OPR_POW: 1103 case OPR_BAND: case OPR_BOR: case OPR_BXOR: 1104 case OPR_SHL: case OPR_SHR: { 1105 if (!tonumeral(v, NULL)) 1106 luaK_exp2RK(fs, v); 1107 /* else keep numeral, which may be folded with 2nd operand */ 1108 break; 1109 } 1110 default: { 1111 luaK_exp2RK(fs, v); 1112 break; 1113 } 1114 } 1115 } 1116 1117 1118 /* 1119 ** Finalize code for binary operation, after reading 2nd operand. 1120 ** For '(a .. b .. c)' (which is '(a .. (b .. c))', because 1121 ** concatenation is right associative), merge second CONCAT into first 1122 ** one. 1123 */ 1124 void luaK_posfix (FuncState *fs, BinOpr op, 1125 expdesc *e1, expdesc *e2, int line) { 1126 switch (op) { 1127 case OPR_AND: { 1128 lua_assert(e1->t == NO_JUMP); /* list closed by 'luK_infix' */ 1129 luaK_dischargevars(fs, e2); 1130 luaK_concat(fs, &e2->f, e1->f); 1131 *e1 = *e2; 1132 break; 1133 } 1134 case OPR_OR: { 1135 lua_assert(e1->f == NO_JUMP); /* list closed by 'luK_infix' */ 1136 luaK_dischargevars(fs, e2); 1137 luaK_concat(fs, &e2->t, e1->t); 1138 *e1 = *e2; 1139 break; 1140 } 1141 case OPR_CONCAT: { 1142 luaK_exp2val(fs, e2); 1143 if (e2->k == VRELOCABLE && 1144 GET_OPCODE(getinstruction(fs, e2)) == OP_CONCAT) { 1145 lua_assert(e1->u.info == GETARG_B(getinstruction(fs, e2))-1); 1146 freeexp(fs, e1); 1147 SETARG_B(getinstruction(fs, e2), e1->u.info); 1148 e1->k = VRELOCABLE; e1->u.info = e2->u.info; 1149 } 1150 else { 1151 luaK_exp2nextreg(fs, e2); /* operand must be on the 'stack' */ 1152 codebinexpval(fs, OP_CONCAT, e1, e2, line); 1153 } 1154 break; 1155 } 1156 case OPR_ADD: case OPR_SUB: case OPR_MUL: case OPR_DIV: 1157 case OPR_IDIV: case OPR_MOD: case OPR_POW: 1158 case OPR_BAND: case OPR_BOR: case OPR_BXOR: 1159 case OPR_SHL: case OPR_SHR: { 1160 if (!constfolding(fs, op + LUA_OPADD, e1, e2)) 1161 codebinexpval(fs, cast(OpCode, op + OP_ADD), e1, e2, line); 1162 break; 1163 } 1164 case OPR_EQ: case OPR_LT: case OPR_LE: 1165 case OPR_NE: case OPR_GT: case OPR_GE: { 1166 codecomp(fs, op, e1, e2); 1167 break; 1168 } 1169 default: lua_assert(0); 1170 } 1171 } 1172 1173 1174 /* 1175 ** Change line information associated with current position. 1176 */ 1177 void luaK_fixline (FuncState *fs, int line) { 1178 fs->f->lineinfo[fs->pc - 1] = line; 1179 } 1180 1181 1182 /* 1183 ** Emit a SETLIST instruction. 1184 ** 'base' is register that keeps table; 1185 ** 'nelems' is #table plus those to be stored now; 1186 ** 'tostore' is number of values (in registers 'base + 1',...) to add to 1187 ** table (or LUA_MULTRET to add up to stack top). 1188 */ 1189 void luaK_setlist (FuncState *fs, int base, int nelems, int tostore) { 1190 int c = (nelems - 1)/LFIELDS_PER_FLUSH + 1; 1191 int b = (tostore == LUA_MULTRET) ? 0 : tostore; 1192 lua_assert(tostore != 0 && tostore <= LFIELDS_PER_FLUSH); 1193 if (c <= MAXARG_C) 1194 luaK_codeABC(fs, OP_SETLIST, base, b, c); 1195 else if (c <= MAXARG_Ax) { 1196 luaK_codeABC(fs, OP_SETLIST, base, b, 0); 1197 codeextraarg(fs, c); 1198 } 1199 else 1200 luaX_syntaxerror(fs->ls, "constructor too long"); 1201 fs->freereg = base + 1; /* free registers with list values */ 1202 } 1203 1204