/* ** Lua parser (source code -> bytecode). ** Copyright (C) 2005-2016 Mike Pall. See Copyright Notice in luajit.h ** ** Major portions taken verbatim or adapted from the Lua interpreter. ** Copyright (C) 1994-2008 Lua.org, PUC-Rio. See Copyright Notice in lua.h */ #define lj_parse_c #define LUA_CORE #include "lj_obj.h" #include "lj_gc.h" #include "lj_err.h" #include "lj_debug.h" #include "lj_buf.h" #include "lj_str.h" #include "lj_tab.h" #include "lj_func.h" #include "lj_state.h" #include "lj_bc.h" #if LJ_HASFFI #include "lj_ctype.h" #endif #include "lj_strfmt.h" #include "lj_lex.h" #include "lj_parse.h" #include "lj_vm.h" #include "lj_vmevent.h" /* -- Parser structures and definitions ----------------------------------- */ /* Expression kinds. */ typedef enum { /* Constant expressions must be first and in this order: */ VKNIL, VKFALSE, VKTRUE, VKSTR, /* sval = string value */ VKNUM, /* nval = number value */ VKLAST = VKNUM, VKCDATA, /* nval = cdata value, not treated as a constant expression */ /* Non-constant expressions follow: */ VLOCAL, /* info = local register, aux = vstack index */ VUPVAL, /* info = upvalue index, aux = vstack index */ VGLOBAL, /* sval = string value */ VINDEXED, /* info = table register, aux = index reg/byte/string const */ VJMP, /* info = instruction PC */ VRELOCABLE, /* info = instruction PC */ VNONRELOC, /* info = result register */ VCALL, /* info = instruction PC, aux = base */ VVOID } ExpKind; /* Expression descriptor. */ typedef struct ExpDesc { union { struct { uint32_t info; /* Primary info. */ uint32_t aux; /* Secondary info. */ } s; TValue nval; /* Number value. */ GCstr *sval; /* String value. */ } u; ExpKind k; BCPos t; /* True condition jump list. */ BCPos f; /* False condition jump list. */ } ExpDesc; /* Macros for expressions. */ #define expr_hasjump(e) ((e)->t != (e)->f) #define expr_isk(e) ((e)->k <= VKLAST) #define expr_isk_nojump(e) (expr_isk(e) && !expr_hasjump(e)) #define expr_isnumk(e) ((e)->k == VKNUM) #define expr_isnumk_nojump(e) (expr_isnumk(e) && !expr_hasjump(e)) #define expr_isstrk(e) ((e)->k == VKSTR) #define expr_numtv(e) check_exp(expr_isnumk((e)), &(e)->u.nval) #define expr_numberV(e) numberVnum(expr_numtv((e))) /* Initialize expression. */ static LJ_AINLINE void expr_init(ExpDesc *e, ExpKind k, uint32_t info) { e->k = k; e->u.s.info = info; e->f = e->t = NO_JMP; } /* Check number constant for +-0. */ static int expr_numiszero(ExpDesc *e) { TValue *o = expr_numtv(e); return tvisint(o) ? (intV(o) == 0) : tviszero(o); } /* Per-function linked list of scope blocks. */ typedef struct FuncScope { struct FuncScope *prev; /* Link to outer scope. */ MSize vstart; /* Start of block-local variables. */ uint8_t nactvar; /* Number of active vars outside the scope. */ uint8_t flags; /* Scope flags. */ } FuncScope; #define FSCOPE_LOOP 0x01 /* Scope is a (breakable) loop. */ #define FSCOPE_BREAK 0x02 /* Break used in scope. */ #define FSCOPE_GOLA 0x04 /* Goto or label used in scope. */ #define FSCOPE_UPVAL 0x08 /* Upvalue in scope. */ #define FSCOPE_NOCLOSE 0x10 /* Do not close upvalues. */ #define NAME_BREAK ((GCstr *)(uintptr_t)1) /* Index into variable stack. */ typedef uint16_t VarIndex; #define LJ_MAX_VSTACK (65536 - LJ_MAX_UPVAL) /* Variable/goto/label info. */ #define VSTACK_VAR_RW 0x01 /* R/W variable. */ #define VSTACK_GOTO 0x02 /* Pending goto. */ #define VSTACK_LABEL 0x04 /* Label. */ /* Per-function state. */ typedef struct FuncState { GCtab *kt; /* Hash table for constants. */ LexState *ls; /* Lexer state. */ lua_State *L; /* Lua state. */ FuncScope *bl; /* Current scope. */ struct FuncState *prev; /* Enclosing function. */ BCPos pc; /* Next bytecode position. */ BCPos lasttarget; /* Bytecode position of last jump target. */ BCPos jpc; /* Pending jump list to next bytecode. */ BCReg freereg; /* First free register. */ BCReg nactvar; /* Number of active local variables. */ BCReg nkn, nkgc; /* Number of lua_Number/GCobj constants */ BCLine linedefined; /* First line of the function definition. */ BCInsLine *bcbase; /* Base of bytecode stack. */ BCPos bclim; /* Limit of bytecode stack. */ MSize vbase; /* Base of variable stack for this function. */ uint8_t flags; /* Prototype flags. */ uint8_t numparams; /* Number of parameters. */ uint8_t framesize; /* Fixed frame size. */ uint8_t nuv; /* Number of upvalues */ VarIndex varmap[LJ_MAX_LOCVAR]; /* Map from register to variable idx. */ VarIndex uvmap[LJ_MAX_UPVAL]; /* Map from upvalue to variable idx. */ VarIndex uvtmp[LJ_MAX_UPVAL]; /* Temporary upvalue map. */ } FuncState; /* Binary and unary operators. ORDER OPR */ typedef enum BinOpr { OPR_ADD, OPR_SUB, OPR_MUL, OPR_DIV, OPR_MOD, OPR_POW, /* ORDER ARITH */ OPR_CONCAT, OPR_NE, OPR_EQ, OPR_LT, OPR_GE, OPR_LE, OPR_GT, OPR_AND, OPR_OR, OPR_NOBINOPR } BinOpr; LJ_STATIC_ASSERT((int)BC_ISGE-(int)BC_ISLT == (int)OPR_GE-(int)OPR_LT); LJ_STATIC_ASSERT((int)BC_ISLE-(int)BC_ISLT == (int)OPR_LE-(int)OPR_LT); LJ_STATIC_ASSERT((int)BC_ISGT-(int)BC_ISLT == (int)OPR_GT-(int)OPR_LT); LJ_STATIC_ASSERT((int)BC_SUBVV-(int)BC_ADDVV == (int)OPR_SUB-(int)OPR_ADD); LJ_STATIC_ASSERT((int)BC_MULVV-(int)BC_ADDVV == (int)OPR_MUL-(int)OPR_ADD); LJ_STATIC_ASSERT((int)BC_DIVVV-(int)BC_ADDVV == (int)OPR_DIV-(int)OPR_ADD); LJ_STATIC_ASSERT((int)BC_MODVV-(int)BC_ADDVV == (int)OPR_MOD-(int)OPR_ADD); /* -- Error handling ------------------------------------------------------ */ LJ_NORET LJ_NOINLINE static void err_syntax(LexState *ls, ErrMsg em) { lj_lex_error(ls, ls->tok, em); } LJ_NORET LJ_NOINLINE static void err_token(LexState *ls, LexToken tok) { lj_lex_error(ls, ls->tok, LJ_ERR_XTOKEN, lj_lex_token2str(ls, tok)); } LJ_NORET static void err_limit(FuncState *fs, uint32_t limit, const char *what) { if (fs->linedefined == 0) lj_lex_error(fs->ls, 0, LJ_ERR_XLIMM, limit, what); else lj_lex_error(fs->ls, 0, LJ_ERR_XLIMF, fs->linedefined, limit, what); } #define checklimit(fs, v, l, m) if ((v) >= (l)) err_limit(fs, l, m) #define checklimitgt(fs, v, l, m) if ((v) > (l)) err_limit(fs, l, m) #define checkcond(ls, c, em) { if (!(c)) err_syntax(ls, em); } /* -- Management of constants --------------------------------------------- */ /* Return bytecode encoding for primitive constant. */ #define const_pri(e) check_exp((e)->k <= VKTRUE, (e)->k) #define tvhaskslot(o) ((o)->u32.hi == 0) #define tvkslot(o) ((o)->u32.lo) /* Add a number constant. */ static BCReg const_num(FuncState *fs, ExpDesc *e) { lua_State *L = fs->L; TValue *o; lua_assert(expr_isnumk(e)); o = lj_tab_set(L, fs->kt, &e->u.nval); if (tvhaskslot(o)) return tvkslot(o); o->u64 = fs->nkn; return fs->nkn++; } /* Add a GC object constant. */ static BCReg const_gc(FuncState *fs, GCobj *gc, uint32_t itype) { lua_State *L = fs->L; TValue key, *o; setgcV(L, &key, gc, itype); /* NOBARRIER: the key is new or kept alive. */ o = lj_tab_set(L, fs->kt, &key); if (tvhaskslot(o)) return tvkslot(o); o->u64 = fs->nkgc; return fs->nkgc++; } /* Add a string constant. */ static BCReg const_str(FuncState *fs, ExpDesc *e) { lua_assert(expr_isstrk(e) || e->k == VGLOBAL); return const_gc(fs, obj2gco(e->u.sval), LJ_TSTR); } /* Anchor string constant to avoid GC. */ GCstr *lj_parse_keepstr(LexState *ls, const char *str, size_t len) { /* NOBARRIER: the key is new or kept alive. */ lua_State *L = ls->L; GCstr *s = lj_str_new(L, str, len); TValue *tv = lj_tab_setstr(L, ls->fs->kt, s); if (tvisnil(tv)) setboolV(tv, 1); lj_gc_check(L); return s; } #if LJ_HASFFI /* Anchor cdata to avoid GC. */ void lj_parse_keepcdata(LexState *ls, TValue *tv, GCcdata *cd) { /* NOBARRIER: the key is new or kept alive. */ lua_State *L = ls->L; setcdataV(L, tv, cd); setboolV(lj_tab_set(L, ls->fs->kt, tv), 1); } #endif /* -- Jump list handling -------------------------------------------------- */ /* Get next element in jump list. */ static BCPos jmp_next(FuncState *fs, BCPos pc) { ptrdiff_t delta = bc_j(fs->bcbase[pc].ins); if ((BCPos)delta == NO_JMP) return NO_JMP; else return (BCPos)(((ptrdiff_t)pc+1)+delta); } /* Check if any of the instructions on the jump list produce no value. */ static int jmp_novalue(FuncState *fs, BCPos list) { for (; list != NO_JMP; list = jmp_next(fs, list)) { BCIns p = fs->bcbase[list >= 1 ? list-1 : list].ins; if (!(bc_op(p) == BC_ISTC || bc_op(p) == BC_ISFC || bc_a(p) == NO_REG)) return 1; } return 0; } /* Patch register of test instructions. */ static int jmp_patchtestreg(FuncState *fs, BCPos pc, BCReg reg) { BCInsLine *ilp = &fs->bcbase[pc >= 1 ? pc-1 : pc]; BCOp op = bc_op(ilp->ins); if (op == BC_ISTC || op == BC_ISFC) { if (reg != NO_REG && reg != bc_d(ilp->ins)) { setbc_a(&ilp->ins, reg); } else { /* Nothing to store or already in the right register. */ setbc_op(&ilp->ins, op+(BC_IST-BC_ISTC)); setbc_a(&ilp->ins, 0); } } else if (bc_a(ilp->ins) == NO_REG) { if (reg == NO_REG) { ilp->ins = BCINS_AJ(BC_JMP, bc_a(fs->bcbase[pc].ins), 0); } else { setbc_a(&ilp->ins, reg); if (reg >= bc_a(ilp[1].ins)) setbc_a(&ilp[1].ins, reg+1); } } else { return 0; /* Cannot patch other instructions. */ } return 1; } /* Drop values for all instructions on jump list. */ static void jmp_dropval(FuncState *fs, BCPos list) { for (; list != NO_JMP; list = jmp_next(fs, list)) jmp_patchtestreg(fs, list, NO_REG); } /* Patch jump instruction to target. */ static void jmp_patchins(FuncState *fs, BCPos pc, BCPos dest) { BCIns *jmp = &fs->bcbase[pc].ins; BCPos offset = dest-(pc+1)+BCBIAS_J; lua_assert(dest != NO_JMP); if (offset > BCMAX_D) err_syntax(fs->ls, LJ_ERR_XJUMP); setbc_d(jmp, offset); } /* Append to jump list. */ static void jmp_append(FuncState *fs, BCPos *l1, BCPos l2) { if (l2 == NO_JMP) { return; } else if (*l1 == NO_JMP) { *l1 = l2; } else { BCPos list = *l1; BCPos next; while ((next = jmp_next(fs, list)) != NO_JMP) /* Find last element. */ list = next; jmp_patchins(fs, list, l2); } } /* Patch jump list and preserve produced values. */ static void jmp_patchval(FuncState *fs, BCPos list, BCPos vtarget, BCReg reg, BCPos dtarget) { while (list != NO_JMP) { BCPos next = jmp_next(fs, list); if (jmp_patchtestreg(fs, list, reg)) jmp_patchins(fs, list, vtarget); /* Jump to target with value. */ else jmp_patchins(fs, list, dtarget); /* Jump to default target. */ list = next; } } /* Jump to following instruction. Append to list of pending jumps. */ static void jmp_tohere(FuncState *fs, BCPos list) { fs->lasttarget = fs->pc; jmp_append(fs, &fs->jpc, list); } /* Patch jump list to target. */ static void jmp_patch(FuncState *fs, BCPos list, BCPos target) { if (target == fs->pc) { jmp_tohere(fs, list); } else { lua_assert(target < fs->pc); jmp_patchval(fs, list, target, NO_REG, target); } } /* -- Bytecode register allocator ----------------------------------------- */ /* Bump frame size. */ static void bcreg_bump(FuncState *fs, BCReg n) { BCReg sz = fs->freereg + n; if (sz > fs->framesize) { if (sz >= LJ_MAX_SLOTS) err_syntax(fs->ls, LJ_ERR_XSLOTS); fs->framesize = (uint8_t)sz; } } /* Reserve registers. */ static void bcreg_reserve(FuncState *fs, BCReg n) { bcreg_bump(fs, n); fs->freereg += n; } /* Free register. */ static void bcreg_free(FuncState *fs, BCReg reg) { if (reg >= fs->nactvar) { fs->freereg--; lua_assert(reg == fs->freereg); } } /* Free register for expression. */ static void expr_free(FuncState *fs, ExpDesc *e) { if (e->k == VNONRELOC) bcreg_free(fs, e->u.s.info); } /* -- Bytecode emitter ---------------------------------------------------- */ /* Emit bytecode instruction. */ static BCPos bcemit_INS(FuncState *fs, BCIns ins) { BCPos pc = fs->pc; LexState *ls = fs->ls; jmp_patchval(fs, fs->jpc, pc, NO_REG, pc); fs->jpc = NO_JMP; if (LJ_UNLIKELY(pc >= fs->bclim)) { ptrdiff_t base = fs->bcbase - ls->bcstack; checklimit(fs, ls->sizebcstack, LJ_MAX_BCINS, "bytecode instructions"); lj_mem_growvec(fs->L, ls->bcstack, ls->sizebcstack, LJ_MAX_BCINS,BCInsLine); fs->bclim = (BCPos)(ls->sizebcstack - base); fs->bcbase = ls->bcstack + base; } fs->bcbase[pc].ins = ins; fs->bcbase[pc].line = ls->lastline; fs->pc = pc+1; return pc; } #define bcemit_ABC(fs, o, a, b, c) bcemit_INS(fs, BCINS_ABC(o, a, b, c)) #define bcemit_AD(fs, o, a, d) bcemit_INS(fs, BCINS_AD(o, a, d)) #define bcemit_AJ(fs, o, a, j) bcemit_INS(fs, BCINS_AJ(o, a, j)) #define bcptr(fs, e) (&(fs)->bcbase[(e)->u.s.info].ins) /* -- Bytecode emitter for expressions ------------------------------------ */ /* Discharge non-constant expression to any register. */ static void expr_discharge(FuncState *fs, ExpDesc *e) { BCIns ins; if (e->k == VUPVAL) { ins = BCINS_AD(BC_UGET, 0, e->u.s.info); } else if (e->k == VGLOBAL) { ins = BCINS_AD(BC_GGET, 0, const_str(fs, e)); } else if (e->k == VINDEXED) { BCReg rc = e->u.s.aux; if ((int32_t)rc < 0) { ins = BCINS_ABC(BC_TGETS, 0, e->u.s.info, ~rc); } else if (rc > BCMAX_C) { ins = BCINS_ABC(BC_TGETB, 0, e->u.s.info, rc-(BCMAX_C+1)); } else { bcreg_free(fs, rc); ins = BCINS_ABC(BC_TGETV, 0, e->u.s.info, rc); } bcreg_free(fs, e->u.s.info); } else if (e->k == VCALL) { e->u.s.info = e->u.s.aux; e->k = VNONRELOC; return; } else if (e->k == VLOCAL) { e->k = VNONRELOC; return; } else { return; } e->u.s.info = bcemit_INS(fs, ins); e->k = VRELOCABLE; } /* Emit bytecode to set a range of registers to nil. */ static void bcemit_nil(FuncState *fs, BCReg from, BCReg n) { if (fs->pc > fs->lasttarget) { /* No jumps to current position? */ BCIns *ip = &fs->bcbase[fs->pc-1].ins; BCReg pto, pfrom = bc_a(*ip); switch (bc_op(*ip)) { /* Try to merge with the previous instruction. */ case BC_KPRI: if (bc_d(*ip) != ~LJ_TNIL) break; if (from == pfrom) { if (n == 1) return; } else if (from == pfrom+1) { from = pfrom; n++; } else { break; } *ip = BCINS_AD(BC_KNIL, from, from+n-1); /* Replace KPRI. */ return; case BC_KNIL: pto = bc_d(*ip); if (pfrom <= from && from <= pto+1) { /* Can we connect both ranges? */ if (from+n-1 > pto) setbc_d(ip, from+n-1); /* Patch previous instruction range. */ return; } break; default: break; } } /* Emit new instruction or replace old instruction. */ bcemit_INS(fs, n == 1 ? BCINS_AD(BC_KPRI, from, VKNIL) : BCINS_AD(BC_KNIL, from, from+n-1)); } /* Discharge an expression to a specific register. Ignore branches. */ static void expr_toreg_nobranch(FuncState *fs, ExpDesc *e, BCReg reg) { BCIns ins; expr_discharge(fs, e); if (e->k == VKSTR) { ins = BCINS_AD(BC_KSTR, reg, const_str(fs, e)); } else if (e->k == VKNUM) { #if LJ_DUALNUM cTValue *tv = expr_numtv(e); if (tvisint(tv) && checki16(intV(tv))) ins = BCINS_AD(BC_KSHORT, reg, (BCReg)(uint16_t)intV(tv)); else #else lua_Number n = expr_numberV(e); int32_t k = lj_num2int(n); if (checki16(k) && n == (lua_Number)k) ins = BCINS_AD(BC_KSHORT, reg, (BCReg)(uint16_t)k); else #endif ins = BCINS_AD(BC_KNUM, reg, const_num(fs, e)); #if LJ_HASFFI } else if (e->k == VKCDATA) { fs->flags |= PROTO_FFI; ins = BCINS_AD(BC_KCDATA, reg, const_gc(fs, obj2gco(cdataV(&e->u.nval)), LJ_TCDATA)); #endif } else if (e->k == VRELOCABLE) { setbc_a(bcptr(fs, e), reg); goto noins; } else if (e->k == VNONRELOC) { if (reg == e->u.s.info) goto noins; ins = BCINS_AD(BC_MOV, reg, e->u.s.info); } else if (e->k == VKNIL) { bcemit_nil(fs, reg, 1); goto noins; } else if (e->k <= VKTRUE) { ins = BCINS_AD(BC_KPRI, reg, const_pri(e)); } else { lua_assert(e->k == VVOID || e->k == VJMP); return; } bcemit_INS(fs, ins); noins: e->u.s.info = reg; e->k = VNONRELOC; } /* Forward declaration. */ static BCPos bcemit_jmp(FuncState *fs); /* Discharge an expression to a specific register. */ static void expr_toreg(FuncState *fs, ExpDesc *e, BCReg reg) { expr_toreg_nobranch(fs, e, reg); if (e->k == VJMP) jmp_append(fs, &e->t, e->u.s.info); /* Add it to the true jump list. */ if (expr_hasjump(e)) { /* Discharge expression with branches. */ BCPos jend, jfalse = NO_JMP, jtrue = NO_JMP; if (jmp_novalue(fs, e->t) || jmp_novalue(fs, e->f)) { BCPos jval = (e->k == VJMP) ? NO_JMP : bcemit_jmp(fs); jfalse = bcemit_AD(fs, BC_KPRI, reg, VKFALSE); bcemit_AJ(fs, BC_JMP, fs->freereg, 1); jtrue = bcemit_AD(fs, BC_KPRI, reg, VKTRUE); jmp_tohere(fs, jval); } jend = fs->pc; fs->lasttarget = jend; jmp_patchval(fs, e->f, jend, reg, jfalse); jmp_patchval(fs, e->t, jend, reg, jtrue); } e->f = e->t = NO_JMP; e->u.s.info = reg; e->k = VNONRELOC; } /* Discharge an expression to the next free register. */ static void expr_tonextreg(FuncState *fs, ExpDesc *e) { expr_discharge(fs, e); expr_free(fs, e); bcreg_reserve(fs, 1); expr_toreg(fs, e, fs->freereg - 1); } /* Discharge an expression to any register. */ static BCReg expr_toanyreg(FuncState *fs, ExpDesc *e) { expr_discharge(fs, e); if (e->k == VNONRELOC) { if (!expr_hasjump(e)) return e->u.s.info; /* Already in a register. */ if (e->u.s.info >= fs->nactvar) { expr_toreg(fs, e, e->u.s.info); /* Discharge to temp. register. */ return e->u.s.info; } } expr_tonextreg(fs, e); /* Discharge to next register. */ return e->u.s.info; } /* Partially discharge expression to a value. */ static void expr_toval(FuncState *fs, ExpDesc *e) { if (expr_hasjump(e)) expr_toanyreg(fs, e); else expr_discharge(fs, e); } /* Emit store for LHS expression. */ static void bcemit_store(FuncState *fs, ExpDesc *var, ExpDesc *e) { BCIns ins; if (var->k == VLOCAL) { fs->ls->vstack[var->u.s.aux].info |= VSTACK_VAR_RW; expr_free(fs, e); expr_toreg(fs, e, var->u.s.info); return; } else if (var->k == VUPVAL) { fs->ls->vstack[var->u.s.aux].info |= VSTACK_VAR_RW; expr_toval(fs, e); if (e->k <= VKTRUE) ins = BCINS_AD(BC_USETP, var->u.s.info, const_pri(e)); else if (e->k == VKSTR) ins = BCINS_AD(BC_USETS, var->u.s.info, const_str(fs, e)); else if (e->k == VKNUM) ins = BCINS_AD(BC_USETN, var->u.s.info, const_num(fs, e)); else ins = BCINS_AD(BC_USETV, var->u.s.info, expr_toanyreg(fs, e)); } else if (var->k == VGLOBAL) { BCReg ra = expr_toanyreg(fs, e); ins = BCINS_AD(BC_GSET, ra, const_str(fs, var)); } else { BCReg ra, rc; lua_assert(var->k == VINDEXED); ra = expr_toanyreg(fs, e); rc = var->u.s.aux; if ((int32_t)rc < 0) { ins = BCINS_ABC(BC_TSETS, ra, var->u.s.info, ~rc); } else if (rc > BCMAX_C) { ins = BCINS_ABC(BC_TSETB, ra, var->u.s.info, rc-(BCMAX_C+1)); } else { /* Free late alloced key reg to avoid assert on free of value reg. */ /* This can only happen when called from expr_table(). */ lua_assert(e->k != VNONRELOC || ra < fs->nactvar || rc < ra || (bcreg_free(fs, rc),1)); ins = BCINS_ABC(BC_TSETV, ra, var->u.s.info, rc); } } bcemit_INS(fs, ins); expr_free(fs, e); } /* Emit method lookup expression. */ static void bcemit_method(FuncState *fs, ExpDesc *e, ExpDesc *key) { BCReg idx, func, obj = expr_toanyreg(fs, e); expr_free(fs, e); func = fs->freereg; bcemit_AD(fs, BC_MOV, func+1+LJ_FR2, obj); /* Copy object to 1st argument. */ lua_assert(expr_isstrk(key)); idx = const_str(fs, key); if (idx <= BCMAX_C) { bcreg_reserve(fs, 2+LJ_FR2); bcemit_ABC(fs, BC_TGETS, func, obj, idx); } else { bcreg_reserve(fs, 3+LJ_FR2); bcemit_AD(fs, BC_KSTR, func+2+LJ_FR2, idx); bcemit_ABC(fs, BC_TGETV, func, obj, func+2+LJ_FR2); fs->freereg--; } e->u.s.info = func; e->k = VNONRELOC; } /* -- Bytecode emitter for branches --------------------------------------- */ /* Emit unconditional branch. */ static BCPos bcemit_jmp(FuncState *fs) { BCPos jpc = fs->jpc; BCPos j = fs->pc - 1; BCIns *ip = &fs->bcbase[j].ins; fs->jpc = NO_JMP; if ((int32_t)j >= (int32_t)fs->lasttarget && bc_op(*ip) == BC_UCLO) { setbc_j(ip, NO_JMP); fs->lasttarget = j+1; } else { j = bcemit_AJ(fs, BC_JMP, fs->freereg, NO_JMP); } jmp_append(fs, &j, jpc); return j; } /* Invert branch condition of bytecode instruction. */ static void invertcond(FuncState *fs, ExpDesc *e) { BCIns *ip = &fs->bcbase[e->u.s.info - 1].ins; setbc_op(ip, bc_op(*ip)^1); } /* Emit conditional branch. */ static BCPos bcemit_branch(FuncState *fs, ExpDesc *e, int cond) { BCPos pc; if (e->k == VRELOCABLE) { BCIns *ip = bcptr(fs, e); if (bc_op(*ip) == BC_NOT) { *ip = BCINS_AD(cond ? BC_ISF : BC_IST, 0, bc_d(*ip)); return bcemit_jmp(fs); } } if (e->k != VNONRELOC) { bcreg_reserve(fs, 1); expr_toreg_nobranch(fs, e, fs->freereg-1); } bcemit_AD(fs, cond ? BC_ISTC : BC_ISFC, NO_REG, e->u.s.info); pc = bcemit_jmp(fs); expr_free(fs, e); return pc; } /* Emit branch on true condition. */ static void bcemit_branch_t(FuncState *fs, ExpDesc *e) { BCPos pc; expr_discharge(fs, e); if (e->k == VKSTR || e->k == VKNUM || e->k == VKTRUE) pc = NO_JMP; /* Never jump. */ else if (e->k == VJMP) invertcond(fs, e), pc = e->u.s.info; else if (e->k == VKFALSE || e->k == VKNIL) expr_toreg_nobranch(fs, e, NO_REG), pc = bcemit_jmp(fs); else pc = bcemit_branch(fs, e, 0); jmp_append(fs, &e->f, pc); jmp_tohere(fs, e->t); e->t = NO_JMP; } /* Emit branch on false condition. */ static void bcemit_branch_f(FuncState *fs, ExpDesc *e) { BCPos pc; expr_discharge(fs, e); if (e->k == VKNIL || e->k == VKFALSE) pc = NO_JMP; /* Never jump. */ else if (e->k == VJMP) pc = e->u.s.info; else if (e->k == VKSTR || e->k == VKNUM || e->k == VKTRUE) expr_toreg_nobranch(fs, e, NO_REG), pc = bcemit_jmp(fs); else pc = bcemit_branch(fs, e, 1); jmp_append(fs, &e->t, pc); jmp_tohere(fs, e->f); e->f = NO_JMP; } /* -- Bytecode emitter for operators -------------------------------------- */ /* Try constant-folding of arithmetic operators. */ static int foldarith(BinOpr opr, ExpDesc *e1, ExpDesc *e2) { TValue o; lua_Number n; if (!expr_isnumk_nojump(e1) || !expr_isnumk_nojump(e2)) return 0; n = lj_vm_foldarith(expr_numberV(e1), expr_numberV(e2), (int)opr-OPR_ADD); setnumV(&o, n); if (tvisnan(&o) || tvismzero(&o)) return 0; /* Avoid NaN and -0 as consts. */ if (LJ_DUALNUM) { int32_t k = lj_num2int(n); if ((lua_Number)k == n) { setintV(&e1->u.nval, k); return 1; } } setnumV(&e1->u.nval, n); return 1; } /* Emit arithmetic operator. */ static void bcemit_arith(FuncState *fs, BinOpr opr, ExpDesc *e1, ExpDesc *e2) { BCReg rb, rc, t; uint32_t op; if (foldarith(opr, e1, e2)) return; if (opr == OPR_POW) { op = BC_POW; rc = expr_toanyreg(fs, e2); rb = expr_toanyreg(fs, e1); } else { op = opr-OPR_ADD+BC_ADDVV; /* Must discharge 2nd operand first since VINDEXED might free regs. */ expr_toval(fs, e2); if (expr_isnumk(e2) && (rc = const_num(fs, e2)) <= BCMAX_C) op -= BC_ADDVV-BC_ADDVN; else rc = expr_toanyreg(fs, e2); /* 1st operand discharged by bcemit_binop_left, but need KNUM/KSHORT. */ lua_assert(expr_isnumk(e1) || e1->k == VNONRELOC); expr_toval(fs, e1); /* Avoid two consts to satisfy bytecode constraints. */ if (expr_isnumk(e1) && !expr_isnumk(e2) && (t = const_num(fs, e1)) <= BCMAX_B) { rb = rc; rc = t; op -= BC_ADDVV-BC_ADDNV; } else { rb = expr_toanyreg(fs, e1); } } /* Using expr_free might cause asserts if the order is wrong. */ if (e1->k == VNONRELOC && e1->u.s.info >= fs->nactvar) fs->freereg--; if (e2->k == VNONRELOC && e2->u.s.info >= fs->nactvar) fs->freereg--; e1->u.s.info = bcemit_ABC(fs, op, 0, rb, rc); e1->k = VRELOCABLE; } /* Emit comparison operator. */ static void bcemit_comp(FuncState *fs, BinOpr opr, ExpDesc *e1, ExpDesc *e2) { ExpDesc *eret = e1; BCIns ins; expr_toval(fs, e1); if (opr == OPR_EQ || opr == OPR_NE) { BCOp op = opr == OPR_EQ ? BC_ISEQV : BC_ISNEV; BCReg ra; if (expr_isk(e1)) { e1 = e2; e2 = eret; } /* Need constant in 2nd arg. */ ra = expr_toanyreg(fs, e1); /* First arg must be in a reg. */ expr_toval(fs, e2); switch (e2->k) { case VKNIL: case VKFALSE: case VKTRUE: ins = BCINS_AD(op+(BC_ISEQP-BC_ISEQV), ra, const_pri(e2)); break; case VKSTR: ins = BCINS_AD(op+(BC_ISEQS-BC_ISEQV), ra, const_str(fs, e2)); break; case VKNUM: ins = BCINS_AD(op+(BC_ISEQN-BC_ISEQV), ra, const_num(fs, e2)); break; default: ins = BCINS_AD(op, ra, expr_toanyreg(fs, e2)); break; } } else { uint32_t op = opr-OPR_LT+BC_ISLT; BCReg ra, rd; if ((op-BC_ISLT) & 1) { /* GT -> LT, GE -> LE */ e1 = e2; e2 = eret; /* Swap operands. */ op = ((op-BC_ISLT)^3)+BC_ISLT; expr_toval(fs, e1); } rd = expr_toanyreg(fs, e2); ra = expr_toanyreg(fs, e1); ins = BCINS_AD(op, ra, rd); } /* Using expr_free might cause asserts if the order is wrong. */ if (e1->k == VNONRELOC && e1->u.s.info >= fs->nactvar) fs->freereg--; if (e2->k == VNONRELOC && e2->u.s.info >= fs->nactvar) fs->freereg--; bcemit_INS(fs, ins); eret->u.s.info = bcemit_jmp(fs); eret->k = VJMP; } /* Fixup left side of binary operator. */ static void bcemit_binop_left(FuncState *fs, BinOpr op, ExpDesc *e) { if (op == OPR_AND) { bcemit_branch_t(fs, e); } else if (op == OPR_OR) { bcemit_branch_f(fs, e); } else if (op == OPR_CONCAT) { expr_tonextreg(fs, e); } else if (op == OPR_EQ || op == OPR_NE) { if (!expr_isk_nojump(e)) expr_toanyreg(fs, e); } else { if (!expr_isnumk_nojump(e)) expr_toanyreg(fs, e); } } /* Emit binary operator. */ static void bcemit_binop(FuncState *fs, BinOpr op, ExpDesc *e1, ExpDesc *e2) { if (op <= OPR_POW) { bcemit_arith(fs, op, e1, e2); } else if (op == OPR_AND) { lua_assert(e1->t == NO_JMP); /* List must be closed. */ expr_discharge(fs, e2); jmp_append(fs, &e2->f, e1->f); *e1 = *e2; } else if (op == OPR_OR) { lua_assert(e1->f == NO_JMP); /* List must be closed. */ expr_discharge(fs, e2); jmp_append(fs, &e2->t, e1->t); *e1 = *e2; } else if (op == OPR_CONCAT) { expr_toval(fs, e2); if (e2->k == VRELOCABLE && bc_op(*bcptr(fs, e2)) == BC_CAT) { lua_assert(e1->u.s.info == bc_b(*bcptr(fs, e2))-1); expr_free(fs, e1); setbc_b(bcptr(fs, e2), e1->u.s.info); e1->u.s.info = e2->u.s.info; } else { expr_tonextreg(fs, e2); expr_free(fs, e2); expr_free(fs, e1); e1->u.s.info = bcemit_ABC(fs, BC_CAT, 0, e1->u.s.info, e2->u.s.info); } e1->k = VRELOCABLE; } else { lua_assert(op == OPR_NE || op == OPR_EQ || op == OPR_LT || op == OPR_GE || op == OPR_LE || op == OPR_GT); bcemit_comp(fs, op, e1, e2); } } /* Emit unary operator. */ static void bcemit_unop(FuncState *fs, BCOp op, ExpDesc *e) { if (op == BC_NOT) { /* Swap true and false lists. */ { BCPos temp = e->f; e->f = e->t; e->t = temp; } jmp_dropval(fs, e->f); jmp_dropval(fs, e->t); expr_discharge(fs, e); if (e->k == VKNIL || e->k == VKFALSE) { e->k = VKTRUE; return; } else if (expr_isk(e) || (LJ_HASFFI && e->k == VKCDATA)) { e->k = VKFALSE; return; } else if (e->k == VJMP) { invertcond(fs, e); return; } else if (e->k == VRELOCABLE) { bcreg_reserve(fs, 1); setbc_a(bcptr(fs, e), fs->freereg-1); e->u.s.info = fs->freereg-1; e->k = VNONRELOC; } else { lua_assert(e->k == VNONRELOC); } } else { lua_assert(op == BC_UNM || op == BC_LEN); if (op == BC_UNM && !expr_hasjump(e)) { /* Constant-fold negations. */ #if LJ_HASFFI if (e->k == VKCDATA) { /* Fold in-place since cdata is not interned. */ GCcdata *cd = cdataV(&e->u.nval); int64_t *p = (int64_t *)cdataptr(cd); if (cd->ctypeid == CTID_COMPLEX_DOUBLE) p[1] ^= (int64_t)U64x(80000000,00000000); else *p = -*p; return; } else #endif if (expr_isnumk(e) && !expr_numiszero(e)) { /* Avoid folding to -0. */ TValue *o = expr_numtv(e); if (tvisint(o)) { int32_t k = intV(o); if (k == -k) setnumV(o, -(lua_Number)k); else setintV(o, -k); return; } else { o->u64 ^= U64x(80000000,00000000); return; } } } expr_toanyreg(fs, e); } expr_free(fs, e); e->u.s.info = bcemit_AD(fs, op, 0, e->u.s.info); e->k = VRELOCABLE; } /* -- Lexer support ------------------------------------------------------- */ /* Check and consume optional token. */ static int lex_opt(LexState *ls, LexToken tok) { if (ls->tok == tok) { lj_lex_next(ls); return 1; } return 0; } /* Check and consume token. */ static void lex_check(LexState *ls, LexToken tok) { if (ls->tok != tok) err_token(ls, tok); lj_lex_next(ls); } /* Check for matching token. */ static void lex_match(LexState *ls, LexToken what, LexToken who, BCLine line) { if (!lex_opt(ls, what)) { if (line == ls->linenumber) { err_token(ls, what); } else { const char *swhat = lj_lex_token2str(ls, what); const char *swho = lj_lex_token2str(ls, who); lj_lex_error(ls, ls->tok, LJ_ERR_XMATCH, swhat, swho, line); } } } /* Check for string token. */ static GCstr *lex_str(LexState *ls) { GCstr *s; if (ls->tok != TK_name && (LJ_52 || ls->tok != TK_goto)) err_token(ls, TK_name); s = strV(&ls->tokval); lj_lex_next(ls); return s; } /* -- Variable handling --------------------------------------------------- */ #define var_get(ls, fs, i) ((ls)->vstack[(fs)->varmap[(i)]]) /* Define a new local variable. */ static void var_new(LexState *ls, BCReg n, GCstr *name) { FuncState *fs = ls->fs; MSize vtop = ls->vtop; checklimit(fs, fs->nactvar+n, LJ_MAX_LOCVAR, "local variables"); if (LJ_UNLIKELY(vtop >= ls->sizevstack)) { if (ls->sizevstack >= LJ_MAX_VSTACK) lj_lex_error(ls, 0, LJ_ERR_XLIMC, LJ_MAX_VSTACK); lj_mem_growvec(ls->L, ls->vstack, ls->sizevstack, LJ_MAX_VSTACK, VarInfo); } lua_assert((uintptr_t)name < VARNAME__MAX || lj_tab_getstr(fs->kt, name) != NULL); /* NOBARRIER: name is anchored in fs->kt and ls->vstack is not a GCobj. */ setgcref(ls->vstack[vtop].name, obj2gco(name)); fs->varmap[fs->nactvar+n] = (uint16_t)vtop; ls->vtop = vtop+1; } #define var_new_lit(ls, n, v) \ var_new(ls, (n), lj_parse_keepstr(ls, "" v, sizeof(v)-1)) #define var_new_fixed(ls, n, vn) \ var_new(ls, (n), (GCstr *)(uintptr_t)(vn)) /* Add local variables. */ static void var_add(LexState *ls, BCReg nvars) { FuncState *fs = ls->fs; BCReg nactvar = fs->nactvar; while (nvars--) { VarInfo *v = &var_get(ls, fs, nactvar); v->startpc = fs->pc; v->slot = nactvar++; v->info = 0; } fs->nactvar = nactvar; } /* Remove local variables. */ static void var_remove(LexState *ls, BCReg tolevel) { FuncState *fs = ls->fs; while (fs->nactvar > tolevel) var_get(ls, fs, --fs->nactvar).endpc = fs->pc; } /* Lookup local variable name. */ static BCReg var_lookup_local(FuncState *fs, GCstr *n) { int i; for (i = fs->nactvar-1; i >= 0; i--) { if (n == strref(var_get(fs->ls, fs, i).name)) return (BCReg)i; } return (BCReg)-1; /* Not found. */ } /* Lookup or add upvalue index. */ static MSize var_lookup_uv(FuncState *fs, MSize vidx, ExpDesc *e) { MSize i, n = fs->nuv; for (i = 0; i < n; i++) if (fs->uvmap[i] == vidx) return i; /* Already exists. */ /* Otherwise create a new one. */ checklimit(fs, fs->nuv, LJ_MAX_UPVAL, "upvalues"); lua_assert(e->k == VLOCAL || e->k == VUPVAL); fs->uvmap[n] = (uint16_t)vidx; fs->uvtmp[n] = (uint16_t)(e->k == VLOCAL ? vidx : LJ_MAX_VSTACK+e->u.s.info); fs->nuv = n+1; return n; } /* Forward declaration. */ static void fscope_uvmark(FuncState *fs, BCReg level); /* Recursively lookup variables in enclosing functions. */ static MSize var_lookup_(FuncState *fs, GCstr *name, ExpDesc *e, int first) { if (fs) { BCReg reg = var_lookup_local(fs, name); if ((int32_t)reg >= 0) { /* Local in this function? */ expr_init(e, VLOCAL, reg); if (!first) fscope_uvmark(fs, reg); /* Scope now has an upvalue. */ return (MSize)(e->u.s.aux = (uint32_t)fs->varmap[reg]); } else { MSize vidx = var_lookup_(fs->prev, name, e, 0); /* Var in outer func? */ if ((int32_t)vidx >= 0) { /* Yes, make it an upvalue here. */ e->u.s.info = (uint8_t)var_lookup_uv(fs, vidx, e); e->k = VUPVAL; return vidx; } } } else { /* Not found in any function, must be a global. */ expr_init(e, VGLOBAL, 0); e->u.sval = name; } return (MSize)-1; /* Global. */ } /* Lookup variable name. */ #define var_lookup(ls, e) \ var_lookup_((ls)->fs, lex_str(ls), (e), 1) /* -- Goto an label handling ---------------------------------------------- */ /* Add a new goto or label. */ static MSize gola_new(LexState *ls, GCstr *name, uint8_t info, BCPos pc) { FuncState *fs = ls->fs; MSize vtop = ls->vtop; if (LJ_UNLIKELY(vtop >= ls->sizevstack)) { if (ls->sizevstack >= LJ_MAX_VSTACK) lj_lex_error(ls, 0, LJ_ERR_XLIMC, LJ_MAX_VSTACK); lj_mem_growvec(ls->L, ls->vstack, ls->sizevstack, LJ_MAX_VSTACK, VarInfo); } lua_assert(name == NAME_BREAK || lj_tab_getstr(fs->kt, name) != NULL); /* NOBARRIER: name is anchored in fs->kt and ls->vstack is not a GCobj. */ setgcref(ls->vstack[vtop].name, obj2gco(name)); ls->vstack[vtop].startpc = pc; ls->vstack[vtop].slot = (uint8_t)fs->nactvar; ls->vstack[vtop].info = info; ls->vtop = vtop+1; return vtop; } #define gola_isgoto(v) ((v)->info & VSTACK_GOTO) #define gola_islabel(v) ((v)->info & VSTACK_LABEL) #define gola_isgotolabel(v) ((v)->info & (VSTACK_GOTO|VSTACK_LABEL)) /* Patch goto to jump to label. */ static void gola_patch(LexState *ls, VarInfo *vg, VarInfo *vl) { FuncState *fs = ls->fs; BCPos pc = vg->startpc; setgcrefnull(vg->name); /* Invalidate pending goto. */ setbc_a(&fs->bcbase[pc].ins, vl->slot); jmp_patch(fs, pc, vl->startpc); } /* Patch goto to close upvalues. */ static void gola_close(LexState *ls, VarInfo *vg) { FuncState *fs = ls->fs; BCPos pc = vg->startpc; BCIns *ip = &fs->bcbase[pc].ins; lua_assert(gola_isgoto(vg)); lua_assert(bc_op(*ip) == BC_JMP || bc_op(*ip) == BC_UCLO); setbc_a(ip, vg->slot); if (bc_op(*ip) == BC_JMP) { BCPos next = jmp_next(fs, pc); if (next != NO_JMP) jmp_patch(fs, next, pc); /* Jump to UCLO. */ setbc_op(ip, BC_UCLO); /* Turn into UCLO. */ setbc_j(ip, NO_JMP); } } /* Resolve pending forward gotos for label. */ static void gola_resolve(LexState *ls, FuncScope *bl, MSize idx) { VarInfo *vg = ls->vstack + bl->vstart; VarInfo *vl = ls->vstack + idx; for (; vg < vl; vg++) if (gcrefeq(vg->name, vl->name) && gola_isgoto(vg)) { if (vg->slot < vl->slot) { GCstr *name = strref(var_get(ls, ls->fs, vg->slot).name); lua_assert((uintptr_t)name >= VARNAME__MAX); ls->linenumber = ls->fs->bcbase[vg->startpc].line; lua_assert(strref(vg->name) != NAME_BREAK); lj_lex_error(ls, 0, LJ_ERR_XGSCOPE, strdata(strref(vg->name)), strdata(name)); } gola_patch(ls, vg, vl); } } /* Fixup remaining gotos and labels for scope. */ static void gola_fixup(LexState *ls, FuncScope *bl) { VarInfo *v = ls->vstack + bl->vstart; VarInfo *ve = ls->vstack + ls->vtop; for (; v < ve; v++) { GCstr *name = strref(v->name); if (name != NULL) { /* Only consider remaining valid gotos/labels. */ if (gola_islabel(v)) { VarInfo *vg; setgcrefnull(v->name); /* Invalidate label that goes out of scope. */ for (vg = v+1; vg < ve; vg++) /* Resolve pending backward gotos. */ if (strref(vg->name) == name && gola_isgoto(vg)) { if ((bl->flags&FSCOPE_UPVAL) && vg->slot > v->slot) gola_close(ls, vg); gola_patch(ls, vg, v); } } else if (gola_isgoto(v)) { if (bl->prev) { /* Propagate goto or break to outer scope. */ bl->prev->flags |= name == NAME_BREAK ? FSCOPE_BREAK : FSCOPE_GOLA; v->slot = bl->nactvar; if ((bl->flags & FSCOPE_UPVAL)) gola_close(ls, v); } else { /* No outer scope: undefined goto label or no loop. */ ls->linenumber = ls->fs->bcbase[v->startpc].line; if (name == NAME_BREAK) lj_lex_error(ls, 0, LJ_ERR_XBREAK); else lj_lex_error(ls, 0, LJ_ERR_XLUNDEF, strdata(name)); } } } } } /* Find existing label. */ static VarInfo *gola_findlabel(LexState *ls, GCstr *name) { VarInfo *v = ls->vstack + ls->fs->bl->vstart; VarInfo *ve = ls->vstack + ls->vtop; for (; v < ve; v++) if (strref(v->name) == name && gola_islabel(v)) return v; return NULL; } /* -- Scope handling ------------------------------------------------------ */ /* Begin a scope. */ static void fscope_begin(FuncState *fs, FuncScope *bl, int flags) { bl->nactvar = (uint8_t)fs->nactvar; bl->flags = flags; bl->vstart = fs->ls->vtop; bl->prev = fs->bl; fs->bl = bl; lua_assert(fs->freereg == fs->nactvar); } /* End a scope. */ static void fscope_end(FuncState *fs) { FuncScope *bl = fs->bl; LexState *ls = fs->ls; fs->bl = bl->prev; var_remove(ls, bl->nactvar); fs->freereg = fs->nactvar; lua_assert(bl->nactvar == fs->nactvar); if ((bl->flags & (FSCOPE_UPVAL|FSCOPE_NOCLOSE)) == FSCOPE_UPVAL) bcemit_AJ(fs, BC_UCLO, bl->nactvar, 0); if ((bl->flags & FSCOPE_BREAK)) { if ((bl->flags & FSCOPE_LOOP)) { MSize idx = gola_new(ls, NAME_BREAK, VSTACK_LABEL, fs->pc); ls->vtop = idx; /* Drop break label immediately. */ gola_resolve(ls, bl, idx); return; } /* else: need the fixup step to propagate the breaks. */ } else if (!(bl->flags & FSCOPE_GOLA)) { return; } gola_fixup(ls, bl); } /* Mark scope as having an upvalue. */ static void fscope_uvmark(FuncState *fs, BCReg level) { FuncScope *bl; for (bl = fs->bl; bl && bl->nactvar > level; bl = bl->prev) ; if (bl) bl->flags |= FSCOPE_UPVAL; } /* -- Function state management ------------------------------------------- */ /* Fixup bytecode for prototype. */ static void fs_fixup_bc(FuncState *fs, GCproto *pt, BCIns *bc, MSize n) { BCInsLine *base = fs->bcbase; MSize i; pt->sizebc = n; bc[0] = BCINS_AD((fs->flags & PROTO_VARARG) ? BC_FUNCV : BC_FUNCF, fs->framesize, 0); for (i = 1; i < n; i++) bc[i] = base[i].ins; } /* Fixup upvalues for child prototype, step #2. */ static void fs_fixup_uv2(FuncState *fs, GCproto *pt) { VarInfo *vstack = fs->ls->vstack; uint16_t *uv = proto_uv(pt); MSize i, n = pt->sizeuv; for (i = 0; i < n; i++) { VarIndex vidx = uv[i]; if (vidx >= LJ_MAX_VSTACK) uv[i] = vidx - LJ_MAX_VSTACK; else if ((vstack[vidx].info & VSTACK_VAR_RW)) uv[i] = vstack[vidx].slot | PROTO_UV_LOCAL; else uv[i] = vstack[vidx].slot | PROTO_UV_LOCAL | PROTO_UV_IMMUTABLE; } } /* Fixup constants for prototype. */ static void fs_fixup_k(FuncState *fs, GCproto *pt, void *kptr) { GCtab *kt; TValue *array; Node *node; MSize i, hmask; checklimitgt(fs, fs->nkn, BCMAX_D+1, "constants"); checklimitgt(fs, fs->nkgc, BCMAX_D+1, "constants"); setmref(pt->k, kptr); pt->sizekn = fs->nkn; pt->sizekgc = fs->nkgc; kt = fs->kt; array = tvref(kt->array); for (i = 0; i < kt->asize; i++) if (tvhaskslot(&array[i])) { TValue *tv = &((TValue *)kptr)[tvkslot(&array[i])]; if (LJ_DUALNUM) setintV(tv, (int32_t)i); else setnumV(tv, (lua_Number)i); } node = noderef(kt->node); hmask = kt->hmask; for (i = 0; i <= hmask; i++) { Node *n = &node[i]; if (tvhaskslot(&n->val)) { ptrdiff_t kidx = (ptrdiff_t)tvkslot(&n->val); lua_assert(!tvisint(&n->key)); if (tvisnum(&n->key)) { TValue *tv = &((TValue *)kptr)[kidx]; if (LJ_DUALNUM) { lua_Number nn = numV(&n->key); int32_t k = lj_num2int(nn); lua_assert(!tvismzero(&n->key)); if ((lua_Number)k == nn) setintV(tv, k); else *tv = n->key; } else { *tv = n->key; } } else { GCobj *o = gcV(&n->key); setgcref(((GCRef *)kptr)[~kidx], o); lj_gc_objbarrier(fs->L, pt, o); if (tvisproto(&n->key)) fs_fixup_uv2(fs, gco2pt(o)); } } } } /* Fixup upvalues for prototype, step #1. */ static void fs_fixup_uv1(FuncState *fs, GCproto *pt, uint16_t *uv) { setmref(pt->uv, uv); pt->sizeuv = fs->nuv; memcpy(uv, fs->uvtmp, fs->nuv*sizeof(VarIndex)); } #ifndef LUAJIT_DISABLE_DEBUGINFO /* Prepare lineinfo for prototype. */ static size_t fs_prep_line(FuncState *fs, BCLine numline) { return (fs->pc-1) << (numline < 256 ? 0 : numline < 65536 ? 1 : 2); } /* Fixup lineinfo for prototype. */ static void fs_fixup_line(FuncState *fs, GCproto *pt, void *lineinfo, BCLine numline) { BCInsLine *base = fs->bcbase + 1; BCLine first = fs->linedefined; MSize i = 0, n = fs->pc-1; pt->firstline = fs->linedefined; pt->numline = numline; setmref(pt->lineinfo, lineinfo); if (LJ_LIKELY(numline < 256)) { uint8_t *li = (uint8_t *)lineinfo; do { BCLine delta = base[i].line - first; lua_assert(delta >= 0 && delta < 256); li[i] = (uint8_t)delta; } while (++i < n); } else if (LJ_LIKELY(numline < 65536)) { uint16_t *li = (uint16_t *)lineinfo; do { BCLine delta = base[i].line - first; lua_assert(delta >= 0 && delta < 65536); li[i] = (uint16_t)delta; } while (++i < n); } else { uint32_t *li = (uint32_t *)lineinfo; do { BCLine delta = base[i].line - first; lua_assert(delta >= 0); li[i] = (uint32_t)delta; } while (++i < n); } } /* Prepare variable info for prototype. */ static size_t fs_prep_var(LexState *ls, FuncState *fs, size_t *ofsvar) { VarInfo *vs =ls->vstack, *ve; MSize i, n; BCPos lastpc; lj_buf_reset(&ls->sb); /* Copy to temp. string buffer. */ /* Store upvalue names. */ for (i = 0, n = fs->nuv; i < n; i++) { GCstr *s = strref(vs[fs->uvmap[i]].name); MSize len = s->len+1; char *p = lj_buf_more(&ls->sb, len); p = lj_buf_wmem(p, strdata(s), len); setsbufP(&ls->sb, p); } *ofsvar = sbuflen(&ls->sb); lastpc = 0; /* Store local variable names and compressed ranges. */ for (ve = vs + ls->vtop, vs += fs->vbase; vs < ve; vs++) { if (!gola_isgotolabel(vs)) { GCstr *s = strref(vs->name); BCPos startpc; char *p; if ((uintptr_t)s < VARNAME__MAX) { p = lj_buf_more(&ls->sb, 1 + 2*5); *p++ = (char)(uintptr_t)s; } else { MSize len = s->len+1; p = lj_buf_more(&ls->sb, len + 2*5); p = lj_buf_wmem(p, strdata(s), len); } startpc = vs->startpc; p = lj_strfmt_wuleb128(p, startpc-lastpc); p = lj_strfmt_wuleb128(p, vs->endpc-startpc); setsbufP(&ls->sb, p); lastpc = startpc; } } lj_buf_putb(&ls->sb, '\0'); /* Terminator for varinfo. */ return sbuflen(&ls->sb); } /* Fixup variable info for prototype. */ static void fs_fixup_var(LexState *ls, GCproto *pt, uint8_t *p, size_t ofsvar) { setmref(pt->uvinfo, p); setmref(pt->varinfo, (char *)p + ofsvar); memcpy(p, sbufB(&ls->sb), sbuflen(&ls->sb)); /* Copy from temp. buffer. */ } #else /* Initialize with empty debug info, if disabled. */ #define fs_prep_line(fs, numline) (UNUSED(numline), 0) #define fs_fixup_line(fs, pt, li, numline) \ pt->firstline = pt->numline = 0, setmref((pt)->lineinfo, NULL) #define fs_prep_var(ls, fs, ofsvar) (UNUSED(ofsvar), 0) #define fs_fixup_var(ls, pt, p, ofsvar) \ setmref((pt)->uvinfo, NULL), setmref((pt)->varinfo, NULL) #endif /* Check if bytecode op returns. */ static int bcopisret(BCOp op) { switch (op) { case BC_CALLMT: case BC_CALLT: case BC_RETM: case BC_RET: case BC_RET0: case BC_RET1: return 1; default: return 0; } } /* Fixup return instruction for prototype. */ static void fs_fixup_ret(FuncState *fs) { BCPos lastpc = fs->pc; if (lastpc <= fs->lasttarget || !bcopisret(bc_op(fs->bcbase[lastpc-1].ins))) { if ((fs->bl->flags & FSCOPE_UPVAL)) bcemit_AJ(fs, BC_UCLO, 0, 0); bcemit_AD(fs, BC_RET0, 0, 1); /* Need final return. */ } fs->bl->flags |= FSCOPE_NOCLOSE; /* Handled above. */ fscope_end(fs); lua_assert(fs->bl == NULL); /* May need to fixup returns encoded before first function was created. */ if (fs->flags & PROTO_FIXUP_RETURN) { BCPos pc; for (pc = 1; pc < lastpc; pc++) { BCIns ins = fs->bcbase[pc].ins; BCPos offset; switch (bc_op(ins)) { case BC_CALLMT: case BC_CALLT: case BC_RETM: case BC_RET: case BC_RET0: case BC_RET1: offset = bcemit_INS(fs, ins); /* Copy original instruction. */ fs->bcbase[offset].line = fs->bcbase[pc].line; offset = offset-(pc+1)+BCBIAS_J; if (offset > BCMAX_D) err_syntax(fs->ls, LJ_ERR_XFIXUP); /* Replace with UCLO plus branch. */ fs->bcbase[pc].ins = BCINS_AD(BC_UCLO, 0, offset); break; case BC_UCLO: return; /* We're done. */ default: break; } } } } /* Finish a FuncState and return the new prototype. */ static GCproto *fs_finish(LexState *ls, BCLine line) { lua_State *L = ls->L; FuncState *fs = ls->fs; BCLine numline = line - fs->linedefined; size_t sizept, ofsk, ofsuv, ofsli, ofsdbg, ofsvar; GCproto *pt; /* Apply final fixups. */ fs_fixup_ret(fs); /* Calculate total size of prototype including all colocated arrays. */ sizept = sizeof(GCproto) + fs->pc*sizeof(BCIns) + fs->nkgc*sizeof(GCRef); sizept = (sizept + sizeof(TValue)-1) & ~(sizeof(TValue)-1); ofsk = sizept; sizept += fs->nkn*sizeof(TValue); ofsuv = sizept; sizept += ((fs->nuv+1)&~1)*2; ofsli = sizept; sizept += fs_prep_line(fs, numline); ofsdbg = sizept; sizept += fs_prep_var(ls, fs, &ofsvar); /* Allocate prototype and initialize its fields. */ pt = (GCproto *)lj_mem_newgco(L, (MSize)sizept); pt->gct = ~LJ_TPROTO; pt->sizept = (MSize)sizept; pt->trace = 0; pt->flags = (uint8_t)(fs->flags & ~(PROTO_HAS_RETURN|PROTO_FIXUP_RETURN)); pt->numparams = fs->numparams; pt->framesize = fs->framesize; setgcref(pt->chunkname, obj2gco(ls->chunkname)); /* Close potentially uninitialized gap between bc and kgc. */ *(uint32_t *)((char *)pt + ofsk - sizeof(GCRef)*(fs->nkgc+1)) = 0; fs_fixup_bc(fs, pt, (BCIns *)((char *)pt + sizeof(GCproto)), fs->pc); fs_fixup_k(fs, pt, (void *)((char *)pt + ofsk)); fs_fixup_uv1(fs, pt, (uint16_t *)((char *)pt + ofsuv)); fs_fixup_line(fs, pt, (void *)((char *)pt + ofsli), numline); fs_fixup_var(ls, pt, (uint8_t *)((char *)pt + ofsdbg), ofsvar); lj_vmevent_send(L, BC, setprotoV(L, L->top++, pt); ); L->top--; /* Pop table of constants. */ ls->vtop = fs->vbase; /* Reset variable stack. */ ls->fs = fs->prev; lua_assert(ls->fs != NULL || ls->tok == TK_eof); return pt; } /* Initialize a new FuncState. */ static void fs_init(LexState *ls, FuncState *fs) { lua_State *L = ls->L; fs->prev = ls->fs; ls->fs = fs; /* Append to list. */ fs->ls = ls; fs->vbase = ls->vtop; fs->L = L; fs->pc = 0; fs->lasttarget = 0; fs->jpc = NO_JMP; fs->freereg = 0; fs->nkgc = 0; fs->nkn = 0; fs->nactvar = 0; fs->nuv = 0; fs->bl = NULL; fs->flags = 0; fs->framesize = 1; /* Minimum frame size. */ fs->kt = lj_tab_new(L, 0, 0); /* Anchor table of constants in stack to avoid being collected. */ settabV(L, L->top, fs->kt); incr_top(L); } /* -- Expressions --------------------------------------------------------- */ /* Forward declaration. */ static void expr(LexState *ls, ExpDesc *v); /* Return string expression. */ static void expr_str(LexState *ls, ExpDesc *e) { expr_init(e, VKSTR, 0); e->u.sval = lex_str(ls); } /* Return index expression. */ static void expr_index(FuncState *fs, ExpDesc *t, ExpDesc *e) { /* Already called: expr_toval(fs, e). */ t->k = VINDEXED; if (expr_isnumk(e)) { #if LJ_DUALNUM if (tvisint(expr_numtv(e))) { int32_t k = intV(expr_numtv(e)); if (checku8(k)) { t->u.s.aux = BCMAX_C+1+(uint32_t)k; /* 256..511: const byte key */ return; } } #else lua_Number n = expr_numberV(e); int32_t k = lj_num2int(n); if (checku8(k) && n == (lua_Number)k) { t->u.s.aux = BCMAX_C+1+(uint32_t)k; /* 256..511: const byte key */ return; } #endif } else if (expr_isstrk(e)) { BCReg idx = const_str(fs, e); if (idx <= BCMAX_C) { t->u.s.aux = ~idx; /* -256..-1: const string key */ return; } } t->u.s.aux = expr_toanyreg(fs, e); /* 0..255: register */ } /* Parse index expression with named field. */ static void expr_field(LexState *ls, ExpDesc *v) { FuncState *fs = ls->fs; ExpDesc key; expr_toanyreg(fs, v); lj_lex_next(ls); /* Skip dot or colon. */ expr_str(ls, &key); expr_index(fs, v, &key); } /* Parse index expression with brackets. */ static void expr_bracket(LexState *ls, ExpDesc *v) { lj_lex_next(ls); /* Skip '['. */ expr(ls, v); expr_toval(ls->fs, v); lex_check(ls, ']'); } /* Get value of constant expression. */ static void expr_kvalue(TValue *v, ExpDesc *e) { if (e->k <= VKTRUE) { setpriV(v, ~(uint32_t)e->k); } else if (e->k == VKSTR) { setgcVraw(v, obj2gco(e->u.sval), LJ_TSTR); } else { lua_assert(tvisnumber(expr_numtv(e))); *v = *expr_numtv(e); } } /* Parse table constructor expression. */ static void expr_table(LexState *ls, ExpDesc *e) { FuncState *fs = ls->fs; BCLine line = ls->linenumber; GCtab *t = NULL; int vcall = 0, needarr = 0, fixt = 0; uint32_t narr = 1; /* First array index. */ uint32_t nhash = 0; /* Number of hash entries. */ BCReg freg = fs->freereg; BCPos pc = bcemit_AD(fs, BC_TNEW, freg, 0); expr_init(e, VNONRELOC, freg); bcreg_reserve(fs, 1); freg++; lex_check(ls, '{'); while (ls->tok != '}') { ExpDesc key, val; vcall = 0; if (ls->tok == '[') { expr_bracket(ls, &key); /* Already calls expr_toval. */ if (!expr_isk(&key)) expr_index(fs, e, &key); if (expr_isnumk(&key) && expr_numiszero(&key)) needarr = 1; else nhash++; lex_check(ls, '='); } else if ((ls->tok == TK_name || (!LJ_52 && ls->tok == TK_goto)) && lj_lex_lookahead(ls) == '=') { expr_str(ls, &key); lex_check(ls, '='); nhash++; } else { expr_init(&key, VKNUM, 0); setintV(&key.u.nval, (int)narr); narr++; needarr = vcall = 1; } expr(ls, &val); if (expr_isk(&key) && key.k != VKNIL && (key.k == VKSTR || expr_isk_nojump(&val))) { TValue k, *v; if (!t) { /* Create template table on demand. */ BCReg kidx; t = lj_tab_new(fs->L, needarr ? narr : 0, hsize2hbits(nhash)); kidx = const_gc(fs, obj2gco(t), LJ_TTAB); fs->bcbase[pc].ins = BCINS_AD(BC_TDUP, freg-1, kidx); } vcall = 0; expr_kvalue(&k, &key); v = lj_tab_set(fs->L, t, &k); lj_gc_anybarriert(fs->L, t); if (expr_isk_nojump(&val)) { /* Add const key/value to template table. */ expr_kvalue(v, &val); } else { /* Otherwise create dummy string key (avoids lj_tab_newkey). */ settabV(fs->L, v, t); /* Preserve key with table itself as value. */ fixt = 1; /* Fix this later, after all resizes. */ goto nonconst; } } else { nonconst: if (val.k != VCALL) { expr_toanyreg(fs, &val); vcall = 0; } if (expr_isk(&key)) expr_index(fs, e, &key); bcemit_store(fs, e, &val); } fs->freereg = freg; if (!lex_opt(ls, ',') && !lex_opt(ls, ';')) break; } lex_match(ls, '}', '{', line); if (vcall) { BCInsLine *ilp = &fs->bcbase[fs->pc-1]; ExpDesc en; lua_assert(bc_a(ilp->ins) == freg && bc_op(ilp->ins) == (narr > 256 ? BC_TSETV : BC_TSETB)); expr_init(&en, VKNUM, 0); en.u.nval.u32.lo = narr-1; en.u.nval.u32.hi = 0x43300000; /* Biased integer to avoid denormals. */ if (narr > 256) { fs->pc--; ilp--; } ilp->ins = BCINS_AD(BC_TSETM, freg, const_num(fs, &en)); setbc_b(&ilp[-1].ins, 0); } if (pc == fs->pc-1) { /* Make expr relocable if possible. */ e->u.s.info = pc; fs->freereg--; e->k = VRELOCABLE; } else { e->k = VNONRELOC; /* May have been changed by expr_index. */ } if (!t) { /* Construct TNEW RD: hhhhhaaaaaaaaaaa. */ BCIns *ip = &fs->bcbase[pc].ins; if (!needarr) narr = 0; else if (narr < 3) narr = 3; else if (narr > 0x7ff) narr = 0x7ff; setbc_d(ip, narr|(hsize2hbits(nhash)<<11)); } else { if (needarr && t->asize < narr) lj_tab_reasize(fs->L, t, narr-1); if (fixt) { /* Fix value for dummy keys in template table. */ Node *node = noderef(t->node); uint32_t i, hmask = t->hmask; for (i = 0; i <= hmask; i++) { Node *n = &node[i]; if (tvistab(&n->val)) { lua_assert(tabV(&n->val) == t); setnilV(&n->val); /* Turn value into nil. */ } } } lj_gc_check(fs->L); } } /* Parse function parameters. */ static BCReg parse_params(LexState *ls, int needself) { FuncState *fs = ls->fs; BCReg nparams = 0; lex_check(ls, '('); if (needself) var_new_lit(ls, nparams++, "self"); if (ls->tok != ')') { do { if (ls->tok == TK_name || (!LJ_52 && ls->tok == TK_goto)) { var_new(ls, nparams++, lex_str(ls)); } else if (ls->tok == TK_dots) { lj_lex_next(ls); fs->flags |= PROTO_VARARG; break; } else { err_syntax(ls, LJ_ERR_XPARAM); } } while (lex_opt(ls, ',')); } var_add(ls, nparams); lua_assert(fs->nactvar == nparams); bcreg_reserve(fs, nparams); lex_check(ls, ')'); return nparams; } /* Forward declaration. */ static void parse_chunk(LexState *ls); /* Parse body of a function. */ static void parse_body(LexState *ls, ExpDesc *e, int needself, BCLine line) { FuncState fs, *pfs = ls->fs; FuncScope bl; GCproto *pt; ptrdiff_t oldbase = pfs->bcbase - ls->bcstack; fs_init(ls, &fs); fscope_begin(&fs, &bl, 0); fs.linedefined = line; fs.numparams = (uint8_t)parse_params(ls, needself); fs.bcbase = pfs->bcbase + pfs->pc; fs.bclim = pfs->bclim - pfs->pc; bcemit_AD(&fs, BC_FUNCF, 0, 0); /* Placeholder. */ parse_chunk(ls); if (ls->tok != TK_end) lex_match(ls, TK_end, TK_function, line); pt = fs_finish(ls, (ls->lastline = ls->linenumber)); pfs->bcbase = ls->bcstack + oldbase; /* May have been reallocated. */ pfs->bclim = (BCPos)(ls->sizebcstack - oldbase); /* Store new prototype in the constant array of the parent. */ expr_init(e, VRELOCABLE, bcemit_AD(pfs, BC_FNEW, 0, const_gc(pfs, obj2gco(pt), LJ_TPROTO))); #if LJ_HASFFI pfs->flags |= (fs.flags & PROTO_FFI); #endif if (!(pfs->flags & PROTO_CHILD)) { if (pfs->flags & PROTO_HAS_RETURN) pfs->flags |= PROTO_FIXUP_RETURN; pfs->flags |= PROTO_CHILD; } lj_lex_next(ls); } /* Parse expression list. Last expression is left open. */ static BCReg expr_list(LexState *ls, ExpDesc *v) { BCReg n = 1; expr(ls, v); while (lex_opt(ls, ',')) { expr_tonextreg(ls->fs, v); expr(ls, v); n++; } return n; } /* Parse function argument list. */ static void parse_args(LexState *ls, ExpDesc *e) { FuncState *fs = ls->fs; ExpDesc args; BCIns ins; BCReg base; BCLine line = ls->linenumber; if (ls->tok == '(') { #if !LJ_52 if (line != ls->lastline) err_syntax(ls, LJ_ERR_XAMBIG); #endif lj_lex_next(ls); if (ls->tok == ')') { /* f(). */ args.k = VVOID; } else { expr_list(ls, &args); if (args.k == VCALL) /* f(a, b, g()) or f(a, b, ...). */ setbc_b(bcptr(fs, &args), 0); /* Pass on multiple results. */ } lex_match(ls, ')', '(', line); } else if (ls->tok == '{') { expr_table(ls, &args); } else if (ls->tok == TK_string) { expr_init(&args, VKSTR, 0); args.u.sval = strV(&ls->tokval); lj_lex_next(ls); } else { err_syntax(ls, LJ_ERR_XFUNARG); return; /* Silence compiler. */ } lua_assert(e->k == VNONRELOC); base = e->u.s.info; /* Base register for call. */ if (args.k == VCALL) { ins = BCINS_ABC(BC_CALLM, base, 2, args.u.s.aux - base - 1 - LJ_FR2); } else { if (args.k != VVOID) expr_tonextreg(fs, &args); ins = BCINS_ABC(BC_CALL, base, 2, fs->freereg - base - LJ_FR2); } expr_init(e, VCALL, bcemit_INS(fs, ins)); e->u.s.aux = base; fs->bcbase[fs->pc - 1].line = line; fs->freereg = base+1; /* Leave one result by default. */ } /* Parse primary expression. */ static void expr_primary(LexState *ls, ExpDesc *v) { FuncState *fs = ls->fs; /* Parse prefix expression. */ if (ls->tok == '(') { BCLine line = ls->linenumber; lj_lex_next(ls); expr(ls, v); lex_match(ls, ')', '(', line); expr_discharge(ls->fs, v); } else if (ls->tok == TK_name || (!LJ_52 && ls->tok == TK_goto)) { var_lookup(ls, v); } else { err_syntax(ls, LJ_ERR_XSYMBOL); } for (;;) { /* Parse multiple expression suffixes. */ if (ls->tok == '.') { expr_field(ls, v); } else if (ls->tok == '[') { ExpDesc key; expr_toanyreg(fs, v); expr_bracket(ls, &key); expr_index(fs, v, &key); } else if (ls->tok == ':') { ExpDesc key; lj_lex_next(ls); expr_str(ls, &key); bcemit_method(fs, v, &key); parse_args(ls, v); } else if (ls->tok == '(' || ls->tok == TK_string || ls->tok == '{') { expr_tonextreg(fs, v); if (LJ_FR2) bcreg_reserve(fs, 1); parse_args(ls, v); } else { break; } } } /* Parse simple expression. */ static void expr_simple(LexState *ls, ExpDesc *v) { switch (ls->tok) { case TK_number: expr_init(v, (LJ_HASFFI && tviscdata(&ls->tokval)) ? VKCDATA : VKNUM, 0); copyTV(ls->L, &v->u.nval, &ls->tokval); break; case TK_string: expr_init(v, VKSTR, 0); v->u.sval = strV(&ls->tokval); break; case TK_nil: expr_init(v, VKNIL, 0); break; case TK_true: expr_init(v, VKTRUE, 0); break; case TK_false: expr_init(v, VKFALSE, 0); break; case TK_dots: { /* Vararg. */ FuncState *fs = ls->fs; BCReg base; checkcond(ls, fs->flags & PROTO_VARARG, LJ_ERR_XDOTS); bcreg_reserve(fs, 1); base = fs->freereg-1; expr_init(v, VCALL, bcemit_ABC(fs, BC_VARG, base, 2, fs->numparams)); v->u.s.aux = base; break; } case '{': /* Table constructor. */ expr_table(ls, v); return; case TK_function: lj_lex_next(ls); parse_body(ls, v, 0, ls->linenumber); return; default: expr_primary(ls, v); return; } lj_lex_next(ls); } /* Manage syntactic levels to avoid blowing up the stack. */ static void synlevel_begin(LexState *ls) { if (++ls->level >= LJ_MAX_XLEVEL) lj_lex_error(ls, 0, LJ_ERR_XLEVELS); } #define synlevel_end(ls) ((ls)->level--) /* Convert token to binary operator. */ static BinOpr token2binop(LexToken tok) { switch (tok) { case '+': return OPR_ADD; case '-': return OPR_SUB; case '*': return OPR_MUL; case '/': return OPR_DIV; case '%': return OPR_MOD; case '^': return OPR_POW; case TK_concat: return OPR_CONCAT; case TK_ne: return OPR_NE; case TK_eq: return OPR_EQ; case '<': return OPR_LT; case TK_le: return OPR_LE; case '>': return OPR_GT; case TK_ge: return OPR_GE; case TK_and: return OPR_AND; case TK_or: return OPR_OR; default: return OPR_NOBINOPR; } } /* Priorities for each binary operator. ORDER OPR. */ static const struct { uint8_t left; /* Left priority. */ uint8_t right; /* Right priority. */ } priority[] = { {6,6}, {6,6}, {7,7}, {7,7}, {7,7}, /* ADD SUB MUL DIV MOD */ {10,9}, {5,4}, /* POW CONCAT (right associative) */ {3,3}, {3,3}, /* EQ NE */ {3,3}, {3,3}, {3,3}, {3,3}, /* LT GE GT LE */ {2,2}, {1,1} /* AND OR */ }; #define UNARY_PRIORITY 8 /* Priority for unary operators. */ /* Forward declaration. */ static BinOpr expr_binop(LexState *ls, ExpDesc *v, uint32_t limit); /* Parse unary expression. */ static void expr_unop(LexState *ls, ExpDesc *v) { BCOp op; if (ls->tok == TK_not) { op = BC_NOT; } else if (ls->tok == '-') { op = BC_UNM; } else if (ls->tok == '#') { op = BC_LEN; } else { expr_simple(ls, v); return; } lj_lex_next(ls); expr_binop(ls, v, UNARY_PRIORITY); bcemit_unop(ls->fs, op, v); } /* Parse binary expressions with priority higher than the limit. */ static BinOpr expr_binop(LexState *ls, ExpDesc *v, uint32_t limit) { BinOpr op; synlevel_begin(ls); expr_unop(ls, v); op = token2binop(ls->tok); while (op != OPR_NOBINOPR && priority[op].left > limit) { ExpDesc v2; BinOpr nextop; lj_lex_next(ls); bcemit_binop_left(ls->fs, op, v); /* Parse binary expression with higher priority. */ nextop = expr_binop(ls, &v2, priority[op].right); bcemit_binop(ls->fs, op, v, &v2); op = nextop; } synlevel_end(ls); return op; /* Return unconsumed binary operator (if any). */ } /* Parse expression. */ static void expr(LexState *ls, ExpDesc *v) { expr_binop(ls, v, 0); /* Priority 0: parse whole expression. */ } /* Assign expression to the next register. */ static void expr_next(LexState *ls) { ExpDesc e; expr(ls, &e); expr_tonextreg(ls->fs, &e); } /* Parse conditional expression. */ static BCPos expr_cond(LexState *ls) { ExpDesc v; expr(ls, &v); if (v.k == VKNIL) v.k = VKFALSE; bcemit_branch_t(ls->fs, &v); return v.f; } /* -- Assignments --------------------------------------------------------- */ /* List of LHS variables. */ typedef struct LHSVarList { ExpDesc v; /* LHS variable. */ struct LHSVarList *prev; /* Link to previous LHS variable. */ } LHSVarList; /* Eliminate write-after-read hazards for local variable assignment. */ static void assign_hazard(LexState *ls, LHSVarList *lh, const ExpDesc *v) { FuncState *fs = ls->fs; BCReg reg = v->u.s.info; /* Check against this variable. */ BCReg tmp = fs->freereg; /* Rename to this temp. register (if needed). */ int hazard = 0; for (; lh; lh = lh->prev) { if (lh->v.k == VINDEXED) { if (lh->v.u.s.info == reg) { /* t[i], t = 1, 2 */ hazard = 1; lh->v.u.s.info = tmp; } if (lh->v.u.s.aux == reg) { /* t[i], i = 1, 2 */ hazard = 1; lh->v.u.s.aux = tmp; } } } if (hazard) { bcemit_AD(fs, BC_MOV, tmp, reg); /* Rename conflicting variable. */ bcreg_reserve(fs, 1); } } /* Adjust LHS/RHS of an assignment. */ static void assign_adjust(LexState *ls, BCReg nvars, BCReg nexps, ExpDesc *e) { FuncState *fs = ls->fs; int32_t extra = (int32_t)nvars - (int32_t)nexps; if (e->k == VCALL) { extra++; /* Compensate for the VCALL itself. */ if (extra < 0) extra = 0; setbc_b(bcptr(fs, e), extra+1); /* Fixup call results. */ if (extra > 1) bcreg_reserve(fs, (BCReg)extra-1); } else { if (e->k != VVOID) expr_tonextreg(fs, e); /* Close last expression. */ if (extra > 0) { /* Leftover LHS are set to nil. */ BCReg reg = fs->freereg; bcreg_reserve(fs, (BCReg)extra); bcemit_nil(fs, reg, (BCReg)extra); } } } /* Recursively parse assignment statement. */ static void parse_assignment(LexState *ls, LHSVarList *lh, BCReg nvars) { ExpDesc e; checkcond(ls, VLOCAL <= lh->v.k && lh->v.k <= VINDEXED, LJ_ERR_XSYNTAX); if (lex_opt(ls, ',')) { /* Collect LHS list and recurse upwards. */ LHSVarList vl; vl.prev = lh; expr_primary(ls, &vl.v); if (vl.v.k == VLOCAL) assign_hazard(ls, lh, &vl.v); checklimit(ls->fs, ls->level + nvars, LJ_MAX_XLEVEL, "variable names"); parse_assignment(ls, &vl, nvars+1); } else { /* Parse RHS. */ BCReg nexps; lex_check(ls, '='); nexps = expr_list(ls, &e); if (nexps == nvars) { if (e.k == VCALL) { if (bc_op(*bcptr(ls->fs, &e)) == BC_VARG) { /* Vararg assignment. */ ls->fs->freereg--; e.k = VRELOCABLE; } else { /* Multiple call results. */ e.u.s.info = e.u.s.aux; /* Base of call is not relocatable. */ e.k = VNONRELOC; } } bcemit_store(ls->fs, &lh->v, &e); return; } assign_adjust(ls, nvars, nexps, &e); if (nexps > nvars) ls->fs->freereg -= nexps - nvars; /* Drop leftover regs. */ } /* Assign RHS to LHS and recurse downwards. */ expr_init(&e, VNONRELOC, ls->fs->freereg-1); bcemit_store(ls->fs, &lh->v, &e); } /* Parse call statement or assignment. */ static void parse_call_assign(LexState *ls) { FuncState *fs = ls->fs; LHSVarList vl; expr_primary(ls, &vl.v); if (vl.v.k == VCALL) { /* Function call statement. */ setbc_b(bcptr(fs, &vl.v), 1); /* No results. */ } else { /* Start of an assignment. */ vl.prev = NULL; parse_assignment(ls, &vl, 1); } } /* Parse 'local' statement. */ static void parse_local(LexState *ls) { if (lex_opt(ls, TK_function)) { /* Local function declaration. */ ExpDesc v, b; FuncState *fs = ls->fs; var_new(ls, 0, lex_str(ls)); expr_init(&v, VLOCAL, fs->freereg); v.u.s.aux = fs->varmap[fs->freereg]; bcreg_reserve(fs, 1); var_add(ls, 1); parse_body(ls, &b, 0, ls->linenumber); /* bcemit_store(fs, &v, &b) without setting VSTACK_VAR_RW. */ expr_free(fs, &b); expr_toreg(fs, &b, v.u.s.info); /* The upvalue is in scope, but the local is only valid after the store. */ var_get(ls, fs, fs->nactvar - 1).startpc = fs->pc; } else { /* Local variable declaration. */ ExpDesc e; BCReg nexps, nvars = 0; do { /* Collect LHS. */ var_new(ls, nvars++, lex_str(ls)); } while (lex_opt(ls, ',')); if (lex_opt(ls, '=')) { /* Optional RHS. */ nexps = expr_list(ls, &e); } else { /* Or implicitly set to nil. */ e.k = VVOID; nexps = 0; } assign_adjust(ls, nvars, nexps, &e); var_add(ls, nvars); } } /* Parse 'function' statement. */ static void parse_func(LexState *ls, BCLine line) { FuncState *fs; ExpDesc v, b; int needself = 0; lj_lex_next(ls); /* Skip 'function'. */ /* Parse function name. */ var_lookup(ls, &v); while (ls->tok == '.') /* Multiple dot-separated fields. */ expr_field(ls, &v); if (ls->tok == ':') { /* Optional colon to signify method call. */ needself = 1; expr_field(ls, &v); } parse_body(ls, &b, needself, line); fs = ls->fs; bcemit_store(fs, &v, &b); fs->bcbase[fs->pc - 1].line = line; /* Set line for the store. */ } /* -- Control transfer statements ----------------------------------------- */ /* Check for end of block. */ static int parse_isend(LexToken tok) { switch (tok) { case TK_else: case TK_elseif: case TK_end: case TK_until: case TK_eof: return 1; default: return 0; } } /* Parse 'return' statement. */ static void parse_return(LexState *ls) { BCIns ins; FuncState *fs = ls->fs; lj_lex_next(ls); /* Skip 'return'. */ fs->flags |= PROTO_HAS_RETURN; if (parse_isend(ls->tok) || ls->tok == ';') { /* Bare return. */ ins = BCINS_AD(BC_RET0, 0, 1); } else { /* Return with one or more values. */ ExpDesc e; /* Receives the _last_ expression in the list. */ BCReg nret = expr_list(ls, &e); if (nret == 1) { /* Return one result. */ if (e.k == VCALL) { /* Check for tail call. */ BCIns *ip = bcptr(fs, &e); /* It doesn't pay off to add BC_VARGT just for 'return ...'. */ if (bc_op(*ip) == BC_VARG) goto notailcall; fs->pc--; ins = BCINS_AD(bc_op(*ip)-BC_CALL+BC_CALLT, bc_a(*ip), bc_c(*ip)); } else { /* Can return the result from any register. */ ins = BCINS_AD(BC_RET1, expr_toanyreg(fs, &e), 2); } } else { if (e.k == VCALL) { /* Append all results from a call. */ notailcall: setbc_b(bcptr(fs, &e), 0); ins = BCINS_AD(BC_RETM, fs->nactvar, e.u.s.aux - fs->nactvar); } else { expr_tonextreg(fs, &e); /* Force contiguous registers. */ ins = BCINS_AD(BC_RET, fs->nactvar, nret+1); } } } if (fs->flags & PROTO_CHILD) bcemit_AJ(fs, BC_UCLO, 0, 0); /* May need to close upvalues first. */ bcemit_INS(fs, ins); } /* Parse 'break' statement. */ static void parse_break(LexState *ls) { ls->fs->bl->flags |= FSCOPE_BREAK; gola_new(ls, NAME_BREAK, VSTACK_GOTO, bcemit_jmp(ls->fs)); } /* Parse 'goto' statement. */ static void parse_goto(LexState *ls) { FuncState *fs = ls->fs; GCstr *name = lex_str(ls); VarInfo *vl = gola_findlabel(ls, name); if (vl) /* Treat backwards goto within same scope like a loop. */ bcemit_AJ(fs, BC_LOOP, vl->slot, -1); /* No BC range check. */ fs->bl->flags |= FSCOPE_GOLA; gola_new(ls, name, VSTACK_GOTO, bcemit_jmp(fs)); } /* Parse label. */ static void parse_label(LexState *ls) { FuncState *fs = ls->fs; GCstr *name; MSize idx; fs->lasttarget = fs->pc; fs->bl->flags |= FSCOPE_GOLA; lj_lex_next(ls); /* Skip '::'. */ name = lex_str(ls); if (gola_findlabel(ls, name)) lj_lex_error(ls, 0, LJ_ERR_XLDUP, strdata(name)); idx = gola_new(ls, name, VSTACK_LABEL, fs->pc); lex_check(ls, TK_label); /* Recursively parse trailing statements: labels and ';' (Lua 5.2 only). */ for (;;) { if (ls->tok == TK_label) { synlevel_begin(ls); parse_label(ls); synlevel_end(ls); } else if (LJ_52 && ls->tok == ';') { lj_lex_next(ls); } else { break; } } /* Trailing label is considered to be outside of scope. */ if (parse_isend(ls->tok) && ls->tok != TK_until) ls->vstack[idx].slot = fs->bl->nactvar; gola_resolve(ls, fs->bl, idx); } /* -- Blocks, loops and conditional statements ---------------------------- */ /* Parse a block. */ static void parse_block(LexState *ls) { FuncState *fs = ls->fs; FuncScope bl; fscope_begin(fs, &bl, 0); parse_chunk(ls); fscope_end(fs); } /* Parse 'while' statement. */ static void parse_while(LexState *ls, BCLine line) { FuncState *fs = ls->fs; BCPos start, loop, condexit; FuncScope bl; lj_lex_next(ls); /* Skip 'while'. */ start = fs->lasttarget = fs->pc; condexit = expr_cond(ls); fscope_begin(fs, &bl, FSCOPE_LOOP); lex_check(ls, TK_do); loop = bcemit_AD(fs, BC_LOOP, fs->nactvar, 0); parse_block(ls); jmp_patch(fs, bcemit_jmp(fs), start); lex_match(ls, TK_end, TK_while, line); fscope_end(fs); jmp_tohere(fs, condexit); jmp_patchins(fs, loop, fs->pc); } /* Parse 'repeat' statement. */ static void parse_repeat(LexState *ls, BCLine line) { FuncState *fs = ls->fs; BCPos loop = fs->lasttarget = fs->pc; BCPos condexit; FuncScope bl1, bl2; fscope_begin(fs, &bl1, FSCOPE_LOOP); /* Breakable loop scope. */ fscope_begin(fs, &bl2, 0); /* Inner scope. */ lj_lex_next(ls); /* Skip 'repeat'. */ bcemit_AD(fs, BC_LOOP, fs->nactvar, 0); parse_chunk(ls); lex_match(ls, TK_until, TK_repeat, line); condexit = expr_cond(ls); /* Parse condition (still inside inner scope). */ if (!(bl2.flags & FSCOPE_UPVAL)) { /* No upvalues? Just end inner scope. */ fscope_end(fs); } else { /* Otherwise generate: cond: UCLO+JMP out, !cond: UCLO+JMP loop. */ parse_break(ls); /* Break from loop and close upvalues. */ jmp_tohere(fs, condexit); fscope_end(fs); /* End inner scope and close upvalues. */ condexit = bcemit_jmp(fs); } jmp_patch(fs, condexit, loop); /* Jump backwards if !cond. */ jmp_patchins(fs, loop, fs->pc); fscope_end(fs); /* End loop scope. */ } /* Parse numeric 'for'. */ static void parse_for_num(LexState *ls, GCstr *varname, BCLine line) { FuncState *fs = ls->fs; BCReg base = fs->freereg; FuncScope bl; BCPos loop, loopend; /* Hidden control variables. */ var_new_fixed(ls, FORL_IDX, VARNAME_FOR_IDX); var_new_fixed(ls, FORL_STOP, VARNAME_FOR_STOP); var_new_fixed(ls, FORL_STEP, VARNAME_FOR_STEP); /* Visible copy of index variable. */ var_new(ls, FORL_EXT, varname); lex_check(ls, '='); expr_next(ls); lex_check(ls, ','); expr_next(ls); if (lex_opt(ls, ',')) { expr_next(ls); } else { bcemit_AD(fs, BC_KSHORT, fs->freereg, 1); /* Default step is 1. */ bcreg_reserve(fs, 1); } var_add(ls, 3); /* Hidden control variables. */ lex_check(ls, TK_do); loop = bcemit_AJ(fs, BC_FORI, base, NO_JMP); fscope_begin(fs, &bl, 0); /* Scope for visible variables. */ var_add(ls, 1); bcreg_reserve(fs, 1); parse_block(ls); fscope_end(fs); /* Perform loop inversion. Loop control instructions are at the end. */ loopend = bcemit_AJ(fs, BC_FORL, base, NO_JMP); fs->bcbase[loopend].line = line; /* Fix line for control ins. */ jmp_patchins(fs, loopend, loop+1); jmp_patchins(fs, loop, fs->pc); } /* Try to predict whether the iterator is next() and specialize the bytecode. ** Detecting next() and pairs() by name is simplistic, but quite effective. ** The interpreter backs off if the check for the closure fails at runtime. */ static int predict_next(LexState *ls, FuncState *fs, BCPos pc) { BCIns ins = fs->bcbase[pc].ins; GCstr *name; cTValue *o; switch (bc_op(ins)) { case BC_MOV: name = gco2str(gcref(var_get(ls, fs, bc_d(ins)).name)); break; case BC_UGET: name = gco2str(gcref(ls->vstack[fs->uvmap[bc_d(ins)]].name)); break; case BC_GGET: /* There's no inverse index (yet), so lookup the strings. */ o = lj_tab_getstr(fs->kt, lj_str_newlit(ls->L, "pairs")); if (o && tvhaskslot(o) && tvkslot(o) == bc_d(ins)) return 1; o = lj_tab_getstr(fs->kt, lj_str_newlit(ls->L, "next")); if (o && tvhaskslot(o) && tvkslot(o) == bc_d(ins)) return 1; return 0; default: return 0; } return (name->len == 5 && !strcmp(strdata(name), "pairs")) || (name->len == 4 && !strcmp(strdata(name), "next")); } /* Parse 'for' iterator. */ static void parse_for_iter(LexState *ls, GCstr *indexname) { FuncState *fs = ls->fs; ExpDesc e; BCReg nvars = 0; BCLine line; BCReg base = fs->freereg + 3; BCPos loop, loopend, exprpc = fs->pc; FuncScope bl; int isnext; /* Hidden control variables. */ var_new_fixed(ls, nvars++, VARNAME_FOR_GEN); var_new_fixed(ls, nvars++, VARNAME_FOR_STATE); var_new_fixed(ls, nvars++, VARNAME_FOR_CTL); /* Visible variables returned from iterator. */ var_new(ls, nvars++, indexname); while (lex_opt(ls, ',')) var_new(ls, nvars++, lex_str(ls)); lex_check(ls, TK_in); line = ls->linenumber; assign_adjust(ls, 3, expr_list(ls, &e), &e); /* The iterator needs another 3 [4] slots (func [pc] | state ctl). */ bcreg_bump(fs, 3+LJ_FR2); isnext = (nvars <= 5 && predict_next(ls, fs, exprpc)); var_add(ls, 3); /* Hidden control variables. */ lex_check(ls, TK_do); loop = bcemit_AJ(fs, isnext ? BC_ISNEXT : BC_JMP, base, NO_JMP); fscope_begin(fs, &bl, 0); /* Scope for visible variables. */ var_add(ls, nvars-3); bcreg_reserve(fs, nvars-3); parse_block(ls); fscope_end(fs); /* Perform loop inversion. Loop control instructions are at the end. */ jmp_patchins(fs, loop, fs->pc); bcemit_ABC(fs, isnext ? BC_ITERN : BC_ITERC, base, nvars-3+1, 2+1); loopend = bcemit_AJ(fs, BC_ITERL, base, NO_JMP); fs->bcbase[loopend-1].line = line; /* Fix line for control ins. */ fs->bcbase[loopend].line = line; jmp_patchins(fs, loopend, loop+1); } /* Parse 'for' statement. */ static void parse_for(LexState *ls, BCLine line) { FuncState *fs = ls->fs; GCstr *varname; FuncScope bl; fscope_begin(fs, &bl, FSCOPE_LOOP); lj_lex_next(ls); /* Skip 'for'. */ varname = lex_str(ls); /* Get first variable name. */ if (ls->tok == '=') parse_for_num(ls, varname, line); else if (ls->tok == ',' || ls->tok == TK_in) parse_for_iter(ls, varname); else err_syntax(ls, LJ_ERR_XFOR); lex_match(ls, TK_end, TK_for, line); fscope_end(fs); /* Resolve break list. */ } /* Parse condition and 'then' block. */ static BCPos parse_then(LexState *ls) { BCPos condexit; lj_lex_next(ls); /* Skip 'if' or 'elseif'. */ condexit = expr_cond(ls); lex_check(ls, TK_then); parse_block(ls); return condexit; } /* Parse 'if' statement. */ static void parse_if(LexState *ls, BCLine line) { FuncState *fs = ls->fs; BCPos flist; BCPos escapelist = NO_JMP; flist = parse_then(ls); while (ls->tok == TK_elseif) { /* Parse multiple 'elseif' blocks. */ jmp_append(fs, &escapelist, bcemit_jmp(fs)); jmp_tohere(fs, flist); flist = parse_then(ls); } if (ls->tok == TK_else) { /* Parse optional 'else' block. */ jmp_append(fs, &escapelist, bcemit_jmp(fs)); jmp_tohere(fs, flist); lj_lex_next(ls); /* Skip 'else'. */ parse_block(ls); } else { jmp_append(fs, &escapelist, flist); } jmp_tohere(fs, escapelist); lex_match(ls, TK_end, TK_if, line); } /* -- Parse statements ---------------------------------------------------- */ /* Parse a statement. Returns 1 if it must be the last one in a chunk. */ static int parse_stmt(LexState *ls) { BCLine line = ls->linenumber; switch (ls->tok) { case TK_if: parse_if(ls, line); break; case TK_while: parse_while(ls, line); break; case TK_do: lj_lex_next(ls); parse_block(ls); lex_match(ls, TK_end, TK_do, line); break; case TK_for: parse_for(ls, line); break; case TK_repeat: parse_repeat(ls, line); break; case TK_function: parse_func(ls, line); break; case TK_local: lj_lex_next(ls); parse_local(ls); break; case TK_return: parse_return(ls); return 1; /* Must be last. */ case TK_break: lj_lex_next(ls); parse_break(ls); return !LJ_52; /* Must be last in Lua 5.1. */ #if LJ_52 case ';': lj_lex_next(ls); break; #endif case TK_label: parse_label(ls); break; case TK_goto: if (LJ_52 || lj_lex_lookahead(ls) == TK_name) { lj_lex_next(ls); parse_goto(ls); break; } /* else: fallthrough */ default: parse_call_assign(ls); break; } return 0; } /* A chunk is a list of statements optionally separated by semicolons. */ static void parse_chunk(LexState *ls) { int islast = 0; synlevel_begin(ls); while (!islast && !parse_isend(ls->tok)) { islast = parse_stmt(ls); lex_opt(ls, ';'); lua_assert(ls->fs->framesize >= ls->fs->freereg && ls->fs->freereg >= ls->fs->nactvar); ls->fs->freereg = ls->fs->nactvar; /* Free registers after each stmt. */ } synlevel_end(ls); } /* Entry point of bytecode parser. */ GCproto *lj_parse(LexState *ls) { FuncState fs; FuncScope bl; GCproto *pt; lua_State *L = ls->L; #ifdef LUAJIT_DISABLE_DEBUGINFO ls->chunkname = lj_str_newlit(L, "="); #else ls->chunkname = lj_str_newz(L, ls->chunkarg); #endif setstrV(L, L->top, ls->chunkname); /* Anchor chunkname string. */ incr_top(L); ls->level = 0; fs_init(ls, &fs); fs.linedefined = 0; fs.numparams = 0; fs.bcbase = NULL; fs.bclim = 0; fs.flags |= PROTO_VARARG; /* Main chunk is always a vararg func. */ fscope_begin(&fs, &bl, 0); bcemit_AD(&fs, BC_FUNCV, 0, 0); /* Placeholder. */ lj_lex_next(ls); /* Read-ahead first token. */ parse_chunk(ls); if (ls->tok != TK_eof) err_token(ls, TK_eof); pt = fs_finish(ls, ls->linenumber); L->top--; /* Drop chunkname. */ lua_assert(fs.prev == NULL); lua_assert(ls->fs == NULL); lua_assert(pt->sizeuv == 0); return pt; }