// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details // This code is based on Lua 5.x implementation licensed under MIT License; see lua_LICENSE.txt for details #include "lvm.h" #include "lstate.h" #include "ltable.h" #include "lfunc.h" #include "lstring.h" #include "lgc.h" #include "lmem.h" #include "ldebug.h" #include "ldo.h" #include "lbuiltins.h" #include "lnumutils.h" #include "lbytecode.h" #include // Disable c99-designator to avoid the warning in CGOTO dispatch table #ifdef __clang__ #if __has_warning("-Wc99-designator") #pragma clang diagnostic ignored "-Wc99-designator" #endif #endif // When working with VM code, pay attention to these rules for correctness: // 1. Many external Lua functions can fail; for them to fail and be able to generate a proper stack, we need to copy pc to L->ci->savedpc before the // call // 2. Many external Lua functions can reallocate the stack. This invalidates stack pointers in VM C stack frame, most importantly base, but also // ra/rb/rc! // 3. VM_PROTECT macro saves savedpc and restores base for you; most external calls need to be wrapped into that. However, it does NOT restore // ra/rb/rc! // 4. When copying an object to any existing object as a field, generally speaking you need to call luaC_barrier! Be careful with all setobj calls // 5. To make 4 easier to follow, please use setobj2s for copies to stack and setobj for other copies. // 6. You can define HARDSTACKTESTS in llimits.h which will aggressively realloc stack; with address sanitizer this should be effective at finding // stack corruption bugs // 7. Many external Lua functions can call GC! GC will *not* traverse pointers to new objects that aren't reachable from Lua root. Be careful when // creating new Lua objects, store them to stack soon. // When calling luau_callTM, we usually push the arguments to the top of the stack. // This is safe to do for complicated reasons: // - stack guarantees 1 + EXTRA_STACK room beyond stack_last (see luaD_reallocstack) // - stack reallocation copies values past stack_last // All external function calls that can cause stack realloc or Lua calls have to be wrapped in VM_PROTECT // This makes sure that we save the pc (in case the Lua call needs to generate a backtrace) before the call, // and restores the stack pointer after in case stack gets reallocated // Should only be used on the slow paths. #define VM_PROTECT(x) \ { \ L->ci->savedpc = pc; \ { \ x; \ }; \ base = L->base; \ } // Some external functions can cause an error, but never reallocate the stack; for these, VM_PROTECT_PC() is // a cheaper version of VM_PROTECT that can be called before the external call. #define VM_PROTECT_PC() L->ci->savedpc = pc #define VM_REG(i) (LUAU_ASSERT(unsigned(i) < unsigned(L->top - base)), &base[i]) #define VM_KV(i) (LUAU_ASSERT(unsigned(i) < unsigned(cl->l.p->sizek)), &k[i]) #define VM_UV(i) (LUAU_ASSERT(unsigned(i) < unsigned(cl->nupvalues)), &cl->l.uprefs[i]) #define VM_PATCH_C(pc, slot) *const_cast(pc) = ((uint8_t(slot) << 24) | (0x00ffffffu & *(pc))) #define VM_PATCH_E(pc, slot) *const_cast(pc) = ((uint32_t(slot) << 8) | (0x000000ffu & *(pc))) // NOTE: If debugging the Luau code, disable this macro to prevent timeouts from // occurring when tracing code in Visual Studio / XCode #if 0 #define VM_INTERRUPT() #else #define VM_INTERRUPT() \ { \ void (*interrupt)(lua_State*, int) = L->global->cb.interrupt; \ if (LUAU_UNLIKELY(!!interrupt)) \ { /* the interrupt hook is called right before we advance pc */ \ VM_PROTECT(L->ci->savedpc++; interrupt(L, -1)); \ } \ } #endif #define VM_DISPATCH_OP(op) &&CASE_##op #define VM_DISPATCH_TABLE() \ VM_DISPATCH_OP(LOP_NOP), VM_DISPATCH_OP(LOP_BREAK), VM_DISPATCH_OP(LOP_LOADNIL), VM_DISPATCH_OP(LOP_LOADB), VM_DISPATCH_OP(LOP_LOADN), \ VM_DISPATCH_OP(LOP_LOADK), VM_DISPATCH_OP(LOP_MOVE), VM_DISPATCH_OP(LOP_GETGLOBAL), VM_DISPATCH_OP(LOP_SETGLOBAL), \ VM_DISPATCH_OP(LOP_GETUPVAL), VM_DISPATCH_OP(LOP_SETUPVAL), VM_DISPATCH_OP(LOP_CLOSEUPVALS), VM_DISPATCH_OP(LOP_GETIMPORT), \ VM_DISPATCH_OP(LOP_GETTABLE), VM_DISPATCH_OP(LOP_SETTABLE), VM_DISPATCH_OP(LOP_GETTABLEKS), VM_DISPATCH_OP(LOP_SETTABLEKS), \ VM_DISPATCH_OP(LOP_GETTABLEN), VM_DISPATCH_OP(LOP_SETTABLEN), VM_DISPATCH_OP(LOP_NEWCLOSURE), VM_DISPATCH_OP(LOP_NAMECALL), \ VM_DISPATCH_OP(LOP_CALL), VM_DISPATCH_OP(LOP_RETURN), VM_DISPATCH_OP(LOP_JUMP), VM_DISPATCH_OP(LOP_JUMPBACK), VM_DISPATCH_OP(LOP_JUMPIF), \ VM_DISPATCH_OP(LOP_JUMPIFNOT), VM_DISPATCH_OP(LOP_JUMPIFEQ), VM_DISPATCH_OP(LOP_JUMPIFLE), VM_DISPATCH_OP(LOP_JUMPIFLT), \ VM_DISPATCH_OP(LOP_JUMPIFNOTEQ), VM_DISPATCH_OP(LOP_JUMPIFNOTLE), VM_DISPATCH_OP(LOP_JUMPIFNOTLT), VM_DISPATCH_OP(LOP_ADD), \ VM_DISPATCH_OP(LOP_SUB), VM_DISPATCH_OP(LOP_MUL), VM_DISPATCH_OP(LOP_DIV), VM_DISPATCH_OP(LOP_MOD), VM_DISPATCH_OP(LOP_POW), \ VM_DISPATCH_OP(LOP_ADDK), VM_DISPATCH_OP(LOP_SUBK), VM_DISPATCH_OP(LOP_MULK), VM_DISPATCH_OP(LOP_DIVK), VM_DISPATCH_OP(LOP_MODK), \ VM_DISPATCH_OP(LOP_POWK), VM_DISPATCH_OP(LOP_AND), VM_DISPATCH_OP(LOP_OR), VM_DISPATCH_OP(LOP_ANDK), VM_DISPATCH_OP(LOP_ORK), \ VM_DISPATCH_OP(LOP_CONCAT), VM_DISPATCH_OP(LOP_NOT), VM_DISPATCH_OP(LOP_MINUS), VM_DISPATCH_OP(LOP_LENGTH), VM_DISPATCH_OP(LOP_NEWTABLE), \ VM_DISPATCH_OP(LOP_DUPTABLE), VM_DISPATCH_OP(LOP_SETLIST), VM_DISPATCH_OP(LOP_FORNPREP), VM_DISPATCH_OP(LOP_FORNLOOP), \ VM_DISPATCH_OP(LOP_FORGLOOP), VM_DISPATCH_OP(LOP_FORGPREP_INEXT), VM_DISPATCH_OP(LOP_FORGLOOP_INEXT), VM_DISPATCH_OP(LOP_FORGPREP_NEXT), \ VM_DISPATCH_OP(LOP_FORGLOOP_NEXT), VM_DISPATCH_OP(LOP_GETVARARGS), VM_DISPATCH_OP(LOP_DUPCLOSURE), VM_DISPATCH_OP(LOP_PREPVARARGS), \ VM_DISPATCH_OP(LOP_LOADKX), VM_DISPATCH_OP(LOP_JUMPX), VM_DISPATCH_OP(LOP_FASTCALL), VM_DISPATCH_OP(LOP_COVERAGE), \ VM_DISPATCH_OP(LOP_CAPTURE), VM_DISPATCH_OP(LOP_JUMPIFEQK), VM_DISPATCH_OP(LOP_JUMPIFNOTEQK), VM_DISPATCH_OP(LOP_FASTCALL1), \ VM_DISPATCH_OP(LOP_FASTCALL2), VM_DISPATCH_OP(LOP_FASTCALL2K), #if defined(__GNUC__) || defined(__clang__) #define VM_USE_CGOTO 1 #else #define VM_USE_CGOTO 0 #endif /** * These macros help dispatching Luau opcodes using either case * statements or computed goto. * VM_CASE(op) Generates either a case statement or a label * VM_NEXT() fetch a byte and dispatch or jump to the beginning of the switch statement * VM_CONTINUE() Use an opcode override to dispatch with computed goto or * switch statement to skip a LOP_BREAK instruction. */ #if VM_USE_CGOTO #define VM_CASE(op) CASE_##op: #define VM_NEXT() goto*(SingleStep ? &&dispatch : kDispatchTable[LUAU_INSN_OP(*pc)]) #define VM_CONTINUE(op) goto* kDispatchTable[uint8_t(op)] #else #define VM_CASE(op) case op: #define VM_NEXT() goto dispatch #define VM_CONTINUE(op) \ dispatchOp = uint8_t(op); \ goto dispatchContinue #endif LUAU_NOINLINE static void luau_prepareFORN(lua_State* L, StkId plimit, StkId pstep, StkId pinit) { if (!ttisnumber(pinit) && !luaV_tonumber(pinit, pinit)) luaG_forerror(L, pinit, "initial value"); if (!ttisnumber(plimit) && !luaV_tonumber(plimit, plimit)) luaG_forerror(L, plimit, "limit"); if (!ttisnumber(pstep) && !luaV_tonumber(pstep, pstep)) luaG_forerror(L, pstep, "step"); } LUAU_NOINLINE static bool luau_loopFORG(lua_State* L, int a, int c) { StkId ra = &L->base[a]; LUAU_ASSERT(ra + 6 <= L->top); setobjs2s(L, ra + 3 + 2, ra + 2); setobjs2s(L, ra + 3 + 1, ra + 1); setobjs2s(L, ra + 3, ra); L->top = ra + 3 + 3; /* func. + 2 args (state and index) */ LUAU_ASSERT(L->top <= L->stack_last); luaD_call(L, ra + 3, c); L->top = L->ci->top; // recompute ra since stack might have been reallocated ra = &L->base[a]; LUAU_ASSERT(ra < L->top); // copy first variable back into the iteration index setobjs2s(L, ra + 2, ra + 3); return ttisnil(ra + 2); } // calls a C function f with no yielding support; optionally save one resulting value to the res register // the function and arguments have to already be pushed to L->top LUAU_NOINLINE static void luau_callTM(lua_State* L, int nparams, int res) { ++L->nCcalls; if (L->nCcalls >= LUAI_MAXCCALLS) luaG_runerror(L, "C stack overflow"); luaD_checkstack(L, LUA_MINSTACK); StkId top = L->top; StkId fun = top - nparams - 1; CallInfo* ci = incr_ci(L); ci->func = fun; ci->base = fun + 1; ci->top = top + LUA_MINSTACK; ci->savedpc = NULL; ci->flags = 0; ci->nresults = (res >= 0); LUAU_ASSERT(ci->top <= L->stack_last); LUAU_ASSERT(ttisfunction(ci->func)); LUAU_ASSERT(clvalue(ci->func)->isC); L->base = fun + 1; LUAU_ASSERT(L->top == L->base + nparams); lua_CFunction func = clvalue(fun)->c.f; int n = func(L); LUAU_ASSERT(n >= 0); // yields should have been blocked by nCcalls // ci is our callinfo, cip is our parent // note that we read L->ci again since it may have been reallocated by the call CallInfo* cip = L->ci - 1; // copy return value into parent stack if (res >= 0) { if (n > 0) { setobj2s(L, &cip->base[res], L->top - n); } else { setnilvalue(&cip->base[res]); } } L->ci = cip; L->base = cip->base; L->top = cip->top; --L->nCcalls; } LUAU_NOINLINE static void luau_tryfuncTM(lua_State* L, StkId func) { const TValue* tm = luaT_gettmbyobj(L, func, TM_CALL); if (!ttisfunction(tm)) luaG_typeerror(L, func, "call"); for (StkId p = L->top; p > func; p--) /* open space for metamethod */ setobjs2s(L, p, p - 1); L->top++; /* stack space pre-allocated by the caller */ setobj2s(L, func, tm); /* tag method is the new function to be called */ } LUAU_NOINLINE void luau_callhook(lua_State* L, lua_Hook hook, void* userdata) { ptrdiff_t base = savestack(L, L->base); ptrdiff_t top = savestack(L, L->top); ptrdiff_t ci_top = savestack(L, L->ci->top); int status = L->status; // if the hook is called externally on a paused thread, we need to make sure the paused thread can emit Lua calls if (status == LUA_YIELD || status == LUA_BREAK) { L->status = 0; L->base = L->ci->base; } luaD_checkstack(L, LUA_MINSTACK); /* ensure minimum stack size */ L->ci->top = L->top + LUA_MINSTACK; LUAU_ASSERT(L->ci->top <= L->stack_last); // note: the pc expectations of the hook are matching the general "pc points to next instruction" // however, for the hook to be able to continue execution from the same point, this is called with savedpc at the *current* instruction if (L->ci->savedpc) L->ci->savedpc++; Closure* cl = clvalue(L->ci->func); lua_Debug ar; ar.currentline = cl->isC ? -1 : luaG_getline(cl->l.p, pcRel(L->ci->savedpc, cl->l.p)); ar.userdata = userdata; hook(L, &ar); if (L->ci->savedpc) L->ci->savedpc--; L->ci->top = restorestack(L, ci_top); L->top = restorestack(L, top); // note that we only restore the paused state if the hook hasn't yielded by itself if (status == LUA_YIELD && L->status != LUA_YIELD) { L->status = LUA_YIELD; L->base = restorestack(L, base); } else if (status == LUA_BREAK) { LUAU_ASSERT(L->status != LUA_BREAK); // hook shouldn't break again L->status = LUA_BREAK; L->base = restorestack(L, base); } } inline bool luau_skipstep(uint8_t op) { return op == LOP_PREPVARARGS || op == LOP_BREAK; } template static void luau_execute(lua_State* L) { #if VM_USE_CGOTO static const void* kDispatchTable[256] = {VM_DISPATCH_TABLE()}; #endif // the critical interpreter state, stored in locals for performance // the hope is that these map to registers without spilling (which is not true for x86 :/) Closure* cl; StkId base; TValue* k; const Instruction* pc; LUAU_ASSERT(isLua(L->ci)); LUAU_ASSERT(luaC_threadactive(L)); LUAU_ASSERT(!luaC_threadsleeping(L)); pc = L->ci->savedpc; cl = clvalue(L->ci->func); base = L->base; k = cl->l.p->k; VM_NEXT(); // starts the interpreter "loop" { dispatch: // Note: this code doesn't always execute! on some platforms we use computed goto which bypasses all of this unless we run in single-step mode // Therefore only ever put assertions here. LUAU_ASSERT(base == L->base && L->base == L->ci->base); LUAU_ASSERT(base <= L->top && L->top <= L->stack + L->stacksize); // ... and singlestep logic :) if (SingleStep) { if (L->global->cb.debugstep && !luau_skipstep(LUAU_INSN_OP(*pc))) { VM_PROTECT(luau_callhook(L, L->global->cb.debugstep, NULL)); // allow debugstep hook to put thread into error/yield state if (L->status != 0) goto exit; } #if VM_USE_CGOTO VM_CONTINUE(LUAU_INSN_OP(*pc)); #endif } #if !VM_USE_CGOTO size_t dispatchOp = LUAU_INSN_OP(*pc); dispatchContinue: switch (dispatchOp) #endif { VM_CASE(LOP_NOP) { Instruction insn = *pc++; LUAU_ASSERT(insn == 0); VM_NEXT(); } VM_CASE(LOP_LOADNIL) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); setnilvalue(ra); VM_NEXT(); } VM_CASE(LOP_LOADB) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); setbvalue(ra, LUAU_INSN_B(insn)); pc += LUAU_INSN_C(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_LOADN) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); setnvalue(ra, LUAU_INSN_D(insn)); VM_NEXT(); } VM_CASE(LOP_LOADK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* kv = VM_KV(LUAU_INSN_D(insn)); setobj2s(L, ra, kv); VM_NEXT(); } VM_CASE(LOP_MOVE) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); setobj2s(L, ra, rb); VM_NEXT(); } VM_CASE(LOP_GETGLOBAL) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); uint32_t aux = *pc++; TValue* kv = VM_KV(aux); LUAU_ASSERT(ttisstring(kv)); // fast-path: value is in expected slot Table* h = cl->env; int slot = LUAU_INSN_C(insn) & h->nodemask8; LuaNode* n = &h->node[slot]; if (LUAU_LIKELY(ttisstring(gkey(n)) && tsvalue(gkey(n)) == tsvalue(kv)) && !ttisnil(gval(n))) { setobj2s(L, ra, gval(n)); VM_NEXT(); } else { // slow-path, may invoke Lua calls via __index metamethod TValue g; sethvalue(L, &g, h); L->cachedslot = slot; VM_PROTECT(luaV_gettable(L, &g, kv, ra)); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); VM_NEXT(); } } VM_CASE(LOP_SETGLOBAL) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); uint32_t aux = *pc++; TValue* kv = VM_KV(aux); LUAU_ASSERT(ttisstring(kv)); // fast-path: value is in expected slot Table* h = cl->env; int slot = LUAU_INSN_C(insn) & h->nodemask8; LuaNode* n = &h->node[slot]; if (LUAU_LIKELY(ttisstring(gkey(n)) && tsvalue(gkey(n)) == tsvalue(kv) && !ttisnil(gval(n)) && !h->readonly)) { setobj(L, gval(n), ra); luaC_barriert(L, h, ra); VM_NEXT(); } else { // slow-path, may invoke Lua calls via __newindex metamethod TValue g; sethvalue(L, &g, h); L->cachedslot = slot; VM_PROTECT(luaV_settable(L, &g, kv, ra)); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); VM_NEXT(); } } VM_CASE(LOP_GETUPVAL) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* ur = VM_UV(LUAU_INSN_B(insn)); TValue* v = ttisupval(ur) ? upvalue(ur)->v : ur; setobj2s(L, ra, v); VM_NEXT(); } VM_CASE(LOP_SETUPVAL) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* ur = VM_UV(LUAU_INSN_B(insn)); UpVal* uv = upvalue(ur); setobj(L, uv->v, ra); luaC_barrier(L, uv, ra); luaC_upvalbarrier(L, uv, uv->v); VM_NEXT(); } VM_CASE(LOP_CLOSEUPVALS) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); if (L->openupval && gco2uv(L->openupval)->v >= ra) luaF_close(L, ra); VM_NEXT(); } VM_CASE(LOP_GETIMPORT) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* kv = VM_KV(LUAU_INSN_D(insn)); // fast-path: import resolution was successful and closure environment is "safe" for import if (!ttisnil(kv) && cl->env->safeenv) { setobj2s(L, ra, kv); pc++; // skip over AUX VM_NEXT(); } else { uint32_t aux = *pc++; VM_PROTECT(luaV_getimport(L, cl->env, k, aux, /* propagatenil= */ false)); ra = VM_REG(LUAU_INSN_A(insn)); // previous call may change the stack setobj2s(L, ra, L->top - 1); L->top--; VM_NEXT(); } } VM_CASE(LOP_GETTABLEKS) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); uint32_t aux = *pc++; TValue* kv = VM_KV(aux); LUAU_ASSERT(ttisstring(kv)); // fast-path: built-in table if (ttistable(rb)) { Table* h = hvalue(rb); int slot = LUAU_INSN_C(insn) & h->nodemask8; LuaNode* n = &h->node[slot]; // fast-path: value is in expected slot if (LUAU_LIKELY(ttisstring(gkey(n)) && tsvalue(gkey(n)) == tsvalue(kv) && !ttisnil(gval(n)))) { setobj2s(L, ra, gval(n)); VM_NEXT(); } else if (!h->metatable) { // fast-path: value is not in expected slot, but the table lookup doesn't involve metatable const TValue* res = luaH_getstr(h, tsvalue(kv)); if (res != luaO_nilobject) { int cachedslot = gval2slot(h, res); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, cachedslot); } setobj2s(L, ra, res); VM_NEXT(); } else { // slow-path, may invoke Lua calls via __index metamethod L->cachedslot = slot; VM_PROTECT(luaV_gettable(L, rb, kv, ra)); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); VM_NEXT(); } } else { // fast-path: user data with C __index TM const TValue* fn = 0; if (ttisuserdata(rb) && (fn = fasttm(L, uvalue(rb)->metatable, TM_INDEX)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, kv); L->top = top + 3; L->cachedslot = LUAU_INSN_C(insn); VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); VM_NEXT(); } else if (ttisvector(rb)) { // fast-path: quick case-insensitive comparison with "X"/"Y"/"Z" const char* name = getstr(tsvalue(kv)); int ic = (name[0] | ' ') - 'x'; #if LUA_VECTOR_SIZE == 4 // 'w' is before 'x' in ascii, so ic is -1 when indexing with 'w' if (ic == -1) ic = 3; #endif if (unsigned(ic) < LUA_VECTOR_SIZE && name[1] == '\0') { setnvalue(ra, rb->value.v[ic]); VM_NEXT(); } fn = fasttm(L, L->global->mt[LUA_TVECTOR], TM_INDEX); if (fn && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, kv); L->top = top + 3; L->cachedslot = LUAU_INSN_C(insn); VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); VM_NEXT(); } else { // slow-path, may invoke Lua calls via __index metamethod VM_PROTECT(luaV_gettable(L, rb, kv, ra)); VM_NEXT(); } } else { // slow-path, may invoke Lua calls via __index metamethod VM_PROTECT(luaV_gettable(L, rb, kv, ra)); VM_NEXT(); } } } VM_CASE(LOP_SETTABLEKS) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); uint32_t aux = *pc++; TValue* kv = VM_KV(aux); LUAU_ASSERT(ttisstring(kv)); // fast-path: built-in table if (ttistable(rb)) { Table* h = hvalue(rb); int slot = LUAU_INSN_C(insn) & h->nodemask8; LuaNode* n = &h->node[slot]; // fast-path: value is in expected slot if (LUAU_LIKELY(ttisstring(gkey(n)) && tsvalue(gkey(n)) == tsvalue(kv) && !ttisnil(gval(n)) && !h->readonly)) { setobj(L, gval(n), ra); luaC_barriert(L, h, ra); VM_NEXT(); } else if (fastnotm(h->metatable, TM_NEWINDEX) && !h->readonly) { VM_PROTECT_PC(); // set may fail TValue* res = luaH_setstr(L, h, tsvalue(kv)); if (res != luaO_nilobject) { int cachedslot = gval2slot(h, res); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, cachedslot); } setobj(L, res, ra); luaC_barriert(L, h, ra); VM_NEXT(); } else { // slow-path, may invoke Lua calls via __index metamethod L->cachedslot = slot; VM_PROTECT(luaV_settable(L, rb, kv, ra)); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); VM_NEXT(); } } else { // fast-path: user data with C __index TM const TValue* fn = 0; if (ttisuserdata(rb) && (fn = fasttm(L, uvalue(rb)->metatable, TM_NEWINDEX)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 4 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, kv); setobj2s(L, top + 3, ra); L->top = top + 4; L->cachedslot = LUAU_INSN_C(insn); VM_PROTECT(luau_callTM(L, 3, -1)); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); VM_NEXT(); } else { // slow-path, may invoke Lua calls via __index metamethod VM_PROTECT(luaV_settable(L, rb, kv, ra)); VM_NEXT(); } } } VM_CASE(LOP_GETTABLE) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path: array lookup if (ttistable(rb) && ttisnumber(rc)) { Table* h = hvalue(rb); double indexd = nvalue(rc); int index = int(indexd); // index has to be an exact integer and in-bounds for the array portion if (LUAU_LIKELY(unsigned(index - 1) < unsigned(h->sizearray) && !h->metatable && double(index) == indexd)) { setobj2s(L, ra, &h->array[unsigned(index - 1)]); VM_NEXT(); } else { // slow-path: handles out of bounds array lookups and non-integer numeric keys VM_PROTECT(luaV_gettable(L, rb, rc, ra)); VM_NEXT(); } } else { // slow-path: handles non-array table lookup as well as __index MT calls VM_PROTECT(luaV_gettable(L, rb, rc, ra)); VM_NEXT(); } } VM_CASE(LOP_SETTABLE) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path: array assign if (ttistable(rb) && ttisnumber(rc)) { Table* h = hvalue(rb); double indexd = nvalue(rc); int index = int(indexd); // index has to be an exact integer and in-bounds for the array portion if (LUAU_LIKELY(unsigned(index - 1) < unsigned(h->sizearray) && !h->metatable && !h->readonly && double(index) == indexd)) { setobj2t(L, &h->array[unsigned(index - 1)], ra); luaC_barriert(L, h, ra); VM_NEXT(); } else { // slow-path: handles out of bounds array assignments and non-integer numeric keys VM_PROTECT(luaV_settable(L, rb, rc, ra)); VM_NEXT(); } } else { // slow-path: handles non-array table access as well as __newindex MT calls VM_PROTECT(luaV_settable(L, rb, rc, ra)); VM_NEXT(); } } VM_CASE(LOP_GETTABLEN) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); int c = LUAU_INSN_C(insn); // fast-path: array lookup if (ttistable(rb)) { Table* h = hvalue(rb); if (LUAU_LIKELY(unsigned(c) < unsigned(h->sizearray) && !h->metatable)) { setobj2s(L, ra, &h->array[c]); VM_NEXT(); } } // slow-path: handles out of bounds array lookups TValue n; setnvalue(&n, c + 1); VM_PROTECT(luaV_gettable(L, rb, &n, ra)); VM_NEXT(); } VM_CASE(LOP_SETTABLEN) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); int c = LUAU_INSN_C(insn); // fast-path: array assign if (ttistable(rb)) { Table* h = hvalue(rb); if (LUAU_LIKELY(unsigned(c) < unsigned(h->sizearray) && !h->metatable && !h->readonly)) { setobj2t(L, &h->array[c], ra); luaC_barriert(L, h, ra); VM_NEXT(); } } // slow-path: handles out of bounds array lookups TValue n; setnvalue(&n, c + 1); VM_PROTECT(luaV_settable(L, rb, &n, ra)); VM_NEXT(); } VM_CASE(LOP_NEWCLOSURE) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); Proto* pv = cl->l.p->p[LUAU_INSN_D(insn)]; LUAU_ASSERT(unsigned(LUAU_INSN_D(insn)) < unsigned(cl->l.p->sizep)); // note: we save closure to stack early in case the code below wants to capture it by value Closure* ncl = luaF_newLclosure(L, pv->nups, cl->env, pv); setclvalue(L, ra, ncl); for (int ui = 0; ui < pv->nups; ++ui) { Instruction uinsn = *pc++; LUAU_ASSERT(LUAU_INSN_OP(uinsn) == LOP_CAPTURE); switch (LUAU_INSN_A(uinsn)) { case LCT_VAL: setobj(L, &ncl->l.uprefs[ui], VM_REG(LUAU_INSN_B(uinsn))); break; case LCT_REF: setupvalue(L, &ncl->l.uprefs[ui], luaF_findupval(L, VM_REG(LUAU_INSN_B(uinsn)))); break; case LCT_UPVAL: setobj(L, &ncl->l.uprefs[ui], VM_UV(LUAU_INSN_B(uinsn))); break; default: LUAU_ASSERT(!"Unknown upvalue capture type"); } } VM_PROTECT(luaC_checkGC(L)); VM_NEXT(); } VM_CASE(LOP_NAMECALL) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); uint32_t aux = *pc++; TValue* kv = VM_KV(aux); LUAU_ASSERT(ttisstring(kv)); if (ttistable(rb)) { Table* h = hvalue(rb); // note: we can't use nodemask8 here because we need to query the main position of the table, and 8-bit nodemask8 only works // for predictive lookups LuaNode* n = &h->node[tsvalue(kv)->hash & (sizenode(h) - 1)]; const TValue* mt = 0; const LuaNode* mtn = 0; // fast-path: key is in the table in expected slot if (ttisstring(gkey(n)) && tsvalue(gkey(n)) == tsvalue(kv) && !ttisnil(gval(n))) { // note: order of copies allows rb to alias ra+1 or ra setobj2s(L, ra + 1, rb); setobj2s(L, ra, gval(n)); } // fast-path: key is absent from the base, table has an __index table, and it has the result in the expected slot else if (gnext(n) == 0 && (mt = fasttm(L, hvalue(rb)->metatable, TM_INDEX)) && ttistable(mt) && (mtn = &hvalue(mt)->node[LUAU_INSN_C(insn) & hvalue(mt)->nodemask8]) && ttisstring(gkey(mtn)) && tsvalue(gkey(mtn)) == tsvalue(kv) && !ttisnil(gval(mtn))) { // note: order of copies allows rb to alias ra+1 or ra setobj2s(L, ra + 1, rb); setobj2s(L, ra, gval(mtn)); } else { // slow-path: handles full table lookup setobj2s(L, ra + 1, rb); L->cachedslot = LUAU_INSN_C(insn); VM_PROTECT(luaV_gettable(L, rb, kv, ra)); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); } } else { Table* mt = ttisuserdata(rb) ? uvalue(rb)->metatable : L->global->mt[ttype(rb)]; const TValue* tmi = 0; // fast-path: metatable with __namecall if (const TValue* fn = fasttm(L, mt, TM_NAMECALL)) { // note: order of copies allows rb to alias ra+1 or ra setobj2s(L, ra + 1, rb); setobj2s(L, ra, fn); L->namecall = tsvalue(kv); } else if ((tmi = fasttm(L, mt, TM_INDEX)) && ttistable(tmi)) { Table* h = hvalue(tmi); int slot = LUAU_INSN_C(insn) & h->nodemask8; LuaNode* n = &h->node[slot]; // fast-path: metatable with __index that has method in expected slot if (LUAU_LIKELY(ttisstring(gkey(n)) && tsvalue(gkey(n)) == tsvalue(kv) && !ttisnil(gval(n)))) { // note: order of copies allows rb to alias ra+1 or ra setobj2s(L, ra + 1, rb); setobj2s(L, ra, gval(n)); } else { // slow-path: handles slot mismatch setobj2s(L, ra + 1, rb); L->cachedslot = slot; VM_PROTECT(luaV_gettable(L, rb, kv, ra)); // save cachedslot to accelerate future lookups; patches currently executing instruction since pc-2 rolls back two pc++ VM_PATCH_C(pc - 2, L->cachedslot); } } else { // slow-path: handles non-table __index setobj2s(L, ra + 1, rb); VM_PROTECT(luaV_gettable(L, rb, kv, ra)); } } // intentional fallthrough to CALL LUAU_ASSERT(LUAU_INSN_OP(*pc) == LOP_CALL); } VM_CASE(LOP_CALL) { VM_INTERRUPT(); Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); int nparams = LUAU_INSN_B(insn) - 1; int nresults = LUAU_INSN_C(insn) - 1; StkId argtop = L->top; argtop = (nparams == LUA_MULTRET) ? argtop : ra + 1 + nparams; // slow-path: not a function call if (LUAU_UNLIKELY(!ttisfunction(ra))) { VM_PROTECT(luau_tryfuncTM(L, ra)); argtop++; // __call adds an extra self } Closure* ccl = clvalue(ra); L->ci->savedpc = pc; CallInfo* ci = incr_ci(L); ci->func = ra; ci->base = ra + 1; ci->top = argtop + ccl->stacksize; // note: technically UB since we haven't reallocated the stack yet ci->savedpc = NULL; ci->flags = 0; ci->nresults = nresults; L->base = ci->base; L->top = argtop; // note: this reallocs stack, but we don't need to VM_PROTECT this // this is because we're going to modify base/savedpc manually anyhow // crucially, we can't use ra/argtop after this line luaD_checkstack(L, ccl->stacksize); LUAU_ASSERT(ci->top <= L->stack_last); if (!ccl->isC) { Proto* p = ccl->l.p; // fill unused parameters with nil StkId argi = L->top; StkId argend = L->base + p->numparams; while (argi < argend) setnilvalue(argi++); /* complete missing arguments */ L->top = p->is_vararg ? argi : ci->top; // reentry pc = p->code; cl = ccl; base = L->base; k = p->k; VM_NEXT(); } else { lua_CFunction func = ccl->c.f; int n = func(L); // yield if (n < 0) goto exit; // ci is our callinfo, cip is our parent CallInfo* ci = L->ci; CallInfo* cip = ci - 1; // copy return values into parent stack (but only up to nresults!), fill the rest with nil // note: in MULTRET context nresults starts as -1 so i != 0 condition never activates intentionally StkId res = ci->func; StkId vali = L->top - n; StkId valend = L->top; int i; for (i = nresults; i != 0 && vali < valend; i--) setobjs2s(L, res++, vali++); while (i-- > 0) setnilvalue(res++); // pop the stack frame L->ci = cip; L->base = cip->base; L->top = (nresults == LUA_MULTRET) ? res : cip->top; base = L->base; // stack may have been reallocated, so we need to refresh base ptr VM_NEXT(); } } VM_CASE(LOP_RETURN) { VM_INTERRUPT(); Instruction insn = *pc++; StkId ra = &base[LUAU_INSN_A(insn)]; // note: this can point to L->top if b == LUA_MULTRET making VM_REG unsafe to use int b = LUAU_INSN_B(insn) - 1; // ci is our callinfo, cip is our parent CallInfo* ci = L->ci; CallInfo* cip = ci - 1; StkId res = ci->func; // note: we assume CALL always puts func+args and expects results to start at func StkId vali = ra; StkId valend = (b == LUA_MULTRET) ? L->top : ra + b; // copy as much as possible for MULTRET calls, and only as much as needed otherwise int nresults = ci->nresults; // copy return values into parent stack (but only up to nresults!), fill the rest with nil // note: in MULTRET context nresults starts as -1 so i != 0 condition never activates intentionally int i; for (i = nresults; i != 0 && vali < valend; i--) setobjs2s(L, res++, vali++); while (i-- > 0) setnilvalue(res++); // pop the stack frame L->ci = cip; L->base = cip->base; L->top = (nresults == LUA_MULTRET) ? res : cip->top; // we're done! if (LUAU_UNLIKELY(ci->flags & LUA_CALLINFO_RETURN)) { L->top = res; goto exit; } LUAU_ASSERT(isLua(L->ci)); // reentry pc = cip->savedpc; cl = clvalue(cip->func); base = L->base; k = cl->l.p->k; VM_NEXT(); } VM_CASE(LOP_JUMP) { Instruction insn = *pc++; pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_JUMPIF) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); pc += l_isfalse(ra) ? 0 : LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_JUMPIFNOT) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); pc += l_isfalse(ra) ? LUAU_INSN_D(insn) : 0; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_JUMPIFEQ) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(aux); // Note that all jumps below jump by 1 in the "false" case to skip over aux if (ttype(ra) == ttype(rb)) { switch (ttype(ra)) { case LUA_TNIL: pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TBOOLEAN: pc += bvalue(ra) == bvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TLIGHTUSERDATA: pc += pvalue(ra) == pvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TNUMBER: pc += nvalue(ra) == nvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TVECTOR: pc += luai_veceq(vvalue(ra), vvalue(rb)) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TSTRING: case LUA_TFUNCTION: case LUA_TTHREAD: pc += gcvalue(ra) == gcvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TTABLE: // fast-path: same metatable, no EQ metamethod if (hvalue(ra)->metatable == hvalue(rb)->metatable) { const TValue* fn = fasttm(L, hvalue(ra)->metatable, TM_EQ); if (!fn) { pc += hvalue(ra) == hvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } // slow path after switch() break; case LUA_TUSERDATA: // fast-path: same metatable, no EQ metamethod or C metamethod if (uvalue(ra)->metatable == uvalue(rb)->metatable) { const TValue* fn = fasttm(L, uvalue(ra)->metatable, TM_EQ); if (!fn) { pc += uvalue(ra) == uvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else if (ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, ra); setobj2s(L, top + 2, rb); int res = int(top - base); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, res)); pc += !l_isfalse(&base[res]) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } // slow path after switch() break; default:; } // slow-path: tables with metatables and userdata values // note that we don't have a fast path for userdata values without metatables, since that's very rare int res; VM_PROTECT(res = luaV_equalval(L, ra, rb)); pc += (res == 1) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { pc += 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_JUMPIFNOTEQ) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(aux); // Note that all jumps below jump by 1 in the "true" case to skip over aux if (ttype(ra) == ttype(rb)) { switch (ttype(ra)) { case LUA_TNIL: pc += 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TBOOLEAN: pc += bvalue(ra) != bvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TLIGHTUSERDATA: pc += pvalue(ra) != pvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TNUMBER: pc += nvalue(ra) != nvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TVECTOR: pc += !luai_veceq(vvalue(ra), vvalue(rb)) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TSTRING: case LUA_TFUNCTION: case LUA_TTHREAD: pc += gcvalue(ra) != gcvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TTABLE: // fast-path: same metatable, no EQ metamethod if (hvalue(ra)->metatable == hvalue(rb)->metatable) { const TValue* fn = fasttm(L, hvalue(ra)->metatable, TM_EQ); if (!fn) { pc += hvalue(ra) != hvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } // slow path after switch() break; case LUA_TUSERDATA: // fast-path: same metatable, no EQ metamethod or C metamethod if (uvalue(ra)->metatable == uvalue(rb)->metatable) { const TValue* fn = fasttm(L, uvalue(ra)->metatable, TM_EQ); if (!fn) { pc += uvalue(ra) != uvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else if (ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, ra); setobj2s(L, top + 2, rb); int res = int(top - base); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, res)); pc += l_isfalse(&base[res]) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } // slow path after switch() break; default:; } // slow-path: tables with metatables and userdata values // note that we don't have a fast path for userdata values without metatables, since that's very rare int res; VM_PROTECT(res = luaV_equalval(L, ra, rb)); pc += (res == 0) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_JUMPIFLE) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(aux); // fast-path: number // Note that all jumps below jump by 1 in the "false" case to skip over aux if (ttisnumber(ra) && ttisnumber(rb)) { pc += nvalue(ra) <= nvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } // fast-path: string else if (ttisstring(ra) && ttisstring(rb)) { pc += luaV_strcmp(tsvalue(ra), tsvalue(rb)) <= 0 ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { int res; VM_PROTECT(res = luaV_lessequal(L, ra, rb)); pc += (res == 1) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_JUMPIFNOTLE) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(aux); // fast-path: number // Note that all jumps below jump by 1 in the "true" case to skip over aux if (ttisnumber(ra) && ttisnumber(rb)) { pc += !(nvalue(ra) <= nvalue(rb)) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } // fast-path: string else if (ttisstring(ra) && ttisstring(rb)) { pc += !(luaV_strcmp(tsvalue(ra), tsvalue(rb)) <= 0) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { int res; VM_PROTECT(res = luaV_lessequal(L, ra, rb)); pc += (res == 0) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_JUMPIFLT) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(aux); // fast-path: number // Note that all jumps below jump by 1 in the "false" case to skip over aux if (ttisnumber(ra) && ttisnumber(rb)) { pc += nvalue(ra) < nvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } // fast-path: string else if (ttisstring(ra) && ttisstring(rb)) { pc += luaV_strcmp(tsvalue(ra), tsvalue(rb)) < 0 ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { int res; VM_PROTECT(res = luaV_lessthan(L, ra, rb)); pc += (res == 1) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_JUMPIFNOTLT) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(aux); // fast-path: number // Note that all jumps below jump by 1 in the "true" case to skip over aux if (ttisnumber(ra) && ttisnumber(rb)) { pc += !(nvalue(ra) < nvalue(rb)) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } // fast-path: string else if (ttisstring(ra) && ttisstring(rb)) { pc += !(luaV_strcmp(tsvalue(ra), tsvalue(rb)) < 0) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { int res; VM_PROTECT(res = luaV_lessthan(L, ra, rb)); pc += (res == 0) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_ADD) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) + nvalue(rc)); VM_NEXT(); } else if (ttisvector(rb) && ttisvector(rc)) { const float* vb = rb->value.v; const float* vc = rc->value.v; setvvalue(ra, vb[0] + vc[0], vb[1] + vc[1], vb[2] + vc[2], vb[3] + vc[3]); VM_NEXT(); } else { // fast-path for userdata with C functions const TValue* fn = 0; if (ttisuserdata(rb) && (fn = luaT_gettmbyobj(L, rb, TM_ADD)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, rc); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, rc, TM_ADD)); VM_NEXT(); } } } VM_CASE(LOP_SUB) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) - nvalue(rc)); VM_NEXT(); } else if (ttisvector(rb) && ttisvector(rc)) { const float* vb = rb->value.v; const float* vc = rc->value.v; setvvalue(ra, vb[0] - vc[0], vb[1] - vc[1], vb[2] - vc[2], vb[3] - vc[3]); VM_NEXT(); } else { // fast-path for userdata with C functions const TValue* fn = 0; if (ttisuserdata(rb) && (fn = luaT_gettmbyobj(L, rb, TM_SUB)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, rc); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, rc, TM_SUB)); VM_NEXT(); } } } VM_CASE(LOP_MUL) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) * nvalue(rc)); VM_NEXT(); } else if (ttisvector(rb) && ttisnumber(rc)) { const float* vb = rb->value.v; float vc = cast_to(float, nvalue(rc)); setvvalue(ra, vb[0] * vc, vb[1] * vc, vb[2] * vc, vb[3] * vc); VM_NEXT(); } else if (ttisvector(rb) && ttisvector(rc)) { const float* vb = rb->value.v; const float* vc = rc->value.v; setvvalue(ra, vb[0] * vc[0], vb[1] * vc[1], vb[2] * vc[2], vb[3] * vc[3]); VM_NEXT(); } else if (ttisnumber(rb) && ttisvector(rc)) { float vb = cast_to(float, nvalue(rb)); const float* vc = rc->value.v; setvvalue(ra, vb * vc[0], vb * vc[1], vb * vc[2], vb * vc[3]); VM_NEXT(); } else { // fast-path for userdata with C functions StkId rbc = ttisnumber(rb) ? rc : rb; const TValue* fn = 0; if (ttisuserdata(rbc) && (fn = luaT_gettmbyobj(L, rbc, TM_MUL)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, rc); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, rc, TM_MUL)); VM_NEXT(); } } } VM_CASE(LOP_DIV) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) / nvalue(rc)); VM_NEXT(); } else if (ttisvector(rb) && ttisnumber(rc)) { const float* vb = rb->value.v; float vc = cast_to(float, nvalue(rc)); setvvalue(ra, vb[0] / vc, vb[1] / vc, vb[2] / vc, vb[3] / vc); VM_NEXT(); } else if (ttisvector(rb) && ttisvector(rc)) { const float* vb = rb->value.v; const float* vc = rc->value.v; setvvalue(ra, vb[0] / vc[0], vb[1] / vc[1], vb[2] / vc[2], vb[3] / vc[3]); VM_NEXT(); } else if (ttisnumber(rb) && ttisvector(rc)) { float vb = cast_to(float, nvalue(rb)); const float* vc = rc->value.v; setvvalue(ra, vb / vc[0], vb / vc[1], vb / vc[2], vb / vc[3]); VM_NEXT(); } else { // fast-path for userdata with C functions StkId rbc = ttisnumber(rb) ? rc : rb; const TValue* fn = 0; if (ttisuserdata(rbc) && (fn = luaT_gettmbyobj(L, rbc, TM_DIV)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, rc); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, rc, TM_DIV)); VM_NEXT(); } } } VM_CASE(LOP_MOD) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb) && ttisnumber(rc)) { double nb = nvalue(rb); double nc = nvalue(rc); setnvalue(ra, luai_nummod(nb, nc)); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, rc, TM_MOD)); VM_NEXT(); } } VM_CASE(LOP_POW) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, pow(nvalue(rb), nvalue(rc))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, rc, TM_POW)); VM_NEXT(); } } VM_CASE(LOP_ADDK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb)) { setnvalue(ra, nvalue(rb) + nvalue(kv)); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, kv, TM_ADD)); VM_NEXT(); } } VM_CASE(LOP_SUBK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb)) { setnvalue(ra, nvalue(rb) - nvalue(kv)); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, kv, TM_SUB)); VM_NEXT(); } } VM_CASE(LOP_MULK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb)) { setnvalue(ra, nvalue(rb) * nvalue(kv)); VM_NEXT(); } else if (ttisvector(rb)) { const float* vb = rb->value.v; float vc = cast_to(float, nvalue(kv)); setvvalue(ra, vb[0] * vc, vb[1] * vc, vb[2] * vc, vb[3] * vc); VM_NEXT(); } else { // fast-path for userdata with C functions const TValue* fn = 0; if (ttisuserdata(rb) && (fn = luaT_gettmbyobj(L, rb, TM_MUL)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, kv); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, kv, TM_MUL)); VM_NEXT(); } } } VM_CASE(LOP_DIVK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb)) { setnvalue(ra, nvalue(rb) / nvalue(kv)); VM_NEXT(); } else if (ttisvector(rb)) { const float* vb = rb->value.v; float vc = cast_to(float, nvalue(kv)); setvvalue(ra, vb[0] / vc, vb[1] / vc, vb[2] / vc, vb[3] / vc); VM_NEXT(); } else { // fast-path for userdata with C functions const TValue* fn = 0; if (ttisuserdata(rb) && (fn = luaT_gettmbyobj(L, rb, TM_DIV)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 3 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); setobj2s(L, top + 2, kv); L->top = top + 3; VM_PROTECT(luau_callTM(L, 2, LUAU_INSN_A(insn))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, kv, TM_DIV)); VM_NEXT(); } } } VM_CASE(LOP_MODK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb)) { double nb = nvalue(rb); double nk = nvalue(kv); setnvalue(ra, luai_nummod(nb, nk)); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, kv, TM_MOD)); VM_NEXT(); } } VM_CASE(LOP_POWK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); // fast-path if (ttisnumber(rb)) { double nb = nvalue(rb); double nk = nvalue(kv); // pow is very slow so we specialize this for ^2, ^0.5 and ^3 double r = (nk == 2.0) ? nb * nb : (nk == 0.5) ? sqrt(nb) : (nk == 3.0) ? nb * nb * nb : pow(nb, nk); setnvalue(ra, r); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, kv, TM_POW)); VM_NEXT(); } } VM_CASE(LOP_AND) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); setobj2s(L, ra, l_isfalse(rb) ? rb : rc); VM_NEXT(); } VM_CASE(LOP_OR) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); StkId rc = VM_REG(LUAU_INSN_C(insn)); setobj2s(L, ra, l_isfalse(rb) ? rc : rb); VM_NEXT(); } VM_CASE(LOP_ANDK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); setobj2s(L, ra, l_isfalse(rb) ? rb : kv); VM_NEXT(); } VM_CASE(LOP_ORK) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); TValue* kv = VM_KV(LUAU_INSN_C(insn)); setobj2s(L, ra, l_isfalse(rb) ? kv : rb); VM_NEXT(); } VM_CASE(LOP_CONCAT) { Instruction insn = *pc++; int b = LUAU_INSN_B(insn); int c = LUAU_INSN_C(insn); // This call may realloc the stack! So we need to query args further down VM_PROTECT(luaV_concat(L, c - b + 1, c)); StkId ra = VM_REG(LUAU_INSN_A(insn)); setobjs2s(L, ra, base + b); VM_PROTECT(luaC_checkGC(L)); VM_NEXT(); } VM_CASE(LOP_NOT) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); int res = l_isfalse(rb); setbvalue(ra, res); VM_NEXT(); } VM_CASE(LOP_MINUS) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); // fast-path if (ttisnumber(rb)) { setnvalue(ra, -nvalue(rb)); VM_NEXT(); } else if (ttisvector(rb)) { const float* vb = rb->value.v; setvvalue(ra, -vb[0], -vb[1], -vb[2], -vb[3]); VM_NEXT(); } else { // fast-path for userdata with C functions const TValue* fn = 0; if (ttisuserdata(rb) && (fn = luaT_gettmbyobj(L, rb, TM_UNM)) && ttisfunction(fn) && clvalue(fn)->isC) { // note: it's safe to push arguments past top for complicated reasons (see top of the file) LUAU_ASSERT(L->top + 2 < L->stack + L->stacksize); StkId top = L->top; setobj2s(L, top + 0, fn); setobj2s(L, top + 1, rb); L->top = top + 2; VM_PROTECT(luau_callTM(L, 1, LUAU_INSN_A(insn))); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_doarith(L, ra, rb, rb, TM_UNM)); VM_NEXT(); } } } VM_CASE(LOP_LENGTH) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = VM_REG(LUAU_INSN_B(insn)); // fast-path #1: tables if (ttistable(rb)) { setnvalue(ra, cast_num(luaH_getn(hvalue(rb)))); VM_NEXT(); } // fast-path #2: strings (not very important but easy to do) else if (ttisstring(rb)) { setnvalue(ra, cast_num(tsvalue(rb)->len)); VM_NEXT(); } else { // slow-path, may invoke C/Lua via metamethods VM_PROTECT(luaV_dolen(L, ra, rb)); VM_NEXT(); } } VM_CASE(LOP_NEWTABLE) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); int b = LUAU_INSN_B(insn); uint32_t aux = *pc++; sethvalue(L, ra, luaH_new(L, aux, b == 0 ? 0 : (1 << (b - 1)))); VM_PROTECT(luaC_checkGC(L)); VM_NEXT(); } VM_CASE(LOP_DUPTABLE) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* kv = VM_KV(LUAU_INSN_D(insn)); sethvalue(L, ra, luaH_clone(L, hvalue(kv))); VM_PROTECT(luaC_checkGC(L)); VM_NEXT(); } VM_CASE(LOP_SETLIST) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); StkId rb = &base[LUAU_INSN_B(insn)]; // note: this can point to L->top if c == LUA_MULTRET making VM_REG unsafe to use int c = LUAU_INSN_C(insn) - 1; uint32_t index = *pc++; if (c == LUA_MULTRET) { c = int(L->top - rb); L->top = L->ci->top; } Table* h = hvalue(ra); if (!ttistable(ra)) return; // temporary workaround to weaken a rather powerful exploitation primitive in case of a MITM attack on bytecode int last = index + c - 1; if (last > h->sizearray) luaH_resizearray(L, h, last); TValue* array = h->array; for (int i = 0; i < c; ++i) setobj2t(L, &array[index + i - 1], rb + i); luaC_barrierfast(L, h); VM_NEXT(); } VM_CASE(LOP_FORNPREP) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); if (!ttisnumber(ra + 0) || !ttisnumber(ra + 1) || !ttisnumber(ra + 2)) { // slow-path: can convert arguments to numbers and trigger Lua errors // Note: this doesn't reallocate stack so we don't need to recompute ra VM_PROTECT(luau_prepareFORN(L, ra + 0, ra + 1, ra + 2)); } double limit = nvalue(ra + 0); double step = nvalue(ra + 1); double idx = nvalue(ra + 2); // Note: make sure the loop condition is exactly the same between this and LOP_FORNLOOP so that we handle NaN/etc. consistently pc += (step > 0 ? idx <= limit : limit <= idx) ? 0 : LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_FORNLOOP) { VM_INTERRUPT(); Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); LUAU_ASSERT(ttisnumber(ra + 0) && ttisnumber(ra + 1) && ttisnumber(ra + 2)); double limit = nvalue(ra + 0); double step = nvalue(ra + 1); double idx = nvalue(ra + 2) + step; setnvalue(ra + 2, idx); // Note: make sure the loop condition is exactly the same between this and LOP_FORNPREP so that we handle NaN/etc. consistently if (step > 0 ? idx <= limit : limit <= idx) { pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { // fallthrough to exit VM_NEXT(); } } VM_CASE(LOP_FORGLOOP) { VM_INTERRUPT(); Instruction insn = *pc++; uint32_t aux = *pc; // note: this is a slow generic path, fast-path is FORGLOOP_INEXT/NEXT bool stop; VM_PROTECT(stop = luau_loopFORG(L, LUAU_INSN_A(insn), aux)); // note that we need to increment pc by 1 to exit the loop since we need to skip over aux pc += stop ? 1 : LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_FORGPREP_INEXT) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); // fast-path: ipairs/inext if (cl->env->safeenv && ttistable(ra + 1) && ttisnumber(ra + 2) && nvalue(ra + 2) == 0.0) { setpvalue(ra + 2, reinterpret_cast(uintptr_t(0))); } pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_FORGLOOP_INEXT) { VM_INTERRUPT(); Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); // fast-path: ipairs/inext if (ttistable(ra + 1) && ttislightuserdata(ra + 2)) { Table* h = hvalue(ra + 1); int index = int(reinterpret_cast(pvalue(ra + 2))); // if 1-based index of the last iteration is in bounds, this means 0-based index of the current iteration is in bounds if (unsigned(index) < unsigned(h->sizearray)) { // note that nil elements inside the array terminate the traversal if (!ttisnil(&h->array[index])) { setpvalue(ra + 2, reinterpret_cast(uintptr_t(index + 1))); setnvalue(ra + 3, double(index + 1)); setobj2s(L, ra + 4, &h->array[index]); pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { // fallthrough to exit VM_NEXT(); } } else if (h->lsizenode == 0 && ttisnil(gval(h->node))) { // hash part is empty: fallthrough to exit VM_NEXT(); } else { // the table has a hash part; index + 1 may appear in it in which case we need to iterate through the hash portion as well const TValue* val = luaH_getnum(h, index + 1); setpvalue(ra + 2, reinterpret_cast(uintptr_t(index + 1))); setnvalue(ra + 3, double(index + 1)); setobj2s(L, ra + 4, val); // note that nil elements inside the array terminate the traversal pc += ttisnil(ra + 4) ? 0 : LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } else { // slow-path; can call Lua/C generators bool stop; VM_PROTECT(stop = luau_loopFORG(L, LUAU_INSN_A(insn), 2)); pc += stop ? 0 : LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_FORGPREP_NEXT) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); // fast-path: pairs/next if (cl->env->safeenv && ttistable(ra + 1) && ttisnil(ra + 2)) { setpvalue(ra + 2, reinterpret_cast(uintptr_t(0))); } pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_FORGLOOP_NEXT) { VM_INTERRUPT(); Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); // fast-path: pairs/next if (ttistable(ra + 1) && ttislightuserdata(ra + 2)) { Table* h = hvalue(ra + 1); int index = int(reinterpret_cast(pvalue(ra + 2))); int sizearray = h->sizearray; int sizenode = 1 << h->lsizenode; // first we advance index through the array portion while (unsigned(index) < unsigned(sizearray)) { if (!ttisnil(&h->array[index])) { setpvalue(ra + 2, reinterpret_cast(uintptr_t(index + 1))); setnvalue(ra + 3, double(index + 1)); setobj2s(L, ra + 4, &h->array[index]); pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } index++; } // then we advance index through the hash portion while (unsigned(index - sizearray) < unsigned(sizenode)) { LuaNode* n = &h->node[index - sizearray]; if (!ttisnil(gval(n))) { setpvalue(ra + 2, reinterpret_cast(uintptr_t(index + 1))); getnodekey(L, ra + 3, n); setobj2s(L, ra + 4, gval(n)); pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } index++; } // fallthrough to exit VM_NEXT(); } else { // slow-path; can call Lua/C generators bool stop; VM_PROTECT(stop = luau_loopFORG(L, LUAU_INSN_A(insn), 2)); pc += stop ? 0 : LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_GETVARARGS) { Instruction insn = *pc++; int b = LUAU_INSN_B(insn) - 1; int n = cast_int(base - L->ci->func) - cl->l.p->numparams - 1; if (b == LUA_MULTRET) { VM_PROTECT(luaD_checkstack(L, n)); StkId ra = VM_REG(LUAU_INSN_A(insn)); // previous call may change the stack for (int j = 0; j < n; j++) setobjs2s(L, ra + j, base - n + j); L->top = ra + n; VM_NEXT(); } else { StkId ra = VM_REG(LUAU_INSN_A(insn)); for (int j = 0; j < b && j < n; j++) setobjs2s(L, ra + j, base - n + j); for (int j = n; j < b; j++) setnilvalue(ra + j); VM_NEXT(); } } VM_CASE(LOP_DUPCLOSURE) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* kv = VM_KV(LUAU_INSN_D(insn)); Closure* kcl = clvalue(kv); // clone closure if the environment is not shared // note: we save closure to stack early in case the code below wants to capture it by value Closure* ncl = (kcl->env == cl->env) ? kcl : luaF_newLclosure(L, kcl->nupvalues, cl->env, kcl->l.p); setclvalue(L, ra, ncl); // this loop does three things: // - if the closure was created anew, it just fills it with upvalues // - if the closure from the constant table is used, it fills it with upvalues so that it can be shared in the future // - if the closure is reused, it checks if the reuse is safe via rawequal, and falls back to duplicating the closure // normally this would use two separate loops, for reuse check and upvalue setup, but MSVC codegen goes crazy if you do that for (int ui = 0; ui < kcl->nupvalues; ++ui) { Instruction uinsn = pc[ui]; LUAU_ASSERT(LUAU_INSN_OP(uinsn) == LOP_CAPTURE); LUAU_ASSERT(LUAU_INSN_A(uinsn) == LCT_VAL || LUAU_INSN_A(uinsn) == LCT_UPVAL); TValue* uv = (LUAU_INSN_A(uinsn) == LCT_VAL) ? VM_REG(LUAU_INSN_B(uinsn)) : VM_UV(LUAU_INSN_B(uinsn)); // check if the existing closure is safe to reuse if (ncl == kcl && luaO_rawequalObj(&ncl->l.uprefs[ui], uv)) continue; // lazily clone the closure and update the upvalues if (ncl == kcl && kcl->preload == 0) { ncl = luaF_newLclosure(L, kcl->nupvalues, cl->env, kcl->l.p); setclvalue(L, ra, ncl); ui = -1; // restart the loop to fill all upvalues continue; } // this updates a newly created closure, or an existing closure created during preload, in which case we need a barrier setobj(L, &ncl->l.uprefs[ui], uv); luaC_barrier(L, ncl, uv); } // this is a noop if ncl is newly created or shared successfully, but it has to run after the closure is preloaded for the first time ncl->preload = 0; if (kcl != ncl) VM_PROTECT(luaC_checkGC(L)); pc += kcl->nupvalues; VM_NEXT(); } VM_CASE(LOP_PREPVARARGS) { Instruction insn = *pc++; int numparams = LUAU_INSN_A(insn); // all fixed parameters are copied after the top so we need more stack space VM_PROTECT(luaD_checkstack(L, cl->stacksize + numparams)); // the caller must have filled extra fixed arguments with nil LUAU_ASSERT(cast_int(L->top - base) >= numparams); // move fixed parameters to final position StkId fixed = base; /* first fixed argument */ base = L->top; /* final position of first argument */ for (int i = 0; i < numparams; ++i) { setobjs2s(L, base + i, fixed + i); setnilvalue(fixed + i); } // rewire our stack frame to point to the new base L->ci->base = base; L->ci->top = base + cl->stacksize; L->base = base; L->top = L->ci->top; VM_NEXT(); } VM_CASE(LOP_JUMPBACK) { VM_INTERRUPT(); Instruction insn = *pc++; pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_LOADKX) { Instruction insn = *pc++; StkId ra = VM_REG(LUAU_INSN_A(insn)); uint32_t aux = *pc++; TValue* kv = VM_KV(aux); setobj2s(L, ra, kv); VM_NEXT(); } VM_CASE(LOP_JUMPX) { VM_INTERRUPT(); Instruction insn = *pc++; pc += LUAU_INSN_E(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } VM_CASE(LOP_FASTCALL) { Instruction insn = *pc++; int bfid = LUAU_INSN_A(insn); int skip = LUAU_INSN_C(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code + skip) < unsigned(cl->l.p->sizecode)); Instruction call = pc[skip]; LUAU_ASSERT(LUAU_INSN_OP(call) == LOP_CALL); StkId ra = VM_REG(LUAU_INSN_A(call)); int nparams = LUAU_INSN_B(call) - 1; int nresults = LUAU_INSN_C(call) - 1; nparams = (nparams == LUA_MULTRET) ? int(L->top - ra - 1) : nparams; luau_FastFunction f = luauF_table[bfid]; if (cl->env->safeenv && f) { VM_PROTECT_PC(); int n = f(L, ra, ra + 1, nresults, ra + 2, nparams); if (n >= 0) { L->top = (nresults == LUA_MULTRET) ? ra + n : L->ci->top; pc += skip + 1; // skip instructions that compute function as well as CALL LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { // continue execution through the fallback code VM_NEXT(); } } else { // continue execution through the fallback code VM_NEXT(); } } VM_CASE(LOP_COVERAGE) { Instruction insn = *pc++; int hits = LUAU_INSN_E(insn); // update hits with saturated add and patch the instruction in place hits = (hits < (1 << 23) - 1) ? hits + 1 : hits; VM_PATCH_E(pc - 1, hits); VM_NEXT(); } VM_CASE(LOP_CAPTURE) { LUAU_ASSERT(!"CAPTURE is a pseudo-opcode and must be executed as part of NEWCLOSURE"); LUAU_UNREACHABLE(); } VM_CASE(LOP_JUMPIFEQK) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* rb = VM_KV(aux); // Note that all jumps below jump by 1 in the "false" case to skip over aux if (ttype(ra) == ttype(rb)) { switch (ttype(ra)) { case LUA_TNIL: pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TBOOLEAN: pc += bvalue(ra) == bvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TNUMBER: pc += nvalue(ra) == nvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TSTRING: pc += gcvalue(ra) == gcvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); default:; } LUAU_ASSERT(!"Constant is expected to be of primitive type"); } else { pc += 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_JUMPIFNOTEQK) { Instruction insn = *pc++; uint32_t aux = *pc; StkId ra = VM_REG(LUAU_INSN_A(insn)); TValue* rb = VM_KV(aux); // Note that all jumps below jump by 1 in the "true" case to skip over aux if (ttype(ra) == ttype(rb)) { switch (ttype(ra)) { case LUA_TNIL: pc += 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TBOOLEAN: pc += bvalue(ra) != bvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TNUMBER: pc += nvalue(ra) != nvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); case LUA_TSTRING: pc += gcvalue(ra) != gcvalue(rb) ? LUAU_INSN_D(insn) : 1; LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); default:; } LUAU_ASSERT(!"Constant is expected to be of primitive type"); } else { pc += LUAU_INSN_D(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } } VM_CASE(LOP_FASTCALL1) { Instruction insn = *pc++; int bfid = LUAU_INSN_A(insn); TValue* arg = VM_REG(LUAU_INSN_B(insn)); int skip = LUAU_INSN_C(insn); LUAU_ASSERT(unsigned(pc - cl->l.p->code + skip) < unsigned(cl->l.p->sizecode)); Instruction call = pc[skip]; LUAU_ASSERT(LUAU_INSN_OP(call) == LOP_CALL); StkId ra = VM_REG(LUAU_INSN_A(call)); int nparams = 1; int nresults = LUAU_INSN_C(call) - 1; luau_FastFunction f = luauF_table[bfid]; if (cl->env->safeenv && f) { VM_PROTECT_PC(); int n = f(L, ra, arg, nresults, nullptr, nparams); if (n >= 0) { L->top = (nresults == LUA_MULTRET) ? ra + n : L->ci->top; pc += skip + 1; // skip instructions that compute function as well as CALL LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { // continue execution through the fallback code VM_NEXT(); } } else { // continue execution through the fallback code VM_NEXT(); } } VM_CASE(LOP_FASTCALL2) { Instruction insn = *pc++; int bfid = LUAU_INSN_A(insn); int skip = LUAU_INSN_C(insn) - 1; uint32_t aux = *pc++; TValue* arg1 = VM_REG(LUAU_INSN_B(insn)); TValue* arg2 = VM_REG(aux); LUAU_ASSERT(unsigned(pc - cl->l.p->code + skip) < unsigned(cl->l.p->sizecode)); Instruction call = pc[skip]; LUAU_ASSERT(LUAU_INSN_OP(call) == LOP_CALL); StkId ra = VM_REG(LUAU_INSN_A(call)); int nparams = 2; int nresults = LUAU_INSN_C(call) - 1; luau_FastFunction f = luauF_table[bfid]; if (cl->env->safeenv && f) { VM_PROTECT_PC(); int n = f(L, ra, arg1, nresults, arg2, nparams); if (n >= 0) { L->top = (nresults == LUA_MULTRET) ? ra + n : L->ci->top; pc += skip + 1; // skip instructions that compute function as well as CALL LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { // continue execution through the fallback code VM_NEXT(); } } else { // continue execution through the fallback code VM_NEXT(); } } VM_CASE(LOP_FASTCALL2K) { Instruction insn = *pc++; int bfid = LUAU_INSN_A(insn); int skip = LUAU_INSN_C(insn) - 1; uint32_t aux = *pc++; TValue* arg1 = VM_REG(LUAU_INSN_B(insn)); TValue* arg2 = VM_KV(aux); LUAU_ASSERT(unsigned(pc - cl->l.p->code + skip) < unsigned(cl->l.p->sizecode)); Instruction call = pc[skip]; LUAU_ASSERT(LUAU_INSN_OP(call) == LOP_CALL); StkId ra = VM_REG(LUAU_INSN_A(call)); int nparams = 2; int nresults = LUAU_INSN_C(call) - 1; luau_FastFunction f = luauF_table[bfid]; if (cl->env->safeenv && f) { VM_PROTECT_PC(); int n = f(L, ra, arg1, nresults, arg2, nparams); if (n >= 0) { L->top = (nresults == LUA_MULTRET) ? ra + n : L->ci->top; pc += skip + 1; // skip instructions that compute function as well as CALL LUAU_ASSERT(unsigned(pc - cl->l.p->code) < unsigned(cl->l.p->sizecode)); VM_NEXT(); } else { // continue execution through the fallback code VM_NEXT(); } } else { // continue execution through the fallback code VM_NEXT(); } } VM_CASE(LOP_BREAK) { LUAU_ASSERT(cl->l.p->debuginsn); uint8_t op = cl->l.p->debuginsn[unsigned(pc - cl->l.p->code)]; LUAU_ASSERT(op != LOP_BREAK); if (L->global->cb.debugbreak) { VM_PROTECT(luau_callhook(L, L->global->cb.debugbreak, NULL)); // allow debugbreak hook to put thread into error/yield state if (L->status != 0) goto exit; } VM_CONTINUE(op); } #if !VM_USE_CGOTO default: LUAU_ASSERT(!"Unknown opcode"); LUAU_UNREACHABLE(); // improves switch() codegen by eliding opcode bounds checks #endif } } exit:; } void luau_execute(lua_State* L) { if (L->singlestep) luau_execute(L); else luau_execute(L); } int luau_precall(lua_State* L, StkId func, int nresults) { if (!ttisfunction(func)) { luau_tryfuncTM(L, func); // L->top is incremented by tryfuncTM } Closure* ccl = clvalue(func); CallInfo* ci = incr_ci(L); ci->func = func; ci->base = func + 1; ci->top = L->top + ccl->stacksize; ci->savedpc = NULL; ci->flags = 0; ci->nresults = nresults; L->base = ci->base; // Note: L->top is assigned externally luaD_checkstack(L, ccl->stacksize); LUAU_ASSERT(ci->top <= L->stack_last); if (!ccl->isC) { // fill unused parameters with nil StkId argi = L->top; StkId argend = L->base + ccl->l.p->numparams; while (argi < argend) setnilvalue(argi++); /* complete missing arguments */ L->top = ccl->l.p->is_vararg ? argi : ci->top; L->ci->savedpc = ccl->l.p->code; return PCRLUA; } else { lua_CFunction func = ccl->c.f; int n = func(L); // yield if (n < 0) return PCRYIELD; // ci is our callinfo, cip is our parent CallInfo* ci = L->ci; CallInfo* cip = ci - 1; // copy return values into parent stack (but only up to nresults!), fill the rest with nil // TODO: it might be worthwhile to handle the case when nresults==b explicitly? StkId res = ci->func; StkId vali = L->top - n; StkId valend = L->top; int i; for (i = nresults; i != 0 && vali < valend; i--) setobjs2s(L, res++, vali++); while (i-- > 0) setnilvalue(res++); // pop the stack frame L->ci = cip; L->base = cip->base; L->top = res; return PCRC; } } void luau_poscall(lua_State* L, StkId first) { // finish interrupted execution of `OP_CALL' // ci is our callinfo, cip is our parent CallInfo* ci = L->ci; CallInfo* cip = ci - 1; // copy return values into parent stack (but only up to nresults!), fill the rest with nil // TODO: it might be worthwhile to handle the case when nresults==b explicitly? StkId res = ci->func; StkId vali = first; StkId valend = L->top; int i; for (i = ci->nresults; i != 0 && vali < valend; i--) setobjs2s(L, res++, vali++); while (i-- > 0) setnilvalue(res++); // pop the stack frame L->ci = cip; L->base = cip->base; L->top = (ci->nresults == LUA_MULTRET) ? res : cip->top; }