void Compiler::CompileGetupval() { auto& ra = stack_.GetR(GETARG_A(cs_.instr_)); auto& upval = stack_.GetUp(GETARG_B(cs_.instr_)); ra.Assign(upval); }
void Compiler::CompileGettable() { auto& table = stack_.GetR(GETARG_B(cs_.instr_)); auto& key = stack_.GetRK(GETARG_C(cs_.instr_)); auto& dest = stack_.GetR(GETARG_A(cs_.instr_)); TableGet(cs_, stack_, table, key, dest).Compile(); }
void Compiler::CompileMove() { auto& ra = stack_.GetR(GETARG_A(cs_.instr_)); auto& rb = stack_.GetR(GETARG_B(cs_.instr_)); ra.Assign(rb); }
void Compiler::CompileLoadbool() { auto& ra = stack_.GetR(GETARG_A(cs_.instr_)); ra.SetBoolean(cs_.MakeInt(GETARG_B(cs_.instr_))); if (GETARG_C(cs_.instr_)) cs_.B_.CreateBr(cs_.blocks_[cs_.curr_ + 2]); }
static Instruction symbexec (const Proto *pt, int lastpc, int reg) { int pc; int last; /* stores position of last instruction that changed `reg' */ last = pt->sizecode-1; /* points to final return (a `neutral' instruction) */ check(precheck(pt)); for (pc = 0; pc < lastpc; pc++) { Instruction i = pt->code[pc]; OpCode op = GET_OPCODE(i); int a = GETARG_A(i); int b = 0; int c = 0; check(op < NUM_OPCODES); checkreg(pt, a); switch (getOpMode(op)) { case iABC: { b = GETARG_B(i); c = GETARG_C(i); check(checkArgMode(pt, b, getBMode(op))); check(checkArgMode(pt, c, getCMode(op))); break; } case iABx: { b = GETARG_Bx(i); if (getBMode(op) == OpArgK) check(b < pt->sizek); break; } case iAsBx: { b = GETARG_sBx(i); if (getBMode(op) == OpArgR) { int dest = pc+1+b; check(0 <= dest && dest < pt->sizecode); if (dest > 0) { /* cannot jump to a setlist count */ Instruction d = pt->code[dest-1]; check(!(GET_OPCODE(d) == OP_SETLIST && GETARG_C(d) == 0)); } } break; } } if (testAMode(op)) { if (a == reg) last = pc; /* change register `a' */ } if (testTMode(op)) { check(pc+2 < pt->sizecode); /* check skip */ check(GET_OPCODE(pt->code[pc+1]) == OP_JMP); } switch (op) { case OP_LOADBOOL: { check(c == 0 || pc+2 < pt->sizecode); /* check its jump */ break; } case OP_LOADNIL: { if (a <= reg && reg <= b) last = pc; /* set registers from `a' to `b' */ break; } case OP_GETUPVAL: case OP_SETUPVAL: { check(b < pt->nups); break; } case OP_GETGLOBAL: case OP_SETGLOBAL: { check(ttisstring(&pt->k[b])); break; } case OP_SELF: { checkreg(pt, a+1); if (reg == a+1) last = pc; break; } case OP_CONCAT: { check(b < c); /* at least two operands */ break; } case OP_TFORLOOP: { check(c >= 1); /* at least one result (control variable) */ checkreg(pt, a+2+c); /* space for results */ if (reg >= a+2) last = pc; /* affect all regs above its base */ break; } case OP_FORLOOP: case OP_FORPREP: checkreg(pt, a+3); /* go through */ case OP_JMP: { int dest = pc+1+b; /* not full check and jump is forward and do not skip `lastpc'? */ if (reg != NO_REG && pc < dest && dest <= lastpc) pc += b; /* do the jump */ break; } case OP_CALL: case OP_TAILCALL: { if (b != 0) { checkreg(pt, a+b-1); } c--; /* c = num. returns */ if (c == LUA_MULTRET) { check(checkopenop(pt, pc)); } else if (c != 0) checkreg(pt, a+c-1); if (reg >= a) last = pc; /* affect all registers above base */ break; } case OP_RETURN: { b--; /* b = num. returns */ if (b > 0) checkreg(pt, a+b-1); break; } case OP_SETLIST: { if (b > 0) checkreg(pt, a + b); if (c == 0) pc++; break; } case OP_CLOSURE: { int nup; check(b < pt->sizep); nup = pt->p[b]->nups; check(pc + nup < pt->sizecode); for (; nup>0; nup--) { OpCode op1 = GET_OPCODE(pt->code[pc+nup]); check(op1 == OP_GETUPVAL || op1 == OP_MOVE); } break; } case OP_VARARG: { check((pt->is_vararg & VARARG_ISVARARG) && !(pt->is_vararg & VARARG_NEEDSARG)); b--; if (b == LUA_MULTRET) check(checkopenop(pt, pc)); checkreg(pt, a+b-1); break; } default: break; } } return pt->code[last]; }
mrb_value mrb_run(mrb_state *mrb, struct RProc *proc, mrb_value self) { /* assert(mrb_proc_cfunc_p(proc)) */ mrb_irep *irep = proc->body.irep; mrb_code *pc = irep->iseq; mrb_value *pool = irep->pool; mrb_sym *syms = irep->syms; mrb_value *regs = NULL; mrb_code i; int ai = mrb->arena_idx; jmp_buf *prev_jmp = (jmp_buf *)mrb->jmp; jmp_buf c_jmp; #ifdef DIRECT_THREADED static void *optable[] = { &&L_OP_NOP, &&L_OP_MOVE, &&L_OP_LOADL, &&L_OP_LOADI, &&L_OP_LOADSYM, &&L_OP_LOADNIL, &&L_OP_LOADSELF, &&L_OP_LOADT, &&L_OP_LOADF, &&L_OP_GETGLOBAL, &&L_OP_SETGLOBAL, &&L_OP_GETSPECIAL, &&L_OP_SETSPECIAL, &&L_OP_GETIV, &&L_OP_SETIV, &&L_OP_GETCV, &&L_OP_SETCV, &&L_OP_GETCONST, &&L_OP_SETCONST, &&L_OP_GETMCNST, &&L_OP_SETMCNST, &&L_OP_GETUPVAR, &&L_OP_SETUPVAR, &&L_OP_JMP, &&L_OP_JMPIF, &&L_OP_JMPNOT, &&L_OP_ONERR, &&L_OP_RESCUE, &&L_OP_POPERR, &&L_OP_RAISE, &&L_OP_EPUSH, &&L_OP_EPOP, &&L_OP_SEND, &&L_OP_SENDB, &&L_OP_FSEND, &&L_OP_CALL, &&L_OP_SUPER, &&L_OP_ARGARY, &&L_OP_ENTER, &&L_OP_KARG, &&L_OP_KDICT, &&L_OP_RETURN, &&L_OP_TAILCALL, &&L_OP_BLKPUSH, &&L_OP_ADD, &&L_OP_ADDI, &&L_OP_SUB, &&L_OP_SUBI, &&L_OP_MUL, &&L_OP_DIV, &&L_OP_EQ, &&L_OP_LT, &&L_OP_LE, &&L_OP_GT, &&L_OP_GE, &&L_OP_ARRAY, &&L_OP_ARYCAT, &&L_OP_ARYPUSH, &&L_OP_AREF, &&L_OP_ASET, &&L_OP_APOST, &&L_OP_STRING, &&L_OP_STRCAT, &&L_OP_HASH, &&L_OP_LAMBDA, &&L_OP_RANGE, &&L_OP_OCLASS, &&L_OP_CLASS, &&L_OP_MODULE, &&L_OP_EXEC, &&L_OP_METHOD, &&L_OP_SCLASS, &&L_OP_TCLASS, &&L_OP_DEBUG, &&L_OP_STOP, &&L_OP_ERR, }; #endif if (setjmp(c_jmp) == 0) { mrb->jmp = &c_jmp; } else { goto L_RAISE; } if (!mrb->stack) { stack_init(mrb); } mrb->ci->proc = proc; mrb->ci->nregs = irep->nregs + 2; regs = mrb->stack; regs[0] = self; INIT_DISPATCH { CASE(OP_NOP) { /* do nothing */ NEXT; } CASE(OP_MOVE) { /* A B R(A) := R(B) */ regs[GETARG_A(i)] = regs[GETARG_B(i)]; NEXT; } CASE(OP_LOADL) { /* A Bx R(A) := Pool(Bx) */ regs[GETARG_A(i)] = pool[GETARG_Bx(i)]; NEXT; } CASE(OP_LOADI) { /* A Bx R(A) := sBx */ SET_INT_VALUE(regs[GETARG_A(i)], GETARG_sBx(i)); NEXT; } CASE(OP_LOADSYM) { /* A B R(A) := Sym(B) */ SET_SYM_VALUE(regs[GETARG_A(i)], syms[GETARG_Bx(i)]); NEXT; } CASE(OP_LOADSELF) { /* A R(A) := self */ regs[GETARG_A(i)] = regs[0]; NEXT; } CASE(OP_LOADT) { /* A R(A) := true */ SET_TRUE_VALUE(regs[GETARG_A(i)]); NEXT; } CASE(OP_LOADF) { /* A R(A) := false */ SET_FALSE_VALUE(regs[GETARG_A(i)]); NEXT; } CASE(OP_GETGLOBAL) { /* A B R(A) := getglobal(Sym(B)) */ regs[GETARG_A(i)] = mrb_gv_get(mrb, syms[GETARG_Bx(i)]); NEXT; } CASE(OP_SETGLOBAL) { /* setglobal(Sym(b), R(A)) */ mrb_gv_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]); NEXT; } CASE(OP_GETSPECIAL) { /* A Bx R(A) := Special[Bx] */ regs[GETARG_A(i)] = mrb_vm_special_get(mrb, GETARG_Bx(i)); NEXT; } CASE(OP_SETSPECIAL) { /* A Bx Special[Bx] := R(A) */ mrb_vm_special_set(mrb, GETARG_Bx(i), regs[GETARG_A(i)]); NEXT; } CASE(OP_GETIV) { /* A Bx R(A) := ivget(Bx) */ regs[GETARG_A(i)] = mrb_vm_iv_get(mrb, syms[GETARG_Bx(i)]); NEXT; } CASE(OP_SETIV) { /* ivset(Sym(B),R(A)) */ mrb_vm_iv_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]); NEXT; } CASE(OP_GETCV) { /* A B R(A) := ivget(Sym(B)) */ regs[GETARG_A(i)] = mrb_vm_cv_get(mrb, syms[GETARG_Bx(i)]); NEXT; } CASE(OP_SETCV) { /* ivset(Sym(B),R(A)) */ mrb_vm_cv_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]); NEXT; } CASE(OP_GETCONST) { /* A B R(A) := constget(Sym(B)) */ regs[GETARG_A(i)] = mrb_vm_const_get(mrb, syms[GETARG_Bx(i)]); NEXT; } CASE(OP_SETCONST) { /* A B constset(Sym(B),R(A)) */ mrb_vm_const_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]); NEXT; } CASE(OP_GETMCNST) { /* A B C R(A) := R(C)::Sym(B) */ int a = GETARG_A(i); regs[a] = mrb_const_get(mrb, regs[a], syms[GETARG_Bx(i)]); NEXT; } CASE(OP_SETMCNST) { /* A B C R(A+1)::Sym(B) := R(A) */ int a = GETARG_A(i); mrb_const_set(mrb, regs[a+1], syms[GETARG_Bx(i)], regs[a]); NEXT; } CASE(OP_GETUPVAR) { /* A B C R(A) := uvget(B,C) */ regs[GETARG_A(i)] = uvget(mrb, GETARG_C(i), GETARG_B(i)); NEXT; } CASE(OP_SETUPVAR) { /* A B C uvset(B,C,R(A)) */ uvset(mrb, GETARG_C(i), GETARG_B(i), regs[GETARG_A(i)]); NEXT; } CASE(OP_JMP) { /* sBx pc+=sBx */ pc += GETARG_sBx(i); JUMP; } CASE(OP_JMPIF) { /* A sBx if R(A) pc+=sBx */ if (mrb_test(regs[GETARG_A(i)])) { pc += GETARG_sBx(i); JUMP; } NEXT; } CASE(OP_JMPNOT) { /* A sBx if R(A) pc+=sBx */ if (!mrb_test(regs[GETARG_A(i)])) { pc += GETARG_sBx(i); JUMP; } NEXT; } CASE(OP_ONERR) { /* sBx pc+=sBx on exception */ if (mrb->rsize <= mrb->ci->ridx) { if (mrb->rsize == 0) mrb->rsize = 16; else mrb->rsize *= 2; mrb->rescue = (mrb_code **)mrb_realloc(mrb, mrb->rescue, sizeof(mrb_code*) * mrb->rsize); } mrb->rescue[mrb->ci->ridx++] = pc + GETARG_sBx(i); NEXT; } CASE(OP_RESCUE) { /* A R(A) := exc; clear(exc) */ SET_OBJ_VALUE(regs[GETARG_A(i)], mrb->exc); mrb->exc = 0; NEXT; } CASE(OP_POPERR) { int a = GETARG_A(i); while (a--) { mrb->ci->ridx--; } NEXT; } CASE(OP_RAISE) { /* A raise(R(A)) */ mrb->exc = (struct RObject*)mrb_object(regs[GETARG_A(i)]); goto L_RAISE; } CASE(OP_EPUSH) { /* Bx ensure_push(SEQ[Bx]) */ struct RProc *p; p = mrb_closure_new(mrb, mrb->irep[irep->idx+GETARG_Bx(i)]); /* push ensure_stack */ if (mrb->esize <= mrb->ci->eidx) { if (mrb->esize == 0) mrb->esize = 16; else mrb->esize *= 2; mrb->ensure = (struct RProc **)mrb_realloc(mrb, mrb->ensure, sizeof(struct RProc*) * mrb->esize); } mrb->ensure[mrb->ci->eidx++] = p; mrb->arena_idx = ai; NEXT; } CASE(OP_EPOP) { /* A A.times{ensure_pop().call} */ int n; int a = GETARG_A(i); for (n=0; n<a; n++) { ecall(mrb, --mrb->ci->eidx); } mrb->arena_idx = ai; NEXT; } CASE(OP_LOADNIL) { /* A B R(A) := nil */ int a = GETARG_A(i); SET_NIL_VALUE(regs[a]); NEXT; } CASE(OP_SENDB) { /* fall through */ }; L_SEND: CASE(OP_SEND) { /* A B C R(A) := call(R(A),Sym(B),R(A+1),... ,R(A+C-1)) */ int a = GETARG_A(i); int n = GETARG_C(i); struct RProc *m; struct RClass *c; mrb_callinfo *ci; mrb_value recv, result; mrb_sym mid = syms[GETARG_B(i)]; recv = regs[a]; if (GET_OPCODE(i) != OP_SENDB) { if (n == CALL_MAXARGS) { SET_NIL_VALUE(regs[a+2]); } else { SET_NIL_VALUE(regs[a+n+1]); } } c = mrb_class(mrb, recv); m = mrb_method_search_vm(mrb, &c, mid); if (!m) { mrb_value sym = mrb_symbol_value(mid); mid = mrb_intern(mrb, "method_missing"); m = mrb_method_search_vm(mrb, &c, mid); if (n == CALL_MAXARGS) { mrb_ary_unshift(mrb, regs[a+1], sym); } else { memmove(regs+a+2, regs+a+1, sizeof(mrb_value)*(n+1)); regs[a+1] = sym; n++; } } /* push callinfo */ ci = cipush(mrb); ci->mid = mid; ci->proc = m; ci->stackidx = mrb->stack - mrb->stbase; ci->argc = n; if (ci->argc == CALL_MAXARGS) ci->argc = -1; ci->target_class = c; ci->pc = pc + 1; ci->acc = a; /* prepare stack */ mrb->stack += a; if (MRB_PROC_CFUNC_P(m)) { if (n == CALL_MAXARGS) { ci->nregs = 3; } else { ci->nregs = n + 2; } result = m->body.func(mrb, recv); mrb->stack[0] = result; mrb->arena_idx = ai; if (mrb->exc) goto L_RAISE; /* pop stackpos */ regs = mrb->stack = mrb->stbase + mrb->ci->stackidx; cipop(mrb); NEXT; } else { /* setup environment for calling method */ proc = mrb->ci->proc = m; irep = m->body.irep; pool = irep->pool; syms = irep->syms; ci->nregs = irep->nregs; if (ci->argc < 0) { stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3); } else { stack_extend(mrb, irep->nregs, ci->argc+2); } regs = mrb->stack; pc = irep->iseq; JUMP; } } CASE(OP_FSEND) { /* A B C R(A) := fcall(R(A),Sym(B),R(A+1),... ,R(A+C)) */ NEXT; } CASE(OP_CALL) { /* A R(A) := self.call(frame.argc, frame.argv) */ mrb_callinfo *ci; mrb_value recv = mrb->stack[0]; struct RProc *m = mrb_proc_ptr(recv); /* replace callinfo */ ci = mrb->ci; ci->target_class = m->target_class; ci->proc = m; if (m->env) { if (m->env->mid) { ci->mid = m->env->mid; } if (!m->env->stack) { m->env->stack = mrb->stack; } } /* prepare stack */ if (MRB_PROC_CFUNC_P(m)) { recv = m->body.func(mrb, recv); mrb->arena_idx = ai; if (mrb->exc) goto L_RAISE; /* pop stackpos */ ci = mrb->ci; regs = mrb->stack = mrb->stbase + ci->stackidx; regs[ci->acc] = recv; pc = ci->pc; cipop(mrb); irep = mrb->ci->proc->body.irep; pool = irep->pool; syms = irep->syms; JUMP; } else { /* setup environment for calling method */ proc = m; irep = m->body.irep; if (!irep) { mrb->stack[0] = mrb_nil_value(); goto L_RETURN; } pool = irep->pool; syms = irep->syms; ci->nregs = irep->nregs; if (ci->argc < 0) { stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3); } else { stack_extend(mrb, irep->nregs, ci->argc+2); } regs = mrb->stack; regs[0] = m->env->stack[0]; pc = m->body.irep->iseq; JUMP; } } CASE(OP_SUPER) { /* A B C R(A) := super(R(A+1),... ,R(A+C-1)) */ mrb_value recv; mrb_callinfo *ci = mrb->ci; struct RProc *m; struct RClass *c; mrb_sym mid = ci->mid; int a = GETARG_A(i); int n = GETARG_C(i); recv = regs[0]; c = mrb->ci->target_class->super; m = mrb_method_search_vm(mrb, &c, mid); if (!m) { mid = mrb_intern(mrb, "method_missing"); m = mrb_method_search_vm(mrb, &c, mid); if (n == CALL_MAXARGS) { mrb_ary_unshift(mrb, regs[a+1], mrb_symbol_value(ci->mid)); } else { memmove(regs+a+2, regs+a+1, sizeof(mrb_value)*(n+1)); SET_SYM_VALUE(regs[a+1], ci->mid); n++; } } /* push callinfo */ ci = cipush(mrb); ci->mid = mid; ci->proc = m; ci->stackidx = mrb->stack - mrb->stbase; ci->argc = n; if (ci->argc == CALL_MAXARGS) ci->argc = -1; ci->target_class = m->target_class; ci->pc = pc + 1; /* prepare stack */ mrb->stack += a; mrb->stack[0] = recv; if (MRB_PROC_CFUNC_P(m)) { mrb->stack[0] = m->body.func(mrb, recv); mrb->arena_idx = ai; if (mrb->exc) goto L_RAISE; /* pop stackpos */ regs = mrb->stack = mrb->stbase + mrb->ci->stackidx; cipop(mrb); NEXT; } else { /* fill callinfo */ ci->acc = a; /* setup environment for calling method */ ci->proc = m; irep = m->body.irep; pool = irep->pool; syms = irep->syms; ci->nregs = irep->nregs; if (ci->argc < 0) { stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3); } else { stack_extend(mrb, irep->nregs, ci->argc+2); } regs = mrb->stack; pc = irep->iseq; JUMP; } } CASE(OP_ARGARY) { /* A Bx R(A) := argument array (16=6:1:5:4) */ int a = GETARG_A(i); int bx = GETARG_Bx(i); int m1 = (bx>>10)&0x3f; int r = (bx>>9)&0x1; int m2 = (bx>>4)&0x1f; int lv = (bx>>0)&0xf; mrb_value *stack; if (lv == 0) stack = regs + 1; else { struct REnv *e = uvenv(mrb, lv-1); if (!e) { mrb_value exc; static const char m[] = "super called outside of method"; exc = mrb_exc_new(mrb, E_NOMETHOD_ERROR, m, sizeof(m) - 1); mrb->exc = (struct RObject*)mrb_object(exc); goto L_RAISE; } stack = e->stack + 1; } if (r == 0) { regs[a] = mrb_ary_new_elts(mrb, m1+m2, stack); } else { mrb_value *pp = NULL; struct RArray *rest; int len = 0; if (mrb_array_p(stack[m1])) { struct RArray *ary = mrb_ary_ptr(stack[m1]); pp = ary->ptr; len = ary->len; } regs[a] = mrb_ary_new_capa(mrb, m1+len+m2); rest = mrb_ary_ptr(regs[a]); stack_copy(rest->ptr, stack, m1); if (len > 0) { stack_copy(rest->ptr+m1, pp, len); } if (m2 > 0) { stack_copy(rest->ptr+m1+len, stack+m1+1, m2); } rest->len = m1+len+m2; } regs[a+1] = stack[m1+r+m2]; mrb->arena_idx = ai; NEXT; } CASE(OP_ENTER) { /* Ax arg setup according to flags (24=5:5:1:5:5:1:1) */ /* number of optional arguments times OP_JMP should follow */ int ax = GETARG_Ax(i); int m1 = (ax>>18)&0x1f; int o = (ax>>13)&0x1f; int r = (ax>>12)&0x1; int m2 = (ax>>7)&0x1f; /* unused int k = (ax>>2)&0x1f; int kd = (ax>>1)&0x1; int b = (ax>>0)& 0x1; */ int argc = mrb->ci->argc; mrb_value *argv = regs+1; mrb_value *argv0 = argv; int len = m1 + o + r + m2; mrb_value *blk = &argv[argc < 0 ? 1 : argc]; if (argc < 0) { struct RArray *ary = mrb_ary_ptr(regs[1]); argv = ary->ptr; argc = ary->len; mrb_gc_protect(mrb, regs[1]); } if (mrb->ci->proc && MRB_PROC_STRICT_P(mrb->ci->proc)) { if (argc >= 0) { if (argc < m1 + m2 || (r == 0 && argc > len)) { argnum_error(mrb, m1+m2); goto L_RAISE; } } } else if (len > 1 && argc == 1 && mrb_array_p(argv[0])) { argc = mrb_ary_ptr(argv[0])->len; argv = mrb_ary_ptr(argv[0])->ptr; } mrb->ci->argc = len; if (argc < len) { regs[len+1] = *blk; /* move block */ if (argv0 != argv) { memmove(®s[1], argv, sizeof(mrb_value)*(argc-m2)); /* m1 + o */ } if (m2) { memmove(®s[len-m2+1], &argv[argc-m2], sizeof(mrb_value)*m2); /* m2 */ } if (r) { /* r */ regs[m1+o+1] = mrb_ary_new_capa(mrb, 0); } if (o == 0) pc++; else pc += argc - m1 - m2 + 1; } else { if (argv0 != argv) { memmove(®s[1], argv, sizeof(mrb_value)*(m1+o)); /* m1 + o */ } if (r) { /* r */ regs[m1+o+1] = mrb_ary_new_elts(mrb, argc-m1-o-m2, argv+m1+o); } if (m2) { memmove(®s[m1+o+r+1], &argv[argc-m2], sizeof(mrb_value)*m2); } regs[len+1] = *blk; /* move block */ pc += o + 1; } JUMP; } CASE(OP_KARG) { /* A B C R(A) := kdict[Sym(B)]; if C kdict.rm(Sym(B)) */ /* if C == 2; raise unless kdict.empty? */ /* OP_JMP should follow to skip init code */ NEXT; } CASE(OP_KDICT) { /* A C R(A) := kdict */ NEXT; } CASE(OP_RETURN) { /* A return R(A) */ L_RETURN: if (mrb->exc) { mrb_callinfo *ci; int eidx; L_RAISE: ci = mrb->ci; eidx = mrb->ci->eidx; if (ci == mrb->cibase) goto L_STOP; while (ci[0].ridx == ci[-1].ridx) { cipop(mrb); ci = mrb->ci; if (ci[1].acc < 0 && prev_jmp) { mrb->jmp = prev_jmp; longjmp(*(jmp_buf*)mrb->jmp, 1); } while (eidx > mrb->ci->eidx) { ecall(mrb, --eidx); } if (ci == mrb->cibase) { if (ci->ridx == 0) { regs = mrb->stack = mrb->stbase; goto L_STOP; } break; } } irep = ci->proc->body.irep; pool = irep->pool; syms = irep->syms; regs = mrb->stack = mrb->stbase + ci[1].stackidx; pc = mrb->rescue[--ci->ridx]; } else { mrb_callinfo *ci = mrb->ci; int acc, eidx = mrb->ci->eidx; mrb_value v = regs[GETARG_A(i)]; switch (GETARG_B(i)) { case OP_R_NORMAL: NORMAL_RETURN: if (ci == mrb->cibase) { localjump_error(mrb, "return"); goto L_RAISE; } ci = mrb->ci; break; case OP_R_BREAK: if (proc->env->cioff < 0) { localjump_error(mrb, "break"); goto L_RAISE; } ci = mrb->ci = mrb->cibase + proc->env->cioff + 1; break; case OP_R_RETURN: if (!proc->env) goto NORMAL_RETURN; if (MRB_PROC_STRICT_P(proc)) goto NORMAL_RETURN; else { struct REnv *e = top_env(mrb, proc); if (e->cioff < 0) { localjump_error(mrb, "return"); goto L_RAISE; } ci = mrb->ci = mrb->cibase + e->cioff; } break; default: /* cannot happen */ break; } cipop(mrb); acc = ci->acc; pc = ci->pc; regs = mrb->stack = mrb->stbase + ci->stackidx; while (eidx > mrb->ci->eidx) { ecall(mrb, --eidx); } if (acc < 0) { mrb->jmp = prev_jmp; return v; } DEBUG(printf("from :%s\n", mrb_sym2name(mrb, ci->mid))); proc = mrb->ci->proc; irep = proc->body.irep; pool = irep->pool; syms = irep->syms; regs[acc] = v; } JUMP; } CASE(OP_TAILCALL) { /* A B C return call(R(A),Sym(B),R(A+1),... ,R(A+C-1)) */ int a = GETARG_A(i); int n = GETARG_C(i); struct RProc *m; struct RClass *c; mrb_callinfo *ci; mrb_value recv; mrb_sym mid = syms[GETARG_B(i)]; recv = regs[a]; c = mrb_class(mrb, recv); m = mrb_method_search_vm(mrb, &c, mid); if (!m) { mrb_value sym = mrb_symbol_value(mid); mid = mrb_intern(mrb, "method_missing"); m = mrb_method_search_vm(mrb, &c, mid); if (n == CALL_MAXARGS) { mrb_ary_unshift(mrb, regs[a+1], sym); } else { memmove(regs+a+2, regs+a+1, sizeof(mrb_value)*(n+1)); regs[a+1] = sym; n++; } } /* replace callinfo */ ci = mrb->ci; ci->mid = mid; ci->target_class = m->target_class; ci->argc = n; if (ci->argc == CALL_MAXARGS) ci->argc = -1; /* move stack */ memmove(mrb->stack, ®s[a], (ci->argc+1)*sizeof(mrb_value)); if (MRB_PROC_CFUNC_P(m)) { mrb->stack[0] = m->body.func(mrb, recv); mrb->arena_idx = ai; goto L_RETURN; } else { /* setup environment for calling method */ irep = m->body.irep; pool = irep->pool; syms = irep->syms; if (ci->argc < 0) { stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3); } else { stack_extend(mrb, irep->nregs, ci->argc+2); } regs = mrb->stack; pc = irep->iseq; } JUMP; } CASE(OP_BLKPUSH) { /* A Bx R(A) := block (16=6:1:5:4) */ int a = GETARG_A(i); int bx = GETARG_Bx(i); int m1 = (bx>>10)&0x3f; int r = (bx>>9)&0x1; int m2 = (bx>>4)&0x1f; int lv = (bx>>0)&0xf; mrb_value *stack; if (lv == 0) stack = regs + 1; else { struct REnv *e = uvenv(mrb, lv-1); if (!e) { localjump_error(mrb, "yield"); goto L_RAISE; } stack = e->stack + 1; } regs[a] = stack[m1+r+m2]; NEXT; } #define attr_i value.i #ifdef MRB_NAN_BOXING #define attr_f f #else #define attr_f value.f #endif #define TYPES2(a,b) (((((int)(a))<<8)|((int)(b)))&0xffff) #define OP_MATH_BODY(op,v1,v2) do {\ regs[a].v1 = regs[a].v1 op regs[a+1].v2;\ } while(0) CASE(OP_ADD) { /* A B C R(A) := R(A)+R(A+1) (Syms[B]=:+,C=1)*/ int a = GETARG_A(i); /* need to check if op is overridden */ switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) { case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM): { mrb_int x, y, z; x = mrb_fixnum(regs[a]); y = mrb_fixnum(regs[a+1]); z = x + y; if (((x < 0) ^ (y < 0)) == 0 && (x < 0) != (z < 0)) { /* integer overflow */ SET_FLT_VALUE(regs[a], (mrb_float)x + (mrb_float)y); break; } SET_INT_VALUE(regs[a], z); } break; case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT): { mrb_int x = mrb_fixnum(regs[a]); mrb_float y = mrb_float(regs[a+1]); SET_FLT_VALUE(regs[a], (mrb_float)x + y); } break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM): OP_MATH_BODY(+,attr_f,attr_i); break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT): OP_MATH_BODY(+,attr_f,attr_f); break; case TYPES2(MRB_TT_STRING,MRB_TT_STRING): regs[a] = mrb_str_plus(mrb, regs[a], regs[a+1]); break; default: goto L_SEND; } mrb->arena_idx = ai; NEXT; } CASE(OP_SUB) { /* A B C R(A) := R(A)-R(A+1) (Syms[B]=:-,C=1)*/ int a = GETARG_A(i); /* need to check if op is overridden */ switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) { case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM): { mrb_int x, y, z; x = mrb_fixnum(regs[a]); y = mrb_fixnum(regs[a+1]); z = x - y; if (((x < 0) ^ (y < 0)) == 0 && (x < 0) != (z < 0)) { /* integer overflow */ SET_FLT_VALUE(regs[a], (mrb_float)x - (mrb_float)y); break; } SET_INT_VALUE(regs[a], z); } break; case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT): { mrb_int x = mrb_fixnum(regs[a]); mrb_float y = mrb_float(regs[a+1]); SET_FLT_VALUE(regs[a], (mrb_float)x - y); } break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM): OP_MATH_BODY(-,attr_f,attr_i); break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT): OP_MATH_BODY(-,attr_f,attr_f); break; default: goto L_SEND; } NEXT; } CASE(OP_MUL) { /* A B C R(A) := R(A)*R(A+1) (Syms[B]=:*,C=1)*/ int a = GETARG_A(i); /* need to check if op is overridden */ switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) { case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM): { mrb_int x, y, z; x = mrb_fixnum(regs[a]); y = mrb_fixnum(regs[a+1]); z = x * y; if (x != 0 && z/x != y) { SET_FLT_VALUE(regs[a], (mrb_float)x * (mrb_float)y); } else { SET_INT_VALUE(regs[a], z); } } break; case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT): { mrb_int x = mrb_fixnum(regs[a]); mrb_float y = mrb_float(regs[a+1]); SET_FLT_VALUE(regs[a], (mrb_float)x * y); } break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM): OP_MATH_BODY(*,attr_f,attr_i); break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT): OP_MATH_BODY(*,attr_f,attr_f); break; default: goto L_SEND; } NEXT; } CASE(OP_DIV) { /* A B C R(A) := R(A)/R(A+1) (Syms[B]=:/,C=1)*/ int a = GETARG_A(i); /* need to check if op is overridden */ switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) { case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM): { mrb_int x = mrb_fixnum(regs[a]); mrb_int y = mrb_fixnum(regs[a+1]); SET_FLT_VALUE(regs[a], (mrb_float)x / (mrb_float)y); } break; case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT): { mrb_int x = mrb_fixnum(regs[a]); mrb_float y = mrb_float(regs[a+1]); SET_FLT_VALUE(regs[a], (mrb_float)x / y); } break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM): OP_MATH_BODY(/,attr_f,attr_i); break; case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT): OP_MATH_BODY(/,attr_f,attr_f); break; default: goto L_SEND; } NEXT; } CASE(OP_ADDI) { /* A B C R(A) := R(A)+C (Syms[B]=:+)*/ int a = GETARG_A(i); /* need to check if + is overridden */ switch (mrb_type(regs[a])) { case MRB_TT_FIXNUM: { mrb_int x = regs[a].attr_i; mrb_int y = GETARG_C(i); mrb_int z = x + y; if (((x < 0) ^ (y < 0)) == 0 && (x < 0) != (z < 0)) { /* integer overflow */ SET_FLT_VALUE(regs[a], (mrb_float)x + (mrb_float)y); break; } regs[a].attr_i = z; } break; case MRB_TT_FLOAT: regs[a].attr_f += GETARG_C(i); break; default: SET_INT_VALUE(regs[a+1], GETARG_C(i)); i = MKOP_ABC(OP_SEND, a, GETARG_B(i), 1); goto L_SEND; } NEXT; } CASE(OP_SUBI) { /* A B C R(A) := R(A)-C (Syms[B]=:+)*/ int a = GETARG_A(i); /* need to check if + is overridden */ switch (mrb_type(regs[a])) { case MRB_TT_FIXNUM: { mrb_int x = regs[a].attr_i; mrb_int y = GETARG_C(i); mrb_int z = x - y; if (((x < 0) ^ (y < 0)) == 0 && (x < 0) != (z < 0)) { /* integer overflow */ SET_FLT_VALUE(regs[a], (mrb_float)x - (mrb_float)y); break; } regs[a].attr_i = z; } break; case MRB_TT_FLOAT: regs[a].attr_f -= GETARG_C(i); break; default: SET_INT_VALUE(regs[a+1], GETARG_C(i)); i = MKOP_ABC(OP_SEND, a, GETARG_B(i), 1); goto L_SEND; } NEXT; } #define OP_CMP_BODY(op,v1,v2) do {\ if (regs[a].v1 op regs[a+1].v2) {\ SET_TRUE_VALUE(regs[a]);\ }\ else {\ SET_FALSE_VALUE(regs[a]);\ }\ } while(0) #define OP_CMP(op) do {\ int a = GETARG_A(i);\ /* need to check if - is overridden */\ switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) {\ case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM):\ OP_CMP_BODY(op,attr_i,attr_i);\ break;\ case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT):\ OP_CMP_BODY(op,attr_i,attr_f);\ break;\ case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM):\ OP_CMP_BODY(op,attr_f,attr_i);\ break;\ case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT):\ OP_CMP_BODY(op,attr_f,attr_f);\ break;\ default:\ goto L_SEND;\ }\ } while (0) CASE(OP_EQ) { /* A B C R(A) := R(A)<R(A+1) (Syms[B]=:<,C=1)*/ int a = GETARG_A(i); if (mrb_obj_eq(mrb, regs[a], regs[a+1])) { SET_TRUE_VALUE(regs[a]); } else { OP_CMP(==); } NEXT; } CASE(OP_LT) { /* A B C R(A) := R(A)<R(A+1) (Syms[B]=:<,C=1)*/ OP_CMP(<); NEXT; } CASE(OP_LE) { /* A B C R(A) := R(A)<R(A+1) (Syms[B]=:<,C=1)*/ OP_CMP(<=); NEXT; } CASE(OP_GT) { /* A B C R(A) := R(A)<R(A+1) (Syms[B]=:<,C=1)*/ OP_CMP(>); NEXT; } CASE(OP_GE) { /* A B C R(A) := R(A)<R(A+1) (Syms[B]=:<,C=1)*/ OP_CMP(>=); NEXT; } CASE(OP_ARRAY) { /* A B C R(A) := ary_new(R(B),R(B+1)..R(B+C)) */ regs[GETARG_A(i)] = mrb_ary_new_from_values(mrb, GETARG_C(i), ®s[GETARG_B(i)]); mrb->arena_idx = ai; NEXT; } CASE(OP_ARYCAT) { /* A B mrb_ary_concat(R(A),R(B)) */ mrb_ary_concat(mrb, regs[GETARG_A(i)], mrb_ary_splat(mrb, regs[GETARG_B(i)])); mrb->arena_idx = ai; NEXT; } CASE(OP_ARYPUSH) { /* A B R(A).push(R(B)) */ mrb_ary_push(mrb, regs[GETARG_A(i)], regs[GETARG_B(i)]); NEXT; } CASE(OP_AREF) { /* A B C R(A) := R(B)[C] */ int a = GETARG_A(i); int c = GETARG_C(i); mrb_value v = regs[GETARG_B(i)]; if (!mrb_array_p(v)) { if (c == 0) { regs[GETARG_A(i)] = v; } else { SET_NIL_VALUE(regs[a]); } } else { regs[GETARG_A(i)] = mrb_ary_ref(mrb, v, c); } NEXT; } CASE(OP_ASET) { /* A B C R(B)[C] := R(A) */ mrb_ary_set(mrb, regs[GETARG_B(i)], GETARG_C(i), regs[GETARG_A(i)]); NEXT; } CASE(OP_APOST) { /* A B C *R(A),R(A+1)..R(A+C) := R(A) */ int a = GETARG_A(i); mrb_value v = regs[a]; int pre = GETARG_B(i); int post = GETARG_C(i); if (!mrb_array_p(v)) { regs[a++] = mrb_ary_new_capa(mrb, 0); while (post--) { SET_NIL_VALUE(regs[a]); a++; } } else { struct RArray *ary = mrb_ary_ptr(v); int len = ary->len; int i; if (len > pre + post) { regs[a++] = mrb_ary_new_elts(mrb, len - pre - post, ary->ptr+pre); while (post--) { regs[a++] = ary->ptr[len-post-1]; } } else { regs[a++] = mrb_ary_new_capa(mrb, 0); for (i=0; i+pre<len; i++) { regs[a+i] = ary->ptr[pre+i]; } while (i < post) { SET_NIL_VALUE(regs[a+i]); i++; } } } mrb->arena_idx = ai; NEXT; } CASE(OP_STRING) { /* A Bx R(A) := str_new(Lit(Bx)) */ regs[GETARG_A(i)] = mrb_str_literal(mrb, pool[GETARG_Bx(i)]); mrb->arena_idx = ai; NEXT; } CASE(OP_STRCAT) { /* A B R(A).concat(R(B)) */ mrb_str_concat(mrb, regs[GETARG_A(i)], regs[GETARG_B(i)]); NEXT; } CASE(OP_HASH) { /* A B C R(A) := hash_new(R(B),R(B+1)..R(B+C)) */ int b = GETARG_B(i); int c = GETARG_C(i); int lim = b+c*2; mrb_value hash = mrb_hash_new_capa(mrb, c); while (b < lim) { mrb_hash_set(mrb, hash, regs[b], regs[b+1]); b+=2; } regs[GETARG_A(i)] = hash; mrb->arena_idx = ai; NEXT; } CASE(OP_LAMBDA) { /* A b c R(A) := lambda(SEQ[b],c) (b:c = 14:2) */ struct RProc *p; int c = GETARG_c(i); if (c & OP_L_CAPTURE) { p = mrb_closure_new(mrb, mrb->irep[irep->idx+GETARG_b(i)]); } else { p = mrb_proc_new(mrb, mrb->irep[irep->idx+GETARG_b(i)]); } if (c & OP_L_STRICT) p->flags |= MRB_PROC_STRICT; regs[GETARG_A(i)] = mrb_obj_value(p); mrb->arena_idx = ai; NEXT; } CASE(OP_OCLASS) { /* A R(A) := ::Object */ regs[GETARG_A(i)] = mrb_obj_value(mrb->object_class); NEXT; } CASE(OP_CLASS) { /* A B R(A) := newclass(R(A),Sym(B),R(A+1)) */ struct RClass *c = 0; int a = GETARG_A(i); mrb_value base, super; mrb_sym id = syms[GETARG_B(i)]; base = regs[a]; super = regs[a+1]; if (mrb_nil_p(base)) { base = mrb_obj_value(mrb->ci->target_class); } c = mrb_vm_define_class(mrb, base, super, id); regs[a] = mrb_obj_value(c); mrb->arena_idx = ai; NEXT; } CASE(OP_MODULE) { /* A B R(A) := newmodule(R(A),Sym(B)) */ struct RClass *c = 0; int a = GETARG_A(i); mrb_value base; mrb_sym id = syms[GETARG_B(i)]; base = regs[a]; if (mrb_nil_p(base)) { base = mrb_obj_value(mrb->ci->target_class); } c = mrb_vm_define_module(mrb, base, id); regs[a] = mrb_obj_value(c); mrb->arena_idx = ai; NEXT; } CASE(OP_EXEC) { /* A Bx R(A) := blockexec(R(A),SEQ[Bx]) */ int a = GETARG_A(i); mrb_callinfo *ci; mrb_value recv = regs[a]; struct RProc *p; /* prepare stack */ ci = cipush(mrb); ci->pc = pc + 1; ci->acc = a; ci->mid = 0; ci->stackidx = mrb->stack - mrb->stbase; ci->argc = 0; ci->target_class = mrb_class_ptr(recv); /* prepare stack */ mrb->stack += a; p = mrb_proc_new(mrb, mrb->irep[irep->idx+GETARG_Bx(i)]); p->target_class = ci->target_class; ci->proc = p; if (MRB_PROC_CFUNC_P(p)) { mrb->stack[0] = p->body.func(mrb, recv); mrb->arena_idx = ai; if (mrb->exc) goto L_RAISE; /* pop stackpos */ regs = mrb->stack = mrb->stbase + mrb->ci->stackidx; cipop(mrb); NEXT; } else { irep = p->body.irep; pool = irep->pool; syms = irep->syms; stack_extend(mrb, irep->nregs, 1); ci->nregs = irep->nregs; regs = mrb->stack; pc = irep->iseq; JUMP; } } CASE(OP_METHOD) { /* A B R(A).newmethod(Sym(B),R(A+1)) */ int a = GETARG_A(i); struct RClass *c = mrb_class_ptr(regs[a]); mrb_define_method_vm(mrb, c, syms[GETARG_B(i)], regs[a+1]); mrb->arena_idx = ai; NEXT; } CASE(OP_SCLASS) { /* A B R(A) := R(B).singleton_class */ regs[GETARG_A(i)] = mrb_singleton_class(mrb, regs[GETARG_B(i)]); mrb->arena_idx = ai; NEXT; } CASE(OP_TCLASS) { /* A B R(A) := target_class */ if (!mrb->ci->target_class) { static const char msg[] = "no target class or module"; mrb_value exc = mrb_exc_new(mrb, E_TYPE_ERROR, msg, sizeof(msg) - 1); mrb->exc = (struct RObject*)mrb_object(exc); goto L_RAISE; } regs[GETARG_A(i)] = mrb_obj_value(mrb->ci->target_class); NEXT; } CASE(OP_RANGE) { /* A B C R(A) := range_new(R(B),R(B+1),C) */ int b = GETARG_B(i); regs[GETARG_A(i)] = mrb_range_new(mrb, regs[b], regs[b+1], GETARG_C(i)); mrb->arena_idx = ai; NEXT; } CASE(OP_DEBUG) { /* A debug print R(A),R(B),R(C) */ #ifdef ENABLE_STDIO printf("OP_DEBUG %d %d %d\n", GETARG_A(i), GETARG_B(i), GETARG_C(i)); #else abort(); #endif NEXT; } CASE(OP_STOP) { /* stop VM */ L_STOP: { int n = mrb->ci->eidx; while (n--) { ecall(mrb, n); } } mrb->jmp = prev_jmp; if (mrb->exc) { return mrb_obj_value(mrb->exc); } return regs[irep->nlocals]; } CASE(OP_ERR) { /* Bx raise RuntimeError with message Lit(Bx) */ mrb_value msg = pool[GETARG_Bx(i)]; mrb_value exc; if (GETARG_A(i) == 0) { exc = mrb_exc_new3(mrb, E_RUNTIME_ERROR, msg); } else { exc = mrb_exc_new3(mrb, E_LOCALJUMP_ERROR, msg); } mrb->exc = (struct RObject*)mrb_object(exc); goto L_RAISE; } } END_DISPATCH; }
static void PrintCode(const Proto* f) { const Instruction* code=f->code; int pc,n=f->sizecode; for (pc=0; pc<n; pc++) { Instruction i=code[pc]; OpCode o=GET_OPCODE(i); int a=GETARG_A(i); int b=GETARG_B(i); int c=GETARG_C(i); int ax=GETARG_Ax(i); int bx=GETARG_Bx(i); int sbx=GETARG_sBx(i); int line=getfuncline(f,pc); printf("\t%d\t",pc+1); if (line>0) printf("[%d]\t",line); else printf("[-]\t"); printf("%-9s\t",luaP_opnames[o]); switch (getOpMode(o)) { case iABC: printf("%d",a); if (getBMode(o)!=OpArgN) printf(" %d", (getBMode(o) == OpArgK && ISK(b)) ? (MYK(INDEXK(b))) : b); if (getCMode(o)!=OpArgN) printf(" %d", (getCMode(o) == OpArgK && ISK(c)) ? (MYK(INDEXK(c))) : c); break; case iABx: printf("%d",a); if (getBMode(o)==OpArgK) printf(" %d",MYK(bx)); if (getBMode(o)==OpArgU) printf(" %d",bx); break; case iAsBx: printf("%d %d",a,sbx); break; case iAx: printf("%d",MYK(ax)); break; } switch (o) { case OP_LOADK: printf("\t; "); PrintConstant(f,bx); break; case OP_GETUPVAL: case OP_RAVI_SETUPVALI: case OP_RAVI_SETUPVALF: case OP_RAVI_SETUPVALAI: case OP_RAVI_SETUPVALAF: case OP_RAVI_SETUPVALT: case OP_SETUPVAL: printf("\t; %s",UPVALNAME(b)); break; case OP_GETTABUP: printf("\t; %s",UPVALNAME(b)); if (ISK(c)) { printf(" "); PrintConstant(f,INDEXK(c)); } break; case OP_SETTABUP: printf("\t; %s",UPVALNAME(a)); if (ISK(b)) { printf(" "); PrintConstant(f,INDEXK(b)); } if (ISK(c)) { printf(" "); PrintConstant(f,INDEXK(c)); } break; case OP_GETTABLE: case OP_RAVI_GETTABLE_I: case OP_RAVI_GETTABLE_S: case OP_RAVI_GETTABLE_AF: case OP_RAVI_GETTABLE_AI: case OP_SELF: if (ISK(c)) { printf("\t; "); PrintConstant(f,INDEXK(c)); } break; case OP_SETTABLE: case OP_RAVI_SETTABLE_I: case OP_RAVI_SETTABLE_S: case OP_RAVI_SETTABLE_AF: case OP_RAVI_SETTABLE_AFF: case OP_RAVI_SETTABLE_AI: case OP_RAVI_SETTABLE_AII: case OP_ADD: case OP_RAVI_ADDFF: case OP_RAVI_ADDFI: case OP_RAVI_ADDII: case OP_SUB: case OP_RAVI_SUBFF: case OP_RAVI_SUBFI: case OP_RAVI_SUBIF: case OP_RAVI_SUBII: case OP_MUL: case OP_RAVI_MULFF: case OP_RAVI_MULFI: case OP_RAVI_MULII: case OP_POW: case OP_DIV: case OP_RAVI_DIVFF: case OP_RAVI_DIVFI: case OP_RAVI_DIVIF: case OP_RAVI_DIVII: case OP_IDIV: case OP_BAND: case OP_RAVI_BAND_II: case OP_BOR: case OP_RAVI_BOR_II: case OP_BXOR: case OP_RAVI_BXOR_II: case OP_SHL: case OP_RAVI_SHL_II: case OP_SHR: case OP_RAVI_SHR_II: case OP_EQ: case OP_RAVI_EQ_II: case OP_RAVI_EQ_FF: case OP_LT: case OP_RAVI_LT_II: case OP_RAVI_LT_FF: case OP_LE: case OP_RAVI_LE_II: case OP_RAVI_LE_FF: if (ISK(b) || ISK(c)) { printf("\t; "); if (ISK(b)) PrintConstant(f,INDEXK(b)); else printf("-"); printf(" "); if (ISK(c)) PrintConstant(f,INDEXK(c)); else printf("-"); } break; case OP_JMP: case OP_FORLOOP: case OP_RAVI_FORLOOP_IP: case OP_RAVI_FORLOOP_I1: case OP_FORPREP: case OP_RAVI_FORPREP_IP: case OP_RAVI_FORPREP_I1: case OP_TFORLOOP: printf("\t; to %d",sbx+pc+2); break; case OP_CLOSURE: printf("\t; %p",VOID(f->p[bx])); break; case OP_SETLIST: if (c==0) printf("\t; %d",(int)code[++pc]); else printf("\t; %d",c); break; case OP_EXTRAARG: printf("\t; "); PrintConstant(f,ax); break; default: break; } printf("\n"); } }
/* ** Executes the given Lua function. Parameters are between [base,top). ** Returns n such that the the results are between [n,top). */ StkId luaV_execute (lua_State *L, const Closure *cl, StkId base) { const Proto *const tf = cl->f.l; StkId top; /* keep top local, for performance */ const Instruction *pc = tf->code; TString **const kstr = tf->kstr; const lua_Hook linehook = L->linehook; infovalue(base-1)->pc = &pc; luaD_checkstack(L, tf->maxstacksize+EXTRA_STACK); if (tf->is_vararg) /* varargs? */ adjust_varargs(L, base, tf->numparams); else luaD_adjusttop(L, base, tf->numparams); top = L->top; /* main loop of interpreter */ for (;;) { const Instruction i = *pc++; if (linehook) traceexec(L, base, top, linehook); switch (GET_OPCODE(i)) { case OP_END: { L->top = top; return top; } case OP_RETURN: { L->top = top; return base+GETARG_U(i); } case OP_CALL: { int nres = GETARG_B(i); if (nres == MULT_RET) nres = LUA_MULTRET; L->top = top; luaD_call(L, base+GETARG_A(i), nres); top = L->top; break; } case OP_TAILCALL: { L->top = top; luaD_call(L, base+GETARG_A(i), LUA_MULTRET); return base+GETARG_B(i); } case OP_PUSHNIL: { int n = GETARG_U(i); LUA_ASSERT(n>0, "invalid argument"); do { ttype(top++) = LUA_TNIL; } while (--n > 0); break; } case OP_POP: { top -= GETARG_U(i); break; } case OP_PUSHINT: { ttype(top) = LUA_TNUMBER; nvalue(top) = (Number)GETARG_S(i); top++; break; } case OP_PUSHSTRING: { ttype(top) = LUA_TSTRING; tsvalue(top) = kstr[GETARG_U(i)]; top++; break; } case OP_PUSHNUM: { ttype(top) = LUA_TNUMBER; nvalue(top) = tf->knum[GETARG_U(i)]; top++; break; } case OP_PUSHNEGNUM: { ttype(top) = LUA_TNUMBER; nvalue(top) = -tf->knum[GETARG_U(i)]; top++; break; } case OP_PUSHUPVALUE: { *top++ = cl->upvalue[GETARG_U(i)]; break; } case OP_GETLOCAL: { *top++ = *(base+GETARG_U(i)); break; } case OP_GETGLOBAL: { L->top = top; *top = *luaV_getglobal(L, kstr[GETARG_U(i)]); top++; break; } case OP_GETTABLE: { L->top = top; top--; *(top-1) = *luaV_gettable(L, top-1); break; } case OP_GETDOTTED: { ttype(top) = LUA_TSTRING; tsvalue(top) = kstr[GETARG_U(i)]; L->top = top+1; *(top-1) = *luaV_gettable(L, top-1); break; } case OP_GETINDEXED: { *top = *(base+GETARG_U(i)); L->top = top+1; *(top-1) = *luaV_gettable(L, top-1); break; } case OP_PUSHSELF: { TObject receiver; receiver = *(top-1); ttype(top) = LUA_TSTRING; tsvalue(top++) = kstr[GETARG_U(i)]; L->top = top; *(top-2) = *luaV_gettable(L, top-2); *(top-1) = receiver; break; } case OP_CREATETABLE: { L->top = top; luaC_checkGC(L); hvalue(top) = luaH_new(L, GETARG_U(i)); ttype(top) = LUA_TTABLE; top++; break; } case OP_SETLOCAL: { *(base+GETARG_U(i)) = *(--top); break; } case OP_SETGLOBAL: { L->top = top; luaV_setglobal(L, kstr[GETARG_U(i)]); top--; break; } case OP_SETTABLE: { StkId t = top-GETARG_A(i); L->top = top; luaV_settable(L, t, t+1); top -= GETARG_B(i); /* pop values */ break; } case OP_SETLIST: { int aux = GETARG_A(i) * LFIELDS_PER_FLUSH; int n = GETARG_B(i); Hash *arr = hvalue(top-n-1); L->top = top-n; /* final value of `top' (in case of errors) */ for (; n; n--) *luaH_setint(L, arr, n+aux) = *(--top); break; } case OP_SETMAP: { int n = GETARG_U(i); StkId finaltop = top-2*n; Hash *arr = hvalue(finaltop-1); L->top = finaltop; /* final value of `top' (in case of errors) */ for (; n; n--) { top-=2; *luaH_set(L, arr, top) = *(top+1); } break; } case OP_ADD: { if (tonumber(top-2) || tonumber(top-1)) call_arith(L, top, TM_ADD); else nvalue(top-2) += nvalue(top-1); top--; break; } case OP_ADDI: { if (tonumber(top-1)) { ttype(top) = LUA_TNUMBER; nvalue(top) = (Number)GETARG_S(i); call_arith(L, top+1, TM_ADD); } else nvalue(top-1) += (Number)GETARG_S(i); break; } case OP_SUB: { if (tonumber(top-2) || tonumber(top-1)) call_arith(L, top, TM_SUB); else nvalue(top-2) -= nvalue(top-1); top--; break; } case OP_MULT: { if (tonumber(top-2) || tonumber(top-1)) call_arith(L, top, TM_MUL); else nvalue(top-2) *= nvalue(top-1); top--; break; } case OP_DIV: { if (tonumber(top-2) || tonumber(top-1)) call_arith(L, top, TM_DIV); else nvalue(top-2) /= nvalue(top-1); top--; break; } case OP_POW: { if (!call_binTM(L, top, TM_POW)) lua_error(L, "undefined operation"); top--; break; } case OP_CONCAT: { int n = GETARG_U(i); luaV_strconc(L, n, top); top -= n-1; L->top = top; luaC_checkGC(L); break; } case OP_MINUS: { if (tonumber(top-1)) { ttype(top) = LUA_TNIL; call_arith(L, top+1, TM_UNM); } else nvalue(top-1) = -nvalue(top-1); break; } case OP_NOT: { ttype(top-1) = (ttype(top-1) == LUA_TNIL) ? LUA_TNUMBER : LUA_TNIL; nvalue(top-1) = 1; break; } case OP_JMPNE: { top -= 2; if (!luaO_equalObj(top, top+1)) dojump(pc, i); break; } case OP_JMPEQ: { top -= 2; if (luaO_equalObj(top, top+1)) dojump(pc, i); break; } case OP_JMPLT: { top -= 2; if (luaV_lessthan(L, top, top+1, top+2)) dojump(pc, i); break; } case OP_JMPLE: { /* a <= b === !(b<a) */ top -= 2; if (!luaV_lessthan(L, top+1, top, top+2)) dojump(pc, i); break; } case OP_JMPGT: { /* a > b === (b<a) */ top -= 2; if (luaV_lessthan(L, top+1, top, top+2)) dojump(pc, i); break; } case OP_JMPGE: { /* a >= b === !(a<b) */ top -= 2; if (!luaV_lessthan(L, top, top+1, top+2)) dojump(pc, i); break; } case OP_JMPT: { if (ttype(--top) != LUA_TNIL) dojump(pc, i); break; } case OP_JMPF: { if (ttype(--top) == LUA_TNIL) dojump(pc, i); break; } case OP_JMPONT: { if (ttype(top-1) == LUA_TNIL) top--; else dojump(pc, i); break; } case OP_JMPONF: { if (ttype(top-1) != LUA_TNIL) top--; else dojump(pc, i); break; } case OP_JMP: { dojump(pc, i); break; } case OP_PUSHNILJMP: { ttype(top++) = LUA_TNIL; pc++; break; } case OP_FORPREP: { if (tonumber(top-1)) lua_error(L, "`for' step must be a number"); if (tonumber(top-2)) lua_error(L, "`for' limit must be a number"); if (tonumber(top-3)) lua_error(L, "`for' initial value must be a number"); if (nvalue(top-1) > 0 ? nvalue(top-3) > nvalue(top-2) : nvalue(top-3) < nvalue(top-2)) { /* `empty' loop? */ top -= 3; /* remove control variables */ dojump(pc, i); /* jump to loop end */ } break; } case OP_FORLOOP: { LUA_ASSERT(ttype(top-1) == LUA_TNUMBER, "invalid step"); LUA_ASSERT(ttype(top-2) == LUA_TNUMBER, "invalid limit"); if (ttype(top-3) != LUA_TNUMBER) lua_error(L, "`for' index must be a number"); nvalue(top-3) += nvalue(top-1); /* increment index */ if (nvalue(top-1) > 0 ? nvalue(top-3) > nvalue(top-2) : nvalue(top-3) < nvalue(top-2)) top -= 3; /* end loop: remove control variables */ else dojump(pc, i); /* repeat loop */ break; } case OP_LFORPREP: { Node *node; if (ttype(top-1) != LUA_TTABLE) lua_error(L, "`for' table must be a table"); node = luaH_next(L, hvalue(top-1), &luaO_nilobject); if (node == NULL) { /* `empty' loop? */ top--; /* remove table */ dojump(pc, i); /* jump to loop end */ } else { top += 2; /* index,value */ *(top-2) = *key(node); *(top-1) = *val(node); } break; } case OP_LFORLOOP: { Node *node; LUA_ASSERT(ttype(top-3) == LUA_TTABLE, "invalid table"); node = luaH_next(L, hvalue(top-3), top-2); if (node == NULL) /* end loop? */ top -= 3; /* remove table, key, and value */ else { *(top-2) = *key(node); *(top-1) = *val(node); dojump(pc, i); /* repeat loop */ } break; } case OP_CLOSURE: { L->top = top; luaV_Lclosure(L, tf->kproto[GETARG_A(i)], GETARG_B(i)); top = L->top; luaC_checkGC(L); break; } } } }
void luaV_execute (lua_State *L, int nexeccalls) { LClosure *cl; StkId base; TValue *k; const Instruction *pc; reentry: /* entry point */ lua_assert(isLua(L->ci)); pc = L->savedpc; cl = &clvalue(L->ci->func)->l; base = L->base; k = cl->p->k; /* main loop of interpreter */ for (;;) { const Instruction i = *pc++; StkId ra; if ((L->hookmask & (LUA_MASKLINE | LUA_MASKCOUNT)) && (--L->hookcount == 0 || L->hookmask & LUA_MASKLINE)) { traceexec(L, pc); if (L->status == LUA_YIELD) { /* did hook yield? */ L->savedpc = pc - 1; return; } base = L->base; } /* warning!! several calls may realloc the stack and invalidate `ra' */ ra = RA(i); lua_assert(base == L->base && L->base == L->ci->base); lua_assert(base <= L->top && L->top <= L->stack + L->stacksize); lua_assert(L->top == L->ci->top || luaG_checkopenop(i)); switch (GET_OPCODE(i)) { case OP_MOVE: { setobjs2s(L, ra, RB(i)); continue; } case OP_LOADK: { setobj2s(L, ra, KBx(i)); continue; } case OP_LOADBOOL: { setbvalue(ra, GETARG_B(i)); if (GETARG_C(i)) pc++; /* skip next instruction (if C) */ continue; } case OP_LOADNIL: { TValue *rb = RB(i); do { setnilvalue(rb--); } while (rb >= ra); continue; } case OP_GETUPVAL: { int b = GETARG_B(i); setobj2s(L, ra, cl->upvals[b]->v); continue; } case OP_GETGLOBAL: { TValue g; TValue *rb = KBx(i); sethvalue(L, &g, cl->env); lua_assert(ttisstring(rb)); Protect(luaV_gettable(L, &g, rb, ra)); continue; } case OP_GETTABLE: { Protect(luaV_gettable(L, RB(i), RKC(i), ra)); continue; } case OP_SETGLOBAL: { TValue g; sethvalue(L, &g, cl->env); lua_assert(ttisstring(KBx(i))); Protect(luaV_settable(L, &g, KBx(i), ra)); continue; } case OP_SETUPVAL: { UpVal *uv = cl->upvals[GETARG_B(i)]; setobj(L, uv->v, ra); luaC_barrier(L, uv, ra); continue; } case OP_SETTABLE: { Protect(luaV_settable(L, ra, RKB(i), RKC(i))); continue; } case OP_NEWTABLE: { int b = GETARG_B(i); int c = GETARG_C(i); Table *h; Protect(h = luaH_new(L, luaO_fb2int(b), luaO_fb2int(c))); sethvalue(L, RA(i), h); Protect(luaC_checkGC(L)); continue; } case OP_SELF: { StkId rb = RB(i); setobjs2s(L, ra+1, rb); Protect(luaV_gettable(L, rb, RKC(i), ra)); continue; } case OP_ADD: { arith_op(luai_numadd, TM_ADD); continue; } case OP_SUB: { arith_op(luai_numsub, TM_SUB); continue; } case OP_MUL: { arith_op(luai_nummul, TM_MUL); continue; } case OP_DIV: { arith_op(luai_lnumdiv, TM_DIV); continue; } case OP_MOD: { arith_op(luai_lnummod, TM_MOD); continue; } case OP_POW: { arith_op(luai_numpow, TM_POW); continue; } case OP_UNM: { TValue *rb = RB(i); if (ttisnumber(rb)) { lua_Number nb = nvalue(rb); setnvalue(ra, luai_numunm(nb)); } else { Protect(Arith(L, ra, rb, rb, TM_UNM)); } continue; } case OP_NOT: { int res = l_isfalse(RB(i)); /* next assignment may change this value */ setbvalue(ra, res); continue; } case OP_LEN: { const TValue *rb = RB(i); switch (ttype(rb)) { case LUA_TTABLE: case LUA_TROTABLE: { setnvalue(ra, ttistable(rb) ? cast_num(luaH_getn(hvalue(rb))) : cast_num(luaH_getn_ro(rvalue(rb)))); break; } case LUA_TSTRING: { setnvalue(ra, cast_num(tsvalue(rb)->len)); break; } default: { /* try metamethod */ ptrdiff_t br = savestack(L, rb); Protect( if (!call_binTM(L, rb, luaO_nilobject, ra, TM_LEN)) luaG_typeerror(L, restorestack(L, br), "get length of"); ) } } continue; } case OP_CONCAT: { int b = GETARG_B(i); int c = GETARG_C(i); Protect(luaV_concat(L, c-b+1, c); luaC_checkGC(L)); setobjs2s(L, RA(i), base+b); continue; } case OP_JMP: { dojump(L, pc, GETARG_sBx(i)); continue; } case OP_EQ: { TValue *rb = RKB(i); TValue *rc = RKC(i); Protect( if (equalobj(L, rb, rc) == GETARG_A(i)) dojump(L, pc, GETARG_sBx(*pc)); ) pc++; continue; } case OP_LT: { Protect( if (luaV_lessthan(L, RKB(i), RKC(i)) == GETARG_A(i)) dojump(L, pc, GETARG_sBx(*pc)); ) pc++; continue; } case OP_LE: { Protect( if (lessequal(L, RKB(i), RKC(i)) == GETARG_A(i)) dojump(L, pc, GETARG_sBx(*pc)); ) pc++; continue; }
static void PrintCode(const Proto* f) { const Instruction* code=f->code; int pc,n=f->sizecode; for (pc=0; pc<n; pc++) { Instruction i=code[pc]; OpCode o=GET_OPCODE(i); int a=GETARG_A(i); int b=GETARG_B(i); int c=GETARG_C(i); int bx=GETARG_Bx(i); int sbx=GETARG_sBx(i); int line=getline(f,pc); printf("\t%d\t",pc+1); if (line>0) printf("[%d]\t",line); else printf("[-]\t"); printf("%-9s\t",luaP_opnames[o]); switch (getOpMode(o)) { case iABC: printf("%d",a); if (getBMode(o)!=OpArgN) printf(" %d",ISK(b) ? (-1-INDEXK(b)) : b); if (getCMode(o)!=OpArgN) printf(" %d",ISK(c) ? (-1-INDEXK(c)) : c); break; case iABx: if (getBMode(o)==OpArgK) printf("%d %d",a,-1-bx); else printf("%d %d",a,bx); break; case iAsBx: if (o==OP_JMP) printf("%d",sbx); else printf("%d %d",a,sbx); break; } switch (o) { case OP_LOADK: printf("\t; "); PrintConstant(f,bx); break; case OP_GETUPVAL: case OP_SETUPVAL: printf("\t; %s", (f->sizeupvalues>0) ? getstr(f->upvalues[b]) : "-"); break; case OP_GETGLOBAL: case OP_SETGLOBAL: printf("\t; %s",svalue(&f->k[bx])); break; case OP_GETTABLE: case OP_SELF: if (ISK(c)) { printf("\t; "); PrintConstant(f,INDEXK(c)); } break; case OP_SETTABLE: case OP_ADD: case OP_SUB: case OP_MUL: case OP_DIV: case OP_POW: case OP_EQ: case OP_LT: case OP_LE: if (ISK(b) || ISK(c)) { printf("\t; "); if (ISK(b)) PrintConstant(f,INDEXK(b)); else printf("-"); printf(" "); if (ISK(c)) PrintConstant(f,INDEXK(c)); else printf("-"); } break; case OP_JMP: case OP_FORLOOP: case OP_FORPREP: printf("\t; to %d",sbx+pc+2); break; case OP_CLOSURE: printf("\t; %p",VOID(f->p[bx])); break; case OP_SETLIST: if (c==0) printf("\t; %d",(int)code[++pc]); else printf("\t; %d",c); break; default: break; } printf("\n"); } }
static Instruction luaG_symbexec (const Proto *pt, int lastpc, int stackpos) { int stack[MAXSTACK]; /* stores last instruction that changed a stack entry */ const Instruction *code = pt->code; int top = pt->numparams; int pc = 0; if (pt->is_vararg) /* varargs? */ top++; /* `arg' */ while (pc < lastpc) { const Instruction i = code[pc++]; LUA_ASSERT(0 <= top && top <= pt->maxstacksize, "wrong stack"); switch (GET_OPCODE(i)) { case OP_RETURN: { LUA_ASSERT(top >= GETARG_U(i), "wrong stack"); top = GETARG_U(i); break; } case OP_TAILCALL: { LUA_ASSERT(top >= GETARG_A(i), "wrong stack"); top = GETARG_B(i); break; } case OP_CALL: { int nresults = GETARG_B(i); if (nresults == MULT_RET) nresults = 1; LUA_ASSERT(top >= GETARG_A(i), "wrong stack"); top = pushpc(stack, pc, GETARG_A(i), nresults); break; } case OP_PUSHNIL: { top = pushpc(stack, pc, top, GETARG_U(i)); break; } case OP_POP: { top -= GETARG_U(i); break; } case OP_SETTABLE: case OP_SETLIST: { top -= GETARG_B(i); break; } case OP_SETMAP: { top -= 2*GETARG_U(i); break; } case OP_CONCAT: { top -= GETARG_U(i); stack[top++] = pc-1; break; } case OP_CLOSURE: { top -= GETARG_B(i); stack[top++] = pc-1; break; } case OP_JMPONT: case OP_JMPONF: { int newpc = pc + GETARG_S(i); /* jump is forward and do not skip `lastpc'? */ if (pc < newpc && newpc <= lastpc) { stack[top-1] = pc-1; /* value comes from `and'/`or' */ pc = newpc; /* do the jump */ } else top--; /* do not jump; pop value */ break; } default: { OpCode op = GET_OPCODE(i); LUA_ASSERT(luaK_opproperties[op].push != VD, "invalid opcode for default"); top -= luaK_opproperties[op].pop; LUA_ASSERT(top >= 0, "wrong stack"); top = pushpc(stack, pc, top, luaK_opproperties[op].push); } } } return code[stack[stackpos]]; }
static Instruction symbexec (const Proto *pt, int lastpc, int reg) { int pc; int last; /* stores position of last instruction that changed `reg' */ last = pt->sizecode - 1; /* points to final return (a `neutral' instruction) */ check(precheck(pt)); for (pc = 0; pc < lastpc; pc++) { Instruction i = pt->code[pc]; OpCode op = GET_OPCODE(i); int a = GETARG_A(i); int b = 0; int c = 0; check(op < NUM_OPCODES); checkreg(pt, a); switch (getOpMode(op)) { case iABC: { b = GETARG_B(i); c = GETARG_C(i); check(checkArgMode(pt, b, getBMode(op))); check(checkArgMode(pt, c, getCMode(op))); break; } case iABx: { b = GETARG_Bx(i); if (getBMode(op) == OpArgK) check(b < pt->sizek); break; } case iAsBx: { b = GETARG_sBx(i); if (getBMode(op) == OpArgR) { int dest = pc + 1 + b; check(0 <= dest && dest < pt->sizecode); if (dest > 0) { int j; /* check that it does not jump to a setlist count; this is tricky, because the count from a previous setlist may have the same value of an invalid setlist; so, we must go all the way back to the first of them (if any) */ for (j = 0; j < dest; j++) { Instruction d = pt->code[dest - 1 - j]; if (!(GET_OPCODE(d) == OP_SETLIST && GETARG_C(d) == 0)) break; } /* if 'j' is even, previous value is not a setlist (even if it looks like one) */ check((j & 1) == 0); } } break; } } if (testAMode(op)) { if (a == reg) last = pc; /* change register `a' */ } if (testTMode(op)) { check(pc + 2 < pt->sizecode); /* check skip */ check(GET_OPCODE(pt->code[pc + 1]) == OP_JMP); } switch (op) { case OP_LOADBOOL: { if (c == 1) { /* does it jump? */ check(pc + 2 < pt->sizecode); /* check its jump */ check(GET_OPCODE(pt->code[pc + 1]) != OP_SETLIST || GETARG_C(pt->code[pc + 1]) != 0); } break; } case OP_LOADNIL: { if (a <= reg && reg <= b) last = pc; /* set registers from `a' to `b' */ break; } case OP_GETUPVAL: case OP_SETUPVAL: { check(b < pt->nups); break; } case OP_GETGLOBAL: case OP_SETGLOBAL: { check(ttisstring(&pt->k[b])); break; } case OP_SELF: { checkreg(pt, a + 1); if (reg == a + 1) last = pc; break; } case OP_CONCAT: { check(b < c); /* at least two operands */ break; } case OP_TFORLOOP: { check(c >= 1); /* at least one result (control variable) */ checkreg(pt, a + 2 + c); /* space for results */ if (reg >= a + 2) last = pc; /* affect all regs above its base */ break; } case OP_FORLOOP: case OP_FORPREP: checkreg(pt, a + 3); /* go through */ case OP_JMP: { int dest = pc + 1 + b; /* not full check and jump is forward and do not skip `lastpc'? */ if (reg != NO_REG && pc < dest && dest <= lastpc) pc += b; /* do the jump */ break; } case OP_CALL: case OP_TAILCALL: { if (b != 0) { checkreg(pt, a + b - 1); } c--; /* c = num. returns */ if (c == LUA_MULTRET) { check(checkopenop(pt, pc)); } else if (c != 0) checkreg(pt, a + c - 1); if (reg >= a) last = pc; /* affect all registers above base */ break; } case OP_RETURN: { b--; /* b = num. returns */ if (b > 0) checkreg(pt, a + b - 1); break; } case OP_SETLIST: { if (b > 0) checkreg(pt, a + b); if (c == 0) { pc++; check(pc < pt->sizecode - 1); } break; } case OP_CLOSURE: { int nup, j; check(b < pt->sizep); nup = pt->p[b]->nups; check(pc + nup < pt->sizecode); for (j = 1; j <= nup; j++) { OpCode op1 = GET_OPCODE(pt->code[pc + j]); check(op1 == OP_GETUPVAL || op1 == OP_MOVE); } if (reg != NO_REG) /* tracing? */ pc += nup; /* do not 'execute' these pseudo-instructions */ break; } case OP_VARARG: { check((pt->is_vararg & VARARG_ISVARARG) && !(pt->is_vararg & VARARG_NEEDSARG)); b--; if (b == LUA_MULTRET) check(checkopenop(pt, pc)); checkreg(pt, a + b - 1); break; } default: break; } } return pt->code[last]; }
static void patch_irep(mrb_state *mrb, mrb_irep *irep, int bnest) { size_t i; mrb_code c; int argc = 0; for (i = 0; i < irep->ilen; i++) { c = irep->iseq[i]; switch(GET_OPCODE(c)){ case OP_ENTER: { mrb_aspec ax = GETARG_Ax(c); /* extra 1 means a slot for block */ argc = MRB_ASPEC_REQ(ax)+MRB_ASPEC_OPT(ax)+MRB_ASPEC_REST(ax)+MRB_ASPEC_POST(ax)+1; } break; case OP_EPUSH: patch_irep(mrb, irep->reps[GETARG_Bx(c)], bnest + 1); break; case OP_LAMBDA: { int arg_c = GETARG_c(c); if (arg_c & OP_L_CAPTURE) { patch_irep(mrb, irep->reps[GETARG_b(c)], bnest + 1); } } break; case OP_SEND: if (GETARG_C(c) != 0) { break; } { mrb_code arg = search_variable(mrb, irep->syms[GETARG_B(c)], bnest); if (arg != 0) { /* must replace */ irep->iseq[i] = MKOPCODE(OP_GETUPVAR) | MKARG_A(GETARG_A(c)) | arg; } } break; case OP_MOVE: /* src part */ if (potential_upvar_p(irep->lv, GETARG_B(c), argc, irep->nlocals)) { mrb_code arg = search_variable(mrb, irep->lv[GETARG_B(c) - 1].name, bnest); if (arg != 0) { /* must replace */ irep->iseq[i] = MKOPCODE(OP_GETUPVAR) | MKARG_A(GETARG_A(c)) | arg; } } /* dst part */ if (potential_upvar_p(irep->lv, GETARG_A(c), argc, irep->nlocals)) { mrb_code arg = search_variable(mrb, irep->lv[GETARG_A(c) - 1].name, bnest); if (arg != 0) { /* must replace */ irep->iseq[i] = MKOPCODE(OP_SETUPVAR) | MKARG_A(GETARG_B(c)) | arg; } } break; } } }
void Compiler::CompileSetupval() { auto& upval = stack_.GetUp(GETARG_B(cs_.instr_)); auto& ra = stack_.GetR(GETARG_A(cs_.instr_)); upval.Assign(ra); cs_.CreateCall("lll_upvalbarrier", {cs_.values_.state, upval.GetUpVal()}); }
static void patchtestreg (Instruction *i, int reg) { if (reg == NO_REG) reg = GETARG_B(*i); SETARG_A(*i, reg); }
void Compiler::CompileSettable() { auto& table = stack_.GetR(GETARG_A(cs_.instr_)); auto& key = stack_.GetRK(GETARG_B(cs_.instr_)); auto& value = stack_.GetRK(GETARG_C(cs_.instr_)); TableSet(cs_, stack_, table, key, value).Compile(); }
StkId luaV_execute (lua_State *L) { LClosure *cl; TObject *k; const Instruction *pc; callentry: /* entry point when calling new functions */ L->ci->u.l.pc = &pc; if (L->hookmask & LUA_MASKCALL) luaD_callhook(L, LUA_HOOKCALL, -1); retentry: /* entry point when returning to old functions */ lua_assert(L->ci->state == CI_SAVEDPC || L->ci->state == (CI_SAVEDPC | CI_CALLING)); L->ci->state = CI_HASFRAME; /* activate frame */ pc = L->ci->u.l.savedpc; cl = &clvalue(L->base - 1)->l; k = cl->p->k; /* main loop of interpreter */ for (;;) { const Instruction i = *pc++; StkId base, ra; if ((L->hookmask & (LUA_MASKLINE | LUA_MASKCOUNT)) && (--L->hookcount == 0 || L->hookmask & LUA_MASKLINE)) { traceexec(L); if (L->ci->state & CI_YIELD) { /* did hook yield? */ L->ci->u.l.savedpc = pc - 1; L->ci->state = CI_YIELD | CI_SAVEDPC; return NULL; } } /* warning!! several calls may realloc the stack and invalidate `ra' */ base = L->base; ra = RA(i); lua_assert(L->ci->state & CI_HASFRAME); lua_assert(base == L->ci->base); lua_assert(L->top <= L->stack + L->stacksize && L->top >= base); lua_assert(L->top == L->ci->top || GET_OPCODE(i) == OP_CALL || GET_OPCODE(i) == OP_TAILCALL || GET_OPCODE(i) == OP_RETURN || GET_OPCODE(i) == OP_SETLISTO); switch (GET_OPCODE(i)) { case OP_MOVE: { setobjs2s(ra, RB(i)); break; } case OP_LOADK: { setobj2s(ra, KBx(i)); break; } case OP_LOADBOOL: { setbvalue(ra, GETARG_B(i)); if (GETARG_C(i)) pc++; /* skip next instruction (if C) */ break; } case OP_LOADNIL: { TObject *rb = RB(i); do { setnilvalue(rb--); } while (rb >= ra); break; } case OP_GETUPVAL: { int b = GETARG_B(i); setobj2s(ra, cl->upvals[b]->v); break; } case OP_GETGLOBAL: { TObject *rb = KBx(i); const TObject *v; lua_assert(ttisstring(rb) && ttistable(&cl->g)); v = luaH_getstr(hvalue(&cl->g), tsvalue(rb)); if (!ttisnil(v)) { setobj2s(ra, v); } else setobj2s(XRA(i), luaV_index(L, &cl->g, rb, 0)); break; } case OP_GETTABLE: { StkId rb = RB(i); TObject *rc = RKC(i); if (ttistable(rb)) { const TObject *v = luaH_get(hvalue(rb), rc); if (!ttisnil(v)) { setobj2s(ra, v); } else setobj2s(XRA(i), luaV_index(L, rb, rc, 0)); } else setobj2s(XRA(i), luaV_getnotable(L, rb, rc, 0)); break; } case OP_SETGLOBAL: { lua_assert(ttisstring(KBx(i)) && ttistable(&cl->g)); luaV_settable(L, &cl->g, KBx(i), ra); break; } case OP_SETUPVAL: { int b = GETARG_B(i); setobj(cl->upvals[b]->v, ra); /* write barrier */ break; } case OP_SETTABLE: { luaV_settable(L, ra, RKB(i), RKC(i)); break; } case OP_NEWTABLE: { int b = GETARG_B(i); b = fb2int(b); sethvalue(ra, luaH_new(L, b, GETARG_C(i))); luaC_checkGC(L); break; } case OP_SELF: { StkId rb = RB(i); TObject *rc = RKC(i); runtime_check(L, ttisstring(rc)); setobjs2s(ra+1, rb); if (ttistable(rb)) { const TObject *v = luaH_getstr(hvalue(rb), tsvalue(rc)); if (!ttisnil(v)) { setobj2s(ra, v); } else setobj2s(XRA(i), luaV_index(L, rb, rc, 0)); } else setobj2s(XRA(i), luaV_getnotable(L, rb, rc, 0)); break; } case OP_ADD: { TObject *rb = RKB(i); TObject *rc = RKC(i); if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) + nvalue(rc)); } else Arith(L, ra, rb, rc, TM_ADD); break; } case OP_SUB: { TObject *rb = RKB(i); TObject *rc = RKC(i); if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) - nvalue(rc)); } else Arith(L, ra, rb, rc, TM_SUB); break; } case OP_MUL: { TObject *rb = RKB(i); TObject *rc = RKC(i); if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) * nvalue(rc)); } else Arith(L, ra, rb, rc, TM_MUL); break; } case OP_DIV: { TObject *rb = RKB(i); TObject *rc = RKC(i); if (ttisnumber(rb) && ttisnumber(rc)) { setnvalue(ra, nvalue(rb) / nvalue(rc)); } else Arith(L, ra, rb, rc, TM_DIV); break; } case OP_POW: { Arith(L, ra, RKB(i), RKC(i), TM_POW); break; } case OP_UNM: { const TObject *rb = RB(i); TObject temp; if (tonumber(rb, &temp)) { setnvalue(ra, -nvalue(rb)); } else { setnilvalue(&temp); if (!call_binTM(L, RB(i), &temp, ra, TM_UNM)) luaG_aritherror(L, RB(i), &temp); } break; } case OP_NOT: { int res = l_isfalse(RB(i)); /* next assignment may change this value */ setbvalue(ra, res); break; } case OP_CONCAT: { int b = GETARG_B(i); int c = GETARG_C(i); luaV_concat(L, c-b+1, c); /* may change `base' (and `ra') */ base = L->base; setobjs2s(RA(i), base+b); luaC_checkGC(L); break; } case OP_JMP: { dojump(pc, GETARG_sBx(i)); break; } case OP_EQ: { if (equalobj(L, RKB(i), RKC(i)) != GETARG_A(i)) pc++; else dojump(pc, GETARG_sBx(*pc) + 1); break; } case OP_LT: { if (luaV_lessthan(L, RKB(i), RKC(i)) != GETARG_A(i)) pc++; else dojump(pc, GETARG_sBx(*pc) + 1); break; } case OP_LE: { if (luaV_lessequal(L, RKB(i), RKC(i)) != GETARG_A(i)) pc++; else dojump(pc, GETARG_sBx(*pc) + 1); break; } case OP_TEST: { TObject *rb = RB(i); if (l_isfalse(rb) == GETARG_C(i)) pc++; else { setobjs2s(ra, rb); dojump(pc, GETARG_sBx(*pc) + 1); } break; } case OP_CALL: case OP_TAILCALL: { StkId firstResult; int b = GETARG_B(i); int nresults; if (b != 0) L->top = ra+b; /* else previous instruction set top */ nresults = GETARG_C(i) - 1; firstResult = luaD_precall(L, ra); if (firstResult) { if (firstResult > L->top) { /* yield? */ lua_assert(L->ci->state == (CI_C | CI_YIELD)); (L->ci - 1)->u.l.savedpc = pc; (L->ci - 1)->state = CI_SAVEDPC; return NULL; } /* it was a C function (`precall' called it); adjust results */ luaD_poscall(L, nresults, firstResult); if (nresults >= 0) L->top = L->ci->top; } else { /* it is a Lua function */ if (GET_OPCODE(i) == OP_CALL) { /* regular call? */ (L->ci-1)->u.l.savedpc = pc; /* save `pc' to return later */ (L->ci-1)->state = (CI_SAVEDPC | CI_CALLING); } else { /* tail call: put new frame in place of previous one */ int aux; base = (L->ci - 1)->base; /* `luaD_precall' may change the stack */ ra = RA(i); if (L->openupval) luaF_close(L, base); for (aux = 0; ra+aux < L->top; aux++) /* move frame down */ setobjs2s(base+aux-1, ra+aux); (L->ci - 1)->top = L->top = base+aux; /* correct top */ lua_assert(L->ci->state & CI_SAVEDPC); (L->ci - 1)->u.l.savedpc = L->ci->u.l.savedpc; (L->ci - 1)->u.l.tailcalls++; /* one more call lost */ (L->ci - 1)->state = CI_SAVEDPC; L->ci--; /* remove new frame */ L->base = L->ci->base; } goto callentry; } break; } case OP_RETURN: { CallInfo *ci = L->ci - 1; /* previous function frame */ int b = GETARG_B(i); if (b != 0) L->top = ra+b-1; lua_assert(L->ci->state & CI_HASFRAME); if (L->openupval) luaF_close(L, base); L->ci->state = CI_SAVEDPC; /* deactivate current function */ L->ci->u.l.savedpc = pc; /* previous function was running `here'? */ if (!(ci->state & CI_CALLING)) { lua_assert((ci->state & CI_C) || ci->u.l.pc != &pc); return ra; /* no: return */ } else { /* yes: continue its execution */ int nresults; lua_assert(ci->u.l.pc == &pc && ttisfunction(ci->base - 1) && (ci->state & CI_SAVEDPC)); lua_assert(GET_OPCODE(*(ci->u.l.savedpc - 1)) == OP_CALL); nresults = GETARG_C(*(ci->u.l.savedpc - 1)) - 1; luaD_poscall(L, nresults, ra); if (nresults >= 0) L->top = L->ci->top; goto retentry; } } case OP_FORLOOP: { lua_Number step, idx, limit; const TObject *plimit = ra+1; const TObject *pstep = ra+2; if (!ttisnumber(ra)) luaG_runerror(L, "`for' initial value must be a number"); if (!tonumber(plimit, ra+1)) luaG_runerror(L, "`for' limit must be a number"); if (!tonumber(pstep, ra+2)) luaG_runerror(L, "`for' step must be a number"); step = nvalue(pstep); idx = nvalue(ra) + step; /* increment index */ limit = nvalue(plimit); if (step > 0 ? idx <= limit : idx >= limit) { dojump(pc, GETARG_sBx(i)); /* jump back */ chgnvalue(ra, idx); /* update index */ } break; } case OP_TFORLOOP: { int nvar = GETARG_C(i) + 1; StkId cb = ra + nvar + 2; /* call base */ setobjs2s(cb, ra); setobjs2s(cb+1, ra+1); setobjs2s(cb+2, ra+2); L->top = cb+3; /* func. + 2 args (state and index) */ luaD_call(L, cb, nvar); L->top = L->ci->top; ra = XRA(i) + 2; /* final position of first result */ cb = ra + nvar; do { /* move results to proper positions */ nvar--; setobjs2s(ra+nvar, cb+nvar); } while (nvar > 0); if (ttisnil(ra)) /* break loop? */ pc++; /* skip jump (break loop) */ else dojump(pc, GETARG_sBx(*pc) + 1); /* jump back */ break; } case OP_TFORPREP: { /* for compatibility only */ if (ttistable(ra)) { setobjs2s(ra+1, ra); setobj2s(ra, luaH_getstr(hvalue(gt(L)), luaS_new(L, "next"))); } dojump(pc, GETARG_sBx(i)); break; } case OP_SETLIST: case OP_SETLISTO: { int bc; int n; Table *h; runtime_check(L, ttistable(ra)); h = hvalue(ra); bc = GETARG_Bx(i); if (GET_OPCODE(i) == OP_SETLIST) n = (bc&(LFIELDS_PER_FLUSH-1)) + 1; else { n = L->top - ra - 1; L->top = L->ci->top; } bc &= ~(LFIELDS_PER_FLUSH-1); /* bc = bc - bc%FPF */ for (; n > 0; n--) setobj2t(luaH_setnum(L, h, bc+n), ra+n); /* write barrier */ break; } case OP_CLOSE: { luaF_close(L, ra); break; } case OP_CLOSURE: { Proto *p; Closure *ncl; int nup, j; p = cl->p->p[GETARG_Bx(i)]; nup = p->nups; ncl = luaF_newLclosure(L, nup, &cl->g); ncl->l.p = p; for (j=0; j<nup; j++, pc++) { if (GET_OPCODE(*pc) == OP_GETUPVAL) ncl->l.upvals[j] = cl->upvals[GETARG_B(*pc)]; else { lua_assert(GET_OPCODE(*pc) == OP_MOVE); ncl->l.upvals[j] = luaF_findupval(L, base + GETARG_B(*pc)); } } setclvalue(ra, ncl); luaC_checkGC(L); break; } } } }