package lua //////////////////////////////////////////////////////// // This file was generated by go-inline. DO NOT EDIT. // //////////////////////////////////////////////////////// import ( "fmt" "math" "strings" ) func mainLoop(L *LState, baseframe *callFrame) { var inst uint32 var cf *callFrame if L.stack.IsEmpty() { return } L.currentFrame = L.stack.Last() if L.currentFrame.Fn.IsG { callGFunction(L, false) return } for { cf = L.currentFrame inst = cf.Fn.Proto.Code[cf.Pc] cf.Pc++ if jumpTable[int(inst>>26)](L, inst, baseframe) == 1 { return } } } func mainLoopWithContext(L *LState, baseframe *callFrame) { var inst uint32 var cf *callFrame if L.stack.IsEmpty() { return } L.currentFrame = L.stack.Last() if L.currentFrame.Fn.IsG { callGFunction(L, false) return } for { cf = L.currentFrame inst = cf.Fn.Proto.Code[cf.Pc] cf.Pc++ select { case <-L.ctx.Done(): L.RaiseError(L.ctx.Err().Error()) return default: if jumpTable[int(inst>>26)](L, inst, baseframe) == 1 { return } } } } // regv is the first target register to copy the return values to. // It can be reg.top, indicating that the copied values are going into new registers, or it can be below reg.top // Indicating that the values should be within the existing registers. // b is the available number of return values + 1. // n is the desired number of return values. // If n more than the available return values then the extra values are set to nil. // When this function returns the top of the registry will be set to regv+n. func copyReturnValues(L *LState, regv, start, n, b int) { // +inline-start if b == 1 { // this section is inlined by go-inline // source function is 'func (rg *registry) FillNil(regm, n int) ' in '_state.go' { rg := L.reg regm := regv newSize := regm + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := 0; i < n; i++ { rg.array[regm+i] = LNil } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regm + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } } else { // this section is inlined by go-inline // source function is 'func (rg *registry) CopyRange(regv, start, limit, n int) ' in '_state.go' { rg := L.reg limit := -1 newSize := regv + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } if limit == -1 || limit > rg.top { limit = rg.top } for i := 0; i < n; i++ { srcIdx := start + i if srcIdx >= limit || srcIdx < 0 { rg.array[regv+i] = LNil } else { rg.array[regv+i] = rg.array[srcIdx] } } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regv + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } if b > 1 && n > (b-1) { // this section is inlined by go-inline // source function is 'func (rg *registry) FillNil(regm, n int) ' in '_state.go' { rg := L.reg regm := regv + b - 1 n := n - (b - 1) newSize := regm + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := 0; i < n; i++ { rg.array[regm+i] = LNil } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regm + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } } } } // +inline-end func switchToParentThread(L *LState, nargs int, haserror bool, kill bool) { parent := L.Parent if parent == nil { L.RaiseError("can not yield from outside of a coroutine") } L.G.CurrentThread = parent L.Parent = nil if !L.wrapped { if haserror { parent.Push(LFalse) } else { parent.Push(LTrue) } } L.XMoveTo(parent, nargs) L.stack.Pop() offset := L.currentFrame.LocalBase - L.currentFrame.ReturnBase L.currentFrame = L.stack.Last() L.reg.SetTop(L.reg.Top() - offset) // remove 'yield' function(including tailcalled functions) if kill { L.kill() } } func callGFunction(L *LState, tailcall bool) bool { frame := L.currentFrame gfnret := frame.Fn.GFunction(L) if tailcall { L.currentFrame = L.RemoveCallerFrame() } if gfnret < 0 { switchToParentThread(L, L.GetTop(), false, false) return true } wantret := frame.NRet if wantret == MultRet { wantret = gfnret } if tailcall && L.Parent != nil && L.stack.Sp() == 1 { switchToParentThread(L, wantret, false, true) return true } // this section is inlined by go-inline // source function is 'func (rg *registry) CopyRange(regv, start, limit, n int) ' in '_state.go' { rg := L.reg regv := frame.ReturnBase start := L.reg.Top() - gfnret limit := -1 n := wantret newSize := regv + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } if limit == -1 || limit > rg.top { limit = rg.top } for i := 0; i < n; i++ { srcIdx := start + i if srcIdx >= limit || srcIdx < 0 { rg.array[regv+i] = LNil } else { rg.array[regv+i] = rg.array[srcIdx] } } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regv + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } L.stack.Pop() L.currentFrame = L.stack.Last() return false } func threadRun(L *LState) { if L.stack.IsEmpty() { return } defer func() { if rcv := recover(); rcv != nil { var lv LValue if v, ok := rcv.(*ApiError); ok { lv = v.Object } else { lv = LString(fmt.Sprint(rcv)) } if parent := L.Parent; parent != nil { if L.wrapped { L.Push(lv) parent.Panic(L) } else { L.SetTop(0) L.Push(lv) switchToParentThread(L, 1, true, true) } } else { panic(rcv) } } }() L.mainLoop(L, nil) } type instFunc func(*LState, uint32, *callFrame) int var jumpTable [opCodeMax + 1]instFunc func init() { jumpTable = [opCodeMax + 1]instFunc{ func(L *LState, inst uint32, baseframe *callFrame) int { //OP_MOVE reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB reg.Set(RA, reg.Get(lbase+B)) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_MOVEN reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC reg.Set(lbase+A, reg.Get(lbase+B)) code := cf.Fn.Proto.Code pc := cf.Pc for i := 0; i < C; i++ { inst = code[pc] pc++ A = int(inst>>18) & 0xff //GETA B = int(inst & 0x1ff) //GETB reg.Set(lbase+A, reg.Get(lbase+B)) } cf.Pc = pc return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_LOADK reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A Bx := int(inst & 0x3ffff) //GETBX reg.Set(RA, cf.Fn.Proto.Constants[Bx]) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_LOADBOOL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC if B != 0 { reg.Set(RA, LTrue) } else { reg.Set(RA, LFalse) } if C != 0 { cf.Pc++ } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_LOADNIL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB for i := RA; i <= lbase+B; i++ { reg.Set(i, LNil) } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_GETUPVAL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB reg.Set(RA, cf.Fn.Upvalues[B].Value()) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_GETGLOBAL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A Bx := int(inst & 0x3ffff) //GETBX //reg.Set(RA, L.getField(cf.Fn.Env, cf.Fn.Proto.Constants[Bx])) reg.Set(RA, L.getFieldString(cf.Fn.Env, cf.Fn.Proto.stringConstants[Bx])) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_GETTABLE reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC reg.Set(RA, L.getField(reg.Get(lbase+B), L.rkValue(C))) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_GETTABLEKS reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC reg.Set(RA, L.getFieldString(reg.Get(lbase+B), L.rkString(C))) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_SETGLOBAL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A Bx := int(inst & 0x3ffff) //GETBX //L.setField(cf.Fn.Env, cf.Fn.Proto.Constants[Bx], reg.Get(RA)) L.setFieldString(cf.Fn.Env, cf.Fn.Proto.stringConstants[Bx], reg.Get(RA)) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_SETUPVAL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB cf.Fn.Upvalues[B].SetValue(reg.Get(RA)) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_SETTABLE reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC L.setField(reg.Get(RA), L.rkValue(B), L.rkValue(C)) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_SETTABLEKS reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC L.setFieldString(reg.Get(RA), L.rkString(B), L.rkValue(C)) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_NEWTABLE reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC reg.Set(RA, newLTable(B, C)) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_SELF reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC selfobj := reg.Get(lbase + B) reg.Set(RA, L.getFieldString(selfobj, L.rkString(C))) reg.Set(RA+1, selfobj) return 0 }, opArith, // OP_ADD opArith, // OP_SUB opArith, // OP_MUL opArith, // OP_DIV opArith, // OP_MOD opArith, // OP_POW func(L *LState, inst uint32, baseframe *callFrame) int { //OP_UNM reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB unaryv := L.rkValue(B) if nm, ok := unaryv.(LNumber); ok { reg.SetNumber(RA, -nm) } else { op := L.metaOp1(unaryv, "__unm") if op.Type() == LTFunction { reg.Push(op) reg.Push(unaryv) L.Call(1, 1) reg.Set(RA, reg.Pop()) } else if str, ok1 := unaryv.(LString); ok1 { if num, err := parseNumber(string(str)); err == nil { reg.Set(RA, -num) } else { L.RaiseError("__unm undefined") } } else { L.RaiseError("__unm undefined") } } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_NOT reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB if LVIsFalse(reg.Get(lbase + B)) { reg.Set(RA, LTrue) } else { reg.Set(RA, LFalse) } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_LEN reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB switch lv := L.rkValue(B).(type) { case LString: reg.SetNumber(RA, LNumber(len(lv))) default: op := L.metaOp1(lv, "__len") if op.Type() == LTFunction { reg.Push(op) reg.Push(lv) L.Call(1, 1) ret := reg.Pop() if ret.Type() == LTNumber { reg.SetNumber(RA, ret.(LNumber)) } else { reg.SetNumber(RA, LNumber(0)) } } else if lv.Type() == LTTable { reg.SetNumber(RA, LNumber(lv.(*LTable).Len())) } else { L.RaiseError("__len undefined") } } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_CONCAT reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC RC := lbase + C RB := lbase + B reg.Set(RA, stringConcat(L, RC-RB+1, RC)) return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_JMP cf := L.currentFrame Sbx := int(inst&0x3ffff) - opMaxArgSbx //GETSBX cf.Pc += Sbx return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_EQ cf := L.currentFrame A := int(inst>>18) & 0xff //GETA B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC ret := equals(L, L.rkValue(B), L.rkValue(C), false) v := 1 if ret { v = 0 } if v == A { cf.Pc++ } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_LT cf := L.currentFrame A := int(inst>>18) & 0xff //GETA B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC ret := lessThan(L, L.rkValue(B), L.rkValue(C)) v := 1 if ret { v = 0 } if v == A { cf.Pc++ } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_LE cf := L.currentFrame A := int(inst>>18) & 0xff //GETA B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC lhs := L.rkValue(B) rhs := L.rkValue(C) ret := false if v1, ok1 := lhs.assertFloat64(); ok1 { if v2, ok2 := rhs.assertFloat64(); ok2 { ret = v1 <= v2 } else { L.RaiseError("attempt to compare %v with %v", lhs.Type().String(), rhs.Type().String()) } } else { if lhs.Type() != rhs.Type() { L.RaiseError("attempt to compare %v with %v", lhs.Type().String(), rhs.Type().String()) } switch lhs.Type() { case LTString: ret = strCmp(string(lhs.(LString)), string(rhs.(LString))) <= 0 default: switch objectRational(L, lhs, rhs, "__le") { case 1: ret = true case 0: ret = false default: ret = !objectRationalWithError(L, rhs, lhs, "__lt") } } } v := 1 if ret { v = 0 } if v == A { cf.Pc++ } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_TEST reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A C := int(inst>>9) & 0x1ff //GETC if LVAsBool(reg.Get(RA)) == (C == 0) { cf.Pc++ } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_TESTSET reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC if value := reg.Get(lbase + B); LVAsBool(value) != (C == 0) { reg.Set(RA, value) } else { cf.Pc++ } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_CALL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC nargs := B - 1 if B == 0 { nargs = reg.Top() - (RA + 1) } lv := reg.Get(RA) nret := C - 1 var callable *LFunction var meta bool if fn, ok := lv.assertFunction(); ok { callable = fn meta = false } else { callable, meta = L.metaCall(lv) } // this section is inlined by go-inline // source function is 'func (ls *LState) pushCallFrame(cf callFrame, fn LValue, meta bool) ' in '_state.go' { ls := L cf := callFrame{Fn: callable, Pc: 0, Base: RA, LocalBase: RA + 1, ReturnBase: RA, NArgs: nargs, NRet: nret, Parent: cf, TailCall: 0} fn := lv if meta { cf.NArgs++ ls.reg.Insert(fn, cf.LocalBase) } if cf.Fn == nil { ls.RaiseError("attempt to call a non-function object") } if ls.stack.IsFull() { ls.RaiseError("stack overflow") } ls.stack.Push(cf) newcf := ls.stack.Last() // this section is inlined by go-inline // source function is 'func (ls *LState) initCallFrame(cf *callFrame) ' in '_state.go' { cf := newcf if cf.Fn.IsG { ls.reg.SetTop(cf.LocalBase + cf.NArgs) } else { proto := cf.Fn.Proto nargs := cf.NArgs np := int(proto.NumParameters) newSize := cf.LocalBase + np // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { rg := ls.reg requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := nargs; i < np; i++ { ls.reg.array[cf.LocalBase+i] = LNil nargs = np } if (proto.IsVarArg & VarArgIsVarArg) == 0 { if nargs < int(proto.NumUsedRegisters) { nargs = int(proto.NumUsedRegisters) } newSize = cf.LocalBase + nargs // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { rg := ls.reg requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := np; i < nargs; i++ { ls.reg.array[cf.LocalBase+i] = LNil } ls.reg.top = cf.LocalBase + int(proto.NumUsedRegisters) } else { /* swap vararg positions: closure namedparam1 <- lbase namedparam2 vararg1 vararg2 TO closure nil nil vararg1 vararg2 namedparam1 <- lbase namedparam2 */ nvarargs := nargs - np if nvarargs < 0 { nvarargs = 0 } ls.reg.SetTop(cf.LocalBase + nargs + np) for i := 0; i < np; i++ { //ls.reg.Set(cf.LocalBase+nargs+i, ls.reg.Get(cf.LocalBase+i)) ls.reg.array[cf.LocalBase+nargs+i] = ls.reg.array[cf.LocalBase+i] //ls.reg.Set(cf.LocalBase+i, LNil) ls.reg.array[cf.LocalBase+i] = LNil } if CompatVarArg { ls.reg.SetTop(cf.LocalBase + nargs + np + 1) if (proto.IsVarArg & VarArgNeedsArg) != 0 { argtb := newLTable(nvarargs, 0) for i := 0; i < nvarargs; i++ { argtb.RawSetInt(i+1, ls.reg.Get(cf.LocalBase+np+i)) } argtb.RawSetString("n", LNumber(nvarargs)) //ls.reg.Set(cf.LocalBase+nargs+np, argtb) ls.reg.array[cf.LocalBase+nargs+np] = argtb } else { ls.reg.array[cf.LocalBase+nargs+np] = LNil } } cf.LocalBase += nargs maxreg := cf.LocalBase + int(proto.NumUsedRegisters) ls.reg.SetTop(maxreg) } } } ls.currentFrame = newcf } if callable.IsG && callGFunction(L, false) { return 1 } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_TAILCALL reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB nargs := B - 1 if B == 0 { nargs = reg.Top() - (RA + 1) } lv := reg.Get(RA) var callable *LFunction var meta bool if fn, ok := lv.assertFunction(); ok { callable = fn meta = false } else { callable, meta = L.metaCall(lv) } if callable == nil { L.RaiseError("attempt to call a non-function object") } // this section is inlined by go-inline // source function is 'func (ls *LState) closeUpvalues(idx int) ' in '_state.go' { ls := L idx := lbase if ls.uvcache != nil { var prev *Upvalue for uv := ls.uvcache; uv != nil; uv = uv.next { if uv.index >= idx { if prev != nil { prev.next = nil } else { ls.uvcache = nil } uv.Close() } prev = uv } } } if callable.IsG { luaframe := cf L.pushCallFrame(callFrame{ Fn: callable, Pc: 0, Base: RA, LocalBase: RA + 1, ReturnBase: cf.ReturnBase, NArgs: nargs, NRet: cf.NRet, Parent: cf, TailCall: 0, }, lv, meta) if callGFunction(L, true) { return 1 } if L.currentFrame == nil || L.currentFrame.Fn.IsG || luaframe == baseframe { return 1 } } else { base := cf.Base cf.Fn = callable cf.Pc = 0 cf.Base = RA cf.LocalBase = RA + 1 cf.ReturnBase = cf.ReturnBase cf.NArgs = nargs cf.NRet = cf.NRet cf.TailCall++ lbase := cf.LocalBase if meta { cf.NArgs++ L.reg.Insert(lv, cf.LocalBase) } // this section is inlined by go-inline // source function is 'func (ls *LState) initCallFrame(cf *callFrame) ' in '_state.go' { ls := L if cf.Fn.IsG { ls.reg.SetTop(cf.LocalBase + cf.NArgs) } else { proto := cf.Fn.Proto nargs := cf.NArgs np := int(proto.NumParameters) newSize := cf.LocalBase + np // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { rg := ls.reg requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := nargs; i < np; i++ { ls.reg.array[cf.LocalBase+i] = LNil nargs = np } if (proto.IsVarArg & VarArgIsVarArg) == 0 { if nargs < int(proto.NumUsedRegisters) { nargs = int(proto.NumUsedRegisters) } newSize = cf.LocalBase + nargs // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { rg := ls.reg requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := np; i < nargs; i++ { ls.reg.array[cf.LocalBase+i] = LNil } ls.reg.top = cf.LocalBase + int(proto.NumUsedRegisters) } else { /* swap vararg positions: closure namedparam1 <- lbase namedparam2 vararg1 vararg2 TO closure nil nil vararg1 vararg2 namedparam1 <- lbase namedparam2 */ nvarargs := nargs - np if nvarargs < 0 { nvarargs = 0 } ls.reg.SetTop(cf.LocalBase + nargs + np) for i := 0; i < np; i++ { //ls.reg.Set(cf.LocalBase+nargs+i, ls.reg.Get(cf.LocalBase+i)) ls.reg.array[cf.LocalBase+nargs+i] = ls.reg.array[cf.LocalBase+i] //ls.reg.Set(cf.LocalBase+i, LNil) ls.reg.array[cf.LocalBase+i] = LNil } if CompatVarArg { ls.reg.SetTop(cf.LocalBase + nargs + np + 1) if (proto.IsVarArg & VarArgNeedsArg) != 0 { argtb := newLTable(nvarargs, 0) for i := 0; i < nvarargs; i++ { argtb.RawSetInt(i+1, ls.reg.Get(cf.LocalBase+np+i)) } argtb.RawSetString("n", LNumber(nvarargs)) //ls.reg.Set(cf.LocalBase+nargs+np, argtb) ls.reg.array[cf.LocalBase+nargs+np] = argtb } else { ls.reg.array[cf.LocalBase+nargs+np] = LNil } } cf.LocalBase += nargs maxreg := cf.LocalBase + int(proto.NumUsedRegisters) ls.reg.SetTop(maxreg) } } } // this section is inlined by go-inline // source function is 'func (rg *registry) CopyRange(regv, start, limit, n int) ' in '_state.go' { rg := L.reg regv := base start := RA limit := -1 n := reg.Top() - RA - 1 newSize := regv + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } if limit == -1 || limit > rg.top { limit = rg.top } for i := 0; i < n; i++ { srcIdx := start + i if srcIdx >= limit || srcIdx < 0 { rg.array[regv+i] = LNil } else { rg.array[regv+i] = rg.array[srcIdx] } } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regv + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } cf.Base = base cf.LocalBase = base + (cf.LocalBase - lbase + 1) } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_RETURN reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB // this section is inlined by go-inline // source function is 'func (ls *LState) closeUpvalues(idx int) ' in '_state.go' { ls := L idx := lbase if ls.uvcache != nil { var prev *Upvalue for uv := ls.uvcache; uv != nil; uv = uv.next { if uv.index >= idx { if prev != nil { prev.next = nil } else { ls.uvcache = nil } uv.Close() } prev = uv } } } nret := B - 1 if B == 0 { nret = reg.Top() - RA } n := cf.NRet if cf.NRet == MultRet { n = nret } if L.Parent != nil && L.stack.Sp() == 1 { // this section is inlined by go-inline // source function is 'func copyReturnValues(L *LState, regv, start, n, b int) ' in '_vm.go' { regv := reg.Top() start := RA b := B if b == 1 { // this section is inlined by go-inline // source function is 'func (rg *registry) FillNil(regm, n int) ' in '_state.go' { rg := L.reg regm := regv newSize := regm + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := 0; i < n; i++ { rg.array[regm+i] = LNil } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regm + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } } else { // this section is inlined by go-inline // source function is 'func (rg *registry) CopyRange(regv, start, limit, n int) ' in '_state.go' { rg := L.reg limit := -1 newSize := regv + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } if limit == -1 || limit > rg.top { limit = rg.top } for i := 0; i < n; i++ { srcIdx := start + i if srcIdx >= limit || srcIdx < 0 { rg.array[regv+i] = LNil } else { rg.array[regv+i] = rg.array[srcIdx] } } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regv + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } if b > 1 && n > (b-1) { // this section is inlined by go-inline // source function is 'func (rg *registry) FillNil(regm, n int) ' in '_state.go' { rg := L.reg regm := regv + b - 1 n := n - (b - 1) newSize := regm + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := 0; i < n; i++ { rg.array[regm+i] = LNil } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regm + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } } } } switchToParentThread(L, n, false, true) return 1 } islast := baseframe == L.stack.Pop() || L.stack.IsEmpty() // this section is inlined by go-inline // source function is 'func copyReturnValues(L *LState, regv, start, n, b int) ' in '_vm.go' { regv := cf.ReturnBase start := RA b := B if b == 1 { // this section is inlined by go-inline // source function is 'func (rg *registry) FillNil(regm, n int) ' in '_state.go' { rg := L.reg regm := regv newSize := regm + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := 0; i < n; i++ { rg.array[regm+i] = LNil } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regm + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } } else { // this section is inlined by go-inline // source function is 'func (rg *registry) CopyRange(regv, start, limit, n int) ' in '_state.go' { rg := L.reg limit := -1 newSize := regv + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } if limit == -1 || limit > rg.top { limit = rg.top } for i := 0; i < n; i++ { srcIdx := start + i if srcIdx >= limit || srcIdx < 0 { rg.array[regv+i] = LNil } else { rg.array[regv+i] = rg.array[srcIdx] } } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regv + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } if b > 1 && n > (b-1) { // this section is inlined by go-inline // source function is 'func (rg *registry) FillNil(regm, n int) ' in '_state.go' { rg := L.reg regm := regv + b - 1 n := n - (b - 1) newSize := regm + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } for i := 0; i < n; i++ { rg.array[regm+i] = LNil } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regm + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } } } } L.currentFrame = L.stack.Last() if islast || L.currentFrame == nil || L.currentFrame.Fn.IsG { return 1 } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_FORLOOP reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A if init, ok1 := reg.Get(RA).assertFloat64(); ok1 { if limit, ok2 := reg.Get(RA + 1).assertFloat64(); ok2 { if step, ok3 := reg.Get(RA + 2).assertFloat64(); ok3 { init += step reg.SetNumber(RA, LNumber(init)) if (step > 0 && init <= limit) || (step <= 0 && init >= limit) { Sbx := int(inst&0x3ffff) - opMaxArgSbx //GETSBX cf.Pc += Sbx reg.SetNumber(RA+3, LNumber(init)) } else { reg.SetTop(RA + 1) } } else { L.RaiseError("for statement step must be a number") } } else { L.RaiseError("for statement limit must be a number") } } else { L.RaiseError("for statement init must be a number") } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_FORPREP reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A Sbx := int(inst&0x3ffff) - opMaxArgSbx //GETSBX if init, ok1 := reg.Get(RA).assertFloat64(); ok1 { if step, ok2 := reg.Get(RA + 2).assertFloat64(); ok2 { reg.SetNumber(RA, LNumber(init-step)) } else { L.RaiseError("for statement step must be a number") } } else { L.RaiseError("for statement init must be a number") } cf.Pc += Sbx return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_TFORLOOP reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A C := int(inst>>9) & 0x1ff //GETC nret := C reg.SetTop(RA + 3 + 2) reg.Set(RA+3+2, reg.Get(RA+2)) reg.Set(RA+3+1, reg.Get(RA+1)) reg.Set(RA+3, reg.Get(RA)) L.callR(2, nret, RA+3) if value := reg.Get(RA + 3); value != LNil { reg.Set(RA+2, value) pc := cf.Fn.Proto.Code[cf.Pc] cf.Pc += int(pc&0x3ffff) - opMaxArgSbx } cf.Pc++ return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_SETLIST reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC if C == 0 { C = int(cf.Fn.Proto.Code[cf.Pc]) cf.Pc++ } offset := (C - 1) * FieldsPerFlush table := reg.Get(RA).(*LTable) nelem := B if B == 0 { nelem = reg.Top() - RA - 1 } for i := 1; i <= nelem; i++ { table.RawSetInt(offset+i, reg.Get(RA+i)) } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_CLOSE cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A // this section is inlined by go-inline // source function is 'func (ls *LState) closeUpvalues(idx int) ' in '_state.go' { ls := L idx := RA if ls.uvcache != nil { var prev *Upvalue for uv := ls.uvcache; uv != nil; uv = uv.next { if uv.index >= idx { if prev != nil { prev.next = nil } else { ls.uvcache = nil } uv.Close() } prev = uv } } } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_CLOSURE reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A Bx := int(inst & 0x3ffff) //GETBX proto := cf.Fn.Proto.FunctionPrototypes[Bx] closure := newLFunctionL(proto, cf.Fn.Env, int(proto.NumUpvalues)) reg.Set(RA, closure) for i := 0; i < int(proto.NumUpvalues); i++ { inst = cf.Fn.Proto.Code[cf.Pc] cf.Pc++ B := opGetArgB(inst) switch opGetOpCode(inst) { case OP_MOVE: closure.Upvalues[i] = L.findUpvalue(lbase + B) case OP_GETUPVAL: closure.Upvalues[i] = cf.Fn.Upvalues[B] } } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_VARARG reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A B := int(inst & 0x1ff) //GETB nparams := int(cf.Fn.Proto.NumParameters) nvarargs := cf.NArgs - nparams if nvarargs < 0 { nvarargs = 0 } nwant := B - 1 if B == 0 { nwant = nvarargs } // this section is inlined by go-inline // source function is 'func (rg *registry) CopyRange(regv, start, limit, n int) ' in '_state.go' { rg := reg regv := RA start := cf.Base + nparams + 1 limit := cf.LocalBase n := nwant newSize := regv + n // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := newSize if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } if limit == -1 || limit > rg.top { limit = rg.top } for i := 0; i < n; i++ { srcIdx := start + i if srcIdx >= limit || srcIdx < 0 { rg.array[regv+i] = LNil } else { rg.array[regv+i] = rg.array[srcIdx] } } // values beyond top don't need to be valid LValues, so setting them to nil is fine // setting them to nil rather than LNil lets us invoke the golang memclr opto oldtop := rg.top rg.top = regv + n if rg.top < oldtop { nilRange := rg.array[rg.top:oldtop] for i := range nilRange { nilRange[i] = nil } } } return 0 }, func(L *LState, inst uint32, baseframe *callFrame) int { //OP_NOP return 0 }, } } func opArith(L *LState, inst uint32, baseframe *callFrame) int { //OP_ADD, OP_SUB, OP_MUL, OP_DIV, OP_MOD, OP_POW reg := L.reg cf := L.currentFrame lbase := cf.LocalBase A := int(inst>>18) & 0xff //GETA RA := lbase + A opcode := int(inst >> 26) //GETOPCODE B := int(inst & 0x1ff) //GETB C := int(inst>>9) & 0x1ff //GETC lhs := L.rkValue(B) rhs := L.rkValue(C) v1, ok1 := lhs.assertFloat64() v2, ok2 := rhs.assertFloat64() if ok1 && ok2 { reg.SetNumber(RA, numberArith(L, opcode, LNumber(v1), LNumber(v2))) } else { reg.Set(RA, objectArith(L, opcode, lhs, rhs)) } return 0 } func luaModulo(lhs, rhs LNumber) LNumber { flhs := float64(lhs) frhs := float64(rhs) v := math.Mod(flhs, frhs) if flhs < 0 || frhs < 0 && !(flhs < 0 && frhs < 0) { v += frhs } return LNumber(v) } func numberArith(L *LState, opcode int, lhs, rhs LNumber) LNumber { switch opcode { case OP_ADD: return lhs + rhs case OP_SUB: return lhs - rhs case OP_MUL: return lhs * rhs case OP_DIV: return lhs / rhs case OP_MOD: return luaModulo(lhs, rhs) case OP_POW: flhs := float64(lhs) frhs := float64(rhs) return LNumber(math.Pow(flhs, frhs)) } panic("should not reach here") return LNumber(0) } func objectArith(L *LState, opcode int, lhs, rhs LValue) LValue { event := "" switch opcode { case OP_ADD: event = "__add" case OP_SUB: event = "__sub" case OP_MUL: event = "__mul" case OP_DIV: event = "__div" case OP_MOD: event = "__mod" case OP_POW: event = "__pow" } op := L.metaOp2(lhs, rhs, event) if op.Type() == LTFunction { L.reg.Push(op) L.reg.Push(lhs) L.reg.Push(rhs) L.Call(2, 1) return L.reg.Pop() } if str, ok := lhs.(LString); ok { if lnum, err := parseNumber(string(str)); err == nil { lhs = lnum } } if str, ok := rhs.(LString); ok { if rnum, err := parseNumber(string(str)); err == nil { rhs = rnum } } if v1, ok1 := lhs.assertFloat64(); ok1 { if v2, ok2 := rhs.assertFloat64(); ok2 { return numberArith(L, opcode, LNumber(v1), LNumber(v2)) } } L.RaiseError(fmt.Sprintf("cannot perform %v operation between %v and %v", strings.TrimLeft(event, "_"), lhs.Type().String(), rhs.Type().String())) return LNil } func stringConcat(L *LState, total, last int) LValue { rhs := L.reg.Get(last) total-- for i := last - 1; total > 0; { lhs := L.reg.Get(i) if !(LVCanConvToString(lhs) && LVCanConvToString(rhs)) { op := L.metaOp2(lhs, rhs, "__concat") if op.Type() == LTFunction { L.reg.Push(op) L.reg.Push(lhs) L.reg.Push(rhs) L.Call(2, 1) rhs = L.reg.Pop() total-- i-- } else { L.RaiseError("cannot perform concat operation between %v and %v", lhs.Type().String(), rhs.Type().String()) return LNil } } else { buf := make([]string, total+1) buf[total] = LVAsString(rhs) for total > 0 { lhs = L.reg.Get(i) if !LVCanConvToString(lhs) { break } buf[total-1] = LVAsString(lhs) i-- total-- } rhs = LString(strings.Join(buf, "")) } } return rhs } func lessThan(L *LState, lhs, rhs LValue) bool { // optimization for numbers if v1, ok1 := lhs.assertFloat64(); ok1 { if v2, ok2 := rhs.assertFloat64(); ok2 { return v1 < v2 } L.RaiseError("attempt to compare %v with %v", lhs.Type().String(), rhs.Type().String()) } if lhs.Type() != rhs.Type() { L.RaiseError("attempt to compare %v with %v", lhs.Type().String(), rhs.Type().String()) return false } ret := false switch lhs.Type() { case LTString: ret = strCmp(string(lhs.(LString)), string(rhs.(LString))) < 0 default: ret = objectRationalWithError(L, lhs, rhs, "__lt") } return ret } func equals(L *LState, lhs, rhs LValue, raw bool) bool { if lhs.Type() != rhs.Type() { return false } ret := false switch lhs.Type() { case LTNil: ret = true case LTNumber: v1, _ := lhs.assertFloat64() v2, _ := rhs.assertFloat64() ret = v1 == v2 case LTBool: ret = bool(lhs.(LBool)) == bool(rhs.(LBool)) case LTString: ret = string(lhs.(LString)) == string(rhs.(LString)) case LTUserData, LTTable: if lhs == rhs { ret = true } else if !raw { switch objectRational(L, lhs, rhs, "__eq") { case 1: ret = true default: ret = false } } default: ret = lhs == rhs } return ret } func objectRationalWithError(L *LState, lhs, rhs LValue, event string) bool { switch objectRational(L, lhs, rhs, event) { case 1: return true case 0: return false } L.RaiseError("attempt to compare %v with %v", lhs.Type().String(), rhs.Type().String()) return false } func objectRational(L *LState, lhs, rhs LValue, event string) int { m1 := L.metaOp1(lhs, event) m2 := L.metaOp1(rhs, event) if m1.Type() == LTFunction && m1 == m2 { L.reg.Push(m1) L.reg.Push(lhs) L.reg.Push(rhs) L.Call(2, 1) if LVAsBool(L.reg.Pop()) { return 1 } return 0 } return -1 }