package lua //////////////////////////////////////////////////////// // This file was generated by go-inline. DO NOT EDIT. // //////////////////////////////////////////////////////// import ( "context" "fmt" "io" "math" "os" "runtime" "strings" "sync" "sync/atomic" "time" "github.com/yuin/gopher-lua/parse" ) const MultRet = -1 const RegistryIndex = -10000 const EnvironIndex = -10001 const GlobalsIndex = -10002 /* ApiError {{{ */ type ApiError struct { Type ApiErrorType Object LValue StackTrace string // Underlying error. This attribute is set only if the Type is ApiErrorFile or ApiErrorSyntax Cause error } func newApiError(code ApiErrorType, object LValue) *ApiError { return &ApiError{code, object, "", nil} } func newApiErrorS(code ApiErrorType, message string) *ApiError { return newApiError(code, LString(message)) } func newApiErrorE(code ApiErrorType, err error) *ApiError { return &ApiError{code, LString(err.Error()), "", err} } func (e *ApiError) Error() string { if len(e.StackTrace) > 0 { return fmt.Sprintf("%s\n%s", e.Object.String(), e.StackTrace) } return e.Object.String() } type ApiErrorType int const ( ApiErrorSyntax ApiErrorType = iota ApiErrorFile ApiErrorRun ApiErrorError ApiErrorPanic ) /* }}} */ /* ResumeState {{{ */ type ResumeState int const ( ResumeOK ResumeState = iota ResumeYield ResumeError ) /* }}} */ /* P {{{ */ type P struct { Fn LValue NRet int Protect bool Handler *LFunction } /* }}} */ /* Options {{{ */ // Options is a configuration that is used to create a new LState. type Options struct { // Call stack size. This defaults to `lua.CallStackSize`. CallStackSize int // Data stack size. This defaults to `lua.RegistrySize`. RegistrySize int // Allow the registry to grow from the registry size specified up to a value of RegistryMaxSize. A value of 0 // indicates no growth is permitted. The registry will not shrink again after any growth. RegistryMaxSize int // If growth is enabled, step up by an additional `RegistryGrowStep` each time to avoid having to resize too often. // This defaults to `lua.RegistryGrowStep` RegistryGrowStep int // Controls whether or not libraries are opened by default SkipOpenLibs bool // Tells whether a Go stacktrace should be included in a Lua stacktrace when panics occur. IncludeGoStackTrace bool // If `MinimizeStackMemory` is set, the call stack will be automatically grown or shrank up to a limit of // `CallStackSize` in order to minimize memory usage. This does incur a slight performance penalty. MinimizeStackMemory bool } /* }}} */ /* Debug {{{ */ type Debug struct { frame *callFrame Name string What string Source string CurrentLine int NUpvalues int LineDefined int LastLineDefined int } /* }}} */ /* callFrame {{{ */ type callFrame struct { Idx int Fn *LFunction Parent *callFrame Pc int Base int LocalBase int ReturnBase int NArgs int NRet int TailCall int } type callFrameStack interface { Push(v callFrame) Pop() *callFrame Last() *callFrame SetSp(sp int) Sp() int At(sp int) *callFrame IsFull() bool IsEmpty() bool FreeAll() } type fixedCallFrameStack struct { array []callFrame sp int } func newFixedCallFrameStack(size int) callFrameStack { return &fixedCallFrameStack{ array: make([]callFrame, size), sp: 0, } } func (cs *fixedCallFrameStack) IsEmpty() bool { return cs.sp == 0 } func (cs *fixedCallFrameStack) IsFull() bool { return cs.sp == len(cs.array) } func (cs *fixedCallFrameStack) Clear() { cs.sp = 0 } func (cs *fixedCallFrameStack) Push(v callFrame) { cs.array[cs.sp] = v cs.array[cs.sp].Idx = cs.sp cs.sp++ } func (cs *fixedCallFrameStack) Sp() int { return cs.sp } func (cs *fixedCallFrameStack) SetSp(sp int) { cs.sp = sp } func (cs *fixedCallFrameStack) Last() *callFrame { if cs.sp == 0 { return nil } return &cs.array[cs.sp-1] } func (cs *fixedCallFrameStack) At(sp int) *callFrame { return &cs.array[sp] } func (cs *fixedCallFrameStack) Pop() *callFrame { cs.sp-- return &cs.array[cs.sp] } func (cs *fixedCallFrameStack) FreeAll() { // nothing to do for fixed callframestack } // FramesPerSegment should be a power of 2 constant for performance reasons. It will allow the go compiler to change // the divs and mods into bitshifts. Max is 256 due to current use of uint8 to count how many frames in a segment are // used. const FramesPerSegment = 8 type callFrameStackSegment struct { array [FramesPerSegment]callFrame } type segIdx uint16 type autoGrowingCallFrameStack struct { segments []*callFrameStackSegment segIdx segIdx // segSp is the number of frames in the current segment which are used. Full 'sp' value is segIdx * FramesPerSegment + segSp. // It points to the next stack slot to use, so 0 means to use the 0th element in the segment, and a value of // FramesPerSegment indicates that the segment is full and cannot accommodate another frame. segSp uint8 } var segmentPool sync.Pool func newCallFrameStackSegment() *callFrameStackSegment { seg := segmentPool.Get() if seg == nil { return &callFrameStackSegment{} } return seg.(*callFrameStackSegment) } func freeCallFrameStackSegment(seg *callFrameStackSegment) { segmentPool.Put(seg) } // newCallFrameStack allocates a new stack for a lua state, which will auto grow up to a max size of at least maxSize. // it will actually grow up to the next segment size multiple after maxSize, where the segment size is dictated by // FramesPerSegment. func newAutoGrowingCallFrameStack(maxSize int) callFrameStack { cs := &autoGrowingCallFrameStack{ segments: make([]*callFrameStackSegment, (maxSize+(FramesPerSegment-1))/FramesPerSegment), segIdx: 0, } cs.segments[0] = newCallFrameStackSegment() return cs } func (cs *autoGrowingCallFrameStack) IsEmpty() bool { return cs.segIdx == 0 && cs.segSp == 0 } // IsFull returns true if the stack cannot receive any more stack pushes without overflowing func (cs *autoGrowingCallFrameStack) IsFull() bool { return int(cs.segIdx) == len(cs.segments) && cs.segSp >= FramesPerSegment } func (cs *autoGrowingCallFrameStack) Clear() { for i := segIdx(1); i <= cs.segIdx; i++ { freeCallFrameStackSegment(cs.segments[i]) cs.segments[i] = nil } cs.segIdx = 0 cs.segSp = 0 } func (cs *autoGrowingCallFrameStack) FreeAll() { for i := segIdx(0); i <= cs.segIdx; i++ { freeCallFrameStackSegment(cs.segments[i]) cs.segments[i] = nil } } // Push pushes the passed callFrame onto the stack. it panics if the stack is full, caller should call IsFull() before // invoking this to avoid this. func (cs *autoGrowingCallFrameStack) Push(v callFrame) { curSeg := cs.segments[cs.segIdx] if cs.segSp >= FramesPerSegment { // segment full, push new segment if allowed if cs.segIdx < segIdx(len(cs.segments)-1) { curSeg = newCallFrameStackSegment() cs.segIdx++ cs.segments[cs.segIdx] = curSeg cs.segSp = 0 } else { panic("lua callstack overflow") } } curSeg.array[cs.segSp] = v curSeg.array[cs.segSp].Idx = int(cs.segSp) + FramesPerSegment*int(cs.segIdx) cs.segSp++ } // Sp retrieves the current stack depth, which is the number of frames currently pushed on the stack. func (cs *autoGrowingCallFrameStack) Sp() int { return int(cs.segSp) + int(cs.segIdx)*FramesPerSegment } // SetSp can be used to rapidly unwind the stack, freeing all stack frames on the way. It should not be used to // allocate new stack space, use Push() for that. func (cs *autoGrowingCallFrameStack) SetSp(sp int) { desiredSegIdx := segIdx(sp / FramesPerSegment) desiredFramesInLastSeg := uint8(sp % FramesPerSegment) for { if cs.segIdx <= desiredSegIdx { break } freeCallFrameStackSegment(cs.segments[cs.segIdx]) cs.segments[cs.segIdx] = nil cs.segIdx-- } cs.segSp = desiredFramesInLastSeg } func (cs *autoGrowingCallFrameStack) Last() *callFrame { curSeg := cs.segments[cs.segIdx] segSp := cs.segSp if segSp == 0 { if cs.segIdx == 0 { return nil } curSeg = cs.segments[cs.segIdx-1] segSp = FramesPerSegment } return &curSeg.array[segSp-1] } func (cs *autoGrowingCallFrameStack) At(sp int) *callFrame { segIdx := segIdx(sp / FramesPerSegment) frameIdx := uint8(sp % FramesPerSegment) return &cs.segments[segIdx].array[frameIdx] } // Pop pops off the most recent stack frame and returns it func (cs *autoGrowingCallFrameStack) Pop() *callFrame { curSeg := cs.segments[cs.segIdx] if cs.segSp == 0 { if cs.segIdx == 0 { // stack empty return nil } freeCallFrameStackSegment(curSeg) cs.segments[cs.segIdx] = nil cs.segIdx-- cs.segSp = FramesPerSegment curSeg = cs.segments[cs.segIdx] } cs.segSp-- return &curSeg.array[cs.segSp] } /* }}} */ /* registry {{{ */ type registryHandler interface { registryOverflow() } type registry struct { array []LValue top int growBy int maxSize int alloc *allocator handler registryHandler } func newRegistry(handler registryHandler, initialSize int, growBy int, maxSize int, alloc *allocator) *registry { return ®istry{make([]LValue, initialSize), 0, growBy, maxSize, alloc, handler} } func (rg *registry) checkSize(requiredSize int) { // +inline-start if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } // +inline-end func (rg *registry) resize(requiredSize int) { // +inline-start newSize := requiredSize + rg.growBy // give some padding if newSize > rg.maxSize { newSize = rg.maxSize } if newSize < requiredSize { rg.handler.registryOverflow() return } rg.forceResize(newSize) } // +inline-end func (rg *registry) forceResize(newSize int) { newSlice := make([]LValue, newSize) copy(newSlice, rg.array[:rg.top]) // should we copy the area beyond top? there shouldn't be any valid values there so it shouldn't be necessary. rg.array = newSlice } func (rg *registry) SetTop(topi int) { // +inline-start // this section is inlined by go-inline // source function is 'func (rg *registry) checkSize(requiredSize int) ' in '_state.go' { requiredSize := topi if requiredSize > cap(rg.array) { rg.resize(requiredSize) } } oldtopi := rg.top rg.top = topi for i := oldtopi; i < rg.top; i++ { rg.array[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 if rg.top < oldtopi { nilRange := rg.array[rg.top:oldtopi] for i := range nilRange { nilRange[i] = nil } } //for i := rg.top; i < oldtop; i++ { // rg.array[i] = LNil //} } // +inline-end func (rg *registry) Top() int { return rg.top } func (rg *registry) Push(v LValue) { newSize := rg.top + 1 // 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) } } rg.array[rg.top] = v rg.top++ } func (rg *registry) Pop() LValue { v := rg.array[rg.top-1] rg.array[rg.top-1] = LNil rg.top-- return v } func (rg *registry) Get(reg int) LValue { return rg.array[reg] } // CopyRange will move a section of values from index `start` to index `regv` // It will move `n` values. // `limit` specifies the maximum end range that can be copied from. If it's set to -1, then it defaults to stopping at // the top of the registry (values beyond the top are not initialized, so if specifying an alternative `limit` you should // pass a value <= rg.top. // If start+n is beyond the limit, then nil values will be copied to the destination slots. // After the copy, the registry is truncated to be at the end of the copied range, ie the original of the copied values // are nilled out. (So top will be regv+n) // CopyRange should ideally be renamed to MoveRange. func (rg *registry) CopyRange(regv, start, limit, n int) { // +inline-start 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 } } } // +inline-end // FillNil fills the registry with nil values from regm to regm+n and then sets the registry top to regm+n func (rg *registry) FillNil(regm, n int) { // +inline-start 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 (rg *registry) Insert(value LValue, reg int) { top := rg.Top() if reg >= top { // this section is inlined by go-inline // source function is 'func (rg *registry) Set(regi int, vali LValue) ' in '_state.go' { regi := reg vali := value newSize := regi + 1 // 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) } } rg.array[regi] = vali if regi >= rg.top { rg.top = regi + 1 } } return } top-- for ; top >= reg; top-- { // FIXME consider using copy() here if Insert() is called enough // this section is inlined by go-inline // source function is 'func (rg *registry) Set(regi int, vali LValue) ' in '_state.go' { regi := top + 1 vali := rg.Get(top) newSize := regi + 1 // 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) } } rg.array[regi] = vali if regi >= rg.top { rg.top = regi + 1 } } } // this section is inlined by go-inline // source function is 'func (rg *registry) Set(regi int, vali LValue) ' in '_state.go' { regi := reg vali := value newSize := regi + 1 // 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) } } rg.array[regi] = vali if regi >= rg.top { rg.top = regi + 1 } } } func (rg *registry) Set(regi int, vali LValue) { // +inline-start newSize := regi + 1 // 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) } } rg.array[regi] = vali if regi >= rg.top { rg.top = regi + 1 } } // +inline-end func (rg *registry) SetNumber(regi int, vali LNumber) { // +inline-start newSize := regi + 1 // 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) } } rg.array[regi] = rg.alloc.LNumber2I(vali) if regi >= rg.top { rg.top = regi + 1 } } // +inline-end func (rg *registry) IsFull() bool { return rg.top >= cap(rg.array) } /* }}} */ /* Global {{{ */ func newGlobal() *Global { return &Global{ MainThread: nil, Registry: newLTable(0, 32), Global: newLTable(0, 64), builtinMts: make(map[int]LValue), tempFiles: make([]*os.File, 0, 10), } } /* }}} */ /* package local methods {{{ */ func panicWithTraceback(L *LState) { err := newApiError(ApiErrorRun, L.Get(-1)) err.StackTrace = L.stackTrace(0) panic(err) } func panicWithoutTraceback(L *LState) { err := newApiError(ApiErrorRun, L.Get(-1)) panic(err) } func newLState(options Options) *LState { al := newAllocator(32) ls := &LState{ G: newGlobal(), Parent: nil, Panic: panicWithTraceback, Dead: false, Options: options, stop: 0, alloc: al, currentFrame: nil, wrapped: false, uvcache: nil, hasErrorFunc: false, mainLoop: mainLoop, ctx: nil, } if options.MinimizeStackMemory { ls.stack = newAutoGrowingCallFrameStack(options.CallStackSize) } else { ls.stack = newFixedCallFrameStack(options.CallStackSize) } ls.reg = newRegistry(ls, options.RegistrySize, options.RegistryGrowStep, options.RegistryMaxSize, al) ls.Env = ls.G.Global return ls } func (ls *LState) printReg() { println("-------------------------") println("thread:", ls) println("top:", ls.reg.Top()) if ls.currentFrame != nil { println("function base:", ls.currentFrame.Base) println("return base:", ls.currentFrame.ReturnBase) } else { println("(vm not started)") } println("local base:", ls.currentLocalBase()) for i := 0; i < ls.reg.Top(); i++ { println(i, ls.reg.Get(i).String()) } println("-------------------------") } func (ls *LState) printCallStack() { println("-------------------------") for i := 0; i < ls.stack.Sp(); i++ { print(i) print(" ") frame := ls.stack.At(i) if frame == nil { break } if frame.Fn.IsG { println("IsG:", true, "Frame:", frame, "Fn:", frame.Fn) } else { println("IsG:", false, "Frame:", frame, "Fn:", frame.Fn, "pc:", frame.Pc) } } println("-------------------------") } func (ls *LState) closeAllUpvalues() { // +inline-start for cf := ls.currentFrame; cf != nil; cf = cf.Parent { if !cf.Fn.IsG { ls.closeUpvalues(cf.LocalBase) } } } // +inline-end func (ls *LState) raiseError(level int, format string, args ...interface{}) { if !ls.hasErrorFunc { ls.closeAllUpvalues() } message := format if len(args) > 0 { message = fmt.Sprintf(format, args...) } if level > 0 { message = fmt.Sprintf("%v %v", ls.where(level-1, true), message) } if ls.reg.IsFull() { // if the registry is full then it won't be possible to push a value, in this case, force a larger size ls.reg.forceResize(ls.reg.Top() + 1) } ls.reg.Push(LString(message)) ls.Panic(ls) } func (ls *LState) findLocal(frame *callFrame, no int) string { fn := frame.Fn if !fn.IsG { if name, ok := fn.LocalName(no, frame.Pc-1); ok { return name } } var top int if ls.currentFrame == frame { top = ls.reg.Top() } else if frame.Idx+1 < ls.stack.Sp() { top = ls.stack.At(frame.Idx + 1).Base } else { return "" } if top-frame.LocalBase >= no { return "(*temporary)" } return "" } func (ls *LState) where(level int, skipg bool) string { dbg, ok := ls.GetStack(level) if !ok { return "" } cf := dbg.frame proto := cf.Fn.Proto sourcename := "[G]" if proto != nil { sourcename = proto.SourceName } else if skipg { return ls.where(level+1, skipg) } line := "" if proto != nil { line = fmt.Sprintf("%v:", proto.DbgSourcePositions[cf.Pc-1]) } return fmt.Sprintf("%v:%v", sourcename, line) } func (ls *LState) stackTrace(level int) string { buf := []string{} header := "stack traceback:" if ls.currentFrame != nil { i := 0 for dbg, ok := ls.GetStack(i); ok; dbg, ok = ls.GetStack(i) { cf := dbg.frame buf = append(buf, fmt.Sprintf("\t%v in %v", ls.Where(i), ls.formattedFrameFuncName(cf))) if !cf.Fn.IsG && cf.TailCall > 0 { for tc := cf.TailCall; tc > 0; tc-- { buf = append(buf, "\t(tailcall): ?") i++ } } i++ } } buf = append(buf, fmt.Sprintf("\t%v: %v", "[G]", "?")) buf = buf[intMax(0, intMin(level, len(buf))):len(buf)] if len(buf) > 20 { newbuf := make([]string, 0, 20) newbuf = append(newbuf, buf[0:7]...) newbuf = append(newbuf, "\t...") newbuf = append(newbuf, buf[len(buf)-7:len(buf)]...) buf = newbuf } return fmt.Sprintf("%s\n%s", header, strings.Join(buf, "\n")) } func (ls *LState) formattedFrameFuncName(fr *callFrame) string { name, ischunk := ls.frameFuncName(fr) if ischunk { return name } if name[0] != '(' && name[0] != '<' { return fmt.Sprintf("function '%s'", name) } return fmt.Sprintf("function %s", name) } func (ls *LState) rawFrameFuncName(fr *callFrame) string { name, _ := ls.frameFuncName(fr) return name } func (ls *LState) frameFuncName(fr *callFrame) (string, bool) { frame := fr.Parent if frame == nil { if ls.Parent == nil { return "main chunk", true } else { return "corountine", true } } if !frame.Fn.IsG { pc := frame.Pc - 1 for _, call := range frame.Fn.Proto.DbgCalls { if call.Pc == pc { name := call.Name if (name == "?" || fr.TailCall > 0) && !fr.Fn.IsG { name = fmt.Sprintf("<%v:%v>", fr.Fn.Proto.SourceName, fr.Fn.Proto.LineDefined) } return name, false } } } if !fr.Fn.IsG { return fmt.Sprintf("<%v:%v>", fr.Fn.Proto.SourceName, fr.Fn.Proto.LineDefined), false } return "(anonymous)", false } func (ls *LState) isStarted() bool { return ls.currentFrame != nil } func (ls *LState) kill() { ls.Dead = true if ls.ctxCancelFn != nil { ls.ctxCancelFn() } } func (ls *LState) indexToReg(idx int) int { base := ls.currentLocalBase() if idx > 0 { return base + idx - 1 } else if idx == 0 { return -1 } else { tidx := ls.reg.Top() + idx if tidx < base { return -1 } return tidx } } func (ls *LState) currentLocalBase() int { base := 0 if ls.currentFrame != nil { base = ls.currentFrame.LocalBase } return base } func (ls *LState) currentEnv() *LTable { return ls.Env /* if ls.currentFrame == nil { return ls.Env } return ls.currentFrame.Fn.Env */ } func (ls *LState) rkValue(idx int) LValue { /* if OpIsK(idx) { return ls.currentFrame.Fn.Proto.Constants[opIndexK(idx)] } return ls.reg.Get(ls.currentFrame.LocalBase + idx) */ if (idx & opBitRk) != 0 { return ls.currentFrame.Fn.Proto.Constants[idx & ^opBitRk] } return ls.reg.array[ls.currentFrame.LocalBase+idx] } func (ls *LState) rkString(idx int) string { if (idx & opBitRk) != 0 { return ls.currentFrame.Fn.Proto.stringConstants[idx & ^opBitRk] } return string(ls.reg.array[ls.currentFrame.LocalBase+idx].(LString)) } func (ls *LState) closeUpvalues(idx int) { // +inline-start 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 } } } // +inline-end func (ls *LState) findUpvalue(idx int) *Upvalue { var prev *Upvalue var next *Upvalue if ls.uvcache != nil { for uv := ls.uvcache; uv != nil; uv = uv.next { if uv.index == idx { return uv } if uv.index > idx { next = uv break } prev = uv } } uv := &Upvalue{reg: ls.reg, index: idx, closed: false} if prev != nil { prev.next = uv } else { ls.uvcache = uv } if next != nil { uv.next = next } return uv } func (ls *LState) metatable(lvalue LValue, rawget bool) LValue { var metatable LValue = LNil switch obj := lvalue.(type) { case *LTable: metatable = obj.Metatable case *LUserData: metatable = obj.Metatable default: if table, ok := ls.G.builtinMts[int(obj.Type())]; ok { metatable = table } } if !rawget && metatable != LNil { oldmt := metatable if tb, ok := metatable.(*LTable); ok { metatable = tb.RawGetString("__metatable") if metatable == LNil { metatable = oldmt } } } return metatable } func (ls *LState) metaOp1(lvalue LValue, event string) LValue { if mt := ls.metatable(lvalue, true); mt != LNil { if tb, ok := mt.(*LTable); ok { return tb.RawGetString(event) } } return LNil } func (ls *LState) metaOp2(value1, value2 LValue, event string) LValue { if mt := ls.metatable(value1, true); mt != LNil { if tb, ok := mt.(*LTable); ok { if ret := tb.RawGetString(event); ret != LNil { return ret } } } if mt := ls.metatable(value2, true); mt != LNil { if tb, ok := mt.(*LTable); ok { return tb.RawGetString(event) } } return LNil } func (ls *LState) metaCall(lvalue LValue) (*LFunction, bool) { if fn, ok := lvalue.(*LFunction); ok { return fn, false } if fn, ok := ls.metaOp1(lvalue, "__call").(*LFunction); ok { return fn, true } return nil, false } func (ls *LState) initCallFrame(cf *callFrame) { // +inline-start if cf.Fn.IsG { ls.reg.SetTop(cf.LocalBase + cf.NArgs) } else { proto := cf.Fn.Proto nargs := cf.NArgs np := int(proto.NumParameters) if nargs < np { // default any missing arguments to nil 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 ls.reg.top = newSize } 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) } } } // +inline-end func (ls *LState) pushCallFrame(cf callFrame, fn LValue, meta bool) { // +inline-start 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) if nargs < np { // default any missing arguments to nil 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 ls.reg.top = newSize } 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 } // +inline-end func (ls *LState) callR(nargs, nret, rbase int) { base := ls.reg.Top() - nargs - 1 if rbase < 0 { rbase = base } lv := ls.reg.Get(base) fn, meta := ls.metaCall(lv) ls.pushCallFrame(callFrame{ Fn: fn, Pc: 0, Base: base, LocalBase: base + 1, ReturnBase: rbase, NArgs: nargs, NRet: nret, Parent: ls.currentFrame, TailCall: 0, }, lv, meta) if ls.G.MainThread == nil { ls.G.MainThread = ls ls.G.CurrentThread = ls ls.mainLoop(ls, nil) } else { ls.mainLoop(ls, ls.currentFrame) } if nret != MultRet { ls.reg.SetTop(rbase + nret) } } func (ls *LState) getField(obj LValue, key LValue) LValue { curobj := obj for i := 0; i < MaxTableGetLoop; i++ { tb, istable := curobj.(*LTable) if istable { ret := tb.RawGet(key) if ret != LNil { return ret } } metaindex := ls.metaOp1(curobj, "__index") if metaindex == LNil { if !istable { ls.RaiseError("attempt to index a non-table object(%v) with key '%s'", curobj.Type().String(), key.String()) } return LNil } if metaindex.Type() == LTFunction { ls.reg.Push(metaindex) ls.reg.Push(curobj) ls.reg.Push(key) ls.Call(2, 1) return ls.reg.Pop() } else { curobj = metaindex } } ls.RaiseError("too many recursions in gettable") return nil } func (ls *LState) getFieldString(obj LValue, key string) LValue { curobj := obj for i := 0; i < MaxTableGetLoop; i++ { tb, istable := curobj.(*LTable) if istable { ret := tb.RawGetString(key) if ret != LNil { return ret } } metaindex := ls.metaOp1(curobj, "__index") if metaindex == LNil { if !istable { ls.RaiseError("attempt to index a non-table object(%v) with key '%s'", curobj.Type().String(), key) } return LNil } if metaindex.Type() == LTFunction { ls.reg.Push(metaindex) ls.reg.Push(curobj) ls.reg.Push(LString(key)) ls.Call(2, 1) return ls.reg.Pop() } else { curobj = metaindex } } ls.RaiseError("too many recursions in gettable") return nil } func (ls *LState) setField(obj LValue, key LValue, value LValue) { curobj := obj for i := 0; i < MaxTableGetLoop; i++ { tb, istable := curobj.(*LTable) if istable { if tb.RawGet(key) != LNil { ls.RawSet(tb, key, value) return } } metaindex := ls.metaOp1(curobj, "__newindex") if metaindex == LNil { if !istable { ls.RaiseError("attempt to index a non-table object(%v) with key '%s'", curobj.Type().String(), key.String()) } ls.RawSet(tb, key, value) return } if metaindex.Type() == LTFunction { ls.reg.Push(metaindex) ls.reg.Push(curobj) ls.reg.Push(key) ls.reg.Push(value) ls.Call(3, 0) return } else { curobj = metaindex } } ls.RaiseError("too many recursions in settable") } func (ls *LState) setFieldString(obj LValue, key string, value LValue) { curobj := obj for i := 0; i < MaxTableGetLoop; i++ { tb, istable := curobj.(*LTable) if istable { if tb.RawGetString(key) != LNil { tb.RawSetString(key, value) return } } metaindex := ls.metaOp1(curobj, "__newindex") if metaindex == LNil { if !istable { ls.RaiseError("attempt to index a non-table object(%v) with key '%s'", curobj.Type().String(), key) } tb.RawSetString(key, value) return } if metaindex.Type() == LTFunction { ls.reg.Push(metaindex) ls.reg.Push(curobj) ls.reg.Push(LString(key)) ls.reg.Push(value) ls.Call(3, 0) return } else { curobj = metaindex } } ls.RaiseError("too many recursions in settable") } /* }}} */ /* api methods {{{ */ func NewState(opts ...Options) *LState { var ls *LState if len(opts) == 0 { ls = newLState(Options{ CallStackSize: CallStackSize, RegistrySize: RegistrySize, }) ls.OpenLibs() } else { if opts[0].CallStackSize < 1 { opts[0].CallStackSize = CallStackSize } if opts[0].RegistrySize < 128 { opts[0].RegistrySize = RegistrySize } if opts[0].RegistryMaxSize < opts[0].RegistrySize { opts[0].RegistryMaxSize = 0 // disable growth if max size is smaller than initial size } else { // if growth enabled, grow step is set if opts[0].RegistryGrowStep < 1 { opts[0].RegistryGrowStep = RegistryGrowStep } } ls = newLState(opts[0]) if !opts[0].SkipOpenLibs { ls.OpenLibs() } } return ls } func (ls *LState) IsClosed() bool { return ls.stack == nil } func (ls *LState) Close() { atomic.AddInt32(&ls.stop, 1) for _, file := range ls.G.tempFiles { // ignore errors in these operations file.Close() os.Remove(file.Name()) } ls.stack.FreeAll() ls.stack = nil } /* registry operations {{{ */ func (ls *LState) GetTop() int { return ls.reg.Top() - ls.currentLocalBase() } func (ls *LState) SetTop(idx int) { base := ls.currentLocalBase() newtop := ls.indexToReg(idx) + 1 if newtop < base { ls.reg.SetTop(base) } else { ls.reg.SetTop(newtop) } } func (ls *LState) Replace(idx int, value LValue) { base := ls.currentLocalBase() if idx > 0 { reg := base + idx - 1 if reg < ls.reg.Top() { ls.reg.Set(reg, value) } } else if idx == 0 { } else if idx > RegistryIndex { if tidx := ls.reg.Top() + idx; tidx >= base { ls.reg.Set(tidx, value) } } else { switch idx { case RegistryIndex: if tb, ok := value.(*LTable); ok { ls.G.Registry = tb } else { ls.RaiseError("registry must be a table(%v)", value.Type().String()) } case EnvironIndex: if ls.currentFrame == nil { ls.RaiseError("no calling environment") } if tb, ok := value.(*LTable); ok { ls.currentFrame.Fn.Env = tb } else { ls.RaiseError("environment must be a table(%v)", value.Type().String()) } case GlobalsIndex: if tb, ok := value.(*LTable); ok { ls.G.Global = tb } else { ls.RaiseError("_G must be a table(%v)", value.Type().String()) } default: fn := ls.currentFrame.Fn index := GlobalsIndex - idx - 1 if index < len(fn.Upvalues) { fn.Upvalues[index].SetValue(value) } } } } func (ls *LState) Get(idx int) LValue { base := ls.currentLocalBase() if idx > 0 { reg := base + idx - 1 if reg < ls.reg.Top() { return ls.reg.Get(reg) } return LNil } else if idx == 0 { return LNil } else if idx > RegistryIndex { tidx := ls.reg.Top() + idx if tidx < base { return LNil } return ls.reg.Get(tidx) } else { switch idx { case RegistryIndex: return ls.G.Registry case EnvironIndex: if ls.currentFrame == nil { return ls.Env } return ls.currentFrame.Fn.Env case GlobalsIndex: return ls.G.Global default: fn := ls.currentFrame.Fn index := GlobalsIndex - idx - 1 if index < len(fn.Upvalues) { return fn.Upvalues[index].Value() } return LNil } } return LNil } func (ls *LState) Push(value LValue) { ls.reg.Push(value) } func (ls *LState) Pop(n int) { for i := 0; i < n; i++ { if ls.GetTop() == 0 { ls.RaiseError("register underflow") } ls.reg.Pop() } } func (ls *LState) Insert(value LValue, index int) { reg := ls.indexToReg(index) top := ls.reg.Top() if reg >= top { ls.reg.Set(reg, value) return } if reg <= ls.currentLocalBase() { reg = ls.currentLocalBase() } top-- for ; top >= reg; top-- { ls.reg.Set(top+1, ls.reg.Get(top)) } ls.reg.Set(reg, value) } func (ls *LState) Remove(index int) { reg := ls.indexToReg(index) top := ls.reg.Top() switch { case reg >= top: return case reg < ls.currentLocalBase(): return case reg == top-1: ls.Pop(1) return } for i := reg; i < top-1; i++ { ls.reg.Set(i, ls.reg.Get(i+1)) } ls.reg.SetTop(top - 1) } /* }}} */ /* object allocation {{{ */ func (ls *LState) NewTable() *LTable { return newLTable(defaultArrayCap, defaultHashCap) } func (ls *LState) CreateTable(acap, hcap int) *LTable { return newLTable(acap, hcap) } // NewThread returns a new LState that shares with the original state all global objects. // If the original state has context.Context, the new state has a new child context of the original state and this function returns its cancel function. func (ls *LState) NewThread() (*LState, context.CancelFunc) { thread := newLState(ls.Options) thread.G = ls.G thread.Env = ls.Env var f context.CancelFunc = nil if ls.ctx != nil { thread.mainLoop = mainLoopWithContext thread.ctx, f = context.WithCancel(ls.ctx) thread.ctxCancelFn = f } return thread, f } func (ls *LState) NewFunctionFromProto(proto *FunctionProto) *LFunction { return newLFunctionL(proto, ls.Env, int(proto.NumUpvalues)) } func (ls *LState) NewUserData() *LUserData { return &LUserData{ Env: ls.currentEnv(), Metatable: LNil, } } func (ls *LState) NewFunction(fn LGFunction) *LFunction { return newLFunctionG(fn, ls.currentEnv(), 0) } func (ls *LState) NewClosure(fn LGFunction, upvalues ...LValue) *LFunction { cl := newLFunctionG(fn, ls.currentEnv(), len(upvalues)) for i, lv := range upvalues { cl.Upvalues[i] = &Upvalue{} cl.Upvalues[i].Close() cl.Upvalues[i].SetValue(lv) } return cl } /* }}} */ /* toType {{{ */ func (ls *LState) ToBool(n int) bool { return LVAsBool(ls.Get(n)) } func (ls *LState) ToInt(n int) int { if lv, ok := ls.Get(n).(LNumber); ok { return int(lv) } if lv, ok := ls.Get(n).(LString); ok { if num, err := parseNumber(string(lv)); err == nil { return int(num) } } return 0 } func (ls *LState) ToInt64(n int) int64 { if lv, ok := ls.Get(n).(LNumber); ok { return int64(lv) } if lv, ok := ls.Get(n).(LString); ok { if num, err := parseNumber(string(lv)); err == nil { return int64(num) } } return 0 } func (ls *LState) ToNumber(n int) LNumber { return LVAsNumber(ls.Get(n)) } func (ls *LState) ToString(n int) string { return LVAsString(ls.Get(n)) } func (ls *LState) ToTable(n int) *LTable { if lv, ok := ls.Get(n).(*LTable); ok { return lv } return nil } func (ls *LState) ToFunction(n int) *LFunction { if lv, ok := ls.Get(n).(*LFunction); ok { return lv } return nil } func (ls *LState) ToUserData(n int) *LUserData { if lv, ok := ls.Get(n).(*LUserData); ok { return lv } return nil } func (ls *LState) ToThread(n int) *LState { if lv, ok := ls.Get(n).(*LState); ok { return lv } return nil } /* }}} */ /* error & debug operations {{{ */ func (ls *LState) registryOverflow() { ls.RaiseError("registry overflow") } // This function is equivalent to luaL_error( http://www.lua.org/manual/5.1/manual.html#luaL_error ). func (ls *LState) RaiseError(format string, args ...interface{}) { ls.raiseError(1, format, args...) } // This function is equivalent to lua_error( http://www.lua.org/manual/5.1/manual.html#lua_error ). func (ls *LState) Error(lv LValue, level int) { if str, ok := lv.(LString); ok { ls.raiseError(level, string(str)) } else { if !ls.hasErrorFunc { ls.closeAllUpvalues() } ls.Push(lv) ls.Panic(ls) } } func (ls *LState) GetInfo(what string, dbg *Debug, fn LValue) (LValue, error) { if !strings.HasPrefix(what, ">") { fn = dbg.frame.Fn } else { what = what[1:] } f, ok := fn.(*LFunction) if !ok { return LNil, newApiErrorS(ApiErrorRun, "can not get debug info(an object in not a function)") } retfn := false for _, c := range what { switch c { case 'f': retfn = true case 'S': if dbg.frame != nil && dbg.frame.Parent == nil { dbg.What = "main" } else if f.IsG { dbg.What = "G" } else if dbg.frame != nil && dbg.frame.TailCall > 0 { dbg.What = "tail" } else { dbg.What = "Lua" } if !f.IsG { dbg.Source = f.Proto.SourceName dbg.LineDefined = f.Proto.LineDefined dbg.LastLineDefined = f.Proto.LastLineDefined } case 'l': if !f.IsG && dbg.frame != nil { if dbg.frame.Pc > 0 { dbg.CurrentLine = f.Proto.DbgSourcePositions[dbg.frame.Pc-1] } } else { dbg.CurrentLine = -1 } case 'u': dbg.NUpvalues = len(f.Upvalues) case 'n': if dbg.frame != nil { dbg.Name = ls.rawFrameFuncName(dbg.frame) } default: return LNil, newApiErrorS(ApiErrorRun, "invalid what: "+string(c)) } } if retfn { return f, nil } return LNil, nil } func (ls *LState) GetStack(level int) (*Debug, bool) { frame := ls.currentFrame for ; level > 0 && frame != nil; frame = frame.Parent { level-- if !frame.Fn.IsG { level -= frame.TailCall } } if level == 0 && frame != nil { return &Debug{frame: frame}, true } else if level < 0 && ls.stack.Sp() > 0 { return &Debug{frame: ls.stack.At(0)}, true } return &Debug{}, false } func (ls *LState) GetLocal(dbg *Debug, no int) (string, LValue) { frame := dbg.frame if name := ls.findLocal(frame, no); len(name) > 0 { return name, ls.reg.Get(frame.LocalBase + no - 1) } return "", LNil } func (ls *LState) SetLocal(dbg *Debug, no int, lv LValue) string { frame := dbg.frame if name := ls.findLocal(frame, no); len(name) > 0 { ls.reg.Set(frame.LocalBase+no-1, lv) return name } return "" } func (ls *LState) GetUpvalue(fn *LFunction, no int) (string, LValue) { if fn.IsG { return "", LNil } no-- if no >= 0 && no < len(fn.Upvalues) { return fn.Proto.DbgUpvalues[no], fn.Upvalues[no].Value() } return "", LNil } func (ls *LState) SetUpvalue(fn *LFunction, no int, lv LValue) string { if fn.IsG { return "" } no-- if no >= 0 && no < len(fn.Upvalues) { fn.Upvalues[no].SetValue(lv) return fn.Proto.DbgUpvalues[no] } return "" } /* }}} */ /* env operations {{{ */ func (ls *LState) GetFEnv(obj LValue) LValue { switch lv := obj.(type) { case *LFunction: return lv.Env case *LUserData: return lv.Env case *LState: return lv.Env } return LNil } func (ls *LState) SetFEnv(obj LValue, env LValue) { tb, ok := env.(*LTable) if !ok { ls.RaiseError("cannot use %v as an environment", env.Type().String()) } switch lv := obj.(type) { case *LFunction: lv.Env = tb case *LUserData: lv.Env = tb case *LState: lv.Env = tb } /* do nothing */ } /* }}} */ /* table operations {{{ */ func (ls *LState) RawGet(tb *LTable, key LValue) LValue { return tb.RawGet(key) } func (ls *LState) RawGetInt(tb *LTable, key int) LValue { return tb.RawGetInt(key) } func (ls *LState) GetField(obj LValue, skey string) LValue { return ls.getFieldString(obj, skey) } func (ls *LState) GetTable(obj LValue, key LValue) LValue { return ls.getField(obj, key) } func (ls *LState) RawSet(tb *LTable, key LValue, value LValue) { if n, ok := key.(LNumber); ok && math.IsNaN(float64(n)) { ls.RaiseError("table index is NaN") } else if key == LNil { ls.RaiseError("table index is nil") } tb.RawSet(key, value) } func (ls *LState) RawSetInt(tb *LTable, key int, value LValue) { tb.RawSetInt(key, value) } func (ls *LState) SetField(obj LValue, key string, value LValue) { ls.setFieldString(obj, key, value) } func (ls *LState) SetTable(obj LValue, key LValue, value LValue) { ls.setField(obj, key, value) } func (ls *LState) ForEach(tb *LTable, cb func(LValue, LValue)) { tb.ForEach(cb) } func (ls *LState) GetGlobal(name string) LValue { return ls.GetField(ls.Get(GlobalsIndex), name) } func (ls *LState) SetGlobal(name string, value LValue) { ls.SetField(ls.Get(GlobalsIndex), name, value) } func (ls *LState) Next(tb *LTable, key LValue) (LValue, LValue) { return tb.Next(key) } /* }}} */ /* unary operations {{{ */ func (ls *LState) ObjLen(v1 LValue) int { if v1.Type() == LTString { return len(string(v1.(LString))) } op := ls.metaOp1(v1, "__len") if op.Type() == LTFunction { ls.Push(op) ls.Push(v1) ls.Call(1, 1) ret := ls.reg.Pop() if ret.Type() == LTNumber { return int(ret.(LNumber)) } } else if v1.Type() == LTTable { return v1.(*LTable).Len() } return 0 } /* }}} */ /* binary operations {{{ */ func (ls *LState) Concat(values ...LValue) string { top := ls.reg.Top() for _, value := range values { ls.reg.Push(value) } ret := stringConcat(ls, len(values), ls.reg.Top()-1) ls.reg.SetTop(top) return LVAsString(ret) } func (ls *LState) LessThan(lhs, rhs LValue) bool { return lessThan(ls, lhs, rhs) } func (ls *LState) Equal(lhs, rhs LValue) bool { return equals(ls, lhs, rhs, false) } func (ls *LState) RawEqual(lhs, rhs LValue) bool { return equals(ls, lhs, rhs, true) } /* }}} */ /* register operations {{{ */ func (ls *LState) Register(name string, fn LGFunction) { ls.SetGlobal(name, ls.NewFunction(fn)) } /* }}} */ /* load and function call operations {{{ */ func (ls *LState) Load(reader io.Reader, name string) (*LFunction, error) { chunk, err := parse.Parse(reader, name) if err != nil { return nil, newApiErrorE(ApiErrorSyntax, err) } proto, err := Compile(chunk, name) if err != nil { return nil, newApiErrorE(ApiErrorSyntax, err) } return newLFunctionL(proto, ls.currentEnv(), 0), nil } func (ls *LState) Call(nargs, nret int) { ls.callR(nargs, nret, -1) } func (ls *LState) PCall(nargs, nret int, errfunc *LFunction) (err error) { err = nil sp := ls.stack.Sp() base := ls.reg.Top() - nargs - 1 oldpanic := ls.Panic ls.Panic = panicWithoutTraceback if errfunc != nil { ls.hasErrorFunc = true } defer func() { ls.Panic = oldpanic ls.hasErrorFunc = false rcv := recover() if rcv != nil { if _, ok := rcv.(*ApiError); !ok { err = newApiErrorS(ApiErrorPanic, fmt.Sprint(rcv)) if ls.Options.IncludeGoStackTrace { buf := make([]byte, 4096) runtime.Stack(buf, false) err.(*ApiError).StackTrace = strings.Trim(string(buf), "\000") + "\n" + ls.stackTrace(0) } } else { err = rcv.(*ApiError) } if errfunc != nil { ls.Push(errfunc) ls.Push(err.(*ApiError).Object) ls.Panic = panicWithoutTraceback defer func() { ls.Panic = oldpanic rcv := recover() if rcv != nil { if _, ok := rcv.(*ApiError); !ok { err = newApiErrorS(ApiErrorPanic, fmt.Sprint(rcv)) if ls.Options.IncludeGoStackTrace { buf := make([]byte, 4096) runtime.Stack(buf, false) err.(*ApiError).StackTrace = strings.Trim(string(buf), "\000") + ls.stackTrace(0) } } else { err = rcv.(*ApiError) err.(*ApiError).StackTrace = ls.stackTrace(0) } ls.stack.SetSp(sp) ls.currentFrame = ls.stack.Last() ls.reg.SetTop(base) } }() ls.Call(1, 1) err = newApiError(ApiErrorError, ls.Get(-1)) } else if len(err.(*ApiError).StackTrace) == 0 { err.(*ApiError).StackTrace = ls.stackTrace(0) } ls.stack.SetSp(sp) ls.currentFrame = ls.stack.Last() ls.reg.SetTop(base) } ls.stack.SetSp(sp) if sp == 0 { ls.currentFrame = nil } }() ls.Call(nargs, nret) return } func (ls *LState) GPCall(fn LGFunction, data LValue) error { ls.Push(newLFunctionG(fn, ls.currentEnv(), 0)) ls.Push(data) return ls.PCall(1, MultRet, nil) } func (ls *LState) CallByParam(cp P, args ...LValue) error { ls.Push(cp.Fn) for _, arg := range args { ls.Push(arg) } if cp.Protect { return ls.PCall(len(args), cp.NRet, cp.Handler) } ls.Call(len(args), cp.NRet) return nil } /* }}} */ /* metatable operations {{{ */ func (ls *LState) GetMetatable(obj LValue) LValue { return ls.metatable(obj, false) } func (ls *LState) SetMetatable(obj LValue, mt LValue) { switch mt.(type) { case *LNilType, *LTable: default: ls.RaiseError("metatable must be a table or nil, but got %v", mt.Type().String()) } switch v := obj.(type) { case *LTable: v.Metatable = mt case *LUserData: v.Metatable = mt default: ls.G.builtinMts[int(obj.Type())] = mt } } /* }}} */ /* coroutine operations {{{ */ func (ls *LState) Status(th *LState) string { status := "suspended" if th.Dead { status = "dead" } else if ls.G.CurrentThread == th { status = "running" } else if ls.Parent == th { status = "normal" } return status } func (ls *LState) Resume(th *LState, fn *LFunction, args ...LValue) (ResumeState, error, []LValue) { isstarted := th.isStarted() if !isstarted { base := 0 th.stack.Push(callFrame{ Fn: fn, Pc: 0, Base: base, LocalBase: base + 1, ReturnBase: base, NArgs: 0, NRet: MultRet, Parent: nil, TailCall: 0, }) } if ls.G.CurrentThread == th { return ResumeError, newApiErrorS(ApiErrorRun, "can not resume a running thread"), nil } if th.Dead { return ResumeError, newApiErrorS(ApiErrorRun, "can not resume a dead thread"), nil } th.Parent = ls ls.G.CurrentThread = th if !isstarted { cf := th.stack.Last() th.currentFrame = cf th.SetTop(0) for _, arg := range args { th.Push(arg) } cf.NArgs = len(args) th.initCallFrame(cf) th.Panic = panicWithoutTraceback } else { for _, arg := range args { th.Push(arg) } } top := ls.GetTop() threadRun(th) haserror := LVIsFalse(ls.Get(top + 1)) ret := make([]LValue, 0, ls.GetTop()) for idx := top + 2; idx <= ls.GetTop(); idx++ { ret = append(ret, ls.Get(idx)) } if len(ret) == 0 { ret = append(ret, LNil) } ls.SetTop(top) if haserror { return ResumeError, newApiError(ApiErrorRun, ret[0]), nil } else if th.stack.IsEmpty() { return ResumeOK, nil, ret } return ResumeYield, nil, ret } func (ls *LState) Yield(values ...LValue) int { ls.SetTop(0) for _, lv := range values { ls.Push(lv) } return -1 } func (ls *LState) XMoveTo(other *LState, n int) { if ls == other { return } top := ls.GetTop() n = intMin(n, top) for i := n; i > 0; i-- { other.Push(ls.Get(top - i + 1)) } ls.SetTop(top - n) } /* }}} */ /* GopherLua original APIs {{{ */ // Set maximum memory size. This function can only be called from the main thread. func (ls *LState) SetMx(mx int) { if ls.Parent != nil { ls.RaiseError("sub threads are not allowed to set a memory limit") } go func() { limit := uint64(mx * 1024 * 1024) //MB var s runtime.MemStats for atomic.LoadInt32(&ls.stop) == 0 { runtime.ReadMemStats(&s) if s.Alloc >= limit { fmt.Println("out of memory") os.Exit(3) } time.Sleep(100 * time.Millisecond) } }() } // SetContext set a context ctx to this LState. The provided ctx must be non-nil. func (ls *LState) SetContext(ctx context.Context) { ls.mainLoop = mainLoopWithContext ls.ctx = ctx } // Context returns the LState's context. To change the context, use WithContext. func (ls *LState) Context() context.Context { return ls.ctx } // RemoveContext removes the context associated with this LState and returns this context. func (ls *LState) RemoveContext() context.Context { oldctx := ls.ctx ls.mainLoop = mainLoop ls.ctx = nil return oldctx } // Converts the Lua value at the given acceptable index to the chan LValue. func (ls *LState) ToChannel(n int) chan LValue { if lv, ok := ls.Get(n).(LChannel); ok { return (chan LValue)(lv) } return nil } // RemoveCallerFrame removes the stack frame above the current stack frame. This is useful in tail calls. It returns // the new current frame. func (ls *LState) RemoveCallerFrame() *callFrame { cs := ls.stack sp := cs.Sp() parentFrame := cs.At(sp - 2) currentFrame := cs.At(sp - 1) parentsParentFrame := parentFrame.Parent *parentFrame = *currentFrame parentFrame.Parent = parentsParentFrame parentFrame.Idx = sp - 2 cs.Pop() return parentFrame } /* }}} */ /* }}} */ //