package lua import ( "fmt" "github.com/yuin/gopher-lua/ast" "math" "reflect" ) /* internal constants & structs {{{ */ const maxRegisters = 200 type expContextType int const ( ecGlobal expContextType = iota ecUpvalue ecLocal ecTable ecVararg ecMethod ecNone ) const regNotDefined = opMaxArgsA + 1 const labelNoJump = 0 type expcontext struct { ctype expContextType reg int // varargopt >= 0: wants varargopt+1 results, i.e a = func() // varargopt = -1: ignore results i.e func() // varargopt = -2: receive all results i.e a = {func()} varargopt int } type assigncontext struct { ec *expcontext keyrk int valuerk int keyks bool needmove bool } type lblabels struct { t int f int e int b bool } type constLValueExpr struct { ast.ExprBase Value LValue } // }}} /* utilities {{{ */ var _ecnone0 = &expcontext{ecNone, regNotDefined, 0} var _ecnonem1 = &expcontext{ecNone, regNotDefined, -1} var _ecnonem2 = &expcontext{ecNone, regNotDefined, -2} var ecfuncdef = &expcontext{ecMethod, regNotDefined, 0} func ecupdate(ec *expcontext, ctype expContextType, reg, varargopt int) { ec.ctype = ctype ec.reg = reg ec.varargopt = varargopt } func ecnone(varargopt int) *expcontext { switch varargopt { case 0: return _ecnone0 case -1: return _ecnonem1 case -2: return _ecnonem2 } return &expcontext{ecNone, regNotDefined, varargopt} } func sline(pos ast.PositionHolder) int { return pos.Line() } func eline(pos ast.PositionHolder) int { return pos.LastLine() } func savereg(ec *expcontext, reg int) int { if ec.ctype != ecLocal || ec.reg == regNotDefined { return reg } return ec.reg } func raiseCompileError(context *funcContext, line int, format string, args ...interface{}) { msg := fmt.Sprintf(format, args...) panic(&CompileError{context: context, Line: line, Message: msg}) } func isVarArgReturnExpr(expr ast.Expr) bool { switch ex := expr.(type) { case *ast.FuncCallExpr: return !ex.AdjustRet case *ast.Comma3Expr: return true } return false } func lnumberValue(expr ast.Expr) (LNumber, bool) { if ex, ok := expr.(*ast.NumberExpr); ok { lv, err := parseNumber(ex.Value) if err != nil { lv = LNumber(math.NaN()) } return lv, true } else if ex, ok := expr.(*constLValueExpr); ok { return ex.Value.(LNumber), true } return 0, false } /* utilities }}} */ type CompileError struct { // {{{ context *funcContext Line int Message string } func (e *CompileError) Error() string { return fmt.Sprintf("compile error near line(%v) %v: %v", e.Line, e.context.Proto.SourceName, e.Message) } // }}} type codeStore struct { // {{{ codes []uint32 lines []int pc int } func (cd *codeStore) Add(inst uint32, line int) { if l := len(cd.codes); l <= 0 || cd.pc == l { cd.codes = append(cd.codes, inst) cd.lines = append(cd.lines, line) } else { cd.codes[cd.pc] = inst cd.lines[cd.pc] = line } cd.pc++ } func (cd *codeStore) AddABC(op int, a int, b int, c int, line int) { cd.Add(opCreateABC(op, a, b, c), line) } func (cd *codeStore) AddABx(op int, a int, bx int, line int) { cd.Add(opCreateABx(op, a, bx), line) } func (cd *codeStore) AddASbx(op int, a int, sbx int, line int) { cd.Add(opCreateASbx(op, a, sbx), line) } func (cd *codeStore) PropagateKMV(top int, save *int, reg *int, inc int) { lastinst := cd.Last() if opGetArgA(lastinst) >= top { switch opGetOpCode(lastinst) { case OP_LOADK: cindex := opGetArgBx(lastinst) if cindex <= opMaxIndexRk { cd.Pop() *save = opRkAsk(cindex) return } case OP_MOVE: cd.Pop() *save = opGetArgB(lastinst) return } } *save = *reg *reg = *reg + inc } func (cd *codeStore) PropagateMV(top int, save *int, reg *int, inc int) { lastinst := cd.Last() if opGetArgA(lastinst) >= top { switch opGetOpCode(lastinst) { case OP_MOVE: cd.Pop() *save = opGetArgB(lastinst) return } } *save = *reg *reg = *reg + inc } func (cd *codeStore) SetOpCode(pc int, v int) { opSetOpCode(&cd.codes[pc], v) } func (cd *codeStore) SetA(pc int, v int) { opSetArgA(&cd.codes[pc], v) } func (cd *codeStore) SetB(pc int, v int) { opSetArgB(&cd.codes[pc], v) } func (cd *codeStore) SetC(pc int, v int) { opSetArgC(&cd.codes[pc], v) } func (cd *codeStore) SetBx(pc int, v int) { opSetArgBx(&cd.codes[pc], v) } func (cd *codeStore) SetSbx(pc int, v int) { opSetArgSbx(&cd.codes[pc], v) } func (cd *codeStore) At(pc int) uint32 { return cd.codes[pc] } func (cd *codeStore) List() []uint32 { return cd.codes[:cd.pc] } func (cd *codeStore) PosList() []int { return cd.lines[:cd.pc] } func (cd *codeStore) LastPC() int { return cd.pc - 1 } func (cd *codeStore) Last() uint32 { if cd.pc == 0 { return opInvalidInstruction } return cd.codes[cd.pc-1] } func (cd *codeStore) Pop() { cd.pc-- } /* }}} Code */ /* {{{ VarNamePool */ type varNamePoolValue struct { Index int Name string } type varNamePool struct { names []string offset int } func newVarNamePool(offset int) *varNamePool { return &varNamePool{make([]string, 0, 16), offset} } func (vp *varNamePool) Names() []string { return vp.names } func (vp *varNamePool) List() []varNamePoolValue { result := make([]varNamePoolValue, len(vp.names), len(vp.names)) for i, name := range vp.names { result[i].Index = i + vp.offset result[i].Name = name } return result } func (vp *varNamePool) LastIndex() int { return vp.offset + len(vp.names) } func (vp *varNamePool) Find(name string) int { for i := len(vp.names) - 1; i >= 0; i-- { if vp.names[i] == name { return i + vp.offset } } return -1 } func (vp *varNamePool) RegisterUnique(name string) int { index := vp.Find(name) if index < 0 { return vp.Register(name) } return index } func (vp *varNamePool) Register(name string) int { vp.names = append(vp.names, name) return len(vp.names) - 1 + vp.offset } /* }}} VarNamePool */ /* FuncContext {{{ */ type codeBlock struct { LocalVars *varNamePool BreakLabel int Parent *codeBlock RefUpvalue bool LineStart int LastLine int } func newCodeBlock(localvars *varNamePool, blabel int, parent *codeBlock, pos ast.PositionHolder) *codeBlock { bl := &codeBlock{localvars, blabel, parent, false, 0, 0} if pos != nil { bl.LineStart = pos.Line() bl.LastLine = pos.LastLine() } return bl } type funcContext struct { Proto *FunctionProto Code *codeStore Parent *funcContext Upvalues *varNamePool Block *codeBlock Blocks []*codeBlock regTop int labelId int labelPc map[int]int } func newFuncContext(sourcename string, parent *funcContext) *funcContext { fc := &funcContext{ Proto: newFunctionProto(sourcename), Code: &codeStore{make([]uint32, 0, 1024), make([]int, 0, 1024), 0}, Parent: parent, Upvalues: newVarNamePool(0), Block: newCodeBlock(newVarNamePool(0), labelNoJump, nil, nil), regTop: 0, labelId: 1, labelPc: map[int]int{}, } fc.Blocks = []*codeBlock{fc.Block} return fc } func (fc *funcContext) NewLabel() int { ret := fc.labelId fc.labelId++ return ret } func (fc *funcContext) SetLabelPc(label int, pc int) { fc.labelPc[label] = pc } func (fc *funcContext) GetLabelPc(label int) int { return fc.labelPc[label] } func (fc *funcContext) ConstIndex(value LValue) int { ctype := value.Type() for i, lv := range fc.Proto.Constants { if lv.Type() == ctype && lv == value { return i } } fc.Proto.Constants = append(fc.Proto.Constants, value) v := len(fc.Proto.Constants) - 1 if v > opMaxArgBx { raiseCompileError(fc, fc.Proto.LineDefined, "too many constants") } return v } func (fc *funcContext) RegisterLocalVar(name string) int { ret := fc.Block.LocalVars.Register(name) fc.Proto.DbgLocals = append(fc.Proto.DbgLocals, &DbgLocalInfo{Name: name, StartPc: fc.Code.LastPC() + 1}) fc.SetRegTop(fc.RegTop() + 1) return ret } func (fc *funcContext) FindLocalVarAndBlock(name string) (int, *codeBlock) { for block := fc.Block; block != nil; block = block.Parent { if index := block.LocalVars.Find(name); index > -1 { return index, block } } return -1, nil } func (fc *funcContext) FindLocalVar(name string) int { idx, _ := fc.FindLocalVarAndBlock(name) return idx } func (fc *funcContext) LocalVars() []varNamePoolValue { result := make([]varNamePoolValue, 0, 32) for _, block := range fc.Blocks { result = append(result, block.LocalVars.List()...) } return result } func (fc *funcContext) EnterBlock(blabel int, pos ast.PositionHolder) { fc.Block = newCodeBlock(newVarNamePool(fc.RegTop()), blabel, fc.Block, pos) fc.Blocks = append(fc.Blocks, fc.Block) } func (fc *funcContext) CloseUpvalues() int { n := -1 if fc.Block.RefUpvalue { n = fc.Block.Parent.LocalVars.LastIndex() fc.Code.AddABC(OP_CLOSE, n, 0, 0, fc.Block.LastLine) } return n } func (fc *funcContext) LeaveBlock() int { closed := fc.CloseUpvalues() fc.EndScope() fc.Block = fc.Block.Parent fc.SetRegTop(fc.Block.LocalVars.LastIndex()) return closed } func (fc *funcContext) EndScope() { for _, vr := range fc.Block.LocalVars.List() { fc.Proto.DbgLocals[vr.Index].EndPc = fc.Code.LastPC() } } func (fc *funcContext) SetRegTop(top int) { if top > maxRegisters { raiseCompileError(fc, fc.Proto.LineDefined, "too many local variables") } fc.regTop = top } func (fc *funcContext) RegTop() int { return fc.regTop } /* FuncContext }}} */ func compileChunk(context *funcContext, chunk []ast.Stmt) { // {{{ for _, stmt := range chunk { compileStmt(context, stmt) } } // }}} func compileBlock(context *funcContext, chunk []ast.Stmt) { // {{{ if len(chunk) == 0 { return } ph := &ast.Node{} ph.SetLine(sline(chunk[0])) ph.SetLastLine(eline(chunk[len(chunk)-1])) context.EnterBlock(labelNoJump, ph) for _, stmt := range chunk { compileStmt(context, stmt) } context.LeaveBlock() } // }}} func compileStmt(context *funcContext, stmt ast.Stmt) { // {{{ switch st := stmt.(type) { case *ast.AssignStmt: compileAssignStmt(context, st) case *ast.LocalAssignStmt: compileLocalAssignStmt(context, st) case *ast.FuncCallStmt: compileFuncCallExpr(context, context.RegTop(), st.Expr.(*ast.FuncCallExpr), ecnone(-1)) case *ast.DoBlockStmt: context.EnterBlock(labelNoJump, st) compileChunk(context, st.Stmts) context.LeaveBlock() case *ast.WhileStmt: compileWhileStmt(context, st) case *ast.RepeatStmt: compileRepeatStmt(context, st) case *ast.FuncDefStmt: compileFuncDefStmt(context, st) case *ast.ReturnStmt: compileReturnStmt(context, st) case *ast.IfStmt: compileIfStmt(context, st) case *ast.BreakStmt: compileBreakStmt(context, st) case *ast.NumberForStmt: compileNumberForStmt(context, st) case *ast.GenericForStmt: compileGenericForStmt(context, st) } } // }}} func compileAssignStmtLeft(context *funcContext, stmt *ast.AssignStmt) (int, []*assigncontext) { // {{{ reg := context.RegTop() acs := make([]*assigncontext, 0, len(stmt.Lhs)) for i, lhs := range stmt.Lhs { islast := i == len(stmt.Lhs)-1 switch st := lhs.(type) { case *ast.IdentExpr: identtype := getIdentRefType(context, context, st) ec := &expcontext{identtype, regNotDefined, 0} switch identtype { case ecGlobal: context.ConstIndex(LString(st.Value)) case ecUpvalue: context.Upvalues.RegisterUnique(st.Value) case ecLocal: if islast { ec.reg = context.FindLocalVar(st.Value) } } acs = append(acs, &assigncontext{ec, 0, 0, false, false}) case *ast.AttrGetExpr: ac := &assigncontext{&expcontext{ecTable, regNotDefined, 0}, 0, 0, false, false} compileExprWithKMVPropagation(context, st.Object, ®, &ac.ec.reg) ac.keyrk = reg reg += compileExpr(context, reg, st.Key, ecnone(0)) if _, ok := st.Key.(*ast.StringExpr); ok { ac.keyks = true } acs = append(acs, ac) default: panic("invalid left expression.") } } return reg, acs } // }}} func compileAssignStmtRight(context *funcContext, stmt *ast.AssignStmt, reg int, acs []*assigncontext) (int, []*assigncontext) { // {{{ lennames := len(stmt.Lhs) lenexprs := len(stmt.Rhs) namesassigned := 0 for namesassigned < lennames { ac := acs[namesassigned] ec := ac.ec var expr ast.Expr = nil if namesassigned >= lenexprs { expr = &ast.NilExpr{} expr.SetLine(sline(stmt.Lhs[namesassigned])) expr.SetLastLine(eline(stmt.Lhs[namesassigned])) } else if isVarArgReturnExpr(stmt.Rhs[namesassigned]) && (lenexprs-namesassigned-1) <= 0 { varargopt := lennames - namesassigned - 1 regstart := reg reginc := compileExpr(context, reg, stmt.Rhs[namesassigned], ecnone(varargopt)) reg += reginc for i := namesassigned; i < namesassigned+int(reginc); i++ { acs[i].needmove = true if acs[i].ec.ctype == ecTable { acs[i].valuerk = regstart + (i - namesassigned) } } namesassigned = lennames continue } if expr == nil { expr = stmt.Rhs[namesassigned] } idx := reg reginc := compileExpr(context, reg, expr, ec) if ec.ctype == ecTable { if _, ok := expr.(*ast.LogicalOpExpr); !ok { context.Code.PropagateKMV(context.RegTop(), &ac.valuerk, ®, reginc) } else { ac.valuerk = idx reg += reginc } } else { ac.needmove = reginc != 0 reg += reginc } namesassigned += 1 } rightreg := reg - 1 // extra right exprs for i := namesassigned; i < lenexprs; i++ { varargopt := -1 if i != lenexprs-1 { varargopt = 0 } reg += compileExpr(context, reg, stmt.Rhs[i], ecnone(varargopt)) } return rightreg, acs } // }}} func compileAssignStmt(context *funcContext, stmt *ast.AssignStmt) { // {{{ code := context.Code lennames := len(stmt.Lhs) reg, acs := compileAssignStmtLeft(context, stmt) reg, acs = compileAssignStmtRight(context, stmt, reg, acs) for i := lennames - 1; i >= 0; i-- { ex := stmt.Lhs[i] switch acs[i].ec.ctype { case ecLocal: if acs[i].needmove { code.AddABC(OP_MOVE, context.FindLocalVar(ex.(*ast.IdentExpr).Value), reg, 0, sline(ex)) reg -= 1 } case ecGlobal: code.AddABx(OP_SETGLOBAL, reg, context.ConstIndex(LString(ex.(*ast.IdentExpr).Value)), sline(ex)) reg -= 1 case ecUpvalue: code.AddABC(OP_SETUPVAL, reg, context.Upvalues.RegisterUnique(ex.(*ast.IdentExpr).Value), 0, sline(ex)) reg -= 1 case ecTable: opcode := OP_SETTABLE if acs[i].keyks { opcode = OP_SETTABLEKS } code.AddABC(opcode, acs[i].ec.reg, acs[i].keyrk, acs[i].valuerk, sline(ex)) if !opIsK(acs[i].valuerk) { reg -= 1 } } } } // }}} func compileRegAssignment(context *funcContext, names []string, exprs []ast.Expr, reg int, nvars int, line int) { // {{{ lennames := len(names) lenexprs := len(exprs) namesassigned := 0 ec := &expcontext{} for namesassigned < lennames && namesassigned < lenexprs { if isVarArgReturnExpr(exprs[namesassigned]) && (lenexprs-namesassigned-1) <= 0 { varargopt := nvars - namesassigned ecupdate(ec, ecVararg, reg, varargopt-1) compileExpr(context, reg, exprs[namesassigned], ec) reg += varargopt namesassigned = lennames } else { ecupdate(ec, ecLocal, reg, 0) compileExpr(context, reg, exprs[namesassigned], ec) reg += 1 namesassigned += 1 } } // extra left names if lennames > namesassigned { restleft := lennames - namesassigned - 1 context.Code.AddABC(OP_LOADNIL, reg, reg+restleft, 0, line) reg += restleft } // extra right exprs for i := namesassigned; i < lenexprs; i++ { varargopt := -1 if i != lenexprs-1 { varargopt = 0 } ecupdate(ec, ecNone, reg, varargopt) reg += compileExpr(context, reg, exprs[i], ec) } } // }}} func compileLocalAssignStmt(context *funcContext, stmt *ast.LocalAssignStmt) { // {{{ reg := context.RegTop() if len(stmt.Names) == 1 && len(stmt.Exprs) == 1 { if _, ok := stmt.Exprs[0].(*ast.FunctionExpr); ok { context.RegisterLocalVar(stmt.Names[0]) compileRegAssignment(context, stmt.Names, stmt.Exprs, reg, len(stmt.Names), sline(stmt)) return } } compileRegAssignment(context, stmt.Names, stmt.Exprs, reg, len(stmt.Names), sline(stmt)) for _, name := range stmt.Names { context.RegisterLocalVar(name) } } // }}} func compileReturnStmt(context *funcContext, stmt *ast.ReturnStmt) { // {{{ lenexprs := len(stmt.Exprs) code := context.Code reg := context.RegTop() a := reg lastisvaarg := false if lenexprs == 1 { switch ex := stmt.Exprs[0].(type) { case *ast.IdentExpr: if idx := context.FindLocalVar(ex.Value); idx > -1 { code.AddABC(OP_RETURN, idx, 2, 0, sline(stmt)) return } case *ast.FuncCallExpr: reg += compileExpr(context, reg, ex, ecnone(-2)) code.SetOpCode(code.LastPC(), OP_TAILCALL) code.AddABC(OP_RETURN, a, 0, 0, sline(stmt)) return } } for i, expr := range stmt.Exprs { if i == lenexprs-1 && isVarArgReturnExpr(expr) { compileExpr(context, reg, expr, ecnone(-2)) lastisvaarg = true } else { reg += compileExpr(context, reg, expr, ecnone(0)) } } count := reg - a + 1 if lastisvaarg { count = 0 } context.Code.AddABC(OP_RETURN, a, count, 0, sline(stmt)) } // }}} func compileIfStmt(context *funcContext, stmt *ast.IfStmt) { // {{{ thenlabel := context.NewLabel() elselabel := context.NewLabel() endlabel := context.NewLabel() compileBranchCondition(context, context.RegTop(), stmt.Condition, thenlabel, elselabel, false) context.SetLabelPc(thenlabel, context.Code.LastPC()) compileBlock(context, stmt.Then) if len(stmt.Else) > 0 { context.Code.AddASbx(OP_JMP, 0, endlabel, sline(stmt)) } context.SetLabelPc(elselabel, context.Code.LastPC()) if len(stmt.Else) > 0 { compileBlock(context, stmt.Else) context.SetLabelPc(endlabel, context.Code.LastPC()) } } // }}} func compileBranchCondition(context *funcContext, reg int, expr ast.Expr, thenlabel, elselabel int, hasnextcond bool) { // {{{ // TODO folding constants? code := context.Code flip := 0 jumplabel := elselabel if hasnextcond { flip = 1 jumplabel = thenlabel } switch ex := expr.(type) { case *ast.FalseExpr, *ast.NilExpr: if !hasnextcond { code.AddASbx(OP_JMP, 0, elselabel, sline(expr)) return } case *ast.TrueExpr, *ast.NumberExpr, *ast.StringExpr: if !hasnextcond { return } case *ast.UnaryNotOpExpr: compileBranchCondition(context, reg, ex.Expr, elselabel, thenlabel, !hasnextcond) return case *ast.LogicalOpExpr: switch ex.Operator { case "and": nextcondlabel := context.NewLabel() compileBranchCondition(context, reg, ex.Lhs, nextcondlabel, elselabel, false) context.SetLabelPc(nextcondlabel, context.Code.LastPC()) compileBranchCondition(context, reg, ex.Rhs, thenlabel, elselabel, hasnextcond) case "or": nextcondlabel := context.NewLabel() compileBranchCondition(context, reg, ex.Lhs, thenlabel, nextcondlabel, true) context.SetLabelPc(nextcondlabel, context.Code.LastPC()) compileBranchCondition(context, reg, ex.Rhs, thenlabel, elselabel, hasnextcond) } return case *ast.RelationalOpExpr: compileRelationalOpExprAux(context, reg, ex, flip, jumplabel) return } a := reg compileExprWithMVPropagation(context, expr, ®, &a) code.AddABC(OP_TEST, a, 0, 0^flip, sline(expr)) code.AddASbx(OP_JMP, 0, jumplabel, sline(expr)) } // }}} func compileWhileStmt(context *funcContext, stmt *ast.WhileStmt) { // {{{ thenlabel := context.NewLabel() elselabel := context.NewLabel() condlabel := context.NewLabel() context.SetLabelPc(condlabel, context.Code.LastPC()) compileBranchCondition(context, context.RegTop(), stmt.Condition, thenlabel, elselabel, false) context.SetLabelPc(thenlabel, context.Code.LastPC()) context.EnterBlock(elselabel, stmt) compileChunk(context, stmt.Stmts) context.CloseUpvalues() context.Code.AddASbx(OP_JMP, 0, condlabel, eline(stmt)) context.LeaveBlock() context.SetLabelPc(elselabel, context.Code.LastPC()) } // }}} func compileRepeatStmt(context *funcContext, stmt *ast.RepeatStmt) { // {{{ initlabel := context.NewLabel() thenlabel := context.NewLabel() elselabel := context.NewLabel() context.SetLabelPc(initlabel, context.Code.LastPC()) context.SetLabelPc(elselabel, context.Code.LastPC()) context.EnterBlock(thenlabel, stmt) compileChunk(context, stmt.Stmts) compileBranchCondition(context, context.RegTop(), stmt.Condition, thenlabel, elselabel, false) context.SetLabelPc(thenlabel, context.Code.LastPC()) n := context.LeaveBlock() if n > -1 { label := context.NewLabel() context.Code.AddASbx(OP_JMP, 0, label, eline(stmt)) context.SetLabelPc(elselabel, context.Code.LastPC()) context.Code.AddABC(OP_CLOSE, n, 0, 0, eline(stmt)) context.Code.AddASbx(OP_JMP, 0, initlabel, eline(stmt)) context.SetLabelPc(label, context.Code.LastPC()) } } // }}} func compileBreakStmt(context *funcContext, stmt *ast.BreakStmt) { // {{{ for block := context.Block; block != nil; block = block.Parent { if label := block.BreakLabel; label != labelNoJump { if block.RefUpvalue { context.Code.AddABC(OP_CLOSE, block.Parent.LocalVars.LastIndex(), 0, 0, sline(stmt)) } context.Code.AddASbx(OP_JMP, 0, label, sline(stmt)) return } } raiseCompileError(context, sline(stmt), "no loop to break") } // }}} func compileFuncDefStmt(context *funcContext, stmt *ast.FuncDefStmt) { // {{{ if stmt.Name.Func == nil { reg := context.RegTop() var treg, kreg int compileExprWithKMVPropagation(context, stmt.Name.Receiver, ®, &treg) kreg = loadRk(context, ®, stmt.Func, LString(stmt.Name.Method)) compileExpr(context, reg, stmt.Func, ecfuncdef) context.Code.AddABC(OP_SETTABLE, treg, kreg, reg, sline(stmt.Name.Receiver)) } else { astmt := &ast.AssignStmt{Lhs: []ast.Expr{stmt.Name.Func}, Rhs: []ast.Expr{stmt.Func}} astmt.SetLine(sline(stmt.Func)) astmt.SetLastLine(eline(stmt.Func)) compileAssignStmt(context, astmt) } } // }}} func compileNumberForStmt(context *funcContext, stmt *ast.NumberForStmt) { // {{{ code := context.Code endlabel := context.NewLabel() ec := &expcontext{} context.EnterBlock(endlabel, stmt) reg := context.RegTop() rindex := context.RegisterLocalVar("(for index)") ecupdate(ec, ecLocal, rindex, 0) compileExpr(context, reg, stmt.Init, ec) reg = context.RegTop() rlimit := context.RegisterLocalVar("(for limit)") ecupdate(ec, ecLocal, rlimit, 0) compileExpr(context, reg, stmt.Limit, ec) reg = context.RegTop() rstep := context.RegisterLocalVar("(for step)") if stmt.Step == nil { stmt.Step = &ast.NumberExpr{Value: "1"} stmt.Step.SetLine(sline(stmt.Init)) } ecupdate(ec, ecLocal, rstep, 0) compileExpr(context, reg, stmt.Step, ec) code.AddASbx(OP_FORPREP, rindex, 0, sline(stmt)) context.RegisterLocalVar(stmt.Name) bodypc := code.LastPC() compileChunk(context, stmt.Stmts) context.LeaveBlock() flpc := code.LastPC() code.AddASbx(OP_FORLOOP, rindex, bodypc-(flpc+1), sline(stmt)) context.SetLabelPc(endlabel, code.LastPC()) code.SetSbx(bodypc, flpc-bodypc) } // }}} func compileGenericForStmt(context *funcContext, stmt *ast.GenericForStmt) { // {{{ code := context.Code endlabel := context.NewLabel() bodylabel := context.NewLabel() fllabel := context.NewLabel() nnames := len(stmt.Names) context.EnterBlock(endlabel, stmt) rgen := context.RegisterLocalVar("(for generator)") context.RegisterLocalVar("(for state)") context.RegisterLocalVar("(for control)") compileRegAssignment(context, stmt.Names, stmt.Exprs, context.RegTop()-3, 3, sline(stmt)) code.AddASbx(OP_JMP, 0, fllabel, sline(stmt)) for _, name := range stmt.Names { context.RegisterLocalVar(name) } context.SetLabelPc(bodylabel, code.LastPC()) compileChunk(context, stmt.Stmts) context.LeaveBlock() context.SetLabelPc(fllabel, code.LastPC()) code.AddABC(OP_TFORLOOP, rgen, 0, nnames, sline(stmt)) code.AddASbx(OP_JMP, 0, bodylabel, sline(stmt)) context.SetLabelPc(endlabel, code.LastPC()) } // }}} func compileExpr(context *funcContext, reg int, expr ast.Expr, ec *expcontext) int { // {{{ code := context.Code sreg := savereg(ec, reg) sused := 1 if sreg < reg { sused = 0 } switch ex := expr.(type) { case *ast.StringExpr: code.AddABx(OP_LOADK, sreg, context.ConstIndex(LString(ex.Value)), sline(ex)) return sused case *ast.NumberExpr: num, err := parseNumber(ex.Value) if err != nil { num = LNumber(math.NaN()) } code.AddABx(OP_LOADK, sreg, context.ConstIndex(num), sline(ex)) return sused case *constLValueExpr: code.AddABx(OP_LOADK, sreg, context.ConstIndex(ex.Value), sline(ex)) return sused case *ast.NilExpr: code.AddABC(OP_LOADNIL, sreg, sreg, 0, sline(ex)) return sused case *ast.FalseExpr: code.AddABC(OP_LOADBOOL, sreg, 0, 0, sline(ex)) return sused case *ast.TrueExpr: code.AddABC(OP_LOADBOOL, sreg, 1, 0, sline(ex)) return sused case *ast.IdentExpr: switch getIdentRefType(context, context, ex) { case ecGlobal: code.AddABx(OP_GETGLOBAL, sreg, context.ConstIndex(LString(ex.Value)), sline(ex)) case ecUpvalue: code.AddABC(OP_GETUPVAL, sreg, context.Upvalues.RegisterUnique(ex.Value), 0, sline(ex)) case ecLocal: b := context.FindLocalVar(ex.Value) code.AddABC(OP_MOVE, sreg, b, 0, sline(ex)) } return sused case *ast.Comma3Expr: if context.Proto.IsVarArg == 0 { raiseCompileError(context, sline(ex), "cannot use '...' outside a vararg function") } context.Proto.IsVarArg &= ^VarArgNeedsArg code.AddABC(OP_VARARG, sreg, 2+ec.varargopt, 0, sline(ex)) if context.RegTop() > (sreg+2+ec.varargopt) || ec.varargopt < -1 { return 0 } return (sreg + 1 + ec.varargopt) - reg case *ast.AttrGetExpr: a := sreg b := reg compileExprWithMVPropagation(context, ex.Object, ®, &b) c := reg compileExprWithKMVPropagation(context, ex.Key, ®, &c) opcode := OP_GETTABLE if _, ok := ex.Key.(*ast.StringExpr); ok { opcode = OP_GETTABLEKS } code.AddABC(opcode, a, b, c, sline(ex)) return sused case *ast.TableExpr: compileTableExpr(context, reg, ex, ec) return 1 case *ast.ArithmeticOpExpr: compileArithmeticOpExpr(context, reg, ex, ec) return sused case *ast.StringConcatOpExpr: compileStringConcatOpExpr(context, reg, ex, ec) return sused case *ast.UnaryMinusOpExpr, *ast.UnaryNotOpExpr, *ast.UnaryLenOpExpr: compileUnaryOpExpr(context, reg, ex, ec) return sused case *ast.RelationalOpExpr: compileRelationalOpExpr(context, reg, ex, ec) return sused case *ast.LogicalOpExpr: compileLogicalOpExpr(context, reg, ex, ec) return sused case *ast.FuncCallExpr: return compileFuncCallExpr(context, reg, ex, ec) case *ast.FunctionExpr: childcontext := newFuncContext(context.Proto.SourceName, context) compileFunctionExpr(childcontext, ex, ec) protono := len(context.Proto.FunctionPrototypes) context.Proto.FunctionPrototypes = append(context.Proto.FunctionPrototypes, childcontext.Proto) code.AddABx(OP_CLOSURE, sreg, protono, sline(ex)) for _, upvalue := range childcontext.Upvalues.List() { localidx, block := context.FindLocalVarAndBlock(upvalue.Name) if localidx > -1 { code.AddABC(OP_MOVE, 0, localidx, 0, sline(ex)) block.RefUpvalue = true } else { upvalueidx := context.Upvalues.Find(upvalue.Name) if upvalueidx < 0 { upvalueidx = context.Upvalues.RegisterUnique(upvalue.Name) } code.AddABC(OP_GETUPVAL, 0, upvalueidx, 0, sline(ex)) } } return sused default: panic(fmt.Sprintf("expr %v not implemented.", reflect.TypeOf(ex).Elem().Name())) } panic("should not reach here") return sused } // }}} func compileExprWithPropagation(context *funcContext, expr ast.Expr, reg *int, save *int, propergator func(int, *int, *int, int)) { // {{{ reginc := compileExpr(context, *reg, expr, ecnone(0)) if _, ok := expr.(*ast.LogicalOpExpr); ok { *save = *reg *reg = *reg + reginc } else { propergator(context.RegTop(), save, reg, reginc) } } // }}} func compileExprWithKMVPropagation(context *funcContext, expr ast.Expr, reg *int, save *int) { // {{{ compileExprWithPropagation(context, expr, reg, save, context.Code.PropagateKMV) } // }}} func compileExprWithMVPropagation(context *funcContext, expr ast.Expr, reg *int, save *int) { // {{{ compileExprWithPropagation(context, expr, reg, save, context.Code.PropagateMV) } // }}} func constFold(exp ast.Expr) ast.Expr { // {{{ switch expr := exp.(type) { case *ast.ArithmeticOpExpr: lvalue, lisconst := lnumberValue(expr.Lhs) rvalue, risconst := lnumberValue(expr.Rhs) if lisconst && risconst { switch expr.Operator { case "+": return &constLValueExpr{Value: lvalue + rvalue} case "-": return &constLValueExpr{Value: lvalue - rvalue} case "*": return &constLValueExpr{Value: lvalue * rvalue} case "/": return &constLValueExpr{Value: lvalue / rvalue} case "%": return &constLValueExpr{Value: luaModulo(lvalue, rvalue)} case "^": return &constLValueExpr{Value: LNumber(math.Pow(float64(lvalue), float64(rvalue)))} default: panic(fmt.Sprintf("unknown binop: %v", expr.Operator)) } } else { retexpr := *expr retexpr.Lhs = constFold(expr.Lhs) retexpr.Rhs = constFold(expr.Rhs) return &retexpr } case *ast.UnaryMinusOpExpr: expr.Expr = constFold(expr.Expr) if value, ok := lnumberValue(expr.Expr); ok { return &constLValueExpr{Value: LNumber(-value)} } return expr default: return exp } return exp } // }}} func compileFunctionExpr(context *funcContext, funcexpr *ast.FunctionExpr, ec *expcontext) { // {{{ context.Proto.LineDefined = sline(funcexpr) context.Proto.LastLineDefined = eline(funcexpr) if len(funcexpr.ParList.Names) > maxRegisters { raiseCompileError(context, context.Proto.LineDefined, "register overflow") } context.Proto.NumParameters = uint8(len(funcexpr.ParList.Names)) if ec.ctype == ecMethod { context.Proto.NumParameters += 1 context.RegisterLocalVar("self") } for _, name := range funcexpr.ParList.Names { context.RegisterLocalVar(name) } if funcexpr.ParList.HasVargs { if CompatVarArg { context.Proto.IsVarArg = VarArgHasArg | VarArgNeedsArg if context.Parent != nil { context.RegisterLocalVar("arg") } } context.Proto.IsVarArg |= VarArgIsVarArg } compileChunk(context, funcexpr.Stmts) context.Code.AddABC(OP_RETURN, 0, 1, 0, eline(funcexpr)) context.EndScope() context.Proto.Code = context.Code.List() context.Proto.DbgSourcePositions = context.Code.PosList() context.Proto.DbgUpvalues = context.Upvalues.Names() context.Proto.NumUpvalues = uint8(len(context.Proto.DbgUpvalues)) for _, clv := range context.Proto.Constants { sv := "" if slv, ok := clv.(LString); ok { sv = string(slv) } context.Proto.stringConstants = append(context.Proto.stringConstants, sv) } patchCode(context) } // }}} func compileTableExpr(context *funcContext, reg int, ex *ast.TableExpr, ec *expcontext) { // {{{ code := context.Code /* tablereg := savereg(ec, reg) if tablereg == reg { reg += 1 } */ tablereg := reg reg++ code.AddABC(OP_NEWTABLE, tablereg, 0, 0, sline(ex)) tablepc := code.LastPC() regbase := reg arraycount := 0 lastvararg := false for i, field := range ex.Fields { islast := i == len(ex.Fields)-1 if field.Key == nil { if islast && isVarArgReturnExpr(field.Value) { reg += compileExpr(context, reg, field.Value, ecnone(-2)) lastvararg = true } else { reg += compileExpr(context, reg, field.Value, ecnone(0)) arraycount += 1 } } else { regorg := reg b := reg compileExprWithKMVPropagation(context, field.Key, ®, &b) c := reg compileExprWithKMVPropagation(context, field.Value, ®, &c) opcode := OP_SETTABLE if _, ok := field.Key.(*ast.StringExpr); ok { opcode = OP_SETTABLEKS } code.AddABC(opcode, tablereg, b, c, sline(ex)) reg = regorg } flush := arraycount % FieldsPerFlush if (arraycount != 0 && (flush == 0 || islast)) || lastvararg { reg = regbase num := flush if num == 0 { num = FieldsPerFlush } c := (arraycount-1)/FieldsPerFlush + 1 b := num if islast && isVarArgReturnExpr(field.Value) { b = 0 } line := field.Value if field.Key != nil { line = field.Key } if c > 511 { c = 0 } code.AddABC(OP_SETLIST, tablereg, b, c, sline(line)) if c == 0 { code.Add(uint32(c), sline(line)) } } } code.SetB(tablepc, int2Fb(arraycount)) code.SetC(tablepc, int2Fb(len(ex.Fields)-arraycount)) if ec.ctype == ecLocal && ec.reg != tablereg { code.AddABC(OP_MOVE, ec.reg, tablereg, 0, sline(ex)) } } // }}} func compileArithmeticOpExpr(context *funcContext, reg int, expr *ast.ArithmeticOpExpr, ec *expcontext) { // {{{ exp := constFold(expr) if ex, ok := exp.(*constLValueExpr); ok { exp.SetLine(sline(expr)) compileExpr(context, reg, ex, ec) return } expr, _ = exp.(*ast.ArithmeticOpExpr) a := savereg(ec, reg) b := reg compileExprWithKMVPropagation(context, expr.Lhs, ®, &b) c := reg compileExprWithKMVPropagation(context, expr.Rhs, ®, &c) op := 0 switch expr.Operator { case "+": op = OP_ADD case "-": op = OP_SUB case "*": op = OP_MUL case "/": op = OP_DIV case "%": op = OP_MOD case "^": op = OP_POW } context.Code.AddABC(op, a, b, c, sline(expr)) } // }}} func compileStringConcatOpExpr(context *funcContext, reg int, expr *ast.StringConcatOpExpr, ec *expcontext) { // {{{ code := context.Code crange := 1 for current := expr.Rhs; current != nil; { if ex, ok := current.(*ast.StringConcatOpExpr); ok { crange += 1 current = ex.Rhs } else { current = nil } } a := savereg(ec, reg) basereg := reg reg += compileExpr(context, reg, expr.Lhs, ecnone(0)) reg += compileExpr(context, reg, expr.Rhs, ecnone(0)) for pc := code.LastPC(); pc != 0 && opGetOpCode(code.At(pc)) == OP_CONCAT; pc-- { code.Pop() } code.AddABC(OP_CONCAT, a, basereg, basereg+crange, sline(expr)) } // }}} func compileUnaryOpExpr(context *funcContext, reg int, expr ast.Expr, ec *expcontext) { // {{{ opcode := 0 code := context.Code var operandexpr ast.Expr switch ex := expr.(type) { case *ast.UnaryMinusOpExpr: exp := constFold(ex) if lvexpr, ok := exp.(*constLValueExpr); ok { exp.SetLine(sline(expr)) compileExpr(context, reg, lvexpr, ec) return } ex, _ = exp.(*ast.UnaryMinusOpExpr) operandexpr = ex.Expr opcode = OP_UNM case *ast.UnaryNotOpExpr: switch ex.Expr.(type) { case *ast.TrueExpr: code.AddABC(OP_LOADBOOL, savereg(ec, reg), 0, 0, sline(expr)) return case *ast.FalseExpr, *ast.NilExpr: code.AddABC(OP_LOADBOOL, savereg(ec, reg), 1, 0, sline(expr)) return default: opcode = OP_NOT operandexpr = ex.Expr } case *ast.UnaryLenOpExpr: opcode = OP_LEN operandexpr = ex.Expr } a := savereg(ec, reg) b := reg compileExprWithMVPropagation(context, operandexpr, ®, &b) code.AddABC(opcode, a, b, 0, sline(expr)) } // }}} func compileRelationalOpExprAux(context *funcContext, reg int, expr *ast.RelationalOpExpr, flip int, label int) { // {{{ code := context.Code b := reg compileExprWithKMVPropagation(context, expr.Lhs, ®, &b) c := reg compileExprWithKMVPropagation(context, expr.Rhs, ®, &c) switch expr.Operator { case "<": code.AddABC(OP_LT, 0^flip, b, c, sline(expr)) case ">": code.AddABC(OP_LT, 0^flip, c, b, sline(expr)) case "<=": code.AddABC(OP_LE, 0^flip, b, c, sline(expr)) case ">=": code.AddABC(OP_LE, 0^flip, c, b, sline(expr)) case "==": code.AddABC(OP_EQ, 0^flip, b, c, sline(expr)) case "~=": code.AddABC(OP_EQ, 1^flip, b, c, sline(expr)) } code.AddASbx(OP_JMP, 0, label, sline(expr)) } // }}} func compileRelationalOpExpr(context *funcContext, reg int, expr *ast.RelationalOpExpr, ec *expcontext) { // {{{ a := savereg(ec, reg) code := context.Code jumplabel := context.NewLabel() compileRelationalOpExprAux(context, reg, expr, 1, jumplabel) code.AddABC(OP_LOADBOOL, a, 0, 1, sline(expr)) context.SetLabelPc(jumplabel, code.LastPC()) code.AddABC(OP_LOADBOOL, a, 1, 0, sline(expr)) } // }}} func compileLogicalOpExpr(context *funcContext, reg int, expr *ast.LogicalOpExpr, ec *expcontext) { // {{{ a := savereg(ec, reg) code := context.Code endlabel := context.NewLabel() lb := &lblabels{context.NewLabel(), context.NewLabel(), endlabel, false} nextcondlabel := context.NewLabel() if expr.Operator == "and" { compileLogicalOpExprAux(context, reg, expr.Lhs, ec, nextcondlabel, endlabel, false, lb) context.SetLabelPc(nextcondlabel, code.LastPC()) compileLogicalOpExprAux(context, reg, expr.Rhs, ec, endlabel, endlabel, false, lb) } else { compileLogicalOpExprAux(context, reg, expr.Lhs, ec, endlabel, nextcondlabel, true, lb) context.SetLabelPc(nextcondlabel, code.LastPC()) compileLogicalOpExprAux(context, reg, expr.Rhs, ec, endlabel, endlabel, false, lb) } if lb.b { context.SetLabelPc(lb.f, code.LastPC()) code.AddABC(OP_LOADBOOL, a, 0, 1, sline(expr)) context.SetLabelPc(lb.t, code.LastPC()) code.AddABC(OP_LOADBOOL, a, 1, 0, sline(expr)) } lastinst := code.Last() if opGetOpCode(lastinst) == OP_JMP && opGetArgSbx(lastinst) == endlabel { code.Pop() } context.SetLabelPc(endlabel, code.LastPC()) } // }}} func compileLogicalOpExprAux(context *funcContext, reg int, expr ast.Expr, ec *expcontext, thenlabel, elselabel int, hasnextcond bool, lb *lblabels) { // {{{ // TODO folding constants? code := context.Code flip := 0 jumplabel := elselabel if hasnextcond { flip = 1 jumplabel = thenlabel } switch ex := expr.(type) { case *ast.FalseExpr: if elselabel == lb.e { code.AddASbx(OP_JMP, 0, lb.f, sline(expr)) lb.b = true } else { code.AddASbx(OP_JMP, 0, elselabel, sline(expr)) } return case *ast.NilExpr: if elselabel == lb.e { compileExpr(context, reg, expr, ec) code.AddASbx(OP_JMP, 0, lb.e, sline(expr)) } else { code.AddASbx(OP_JMP, 0, elselabel, sline(expr)) } return case *ast.TrueExpr: if thenlabel == lb.e { code.AddASbx(OP_JMP, 0, lb.t, sline(expr)) lb.b = true } else { code.AddASbx(OP_JMP, 0, thenlabel, sline(expr)) } return case *ast.NumberExpr, *ast.StringExpr: if thenlabel == lb.e { compileExpr(context, reg, expr, ec) code.AddASbx(OP_JMP, 0, lb.e, sline(expr)) } else { code.AddASbx(OP_JMP, 0, thenlabel, sline(expr)) } return case *ast.LogicalOpExpr: switch ex.Operator { case "and": nextcondlabel := context.NewLabel() compileLogicalOpExprAux(context, reg, ex.Lhs, ec, nextcondlabel, elselabel, false, lb) context.SetLabelPc(nextcondlabel, context.Code.LastPC()) compileLogicalOpExprAux(context, reg, ex.Rhs, ec, thenlabel, elselabel, hasnextcond, lb) case "or": nextcondlabel := context.NewLabel() compileLogicalOpExprAux(context, reg, ex.Lhs, ec, thenlabel, nextcondlabel, true, lb) context.SetLabelPc(nextcondlabel, context.Code.LastPC()) compileLogicalOpExprAux(context, reg, ex.Rhs, ec, thenlabel, elselabel, hasnextcond, lb) } return case *ast.RelationalOpExpr: if thenlabel == elselabel { flip ^= 1 jumplabel = lb.t lb.b = true } else if thenlabel == lb.e { jumplabel = lb.t lb.b = true } else if elselabel == lb.e { jumplabel = lb.f lb.b = true } compileRelationalOpExprAux(context, reg, ex, flip, jumplabel) return } if !hasnextcond && thenlabel == elselabel { reg += compileExpr(context, reg, expr, ec) } else { a := reg sreg := savereg(ec, a) reg += compileExpr(context, reg, expr, ecnone(0)) if sreg == a { code.AddABC(OP_TEST, a, 0, 0^flip, sline(expr)) } else { code.AddABC(OP_TESTSET, sreg, a, 0^flip, sline(expr)) } } code.AddASbx(OP_JMP, 0, jumplabel, sline(expr)) } // }}} func compileFuncCallExpr(context *funcContext, reg int, expr *ast.FuncCallExpr, ec *expcontext) int { // {{{ funcreg := reg if ec.ctype == ecLocal && ec.reg == (int(context.Proto.NumParameters)-1) { funcreg = ec.reg reg = ec.reg } argc := len(expr.Args) islastvararg := false name := "(anonymous)" if expr.Func != nil { // hoge.func() reg += compileExpr(context, reg, expr.Func, ecnone(0)) name = getExprName(context, expr.Func) } else { // hoge:method() b := reg compileExprWithMVPropagation(context, expr.Receiver, ®, &b) c := loadRk(context, ®, expr, LString(expr.Method)) context.Code.AddABC(OP_SELF, funcreg, b, c, sline(expr)) // increments a register for an implicit "self" reg = b + 1 reg2 := funcreg + 2 if reg2 > reg { reg = reg2 } argc += 1 name = string(expr.Method) } for i, ar := range expr.Args { islastvararg = (i == len(expr.Args)-1) && isVarArgReturnExpr(ar) if islastvararg { compileExpr(context, reg, ar, ecnone(-2)) } else { reg += compileExpr(context, reg, ar, ecnone(0)) } } b := argc + 1 if islastvararg { b = 0 } context.Code.AddABC(OP_CALL, funcreg, b, ec.varargopt+2, sline(expr)) context.Proto.DbgCalls = append(context.Proto.DbgCalls, DbgCall{Pc: context.Code.LastPC(), Name: name}) if ec.varargopt == 0 && ec.ctype == ecLocal && funcreg != ec.reg { context.Code.AddABC(OP_MOVE, ec.reg, funcreg, 0, sline(expr)) return 1 } if context.RegTop() > (funcreg+2+ec.varargopt) || ec.varargopt < -1 { return 0 } return ec.varargopt + 1 } // }}} func loadRk(context *funcContext, reg *int, expr ast.Expr, cnst LValue) int { // {{{ cindex := context.ConstIndex(cnst) if cindex <= opMaxIndexRk { return opRkAsk(cindex) } else { ret := *reg *reg++ context.Code.AddABx(OP_LOADK, ret, cindex, sline(expr)) return ret } } // }}} func getIdentRefType(context *funcContext, current *funcContext, expr *ast.IdentExpr) expContextType { // {{{ if current == nil { return ecGlobal } else if current.FindLocalVar(expr.Value) > -1 { if current == context { return ecLocal } return ecUpvalue } return getIdentRefType(context, current.Parent, expr) } // }}} func getExprName(context *funcContext, expr ast.Expr) string { // {{{ switch ex := expr.(type) { case *ast.IdentExpr: return ex.Value case *ast.AttrGetExpr: switch kex := ex.Key.(type) { case *ast.StringExpr: return kex.Value } return "?" } return "?" } // }}} func patchCode(context *funcContext) { // {{{ maxreg := 1 if np := int(context.Proto.NumParameters); np > 1 { maxreg = np } moven := 0 code := context.Code.List() for pc := 0; pc < len(code); pc++ { inst := code[pc] curop := opGetOpCode(inst) switch curop { case OP_CLOSURE: pc += int(context.Proto.FunctionPrototypes[opGetArgBx(inst)].NumUpvalues) moven = 0 continue case OP_SETGLOBAL, OP_SETUPVAL, OP_EQ, OP_LT, OP_LE, OP_TEST, OP_TAILCALL, OP_RETURN, OP_FORPREP, OP_FORLOOP, OP_TFORLOOP, OP_SETLIST, OP_CLOSE: /* nothing to do */ case OP_CALL: if reg := opGetArgA(inst) + opGetArgC(inst) - 2; reg > maxreg { maxreg = reg } case OP_VARARG: if reg := opGetArgA(inst) + opGetArgB(inst) - 1; reg > maxreg { maxreg = reg } case OP_SELF: if reg := opGetArgA(inst) + 1; reg > maxreg { maxreg = reg } case OP_LOADNIL: if reg := opGetArgB(inst); reg > maxreg { maxreg = reg } case OP_JMP: // jump to jump optimization distance := 0 count := 0 // avoiding infinite loops for jmp := inst; opGetOpCode(jmp) == OP_JMP && count < 5; jmp = context.Code.At(pc + distance + 1) { d := context.GetLabelPc(opGetArgSbx(jmp)) - pc if d > opMaxArgSbx { if distance == 0 { raiseCompileError(context, context.Proto.LineDefined, "too long to jump.") } break } distance = d count++ } if distance == 0 { context.Code.SetOpCode(pc, OP_NOP) } else { context.Code.SetSbx(pc, distance) } default: if reg := opGetArgA(inst); reg > maxreg { maxreg = reg } } // bulk move optimization(reducing op dipatch costs) if curop == OP_MOVE { moven++ } else { if moven > 1 { context.Code.SetOpCode(pc-moven, OP_MOVEN) context.Code.SetC(pc-moven, intMin(moven-1, opMaxArgsC)) } moven = 0 } } maxreg++ if maxreg > maxRegisters { raiseCompileError(context, context.Proto.LineDefined, "register overflow(too many local variables)") } context.Proto.NumUsedRegisters = uint8(maxreg) } // }}} func Compile(chunk []ast.Stmt, name string) (proto *FunctionProto, err error) { // {{{ defer func() { if rcv := recover(); rcv != nil { if _, ok := rcv.(*CompileError); ok { err = rcv.(error) } else { panic(rcv) } } }() err = nil parlist := &ast.ParList{HasVargs: true, Names: []string{}} funcexpr := &ast.FunctionExpr{ParList: parlist, Stmts: chunk} context := newFuncContext(name, nil) compileFunctionExpr(context, funcexpr, ecnone(0)) proto = context.Proto return } // }}}