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compiler.go
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compiler.go
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package tengo
import (
"errors"
"fmt"
"io"
"io/ioutil"
"os"
"path/filepath"
"reflect"
"strings"
"github.com/d5/tengo/v2/parser"
"github.com/d5/tengo/v2/token"
)
// compilationScope represents a compiled instructions and the last two
// instructions that were emitted.
type compilationScope struct {
Instructions []byte
SymbolInit map[string]bool
SourceMap map[int]parser.Pos
}
// loop represents a loop construct that the compiler uses to track the current
// loop.
type loop struct {
Continues []int
Breaks []int
}
// CompilerError represents a compiler error.
type CompilerError struct {
FileSet *parser.SourceFileSet
Node parser.Node
Err error
}
func (e *CompilerError) Error() string {
filePos := e.FileSet.Position(e.Node.Pos())
return fmt.Sprintf("Compile Error: %s\n\tat %s", e.Err.Error(), filePos)
}
// Compiler compiles the AST into a bytecode.
type Compiler struct {
file *parser.SourceFile
parent *Compiler
modulePath string
importDir string
importFileExt []string
constants []Object
symbolTable *SymbolTable
scopes []compilationScope
scopeIndex int
modules ModuleGetter
compiledModules map[string]*CompiledFunction
allowFileImport bool
loops []*loop
loopIndex int
trace io.Writer
indent int
}
// NewCompiler creates a Compiler.
func NewCompiler(
file *parser.SourceFile,
symbolTable *SymbolTable,
constants []Object,
modules ModuleGetter,
trace io.Writer,
) *Compiler {
mainScope := compilationScope{
SymbolInit: make(map[string]bool),
SourceMap: make(map[int]parser.Pos),
}
// symbol table
if symbolTable == nil {
symbolTable = NewSymbolTable()
}
// add builtin functions to the symbol table
for idx, fn := range builtinFuncs {
symbolTable.DefineBuiltin(idx, fn.Name)
}
// builtin modules
if modules == nil {
modules = NewModuleMap()
}
return &Compiler{
file: file,
symbolTable: symbolTable,
constants: constants,
scopes: []compilationScope{mainScope},
scopeIndex: 0,
loopIndex: -1,
trace: trace,
modules: modules,
compiledModules: make(map[string]*CompiledFunction),
importFileExt: []string{SourceFileExtDefault},
}
}
// Compile compiles the AST node.
func (c *Compiler) Compile(node parser.Node) error {
if c.trace != nil {
if node != nil {
defer untracec(tracec(c, fmt.Sprintf("%s (%s)",
node.String(), reflect.TypeOf(node).Elem().Name())))
} else {
defer untracec(tracec(c, "<nil>"))
}
}
switch node := node.(type) {
case *parser.File:
for _, stmt := range node.Stmts {
if err := c.Compile(stmt); err != nil {
return err
}
}
case *parser.ExprStmt:
if err := c.Compile(node.Expr); err != nil {
return err
}
c.emit(node, parser.OpPop)
case *parser.IncDecStmt:
op := token.AddAssign
if node.Token == token.Dec {
op = token.SubAssign
}
return c.compileAssign(node, []parser.Expr{node.Expr},
[]parser.Expr{&parser.IntLit{Value: 1}}, op)
case *parser.ParenExpr:
if err := c.Compile(node.Expr); err != nil {
return err
}
case *parser.BinaryExpr:
if node.Token == token.LAnd || node.Token == token.LOr {
return c.compileLogical(node)
}
if err := c.Compile(node.LHS); err != nil {
return err
}
if err := c.Compile(node.RHS); err != nil {
return err
}
switch node.Token {
case token.Add:
c.emit(node, parser.OpBinaryOp, int(token.Add))
case token.Sub:
c.emit(node, parser.OpBinaryOp, int(token.Sub))
case token.Mul:
c.emit(node, parser.OpBinaryOp, int(token.Mul))
case token.Quo:
c.emit(node, parser.OpBinaryOp, int(token.Quo))
case token.Rem:
c.emit(node, parser.OpBinaryOp, int(token.Rem))
case token.Greater:
c.emit(node, parser.OpBinaryOp, int(token.Greater))
case token.GreaterEq:
c.emit(node, parser.OpBinaryOp, int(token.GreaterEq))
case token.Less:
c.emit(node, parser.OpBinaryOp, int(token.Less))
case token.LessEq:
c.emit(node, parser.OpBinaryOp, int(token.LessEq))
case token.Equal:
c.emit(node, parser.OpEqual)
case token.NotEqual:
c.emit(node, parser.OpNotEqual)
case token.And:
c.emit(node, parser.OpBinaryOp, int(token.And))
case token.Or:
c.emit(node, parser.OpBinaryOp, int(token.Or))
case token.Xor:
c.emit(node, parser.OpBinaryOp, int(token.Xor))
case token.AndNot:
c.emit(node, parser.OpBinaryOp, int(token.AndNot))
case token.Shl:
c.emit(node, parser.OpBinaryOp, int(token.Shl))
case token.Shr:
c.emit(node, parser.OpBinaryOp, int(token.Shr))
default:
return c.errorf(node, "invalid binary operator: %s",
node.Token.String())
}
case *parser.IntLit:
c.emit(node, parser.OpConstant,
c.addConstant(&Int{Value: node.Value}))
case *parser.FloatLit:
c.emit(node, parser.OpConstant,
c.addConstant(&Float{Value: node.Value}))
case *parser.BoolLit:
if node.Value {
c.emit(node, parser.OpTrue)
} else {
c.emit(node, parser.OpFalse)
}
case *parser.StringLit:
if len(node.Value) > MaxStringLen {
return c.error(node, ErrStringLimit)
}
c.emit(node, parser.OpConstant,
c.addConstant(&String{Value: node.Value}))
case *parser.CharLit:
c.emit(node, parser.OpConstant,
c.addConstant(&Char{Value: node.Value}))
case *parser.UndefinedLit:
c.emit(node, parser.OpNull)
case *parser.UnaryExpr:
if err := c.Compile(node.Expr); err != nil {
return err
}
switch node.Token {
case token.Not:
c.emit(node, parser.OpLNot)
case token.Sub:
c.emit(node, parser.OpMinus)
case token.Xor:
c.emit(node, parser.OpBComplement)
case token.Add:
// do nothing?
default:
return c.errorf(node,
"invalid unary operator: %s", node.Token.String())
}
case *parser.IfStmt:
// open new symbol table for the statement
c.symbolTable = c.symbolTable.Fork(true)
defer func() {
c.symbolTable = c.symbolTable.Parent(false)
}()
if node.Init != nil {
if err := c.Compile(node.Init); err != nil {
return err
}
}
if err := c.Compile(node.Cond); err != nil {
return err
}
// first jump placeholder
jumpPos1 := c.emit(node, parser.OpJumpFalsy, 0)
if err := c.Compile(node.Body); err != nil {
return err
}
if node.Else != nil {
// second jump placeholder
jumpPos2 := c.emit(node, parser.OpJump, 0)
// update first jump offset
curPos := len(c.currentInstructions())
c.changeOperand(jumpPos1, curPos)
if err := c.Compile(node.Else); err != nil {
return err
}
// update second jump offset
curPos = len(c.currentInstructions())
c.changeOperand(jumpPos2, curPos)
} else {
// update first jump offset
curPos := len(c.currentInstructions())
c.changeOperand(jumpPos1, curPos)
}
case *parser.ForStmt:
return c.compileForStmt(node)
case *parser.ForInStmt:
return c.compileForInStmt(node)
case *parser.BranchStmt:
if node.Token == token.Break {
curLoop := c.currentLoop()
if curLoop == nil {
return c.errorf(node, "break not allowed outside loop")
}
pos := c.emit(node, parser.OpJump, 0)
curLoop.Breaks = append(curLoop.Breaks, pos)
} else if node.Token == token.Continue {
curLoop := c.currentLoop()
if curLoop == nil {
return c.errorf(node, "continue not allowed outside loop")
}
pos := c.emit(node, parser.OpJump, 0)
curLoop.Continues = append(curLoop.Continues, pos)
} else {
panic(fmt.Errorf("invalid branch statement: %s",
node.Token.String()))
}
case *parser.BlockStmt:
if len(node.Stmts) == 0 {
return nil
}
c.symbolTable = c.symbolTable.Fork(true)
defer func() {
c.symbolTable = c.symbolTable.Parent(false)
}()
for _, stmt := range node.Stmts {
if err := c.Compile(stmt); err != nil {
return err
}
}
case *parser.AssignStmt:
err := c.compileAssign(node, node.LHS, node.RHS, node.Token)
if err != nil {
return err
}
case *parser.Ident:
symbol, _, ok := c.symbolTable.Resolve(node.Name, false)
if !ok {
return c.errorf(node, "unresolved reference '%s'", node.Name)
}
switch symbol.Scope {
case ScopeGlobal:
c.emit(node, parser.OpGetGlobal, symbol.Index)
case ScopeLocal:
c.emit(node, parser.OpGetLocal, symbol.Index)
case ScopeBuiltin:
c.emit(node, parser.OpGetBuiltin, symbol.Index)
case ScopeFree:
c.emit(node, parser.OpGetFree, symbol.Index)
}
case *parser.ArrayLit:
for _, elem := range node.Elements {
if err := c.Compile(elem); err != nil {
return err
}
}
c.emit(node, parser.OpArray, len(node.Elements))
case *parser.MapLit:
for _, elt := range node.Elements {
// key
if len(elt.Key) > MaxStringLen {
return c.error(node, ErrStringLimit)
}
c.emit(node, parser.OpConstant,
c.addConstant(&String{Value: elt.Key}))
// value
if err := c.Compile(elt.Value); err != nil {
return err
}
}
c.emit(node, parser.OpMap, len(node.Elements)*2)
case *parser.SelectorExpr: // selector on RHS side
if err := c.Compile(node.Expr); err != nil {
return err
}
if err := c.Compile(node.Sel); err != nil {
return err
}
c.emit(node, parser.OpIndex)
case *parser.IndexExpr:
if err := c.Compile(node.Expr); err != nil {
return err
}
if err := c.Compile(node.Index); err != nil {
return err
}
c.emit(node, parser.OpIndex)
case *parser.SliceExpr:
if err := c.Compile(node.Expr); err != nil {
return err
}
if node.Low != nil {
if err := c.Compile(node.Low); err != nil {
return err
}
} else {
c.emit(node, parser.OpNull)
}
if node.High != nil {
if err := c.Compile(node.High); err != nil {
return err
}
} else {
c.emit(node, parser.OpNull)
}
c.emit(node, parser.OpSliceIndex)
case *parser.FuncLit:
c.enterScope()
for _, p := range node.Type.Params.List {
s := c.symbolTable.Define(p.Name)
// function arguments is not assigned directly.
s.LocalAssigned = true
}
if err := c.Compile(node.Body); err != nil {
return err
}
// code optimization
c.optimizeFunc(node)
freeSymbols := c.symbolTable.FreeSymbols()
numLocals := c.symbolTable.MaxSymbols()
instructions, sourceMap := c.leaveScope()
for _, s := range freeSymbols {
switch s.Scope {
case ScopeLocal:
if !s.LocalAssigned {
// Here, the closure is capturing a local variable that's
// not yet assigned its value. One example is a local
// recursive function:
//
// func() {
// foo := func(x) {
// // ..
// return foo(x-1)
// }
// }
//
// which translate into
//
// 0000 GETL 0
// 0002 CLOSURE ? 1
// 0006 DEFL 0
//
// . So the local variable (0) is being captured before
// it's assigned the value.
//
// Solution is to transform the code into something like
// this:
//
// func() {
// foo := undefined
// foo = func(x) {
// // ..
// return foo(x-1)
// }
// }
//
// that is equivalent to
//
// 0000 NULL
// 0001 DEFL 0
// 0003 GETL 0
// 0005 CLOSURE ? 1
// 0009 SETL 0
//
c.emit(node, parser.OpNull)
c.emit(node, parser.OpDefineLocal, s.Index)
s.LocalAssigned = true
}
c.emit(node, parser.OpGetLocalPtr, s.Index)
case ScopeFree:
c.emit(node, parser.OpGetFreePtr, s.Index)
}
}
compiledFunction := &CompiledFunction{
Instructions: instructions,
NumLocals: numLocals,
NumParameters: len(node.Type.Params.List),
VarArgs: node.Type.Params.VarArgs,
SourceMap: sourceMap,
}
if len(freeSymbols) > 0 {
c.emit(node, parser.OpClosure,
c.addConstant(compiledFunction), len(freeSymbols))
} else {
c.emit(node, parser.OpConstant, c.addConstant(compiledFunction))
}
case *parser.ReturnStmt:
if c.symbolTable.Parent(true) == nil {
// outside the function
return c.errorf(node, "return not allowed outside function")
}
if node.Result == nil {
c.emit(node, parser.OpReturn, 0)
} else {
if err := c.Compile(node.Result); err != nil {
return err
}
c.emit(node, parser.OpReturn, 1)
}
case *parser.CallExpr:
if err := c.Compile(node.Func); err != nil {
return err
}
for _, arg := range node.Args {
if err := c.Compile(arg); err != nil {
return err
}
}
ellipsis := 0
if node.Ellipsis.IsValid() {
ellipsis = 1
}
c.emit(node, parser.OpCall, len(node.Args), ellipsis)
case *parser.ImportExpr:
if node.ModuleName == "" {
return c.errorf(node, "empty module name")
}
if mod := c.modules.Get(node.ModuleName); mod != nil {
v, err := mod.Import(node.ModuleName)
if err != nil {
return err
}
switch v := v.(type) {
case []byte: // module written in Tengo
compiled, err := c.compileModule(node,
node.ModuleName, v, false)
if err != nil {
return err
}
c.emit(node, parser.OpConstant, c.addConstant(compiled))
c.emit(node, parser.OpCall, 0, 0)
case Object: // builtin module
c.emit(node, parser.OpConstant, c.addConstant(v))
default:
panic(fmt.Errorf("invalid import value type: %T", v))
}
} else if c.allowFileImport {
moduleName := node.ModuleName
modulePath, err := c.getPathModule(moduleName)
if err != nil {
return c.errorf(node, "module file path error: %s",
err.Error())
}
moduleSrc, err := ioutil.ReadFile(modulePath)
if err != nil {
return c.errorf(node, "module file read error: %s",
err.Error())
}
compiled, err := c.compileModule(node, modulePath, moduleSrc, true)
if err != nil {
return err
}
c.emit(node, parser.OpConstant, c.addConstant(compiled))
c.emit(node, parser.OpCall, 0, 0)
} else {
return c.errorf(node, "module '%s' not found", node.ModuleName)
}
case *parser.ExportStmt:
// export statement must be in top-level scope
if c.scopeIndex != 0 {
return c.errorf(node, "export not allowed inside function")
}
// export statement is simply ignore when compiling non-module code
if c.parent == nil {
break
}
if err := c.Compile(node.Result); err != nil {
return err
}
c.emit(node, parser.OpImmutable)
c.emit(node, parser.OpReturn, 1)
case *parser.ErrorExpr:
if err := c.Compile(node.Expr); err != nil {
return err
}
c.emit(node, parser.OpError)
case *parser.ImmutableExpr:
if err := c.Compile(node.Expr); err != nil {
return err
}
c.emit(node, parser.OpImmutable)
case *parser.CondExpr:
if err := c.Compile(node.Cond); err != nil {
return err
}
// first jump placeholder
jumpPos1 := c.emit(node, parser.OpJumpFalsy, 0)
if err := c.Compile(node.True); err != nil {
return err
}
// second jump placeholder
jumpPos2 := c.emit(node, parser.OpJump, 0)
// update first jump offset
curPos := len(c.currentInstructions())
c.changeOperand(jumpPos1, curPos)
if err := c.Compile(node.False); err != nil {
return err
}
// update second jump offset
curPos = len(c.currentInstructions())
c.changeOperand(jumpPos2, curPos)
}
return nil
}
// Bytecode returns a compiled bytecode.
func (c *Compiler) Bytecode() *Bytecode {
return &Bytecode{
FileSet: c.file.Set(),
MainFunction: &CompiledFunction{
Instructions: append(c.currentInstructions(), parser.OpSuspend),
SourceMap: c.currentSourceMap(),
},
Constants: c.constants,
}
}
// EnableFileImport enables or disables module loading from local files.
// Local file modules are disabled by default.
func (c *Compiler) EnableFileImport(enable bool) {
c.allowFileImport = enable
}
// SetImportDir sets the initial import directory path for file imports.
func (c *Compiler) SetImportDir(dir string) {
c.importDir = dir
}
// SetImportFileExt sets the extension name of the source file for loading
// local module files.
//
// Use this method if you want other source file extension than ".tengo".
//
// // this will search for *.tengo, *.foo, *.bar
// err := c.SetImportFileExt(".tengo", ".foo", ".bar")
//
// This function requires at least one argument, since it will replace the
// current list of extension name.
func (c *Compiler) SetImportFileExt(exts ...string) error {
if len(exts) == 0 {
return fmt.Errorf("missing arg: at least one argument is required")
}
for _, ext := range exts {
if ext != filepath.Ext(ext) || ext == "" {
return fmt.Errorf("invalid file extension: %s", ext)
}
}
c.importFileExt = exts // Replace the hole current extension list
return nil
}
// GetImportFileExt returns the current list of extension name.
// Thease are the complementary suffix of the source file to search and load
// local module files.
func (c *Compiler) GetImportFileExt() []string {
return c.importFileExt
}
func (c *Compiler) compileAssign(
node parser.Node,
lhs, rhs []parser.Expr,
op token.Token,
) error {
numLHS, numRHS := len(lhs), len(rhs)
if numLHS > 1 || numRHS > 1 {
return c.errorf(node, "tuple assignment not allowed")
}
// resolve and compile left-hand side
ident, selectors := resolveAssignLHS(lhs[0])
numSel := len(selectors)
if op == token.Define && numSel > 0 {
// using selector on new variable does not make sense
return c.errorf(node, "operator ':=' not allowed with selector")
}
_, isFunc := rhs[0].(*parser.FuncLit)
symbol, depth, exists := c.symbolTable.Resolve(ident, false)
if op == token.Define {
if depth == 0 && exists {
return c.errorf(node, "'%s' redeclared in this block", ident)
}
if isFunc {
symbol = c.symbolTable.Define(ident)
}
} else {
if !exists {
return c.errorf(node, "unresolved reference '%s'", ident)
}
}
// +=, -=, *=, /=
if op != token.Assign && op != token.Define {
if err := c.Compile(lhs[0]); err != nil {
return err
}
}
// compile RHSs
for _, expr := range rhs {
if err := c.Compile(expr); err != nil {
return err
}
}
if op == token.Define && !isFunc {
symbol = c.symbolTable.Define(ident)
}
switch op {
case token.AddAssign:
c.emit(node, parser.OpBinaryOp, int(token.Add))
case token.SubAssign:
c.emit(node, parser.OpBinaryOp, int(token.Sub))
case token.MulAssign:
c.emit(node, parser.OpBinaryOp, int(token.Mul))
case token.QuoAssign:
c.emit(node, parser.OpBinaryOp, int(token.Quo))
case token.RemAssign:
c.emit(node, parser.OpBinaryOp, int(token.Rem))
case token.AndAssign:
c.emit(node, parser.OpBinaryOp, int(token.And))
case token.OrAssign:
c.emit(node, parser.OpBinaryOp, int(token.Or))
case token.AndNotAssign:
c.emit(node, parser.OpBinaryOp, int(token.AndNot))
case token.XorAssign:
c.emit(node, parser.OpBinaryOp, int(token.Xor))
case token.ShlAssign:
c.emit(node, parser.OpBinaryOp, int(token.Shl))
case token.ShrAssign:
c.emit(node, parser.OpBinaryOp, int(token.Shr))
}
// compile selector expressions (right to left)
for i := numSel - 1; i >= 0; i-- {
if err := c.Compile(selectors[i]); err != nil {
return err
}
}
switch symbol.Scope {
case ScopeGlobal:
if numSel > 0 {
c.emit(node, parser.OpSetSelGlobal, symbol.Index, numSel)
} else {
c.emit(node, parser.OpSetGlobal, symbol.Index)
}
case ScopeLocal:
if numSel > 0 {
c.emit(node, parser.OpSetSelLocal, symbol.Index, numSel)
} else {
if op == token.Define && !symbol.LocalAssigned {
c.emit(node, parser.OpDefineLocal, symbol.Index)
} else {
c.emit(node, parser.OpSetLocal, symbol.Index)
}
}
// mark the symbol as local-assigned
symbol.LocalAssigned = true
case ScopeFree:
if numSel > 0 {
c.emit(node, parser.OpSetSelFree, symbol.Index, numSel)
} else {
c.emit(node, parser.OpSetFree, symbol.Index)
}
default:
panic(fmt.Errorf("invalid assignment variable scope: %s",
symbol.Scope))
}
return nil
}
func (c *Compiler) compileLogical(node *parser.BinaryExpr) error {
// left side term
if err := c.Compile(node.LHS); err != nil {
return err
}
// jump position
var jumpPos int
if node.Token == token.LAnd {
jumpPos = c.emit(node, parser.OpAndJump, 0)
} else {
jumpPos = c.emit(node, parser.OpOrJump, 0)
}
// right side term
if err := c.Compile(node.RHS); err != nil {
return err
}
c.changeOperand(jumpPos, len(c.currentInstructions()))
return nil
}
func (c *Compiler) compileForStmt(stmt *parser.ForStmt) error {
c.symbolTable = c.symbolTable.Fork(true)
defer func() {
c.symbolTable = c.symbolTable.Parent(false)
}()
// init statement
if stmt.Init != nil {
if err := c.Compile(stmt.Init); err != nil {
return err
}
}
// pre-condition position
preCondPos := len(c.currentInstructions())
// condition expression
postCondPos := -1
if stmt.Cond != nil {
if err := c.Compile(stmt.Cond); err != nil {
return err
}
// condition jump position
postCondPos = c.emit(stmt, parser.OpJumpFalsy, 0)
}
// enter loop
loop := c.enterLoop()
// body statement
if err := c.Compile(stmt.Body); err != nil {
c.leaveLoop()
return err
}
c.leaveLoop()
// post-body position
postBodyPos := len(c.currentInstructions())
// post statement
if stmt.Post != nil {
if err := c.Compile(stmt.Post); err != nil {
return err
}
}
// back to condition
c.emit(stmt, parser.OpJump, preCondPos)
// post-statement position
postStmtPos := len(c.currentInstructions())
if postCondPos >= 0 {
c.changeOperand(postCondPos, postStmtPos)
}
// update all break/continue jump positions
for _, pos := range loop.Breaks {
c.changeOperand(pos, postStmtPos)
}
for _, pos := range loop.Continues {
c.changeOperand(pos, postBodyPos)
}
return nil
}
func (c *Compiler) compileForInStmt(stmt *parser.ForInStmt) error {
c.symbolTable = c.symbolTable.Fork(true)
defer func() {
c.symbolTable = c.symbolTable.Parent(false)
}()
// for-in statement is compiled like following:
//
// for :it := iterator(iterable); :it.next(); {
// k, v := :it.get() // DEFINE operator
//
// ... body ...
// }
//
// ":it" is a local variable but it will not conflict with other user variables
// because character ":" is not allowed in the variable names.
// init
// :it = iterator(iterable)
itSymbol := c.symbolTable.Define(":it")
if err := c.Compile(stmt.Iterable); err != nil {
return err
}
c.emit(stmt, parser.OpIteratorInit)
if itSymbol.Scope == ScopeGlobal {
c.emit(stmt, parser.OpSetGlobal, itSymbol.Index)
} else {
c.emit(stmt, parser.OpDefineLocal, itSymbol.Index)
}
// pre-condition position
preCondPos := len(c.currentInstructions())
// condition
// :it.HasMore()
if itSymbol.Scope == ScopeGlobal {
c.emit(stmt, parser.OpGetGlobal, itSymbol.Index)
} else {
c.emit(stmt, parser.OpGetLocal, itSymbol.Index)
}
c.emit(stmt, parser.OpIteratorNext)
// condition jump position
postCondPos := c.emit(stmt, parser.OpJumpFalsy, 0)
// enter loop
loop := c.enterLoop()
// assign key variable
if stmt.Key.Name != "_" {
keySymbol := c.symbolTable.Define(stmt.Key.Name)
if itSymbol.Scope == ScopeGlobal {
c.emit(stmt, parser.OpGetGlobal, itSymbol.Index)
} else {
c.emit(stmt, parser.OpGetLocal, itSymbol.Index)
}
c.emit(stmt, parser.OpIteratorKey)
if keySymbol.Scope == ScopeGlobal {
c.emit(stmt, parser.OpSetGlobal, keySymbol.Index)
} else {
keySymbol.LocalAssigned = true
c.emit(stmt, parser.OpDefineLocal, keySymbol.Index)
}
}
// assign value variable
if stmt.Value.Name != "_" {
valueSymbol := c.symbolTable.Define(stmt.Value.Name)
if itSymbol.Scope == ScopeGlobal {
c.emit(stmt, parser.OpGetGlobal, itSymbol.Index)
} else {
c.emit(stmt, parser.OpGetLocal, itSymbol.Index)
}
c.emit(stmt, parser.OpIteratorValue)
if valueSymbol.Scope == ScopeGlobal {
c.emit(stmt, parser.OpSetGlobal, valueSymbol.Index)
} else {
valueSymbol.LocalAssigned = true
c.emit(stmt, parser.OpDefineLocal, valueSymbol.Index)
}
}
// body statement
if err := c.Compile(stmt.Body); err != nil {
c.leaveLoop()
return err
}
c.leaveLoop()
// post-body position
postBodyPos := len(c.currentInstructions())
// back to condition
c.emit(stmt, parser.OpJump, preCondPos)
// post-statement position
postStmtPos := len(c.currentInstructions())
c.changeOperand(postCondPos, postStmtPos)
// update all break/continue jump positions
for _, pos := range loop.Breaks {
c.changeOperand(pos, postStmtPos)
}
for _, pos := range loop.Continues {
c.changeOperand(pos, postBodyPos)
}
return nil
}
func (c *Compiler) checkCyclicImports(
node parser.Node,
modulePath string,
) error {
if c.modulePath == modulePath {
return c.errorf(node, "cyclic module import: %s", modulePath)
} else if c.parent != nil {
return c.parent.checkCyclicImports(node, modulePath)
}
return nil
}
func (c *Compiler) compileModule(
node parser.Node,
modulePath string,
src []byte,
isFile bool,
) (*CompiledFunction, error) {
if err := c.checkCyclicImports(node, modulePath); err != nil {
return nil, err
}
compiledModule, exists := c.loadCompiledModule(modulePath)