private bool Compile(List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList, ProtoCore.Core core, ProtoCore.CompileTime.Context context)
        {
            bool buildSucceeded = false;
            if (astList.Count <= 0)
            {
                // Nothing to compile
                buildSucceeded = true;
            }
            else
            {
                try
                {
                    //defining the global Assoc block that wraps the entire .ds source file
                    ProtoCore.LanguageCodeBlock globalBlock = new ProtoCore.LanguageCodeBlock();
                    globalBlock.language = ProtoCore.Language.kAssociative;
                    globalBlock.body = string.Empty;
                    //the wrapper block can be given a unique id to identify it as the global scope
                    globalBlock.id = ProtoCore.LanguageCodeBlock.OUTERMOST_BLOCK_ID;


                    //passing the global Assoc wrapper block to the compiler
                    context.SetData(string.Empty, new Dictionary<string, object>(), null);
                    ProtoCore.Language id = globalBlock.language;


                    ProtoCore.AST.AssociativeAST.CodeBlockNode codeblock = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
                    codeblock.Body.AddRange(astList);

                    int blockId = ProtoCore.DSASM.Constants.kInvalidIndex;
                    core.Compilers[id].Compile(out blockId, null, globalBlock, context, EventSink, codeblock);

                    core.BuildStatus.ReportBuildResult();

                    buildSucceeded = core.BuildStatus.BuildSucceeded;
                }
                catch (Exception ex)
                {
                    Console.WriteLine(ex.ToString());
                }
            }

            return buildSucceeded;
        }

        public void TestCodeGenDS_FunctionDefNode1()
        {
            ProtoCore.AST.AssociativeAST.CodeBlockNode cbn = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignment1 = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.assign);
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnExpr = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.add);

            var returnIdent = new ProtoCore.AST.AssociativeAST.IdentifierNode("return");
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnNode = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(returnIdent, returnExpr);
            cbn.Body.Add(assignment1);
            cbn.Body.Add(returnNode);
            ///
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
            funcDefNode.Name = "foo";
            funcDefNode.FunctionBody = cbn;
            /* def foo()
             * {
             *   b = 10;
             *   return = b + 10;
             * }*/
            List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();

        public void TestRoundTrip_FunctionDefAndCall_01()
        {

            //=================================
            // 1. Build AST 
            // 2. Execute AST and verify
            // 3. Convert AST to source
            // 4. Execute source and verify
            //=================================
            int result1 = 20;
            ExecutionMirror mirror = null;



            // 1. Build the AST tree

            //  def foo()
            //  {
            //    b = 10;
            //    return = b + 10;
            //  }
            //  
            //  x = foo();
            ProtoCore.AST.AssociativeAST.CodeBlockNode cbn = new ProtoCore.AST.AssociativeAST.CodeBlockNode();


            // Build the function body
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignment1 = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.assign);
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnExpr = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.add);

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnNode = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode(ProtoCore.DSDefinitions.Keyword.Return),
                returnExpr,
                ProtoCore.DSASM.Operator.assign);
            cbn.Body.Add(assignment1);
            cbn.Body.Add(returnNode);


            // Build the function definition foo
            const string functionName = "foo";
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
            funcDefNode.Name = functionName;
            funcDefNode.FunctionBody = cbn;

            // Function Return type
            ProtoCore.Type returnType = new ProtoCore.Type();
            returnType.Initialize();
            returnType.UID = (int)ProtoCore.PrimitiveType.Var;
            returnType.Name = ProtoCore.DSDefinitions.Keyword.Var;
            funcDefNode.ReturnType = returnType;

            List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();
            astList.Add(funcDefNode);

            // Build the statement that calls the function foo
            ProtoCore.AST.AssociativeAST.FunctionCallNode functionCall = new ProtoCore.AST.AssociativeAST.FunctionCallNode();
            functionCall.Function = new ProtoCore.AST.AssociativeAST.IdentifierNode(functionName);

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode callstmt = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("x"),
                functionCall,
                ProtoCore.DSASM.Operator.assign);
            astList.Add(callstmt);


            // 2. Execute AST and verify
            mirror = thisTest.RunASTSource(astList);
            Assert.IsTrue((Int64)mirror.GetValue("x").Payload == result1);


            // 3. Convert AST to source
            ProtoCore.CodeGenDS codegenDS = new ProtoCore.CodeGenDS(astList);
            string code = codegenDS.GenerateCode();

            Console.WriteLine(code);

            // 4. Execute source and verify
            mirror = thisTest.RunScriptSource(code);
            Assert.IsTrue((Int64)mirror.GetValue("x").Payload == result1);

        }

        public void TestRoundTrip_ClassDecl_MemFunctionCall_01()
        {
            int result1 = 20;
            ExecutionMirror mirror = null;

            List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();

            // Create an exact copy of the AST list to pass to the source conversion
            // This needs to be done because the astlist to be run will be SSA'd on the AST execution run
            List<ProtoCore.AST.AssociativeAST.AssociativeNode> astListcopy = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();

            // 1. Build AST

            //  class bar
            //  {
            //       f : var
            //       def foo (b:int)
            //       {
            //           b = 10;
            //           return = b + 10;
            //       }
            //  }
            //
            //  p = bar.bar();
            //  a = p.foo();


            ProtoCore.AST.AssociativeAST.CodeBlockNode cbn = new ProtoCore.AST.AssociativeAST.CodeBlockNode();


            // Build the function body
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignment1 = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.assign);
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnExpr = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.add);

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnNode = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode(ProtoCore.DSDefinitions.Keyword.Return),
                returnExpr,
                ProtoCore.DSASM.Operator.assign);
            cbn.Body.Add(assignment1);
            cbn.Body.Add(returnNode);


            // Build the function definition foo
            const string functionName = "foo";
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
            funcDefNode.Name = functionName;
            funcDefNode.FunctionBody = cbn;

            // Function Return type
            ProtoCore.Type returnType = new ProtoCore.Type();
            returnType.Initialize();
            returnType.UID = (int)ProtoCore.PrimitiveType.Var;
            returnType.Name = ProtoCore.DSDefinitions.Keyword.Var;
            funcDefNode.ReturnType = returnType;

            // Create the class node AST
            ProtoCore.AST.AssociativeAST.ClassDeclNode classDefNode = new ProtoCore.AST.AssociativeAST.ClassDeclNode();
            classDefNode.ClassName = "bar";

            // Add the member function 'foo'
            classDefNode.Procedures.Add(funcDefNode);


            // Create the property AST
            ProtoCore.AST.AssociativeAST.VarDeclNode varDeclNode = new ProtoCore.AST.AssociativeAST.VarDeclNode();
            varDeclNode.Name = "f";
            varDeclNode.NameNode = new ProtoCore.AST.AssociativeAST.IdentifierNode("f");
            varDeclNode.ArgumentType = new ProtoCore.Type()
            {
                Name = "int",
                rank = 0,
                UID = (int)ProtoCore.PrimitiveType.Integer
            };
            classDefNode.Variables.Add(varDeclNode);


            // Add the constructed class AST
            astList.Add(classDefNode);
            astListcopy.Add(new ProtoCore.AST.AssociativeAST.ClassDeclNode(classDefNode));


            // p = bar.bar();
            ProtoCore.AST.AssociativeAST.FunctionCallNode constructorCall = new ProtoCore.AST.AssociativeAST.FunctionCallNode();
            constructorCall.Function = new ProtoCore.AST.AssociativeAST.IdentifierNode("bar");

            ProtoCore.AST.AssociativeAST.IdentifierListNode identListConstrcctorCall = new ProtoCore.AST.AssociativeAST.IdentifierListNode();
            identListConstrcctorCall.LeftNode = new ProtoCore.AST.AssociativeAST.IdentifierNode("bar");
            identListConstrcctorCall.RightNode = constructorCall;

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode stmtInitClass = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("p"),
                identListConstrcctorCall,
                ProtoCore.DSASM.Operator.assign);

//.........这里部分代码省略.........

        // The following methods are used to insert methods to the bottom of the AST and convert operator to these method calls
        // to support replication on operators
        private static void InsertUnaryOperationMethod(ProtoLanguage.CompileStateTracker compileState, ProtoCore.AST.Node root, UnaryOperator op, PrimitiveType r, PrimitiveType operand)
        {
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
            funcDefNode.access = ProtoCore.DSASM.AccessSpecifier.kPublic;
            funcDefNode.IsAssocOperator = true;
            funcDefNode.IsBuiltIn = true;
            funcDefNode.Name = Op.GetUnaryOpFunction(op);
            funcDefNode.ReturnType = new ProtoCore.Type() { Name = compileState.TypeSystem.GetType((int)r), UID = (int)r };
            ProtoCore.AST.AssociativeAST.ArgumentSignatureNode args = new ProtoCore.AST.AssociativeAST.ArgumentSignatureNode();
            args.AddArgument(new ProtoCore.AST.AssociativeAST.VarDeclNode()
            {
            memregion = ProtoCore.DSASM.MemoryRegion.kMemStack,
            access = ProtoCore.DSASM.AccessSpecifier.kPublic,
            NameNode = BuildAssocIdentifier(compileState, "%param"),
            ArgumentType = new ProtoCore.Type { Name = compileState.TypeSystem.GetType((int)operand), UID = (int)operand }
            });
            funcDefNode.Singnature = args;

            ProtoCore.AST.AssociativeAST.CodeBlockNode body = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
            ProtoCore.AST.AssociativeAST.IdentifierNode _return = BuildAssocIdentifier(compileState, ProtoCore.DSDefinitions.Keyword.Return, ProtoCore.PrimitiveType.kTypeReturn);
            ProtoCore.AST.AssociativeAST.IdentifierNode param = BuildAssocIdentifier(compileState, "%param");
            body.Body.Add(new ProtoCore.AST.AssociativeAST.BinaryExpressionNode() { LeftNode = _return, Optr = ProtoCore.DSASM.Operator.assign, RightNode = new ProtoCore.AST.AssociativeAST.UnaryExpressionNode() { Expression = param, Operator = op } });
            funcDefNode.FunctionBody = body;
            (root as ProtoCore.AST.AssociativeAST.CodeBlockNode).Body.Add(funcDefNode);
        }

        private static void InsertInlineConditionOperationMethod(ProtoLanguage.CompileStateTracker compileState, ProtoCore.AST.Node root, PrimitiveType condition, PrimitiveType r)
        {
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
            funcDefNode.access = ProtoCore.DSASM.AccessSpecifier.kPublic;
            funcDefNode.Name = ProtoCore.DSASM.Constants.kInlineCondition;
            funcDefNode.ReturnType = new ProtoCore.Type() { Name = compileState.TypeSystem.GetType((int)r), UID = (int)r };
            ProtoCore.AST.AssociativeAST.ArgumentSignatureNode args = new ProtoCore.AST.AssociativeAST.ArgumentSignatureNode();
            args.AddArgument(new ProtoCore.AST.AssociativeAST.VarDeclNode()
            {
            memregion = ProtoCore.DSASM.MemoryRegion.kMemStack,
            access = ProtoCore.DSASM.AccessSpecifier.kPublic,
            NameNode = BuildAssocIdentifier(compileState, "%condition"),
            ArgumentType = new ProtoCore.Type { Name = compileState.TypeSystem.GetType((int)condition), UID = (int)condition }
            });
            args.AddArgument(new ProtoCore.AST.AssociativeAST.VarDeclNode()
            {
            memregion = ProtoCore.DSASM.MemoryRegion.kMemStack,
            access = ProtoCore.DSASM.AccessSpecifier.kPublic,
            NameNode = BuildAssocIdentifier(compileState, "%trueExp"),
            ArgumentType = new ProtoCore.Type { Name = compileState.TypeSystem.GetType((int)r), UID = (int)r }
            });
            args.AddArgument(new ProtoCore.AST.AssociativeAST.VarDeclNode()
            {
            memregion = ProtoCore.DSASM.MemoryRegion.kMemStack,
            access = ProtoCore.DSASM.AccessSpecifier.kPublic,
            NameNode = BuildAssocIdentifier(compileState, "%falseExp"),
            ArgumentType = new ProtoCore.Type { Name = compileState.TypeSystem.GetType((int)r), UID = (int)r }
            });
            funcDefNode.Singnature = args;

            ProtoCore.AST.AssociativeAST.CodeBlockNode body = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
            ProtoCore.AST.AssociativeAST.IdentifierNode _return = BuildAssocIdentifier(compileState, ProtoCore.DSDefinitions.Keyword.Return, ProtoCore.PrimitiveType.kTypeReturn);
            ProtoCore.AST.AssociativeAST.IdentifierNode con = BuildAssocIdentifier(compileState, "%condition");
            ProtoCore.AST.AssociativeAST.IdentifierNode t = BuildAssocIdentifier(compileState, "%trueExp");
            ProtoCore.AST.AssociativeAST.IdentifierNode f = BuildAssocIdentifier(compileState, "%falseExp");

            body.Body.Add(new ProtoCore.AST.AssociativeAST.BinaryExpressionNode() { LeftNode = _return, Optr = Operator.assign, RightNode = new ProtoCore.AST.AssociativeAST.InlineConditionalNode() { ConditionExpression = con, TrueExpression = t, FalseExpression = f } });
            funcDefNode.FunctionBody = body;
            (root as ProtoCore.AST.AssociativeAST.CodeBlockNode).Body.Add(funcDefNode);
        }

        public void TestProtoASTExecute_ArrayIndex_LHS_Assign04()
        {
            List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();

            // a = {1, 2, 3, 4};
            int[] input = { 1, 2, 3, 4 };
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode declareNodeA = CreateDeclareArrayNode("a", input);
            astList.Add(declareNodeA);

            // b = 4;
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode declareNodeB = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(4),
                ProtoCore.DSASM.Operator.assign);
            astList.Add(declareNodeB);

            // def foo(){
            //    return = -2;
            // }
            ProtoCore.AST.AssociativeAST.CodeBlockNode cbn = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnNode = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode(ProtoCore.DSDefinitions.Keyword.Return),
                new ProtoCore.AST.AssociativeAST.IntNode(-2),
                ProtoCore.DSASM.Operator.assign);
            cbn.Body.Add(returnNode);

            // Build the function definition foo
            const string functionName = "foo";
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode() {
                Name = functionName,
                FunctionBody = cbn };

            // Function Return Type
            ProtoCore.Type returnType = new ProtoCore.Type();
            returnType.Initialize();
            returnType.UID = (int)ProtoCore.PrimitiveType.Var;
            returnType.Name = ProtoCore.DSDefinitions.Keyword.Var;
            funcDefNode.ReturnType = returnType;

            astList.Add(funcDefNode);

            // a[b + foo()] = -1;
            ProtoCore.AST.AssociativeAST.FunctionCallNode functionCall = new ProtoCore.AST.AssociativeAST.FunctionCallNode();
            functionCall.Function = new ProtoCore.AST.AssociativeAST.IdentifierNode(functionName);

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode operation1 = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                functionCall,
                ProtoCore.DSASM.Operator.add);

            ProtoCore.AST.AssociativeAST.IdentifierNode nodeALHS = new ProtoCore.AST.AssociativeAST.IdentifierNode("a");
            nodeALHS.ArrayDimensions = new ProtoCore.AST.AssociativeAST.ArrayNode();
            nodeALHS.ArrayDimensions.Expr = operation1;

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode nodeALHSAssignment = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                nodeALHS,
                new ProtoCore.AST.AssociativeAST.IntNode(-1),
                ProtoCore.DSASM.Operator.assign);

            astList.Add(nodeALHSAssignment);

            // Verify the results
            ExecutionMirror mirror = thisTest.RunASTSource(astList);
            thisTest.Verify("a", new [] { 1, 2, -1, 4});
        }

        public void TestProtoASTExecute_FunctionDefAndCall_01()
        {
            //  def foo()
            //  {
            //    b = 10;
            //    return = b + 10;
            //  }
            //  
            //  x = foo();

            ProtoCore.AST.AssociativeAST.CodeBlockNode cbn = new ProtoCore.AST.AssociativeAST.CodeBlockNode();


            // Build the function body
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignment1 = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.assign);
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnExpr = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.add);

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnNode = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode(ProtoCore.DSDefinitions.Keyword.Return),
                returnExpr,
                ProtoCore.DSASM.Operator.assign);
            cbn.Body.Add(assignment1);
            cbn.Body.Add(returnNode);


            // Build the function definition foo
            const string functionName = "foo";
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
            funcDefNode.Name = functionName;
            funcDefNode.FunctionBody = cbn;

            // Function Return type
            ProtoCore.Type returnType = new ProtoCore.Type();
            returnType.Initialize();
            returnType.UID = (int)ProtoCore.PrimitiveType.Var;
            returnType.Name = ProtoCore.DSDefinitions.Keyword.Var;
            funcDefNode.ReturnType = returnType;

            List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();
            astList.Add(funcDefNode);

            // Build the statement that calls the function foo
            ProtoCore.AST.AssociativeAST.FunctionCallNode functionCall = new ProtoCore.AST.AssociativeAST.FunctionCallNode();
            functionCall.Function = new ProtoCore.AST.AssociativeAST.IdentifierNode(functionName);

            ProtoCore.AST.AssociativeAST.BinaryExpressionNode callstmt = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("x"),
                functionCall,
                ProtoCore.DSASM.Operator.assign);
            astList.Add(callstmt);


            ExecutionMirror mirror = thisTest.RunASTSource(astList);
            Obj o = mirror.GetValue("x");
            Assert.IsTrue((Int64)o.Payload == 20);

        }

        public override bool Compile(ProtoLanguage.CompileStateTracker compileState, out int blockId, ProtoCore.DSASM.CodeBlock parentBlock, ProtoCore.LanguageCodeBlock langBlock, ProtoCore.CompileTime.Context callContext, ProtoCore.DebugServices.EventSink sink, ProtoCore.AST.Node codeBlockNode, ProtoCore.AssociativeGraph.GraphNode graphNode = null)
        {
            Debug.Assert(langBlock != null);
            blockId = ProtoCore.DSASM.Constants.kInvalidIndex;

            bool buildSucceeded = false;
            bool isLangSignValid = compileState.Langverify.Verify(langBlock);

            if (isLangSignValid)
            {
                try
                {
                    ProtoCore.CodeGen oldCodegen = compileState.assocCodegen;

                    if (ProtoCore.DSASM.InterpreterMode.kNormal == compileState.ExecMode)
                    {
                        if ((compileState.IsParsingPreloadedAssembly || compileState.IsParsingCodeBlockNode) && parentBlock == null)
                        {
                            if (compileState.CodeBlockList.Count == 0)
                            {
                                compileState.assocCodegen = new ProtoAssociative.CodeGen(compileState, parentBlock);
                            }
                            else
                            {
                                // We reuse the existing toplevel CodeBlockList's for the procedureTable's
                                // by calling this overloaded constructor - pratapa
                                compileState.assocCodegen = new ProtoAssociative.CodeGen(compileState);
                            }
                        }
                        else
                            compileState.assocCodegen = new ProtoAssociative.CodeGen(compileState, parentBlock);
                    }

                    if (null != compileState.AssocNode)
                    {
                        ProtoCore.AST.AssociativeAST.CodeBlockNode cnode = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
                        cnode.Body.Add(compileState.AssocNode as ProtoCore.AST.AssociativeAST.AssociativeNode);

                        compileState.assocCodegen.context = callContext;

                        blockId = compileState.assocCodegen.Emit((cnode as ProtoCore.AST.AssociativeAST.CodeBlockNode), graphNode);
                    }
                    else
                    {
                        //if not null, Compile has been called from DfsTraverse. No parsing is needed.
                        if (codeBlockNode == null)
                        {
                            System.IO.MemoryStream memstream = new System.IO.MemoryStream(System.Text.Encoding.UTF8.GetBytes(langBlock.body));
                            ProtoCore.DesignScriptParser.Scanner s = new ProtoCore.DesignScriptParser.Scanner(memstream);
                            ProtoCore.DesignScriptParser.Parser p = new ProtoCore.DesignScriptParser.Parser(s, compileState, compileState.builtInsLoaded);
                            p.Parse();

                            // TODO Jun: Set this flag inside a persistent object
                            compileState.builtInsLoaded = true;

                            codeBlockNode = p.root;

                            //compileState.AstNodeList = p.GetParsedASTList(codeBlockNode as ProtoCore.AST.AssociativeAST.CodeBlockNode);
                            List<ProtoCore.AST.Node> astNodes = ProtoCore.Utils.ParserUtils.GetAstNodes(codeBlockNode);
                            compileState.AstNodeList = astNodes;
                        }
                        else
                        {
                            if (!compileState.builtInsLoaded)
                            {
                                // Load the built-in methods manually
                                ProtoCore.Utils.CoreUtils.InsertPredefinedAndBuiltinMethods(compileState, codeBlockNode, false);
                                compileState.builtInsLoaded = true;
                            }
                        }

                        compileState.assocCodegen.context = callContext;

                        //Temporarily change the code block for code gen to the current block, in the case it is an imperative block
                        //CodeGen for ProtoImperative is modified to passing in the core object.
                        ProtoCore.DSASM.CodeBlock oldCodeBlock = compileState.assocCodegen.codeBlock;
                        if (compileState.ExecMode == ProtoCore.DSASM.InterpreterMode.kExpressionInterpreter)
                        {
                            int tempBlockId = compileState.GetCurrentBlockId();

                            ProtoCore.DSASM.CodeBlock tempCodeBlock = compileState.GetCodeBlock(compileState.CodeBlockList, tempBlockId);
                            while (null != tempCodeBlock && tempCodeBlock.blockType != ProtoCore.DSASM.CodeBlockType.kLanguage)
                            {
                                tempCodeBlock = tempCodeBlock.parent;
                            }
                            compileState.assocCodegen.codeBlock = tempCodeBlock;
                        }
                        compileState.assocCodegen.codeBlock.EventSink = sink;
                        if (compileState.BuildStatus.Errors.Count == 0) //if there is syntax error, no build needed
                        {
                             blockId = compileState.assocCodegen.Emit((codeBlockNode as ProtoCore.AST.AssociativeAST.CodeBlockNode), graphNode);
                        }
                        if (compileState.ExecMode == ProtoCore.DSASM.InterpreterMode.kExpressionInterpreter)
                        {
                            blockId = compileState.assocCodegen.codeBlock.codeBlockId;
                            //Restore the code block.
                            compileState.assocCodegen.codeBlock = oldCodeBlock;
                        }
                    }

//.........这里部分代码省略.........

        public ProtoLanguage.CompileStateTracker Compile(List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList, ProtoCore.Core core, out int blockId)
        {
            ProtoLanguage.CompileStateTracker compileState = ProtoScript.CompilerUtils.BuildDefaultCompilerState();

            compileState.ExecMode = ProtoCore.DSASM.InterpreterMode.kNormal;

            blockId = ProtoCore.DSASM.Constants.kInvalidIndex;
            try
            {
                //defining the global Assoc block that wraps the entire .ds source file
                ProtoCore.LanguageCodeBlock globalBlock = new ProtoCore.LanguageCodeBlock();
                globalBlock.language = ProtoCore.Language.kAssociative;
                globalBlock.body = string.Empty;
                //the wrapper block can be given a unique id to identify it as the global scope
                globalBlock.id = ProtoCore.LanguageCodeBlock.OUTERMOST_BLOCK_ID;

                //passing the global Assoc wrapper block to the compiler
                ProtoCore.CompileTime.Context context = new ProtoCore.CompileTime.Context();
                ProtoCore.Language id = globalBlock.language;

                ProtoCore.AST.AssociativeAST.CodeBlockNode codeblock = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
                codeblock.Body.AddRange(astList);

                compileState.Executives[id].Compile(compileState, out blockId, null, globalBlock, context, EventSink, codeblock);

                compileState.BuildStatus.ReportBuildResult();

                int errors = 0;
                int warnings = 0;
                compileState.compileSucceeded = compileState.BuildStatus.GetBuildResult(out errors, out warnings);
            }
            catch (Exception ex)
            {
                Console.WriteLine(ex.ToString());
            }

            return compileState;
        }

        public override bool Compile(out int blockId, ProtoCore.DSASM.CodeBlock parentBlock, ProtoCore.LanguageCodeBlock langBlock, ProtoCore.CompileTime.Context callContext, ProtoCore.DebugServices.EventSink sink = null, ProtoCore.AST.Node codeBlockNode = null, ProtoCore.AssociativeGraph.GraphNode graphNode = null)
        {
            Validity.Assert(langBlock != null);
            blockId = ProtoCore.DSASM.Constants.kInvalidIndex;

            bool buildSucceeded = false;

            try
            {
                ProtoCore.CodeGen oldCodegen = core.assocCodegen;

                if (ProtoCore.DSASM.InterpreterMode.Normal == core.Options.RunMode)
                {
                    if ((core.IsParsingPreloadedAssembly || core.IsParsingCodeBlockNode) && parentBlock == null)
                    {
                        if (core.CodeBlockList.Count == 0)
                        {
                            core.assocCodegen = new ProtoAssociative.CodeGen(core, callContext, parentBlock);
                        }
                        else
                        {
                            // We reuse the existing toplevel CodeBlockList's for the procedureTable's 
                            // by calling this overloaded constructor - pratapa
                            core.assocCodegen = new ProtoAssociative.CodeGen(core);
                        }
                    }
                    else
                        core.assocCodegen = new ProtoAssociative.CodeGen(core, callContext, parentBlock);
                }

                if (null != core.AssocNode)
                {
                    ProtoCore.AST.AssociativeAST.CodeBlockNode cnode = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
                    cnode.Body.Add(core.AssocNode as ProtoCore.AST.AssociativeAST.AssociativeNode);

                    core.assocCodegen.context = callContext;

                    blockId = core.assocCodegen.Emit((cnode as ProtoCore.AST.AssociativeAST.CodeBlockNode), graphNode);
                }
                else
                {
                    //if not null, Compile has been called from DfsTraverse. No parsing is needed. 
                    if (codeBlockNode == null)
                    {
                        var parseResult = ParserUtils.ParseWithCore(langBlock.Code, core);
                        // TODO Jun: Set this flag inside a persistent object
                        core.builtInsLoaded = true;
                        codeBlockNode = parseResult.CodeBlockNode;
                    }
                    else
                    {
                        if (!core.builtInsLoaded)
                        {
                            // Load the built-in methods manually
                            CoreUtils.InsertPredefinedAndBuiltinMethods(core, codeBlockNode as ProtoCore.AST.AssociativeAST.CodeBlockNode);
                            core.builtInsLoaded = true;
                        }
                    }

                    core.assocCodegen.context = callContext;

                    //Temporarily change the code block for code gen to the current block, in the case it is an imperative block
                    //CodeGen for ProtoImperative is modified to passing in the core object.
                    ProtoCore.DSASM.CodeBlock oldCodeBlock = core.assocCodegen.codeBlock;
                    if (core.Options.RunMode == ProtoCore.DSASM.InterpreterMode.Expression)
                    {
                        int tempBlockId = callContext.CurrentBlockId;
                        ProtoCore.DSASM.CodeBlock tempCodeBlock = ProtoCore.Utils.CoreUtils.GetCodeBlock(core.CodeBlockList, tempBlockId);
                        while (null != tempCodeBlock && tempCodeBlock.blockType != ProtoCore.DSASM.CodeBlockType.Language)
                        {
                            tempCodeBlock = tempCodeBlock.parent;
                        }
                        core.assocCodegen.codeBlock = tempCodeBlock;
                    }
                    core.assocCodegen.codeBlock.EventSink = sink;
                    if (core.BuildStatus.ErrorCount == 0) //if there is syntax error, no build needed
                    {
                        blockId = core.assocCodegen.Emit((codeBlockNode as ProtoCore.AST.AssociativeAST.CodeBlockNode), graphNode);
                    }
                    if (core.Options.RunMode == ProtoCore.DSASM.InterpreterMode.Expression)
                    {
                        blockId = core.assocCodegen.codeBlock.codeBlockId;
                        //Restore the code block.
                        core.assocCodegen.codeBlock = oldCodeBlock;
                    }
                }

                // @keyu: we have to restore asscoCodegen here. It may be 
                // reused later on. Suppose for an inline expression 
                // "x = 1 == 2 ? 3 : 4", we dynamically create assocCodegen
                // to compile true and false expression in this inline 
                // expression, and if we don't restore assocCodegen, the pc
                // is totally messed up.
                //
                // But if directly replace with old assocCodegen, will it
                // replace some other useful information? Need to revisit it.
                //
                // Also refer to defect IDE-2120.
                if (oldCodegen != null && core.assocCodegen != oldCodegen)
                {
//.........这里部分代码省略.........

 public void GraphILTest_FFIClassUsage_03()
 {
     /* def f() {
      *     X = 10;
      *     return = X;
      * }
      */
     ProtoCore.AST.AssociativeAST.BinaryExpressionNode assign1 = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
             new ProtoCore.AST.AssociativeAST.IdentifierNode("X"),
             new ProtoCore.AST.AssociativeAST.IntNode(10),
             ProtoCore.DSASM.Operator.assign);
     ProtoCore.AST.AssociativeAST.IdentifierNode returnExpr = new ProtoCore.AST.AssociativeAST.IdentifierNode("X");
     ProtoCore.AST.AssociativeAST.ReturnNode returnNode = new ProtoCore.AST.AssociativeAST.ReturnNode();
     returnNode.ReturnExpr = returnExpr;
     ProtoCore.AST.AssociativeAST.CodeBlockNode cbn = new ProtoCore.AST.AssociativeAST.CodeBlockNode();
     cbn.Body.Add(assign1);
     cbn.Body.Add(returnNode);
     ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
     funcDefNode.FunctionBody = cbn;
     funcDefNode.Name = "f";
     funcDefNode.ReturnType = new ProtoCore.Type()
     {
         Name = "int",
         UID = (int)ProtoCore.PrimitiveType.kTypeInt,
         //IsIndexable = false,
         rank = 0
     };
     /*Class C { }*/
     ProtoCore.AST.AssociativeAST.VarDeclNode varDeclNode = new ProtoCore.AST.AssociativeAST.VarDeclNode();
     varDeclNode.Name = "X";
     ProtoCore.AST.AssociativeAST.IdentifierNode varDeclId = new ProtoCore.AST.AssociativeAST.IdentifierNode()
     {
         Value = "X",
         Name = "X",
         datatype = new ProtoCore.Type()
         {
             Name = "int",
             //IsIndexable = false,
             rank = 0,
             UID = (int)ProtoCore.PrimitiveType.kTypeInt
         }
     };
     varDeclNode.NameNode = varDeclId;
     varDeclNode.ArgumentType = new ProtoCore.Type()
     {
         Name = "int",
         //IsIndexable = false,
         rank = 0,
         UID = (int)ProtoCore.PrimitiveType.kTypeVar
     };
     ProtoCore.AST.AssociativeAST.ClassDeclNode classDeclNode = new ProtoCore.AST.AssociativeAST.ClassDeclNode();
     classDeclNode.className = "C";
     classDeclNode.funclist.Add(funcDefNode);
     classDeclNode.varlist.Add(varDeclNode);
     // p = new C.C(); t = p.f(); val = p.X;
     ProtoCore.AST.AssociativeAST.FunctionCallNode funcCallP = new ProtoCore.AST.AssociativeAST.FunctionCallNode();
     funcCallP.Function = new ProtoCore.AST.AssociativeAST.IdentifierNode("C");
     List<ProtoCore.AST.AssociativeAST.AssociativeNode> listArgs = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();
     funcCallP.FormalArguments = listArgs;
     ProtoCore.AST.AssociativeAST.FunctionDotCallNode funcDotCallNode = new ProtoCore.AST.AssociativeAST.FunctionDotCallNode("C", funcCallP);
     ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignP = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
             new ProtoCore.AST.AssociativeAST.IdentifierNode("p"),
             funcDotCallNode,
             ProtoCore.DSASM.Operator.assign
         );
     //p = C.C()
     ProtoCore.AST.AssociativeAST.FunctionCallNode funcCallT = new ProtoCore.AST.AssociativeAST.FunctionCallNode();
     funcCallT.Function = new ProtoCore.AST.AssociativeAST.IdentifierNode("f");
     funcCallT.FormalArguments = listArgs;
     funcDotCallNode = new ProtoCore.AST.AssociativeAST.FunctionDotCallNode("p", funcCallT);
     ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignT = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
             new ProtoCore.AST.AssociativeAST.IdentifierNode("t"),
             funcDotCallNode,
             ProtoCore.DSASM.Operator.assign
         );
     //t = p.f();
     ProtoCore.AST.AssociativeAST.IdentifierListNode idListNode = new ProtoCore.AST.AssociativeAST.IdentifierListNode();
     idListNode.LeftNode = new ProtoCore.AST.AssociativeAST.IdentifierNode("p");
     idListNode.Optr = ProtoCore.DSASM.Operator.dot;
     idListNode.RightNode = new ProtoCore.AST.AssociativeAST.IdentifierNode("X");
     ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignVal = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
             new ProtoCore.AST.AssociativeAST.IdentifierNode("val"),
             idListNode,
             ProtoCore.DSASM.Operator.assign);
     List<ProtoCore.AST.AssociativeAST.AssociativeNode> astList = new List<ProtoCore.AST.AssociativeAST.AssociativeNode>();
     astList.Add(classDeclNode);
     astList.Add(assignP);
     astList.Add(assignT);
     astList.Add(assignVal);
     //==============================================
     // emit the DS code from the AST tree
     //
     // Class C {
     //      X : int
     //      def f() {
     //          x = 2;
     //          return = X;
     //      }
     // }
     // p = new C();
//.........这里部分代码省略.........

        public void TestRoundTrip_FunctionDefAndCall_02()
        {
            //=================================
            // 1. Build AST 
            // 2. Execute AST and verify
            // 3. Convert AST to source
            // 4. Execute source and verify
            //=================================
            int result1 = 11;
            ExecutionMirror mirror = null;

            // 1. Build the AST tree


            //  def foo(a : int)
            //  {
            //    b = 10;
            //    return = b + a;
            //  }
            //  
            //  x = foo(1);

            ProtoCore.AST.AssociativeAST.CodeBlockNode cbn = new ProtoCore.AST.AssociativeAST.CodeBlockNode();


            // Build the function body
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode assignment1 = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IntNode(10),
                ProtoCore.DSASM.Operator.assign);
            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnExpr = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode("b"),
                new ProtoCore.AST.AssociativeAST.IdentifierNode("a"),
                ProtoCore.DSASM.Operator.add);


            ProtoCore.AST.AssociativeAST.BinaryExpressionNode returnNode = new ProtoCore.AST.AssociativeAST.BinaryExpressionNode(
                new ProtoCore.AST.AssociativeAST.IdentifierNode(ProtoCore.DSDefinitions.Keyword.Return),
                returnExpr,
                ProtoCore.DSASM.Operator.assign);

            cbn.Body.Add(assignment1);
            cbn.Body.Add(returnNode);


            // Build the function definition foo
            const string functionName = "foo";
            ProtoCore.AST.AssociativeAST.FunctionDefinitionNode funcDefNode = new ProtoCore.AST.AssociativeAST.FunctionDefinitionNode();
            funcDefNode.Name = functionName;
            funcDefNode.FunctionBody = cbn;

            // build the args signature
            funcDefNode.Signature = new ProtoCore.AST.AssociativeAST.ArgumentSignatureNode();
            ProtoCore.AST.AssociativeAST.VarDeclNode arg1Decl = new ProtoCore.AST.AssociativeAST.VarDeclNode();
            arg1Decl.NameNode = new ProtoCore.AST.AssociativeAST.IdentifierNode("a");

            // Build the type of arg1
            ProtoCore.Type arg1Type = new ProtoCore.Type();
            arg1Type.Initialize();
            arg1Type.UID = (int)ProtoCore.PrimitiveType.Integer;
            arg1Type.Name = ProtoCore.DSDefinitions.Keyword.Int;
            arg1Decl.ArgumentType = arg1Type;
            funcDefNode.Signature.AddArgument(arg1Decl);


            // Function Return type
            ProtoCore.Type returnType = new ProtoCore.Type();
            returnType.Initialize();
            returnType.UID = (int)ProtoCore.PrimitiveType.Var;
            returnType.Name