/// <summary> /// Stores the value on the top of the stack in the reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="valueType"> The primitive type of the value that is on the top of the stack. </param> public void GenerateSet(ILGenerator generator, OptimizationInfo optimizationInfo, PrimitiveType valueType) { // TODO: Optimize this. // // ++ or -- // GenerateReference // DuplicateReference // GenerateGet // ToNumber // if (postfix) Dup/Store in variable // Increment/Decrement // if (prefix) Dup/Store in variable // GenerateSet // Load variable // // += // GenerateReference // DuplicateReference // GenerateGet // Dup/Store in variable // GenerateSet // Load variable // // for (in/of) // GenerateReference // LoadVariable(enumerator) // GenerateGet // GenerateSet // // = // GenerateReference // target.GenerateGet // Dup/Store in variable // GenerateSet // Load variable // If we have allocated an IL variable, use it. var variableInfo = Scope.FindStaticVariable(Name); if (variableInfo != null && variableInfo.Store != null) { EmitConversion.Convert(generator, valueType, variableInfo.Type); generator.StoreVariable(variableInfo.Store); return; } // Fallback: call RuntimeScope.SetValue() or RuntimeScope.SetValueStrict(). var temp = generator.CreateTemporaryVariable(valueType); generator.StoreVariable(temp); Scope.GenerateReference(generator, optimizationInfo); generator.LoadString(Name); generator.LoadVariable(temp); EmitConversion.ToAny(generator, valueType); generator.LoadInt32(optimizationInfo.SourceSpan.StartLine); generator.LoadStringOrNull(optimizationInfo.Source.Path); generator.Call(optimizationInfo.StrictMode ? ReflectionHelpers.RuntimeScope_SetValueStrict : ReflectionHelpers.RuntimeScope_SetValue); generator.ReleaseTemporaryVariable(temp); }
/// <summary> /// Generates CIL for the in operator. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> private void GenerateIn(ILGenerator generator, OptimizationInfo optimizationInfo) { // Emit the left-hand side expression and convert it to a string. this.Left.GenerateCode(generator, optimizationInfo); EmitConversion.ToString(generator, this.Left.ResultType); // Store the left-hand side expression in a temporary variable. var temp = generator.CreateTemporaryVariable(typeof(string)); generator.StoreVariable(temp); // Emit the right-hand side expression. this.Right.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Right.ResultType); // Check the right-hand side is a javascript object - if not, throw an exception. generator.Duplicate(); generator.IsInstance(typeof(ObjectInstance)); var endOfTypeCheck = generator.CreateLabel(); generator.BranchIfTrue(endOfTypeCheck); // Throw an nicely formatted exception. var rightValue = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(rightValue); generator.LoadEnumValue(ErrorType.TypeError); generator.LoadString("The in operator expected an object, but found '{0}' instead"); generator.LoadInt32(1); generator.NewArray(typeof(object)); generator.Duplicate(); generator.LoadInt32(0); generator.LoadVariable(rightValue); generator.Call(ReflectionHelpers.TypeUtilities_TypeOf); generator.StoreArrayElement(typeof(object)); generator.Call(ReflectionHelpers.String_Format); generator.LoadInt32(optimizationInfo.SourceSpan.StartLine); generator.LoadStringOrNull(optimizationInfo.Source.Path); generator.LoadStringOrNull(optimizationInfo.FunctionName); generator.NewObject(ReflectionHelpers.JavaScriptException_Constructor_Error); generator.Throw(); generator.DefineLabelPosition(endOfTypeCheck); generator.ReleaseTemporaryVariable(rightValue); generator.ReinterpretCast(typeof(ObjectInstance)); // Load the left-hand side expression from the temporary variable. generator.LoadVariable(temp); // Call ObjectInstance.HasProperty(object) generator.Call(ReflectionHelpers.ObjectInstance_HasProperty); // Allow the temporary variable to be reused. generator.ReleaseTemporaryVariable(temp); }
/// <summary> /// Generates CIL for the instanceof operator. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> private void GenerateInstanceOf(ILGenerator generator, OptimizationInfo optimizationInfo) { // Emit the left-hand side expression and convert it to an object. this.Left.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Left.ResultType); // Store the left-hand side expression in a temporary variable. var temp = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(temp); // Emit the right-hand side expression. this.Right.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Right.ResultType); // Check the right-hand side is a function - if not, throw an exception. generator.IsInstance(typeof(Library.FunctionInstance)); generator.Duplicate(); var endOfTypeCheck = generator.CreateLabel(); generator.BranchIfNotNull(endOfTypeCheck); // Throw an nicely formatted exception. var rightValue = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(rightValue); EmitHelpers.LoadScriptEngine(generator); generator.LoadString("TypeError"); generator.LoadString("The instanceof operator expected a function, but found '{0}' instead"); generator.LoadInt32(1); generator.NewArray(typeof(object)); generator.Duplicate(); generator.LoadInt32(0); generator.LoadVariable(rightValue); generator.Call(ReflectionHelpers.TypeUtilities_TypeOf); generator.StoreArrayElement(typeof(object)); generator.Call(ReflectionHelpers.String_Format); generator.NewObject(ReflectionHelpers.JavaScriptException_Constructor_Error); generator.Throw(); generator.DefineLabelPosition(endOfTypeCheck); generator.ReleaseTemporaryVariable(rightValue); // Load the left-hand side expression from the temporary variable. generator.LoadVariable(temp); // Call FunctionInstance.HasInstance(object) generator.Call(ReflectionHelpers.FunctionInstance_HasInstance); // Allow the temporary variable to be reused. generator.ReleaseTemporaryVariable(temp); }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals(); GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // Create the scope instance. WithScope.GenerateScopeCreation(generator, optimizationInfo); WithScope.GenerateHoistedDeclarations(generator, optimizationInfo); // Bind the scope to the with() object. WithScope.GenerateReference(generator, optimizationInfo); WithObject.GenerateCode(generator, optimizationInfo); ILLocalVariable withObject = generator.CreateTemporaryVariable(typeof(object)); generator.Duplicate(); generator.StoreVariable(withObject); generator.Call(ReflectionHelpers.RuntimeScope_With); // Generate code for the body statements. this.Body.GenerateCode(generator, optimizationInfo); // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals(); GenerateStartOfStatement(generator, optimizationInfo, statementLocals); if (this.ContributesToEvalResult == true && optimizationInfo.EvalResult != null) { // Emit the expression. this.Expression.GenerateCode(generator, optimizationInfo); // Store the result. EmitConversion.ToAny(generator, this.Expression.ResultType); generator.StoreVariable(optimizationInfo.EvalResult); } else { // Emit the expression. this.Expression.GenerateCode(generator, optimizationInfo); generator.Pop(); } // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Generates CIL for an assignment expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="target"> The target to modify. </param> private void GenerateAssignment(ILGenerator generator, OptimizationInfo optimizationInfo, IReferenceExpression target) { // Evaluate the left hand side first! target.GenerateReference(generator, optimizationInfo); // Load the value to assign. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (rhs is FunctionExpression) { ((FunctionExpression)rhs).GenerateDisplayName(generator, optimizationInfo, target.ToString(), false); } // Store the RHS value so we can return it as the result of the expression. var result = generator.CreateTemporaryVariable(rhs.ResultType); generator.Duplicate(); generator.StoreVariable(result); // Store the value. target.GenerateSet(generator, optimizationInfo, rhs.ResultType, optimizationInfo.StrictMode); // Restore the RHS value. generator.LoadVariable(result); generator.ReleaseTemporaryVariable(result); }
/// <summary> /// Generates CIL for a compound assignment expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="target"> The target to modify. </param> private void GenerateCompoundAssignment(ILGenerator generator, OptimizationInfo optimizationInfo, IReferenceExpression target) { // Evaluate the left hand side only once. target.GenerateReference(generator, optimizationInfo); target.DuplicateReference(generator, optimizationInfo); // For the GenerateSet, later on. // Load the value to assign. var compoundOperator = new BinaryExpression(GetCompoundBaseOperator(this.OperatorType), new ReferenceGetExpression(target), this.GetOperand(1)); compoundOperator.GenerateCode(generator, optimizationInfo); ILLocalVariable result = null; if (optimizationInfo.IgnoreReturnValue != this) { // Store the resulting value so we can return it as the result of the expression. result = generator.CreateTemporaryVariable(compoundOperator.ResultType); generator.Duplicate(); generator.StoreVariable(result); } // Store the value. target.GenerateSet(generator, optimizationInfo, compoundOperator.ResultType); if (optimizationInfo.IgnoreReturnValue != this) { // Restore the expression result. generator.LoadVariable(result); generator.ReleaseTemporaryVariable(result); } else { optimizationInfo.ReturnValueWasNotGenerated = true; } }
/// <summary> /// Generates CIL for an assignment expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="target"> The target to modify. </param> private void GenerateAssignment(ILGenerator generator, OptimizationInfo optimizationInfo, IReferenceExpression target) { // Evaluate the left hand side first! target.GenerateReference(generator, optimizationInfo); // Load the value to assign. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); ILLocalVariable result = null; if (optimizationInfo.IgnoreReturnValue != this) { // Store the RHS value so we can return it as the result of the expression. result = generator.CreateTemporaryVariable(rhs.ResultType); generator.Duplicate(); generator.StoreVariable(result); } // Store the value. target.GenerateSet(generator, optimizationInfo, rhs.ResultType); if (optimizationInfo.IgnoreReturnValue != this) { // Restore the RHS value. generator.LoadVariable(result); generator.ReleaseTemporaryVariable(result); } else { optimizationInfo.ReturnValueWasNotGenerated = true; } }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals(); GenerateStartOfStatement(generator, optimizationInfo, statementLocals); if (this.ContributesToEvalResult == true && optimizationInfo.EvalResult != null) { // Emit the expression. this.Expression.GenerateCode(generator, optimizationInfo); // Store the result. EmitConversion.ToAny(generator, this.Expression.ResultType); generator.StoreVariable(optimizationInfo.EvalResult); } else { // Emit the expression. optimizationInfo.IgnoreReturnValue = this.Expression; optimizationInfo.ReturnValueWasNotGenerated = false; this.Expression.GenerateCode(generator, optimizationInfo); if (!optimizationInfo.ReturnValueWasNotGenerated) { generator.Pop(); } } // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Pushes the value of the reference onto the stack. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to output <c>null</c> instead. </param> public void GenerateGet(ILGenerator generator, OptimizationInfo optimizationInfo, bool throwIfUnresolvable) { string propertyName = null; TypeOfMemberAccess memberAccessType = DetermineTypeOfMemberAccess(optimizationInfo, out propertyName); if (memberAccessType == TypeOfMemberAccess.ArrayIndex) { // Array indexer // ------------- // xxx = object[index] // Call the indexer. generator.Call(ReflectionHelpers.ObjectInstance_Indexer_UInt); } else if (memberAccessType == TypeOfMemberAccess.Static) { // Named property access (e.g. x = y.property) // ------------------------------------------- // Use a PropertyReference to speed up access if we are inside a loop. if (optimizationInfo.InsideLoop) { // C# // if (propertyReference != null) // propertyReference = new PropertyReference("property"); // value = object.GetPropertyValue(propertyReference) ILLocalVariable propertyReference = optimizationInfo.GetPropertyReferenceVariable(generator, propertyName); generator.LoadVariable(propertyReference); generator.Duplicate(); var afterIf = generator.CreateLabel(); generator.BranchIfNotNull(afterIf); generator.Pop(); generator.LoadString(propertyName); generator.NewObject(ReflectionHelpers.PropertyName_Constructor); generator.Duplicate(); generator.StoreVariable(propertyReference); generator.DefineLabelPosition(afterIf); generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_PropertyReference); } else { // C# // value = object.GetPropertyValue("property") generator.LoadString(propertyName); generator.Call(ReflectionHelpers.ObjectInstance_Indexer_Object); } } else { // Dynamic property access // ----------------------- // x = y.GetPropertyValue("property") generator.Call(ReflectionHelpers.ObjectInstance_Indexer_Object); } }
/// <summary> /// Outputs the values needed to get or set this reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public void DuplicateReference(ILGenerator generator, OptimizationInfo optimizationInfo) { string propertyName = null; TypeOfMemberAccess memberAccessType = DetermineTypeOfMemberAccess(optimizationInfo, out propertyName); if (memberAccessType == TypeOfMemberAccess.ArrayIndex) { // Array indexer var arg1 = generator.CreateTemporaryVariable(typeof(object)); var arg2 = generator.CreateTemporaryVariable(typeof(uint)); generator.StoreVariable(arg2); generator.StoreVariable(arg1); generator.LoadVariable(arg1); generator.LoadVariable(arg2); generator.LoadVariable(arg1); generator.LoadVariable(arg2); generator.ReleaseTemporaryVariable(arg1); generator.ReleaseTemporaryVariable(arg2); } else if (memberAccessType == TypeOfMemberAccess.Static) { // Named property access generator.Duplicate(); } else { // Dynamic property access var arg1 = generator.CreateTemporaryVariable(typeof(object)); var arg2 = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(arg2); generator.StoreVariable(arg1); generator.LoadVariable(arg1); generator.LoadVariable(arg2); generator.LoadVariable(arg1); generator.LoadVariable(arg2); generator.ReleaseTemporaryVariable(arg1); generator.ReleaseTemporaryVariable(arg2); } }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals(); GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // Emit the return value. if (this.Value == null) { EmitHelpers.EmitUndefined(generator); } else { this.Value.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Value.ResultType); } // Determine if this is the last statement in the function. bool lastStatement = optimizationInfo.AbstractSyntaxTree is BlockStatement && ((BlockStatement)optimizationInfo.AbstractSyntaxTree).Statements.Count > 0 && ((BlockStatement)optimizationInfo.AbstractSyntaxTree).Statements[((BlockStatement)optimizationInfo.AbstractSyntaxTree).Statements.Count - 1] == this; // The first return statement initializes the variable that holds the return value. if (optimizationInfo.ReturnVariable == null) { optimizationInfo.ReturnVariable = generator.DeclareVariable(typeof(object), "returnValue"); } // Store the return value in a variable. generator.StoreVariable(optimizationInfo.ReturnVariable); // There is no need to jump to the end of the function if this is the last statement. if (lastStatement == false) { // The first return statement that needs to branch creates the return label. This is // defined in FunctionmethodGenerator.GenerateCode() at the end of the function. if (optimizationInfo.ReturnTarget == null) { optimizationInfo.ReturnTarget = generator.CreateLabel(); } // Branch to the end of the function. Note: the return statement might be branching // from inside a try { } or finally { } block to outside. EmitLongJump() handles this. optimizationInfo.EmitLongJump(generator, optimizationInfo.ReturnTarget); } // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Pops the value on the stack, converts it to a javascript object, then pushes the result /// onto the stack. /// </summary> /// <param name="generator"> The IL generator. </param> /// <param name="fromType"> The type to convert from. </param> /// <param name="path"> The path of the javascript source file that is currently executing. </param> /// <param name="function"> The name of the currently executing function. </param> /// <param name="line"> The line number of the statement that is currently executing. </param> public static void ToObject(ILGenerator generator, PrimitiveType fromType, string path, string function, int line) { // Check that a conversion is actually necessary. if (fromType == PrimitiveType.Object) { generator.ReinterpretCast(typeof(ObjectInstance)); return; } switch (fromType) { case PrimitiveType.Undefined: // Converting from undefined always throws an exception. EmitHelpers.EmitThrow(generator, ErrorType.TypeError, "Undefined cannot be converted to an object", path, function, line); generator.ReinterpretCast(typeof(ObjectInstance)); break; case PrimitiveType.Null: // Converting from null always throws an exception. EmitHelpers.EmitThrow(generator, ErrorType.TypeError, "Null cannot be converted to an object", path, function, line); generator.ReinterpretCast(typeof(ObjectInstance)); break; case PrimitiveType.Bool: case PrimitiveType.Int32: case PrimitiveType.UInt32: case PrimitiveType.Number: case PrimitiveType.String: case PrimitiveType.ConcatenatedString: case PrimitiveType.Any: // Otherwise, fall back to calling TypeConverter.ToObject() ToAny(generator, fromType); var temp = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(temp); EmitHelpers.LoadScriptEngine(generator); generator.LoadVariable(temp); generator.ReleaseTemporaryVariable(temp); generator.LoadInt32(line); generator.LoadStringOrNull(path); generator.LoadStringOrNull(function); generator.Call(ReflectionHelpers.TypeConverter_ToObject); break; default: throw new NotImplementedException(string.Format("Unsupported primitive type: {0}", fromType)); } }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals(); GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // Emit the return value. if (this.Value == null) EmitHelpers.EmitUndefined(generator); else { this.Value.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Value.ResultType); } // Determine if this is the last statement in the function. bool lastStatement = optimizationInfo.AbstractSyntaxTree is BlockStatement && ((BlockStatement)optimizationInfo.AbstractSyntaxTree).Statements.Count > 0 && ((BlockStatement)optimizationInfo.AbstractSyntaxTree).Statements[((BlockStatement)optimizationInfo.AbstractSyntaxTree).Statements.Count - 1] == this; // The first return statement initializes the variable that holds the return value. if (optimizationInfo.ReturnVariable == null) optimizationInfo.ReturnVariable = generator.DeclareVariable(typeof(object), "returnValue"); // Store the return value in a variable. generator.StoreVariable(optimizationInfo.ReturnVariable); // There is no need to jump to the end of the function if this is the last statement. if (lastStatement == false) { // The first return statement that needs to branch creates the return label. This is // defined in FunctionmethodGenerator.GenerateCode() at the end of the function. if (optimizationInfo.ReturnTarget == null) optimizationInfo.ReturnTarget = generator.CreateLabel(); // Branch to the end of the function. Note: the return statement might be branching // from inside a try { } or finally { } block to outside. EmitLongJump() handles this. optimizationInfo.EmitLongJump(generator, optimizationInfo.ReturnTarget); } // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Deletes the reference and pushes <c>true</c> if the delete succeeded, or <c>false</c> /// if the delete failed. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public void GenerateDelete(ILGenerator generator, OptimizationInfo optimizationInfo) { // Deleting a variable is not allowed in strict mode. if (optimizationInfo.StrictMode == true) { throw new JavaScriptException(optimizationInfo.Engine, ErrorType.SyntaxError, string.Format("Cannot delete {0} because deleting a variable or argument is not allowed in strict mode", this.Name), optimizationInfo.SourceSpan.StartLine, optimizationInfo.Source.Path, optimizationInfo.FunctionName); } var endOfDelete = generator.CreateLabel(); var scope = this.Scope; ILLocalVariable scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); generator.StoreVariable(scopeVariable); do { if (scope is DeclarativeScope) { var variable = scope.GetDeclaredVariable(this.Name); if (variable != null) { // The variable is known at compile-time. if (variable.Deletable == false) { // The variable cannot be deleted - return false. generator.LoadBoolean(false); } else { // The variable can be deleted (it was declared inside an eval()). // Delete the variable. generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_Delete); } break; } else { // The variable was not defined at compile time, but may have been // introduced by an eval() statement. if (optimizationInfo.MethodOptimizationHints.HasEval == true) { // Check the variable exists: if (scope.HasValue(variableName) == true) { generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_HasValue); var hasValueClause = generator.CreateLabel(); generator.BranchIfFalse(hasValueClause); // If the variable does exist, return true. generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_Delete); generator.Branch(endOfDelete); // } generator.DefineLabelPosition(hasValueClause); } } } else { // Check if the property exists by calling scope.ScopeObject.HasProperty(propertyName) generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); generator.Duplicate(); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.ObjectInstance_HasProperty); // Jump past the delete if the property doesn't exist. var endOfExistsCheck = generator.CreateLabel(); generator.BranchIfFalse(endOfExistsCheck); // Call scope.ScopeObject.Delete(key, false) generator.LoadString(this.Name); generator.LoadBoolean(false); generator.Call(ReflectionHelpers.ObjectInstance_Delete); generator.Branch(endOfDelete); generator.DefineLabelPosition(endOfExistsCheck); generator.Pop(); // If the name is not defined, return true. if (scope.ParentScope == null) { generator.LoadBoolean(true); } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { generator.LoadVariable(scopeVariable); generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // Release the temporary variable. generator.ReleaseTemporaryVariable(scopeVariable); // Define a label at the end. generator.DefineLabelPosition(endOfDelete); // Delete obviously has side-effects so we evaluate the return value then pop it from // the stack. //if (optimizationInfo.SuppressReturnValue == true) // generator.Pop(); }
/// <summary> /// Pops the value on the stack, converts it to an integer, then pushes the integer result /// onto the stack. /// </summary> /// <param name="generator"> The IL generator. </param> /// <param name="fromType"> The type to convert from. </param> public static void ToInteger(ILGenerator generator, PrimitiveType fromType) { // Check that a conversion is actually necessary. if (fromType == PrimitiveType.Int32 || fromType == PrimitiveType.UInt32 || fromType == PrimitiveType.Bool) { return; } switch (fromType) { case PrimitiveType.Undefined: case PrimitiveType.Null: // Converting from undefined or null produces 0. generator.Pop(); generator.LoadInt32(0); break; case PrimitiveType.Number: // Converting from a number produces the following: // Any number between -2147483648 and +2147483647 -> itself // Any number smaller than -2147483648 -> -2147483648 // Any number larger than +2147483647 -> +2147483647 // NaN -> 0 // bool isPositiveInfinity = input > 2147483647.0 var isPositiveInfinity = generator.CreateTemporaryVariable(typeof(bool)); generator.Duplicate(); generator.LoadDouble(2147483647.0); generator.CompareGreaterThan(); generator.StoreVariable(isPositiveInfinity); // bool notNaN = input == input var notNaN = generator.CreateTemporaryVariable(typeof(bool)); generator.Duplicate(); generator.Duplicate(); generator.CompareEqual(); generator.StoreVariable(notNaN); // input = (int)input // Infinity -> -2147483648 // -Infinity -> -2147483648 // NaN -> -2147483648 generator.ConvertToInteger(); // input = input & -((int)notNaN) generator.LoadVariable(notNaN); generator.Negate(); generator.BitwiseAnd(); // input = input - (int)isPositiveInfinity generator.LoadVariable(isPositiveInfinity); generator.Subtract(); // The temporary variables are no longer needed. generator.ReleaseTemporaryVariable(notNaN); generator.ReleaseTemporaryVariable(isPositiveInfinity); break; case PrimitiveType.String: case PrimitiveType.ConcatenatedString: case PrimitiveType.Any: case PrimitiveType.Object: // Otherwise, fall back to calling TypeConverter.ToInteger() generator.Call(ReflectionHelpers.TypeConverter_ToInteger); break; default: throw new NotImplementedException(string.Format("Unsupported primitive type: {0}", fromType)); } }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals() { NonDefaultBreakStatementBehavior = true }; GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // We need a label for each case clause and one for the default case. var jumpTargets = new ILLabel[this.CaseClauses.Count]; int defaultIndex = -1; ILLabel endOfSwitch = generator.CreateLabel(); // Generate code for the switch value. var startOfSwitch = generator.CreateLabel(); this.Value.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Value.ResultType); // Save the switch value in a variable. var switchValue = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(switchValue); for (int i = 0; i < this.CaseClauses.Count; i++) { var caseClause = this.CaseClauses[i]; // Create a label for each clause. jumpTargets[i] = generator.CreateLabel(); if (caseClause.Value == null) { // This is a default clause. defaultIndex = i; continue; } // TypeComparer.StrictEquals(switchValue, caseValue) generator.LoadVariable(switchValue); caseClause.Value.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, caseClause.Value.ResultType); generator.Call(ReflectionHelpers.TypeComparer_StrictEquals); // if (TypeComparer.StrictEquals(switchValue, caseValue) == true) // goto case i generator.BranchIfTrue(jumpTargets[i]); } // None of the cases matched, jump to the default clause or the end of the switch. if (defaultIndex >= 0) { generator.Branch(jumpTargets[defaultIndex]); } else { generator.Branch(endOfSwitch); } for (int i = 0; i < this.CaseClauses.Count; i++) { // Define a label at the start of the case clause. generator.DefineLabelPosition(jumpTargets[i]); // Set up the information needed by the break statement. optimizationInfo.PushBreakOrContinueInfo(this.Labels, endOfSwitch, null, labelledOnly: false); // Emit the case clause statements. foreach (var statement in this.CaseClauses[i].BodyStatements) { statement.GenerateCode(generator, optimizationInfo); } // Revert the information needed by the break statement. optimizationInfo.PopBreakOrContinueInfo(); } // Define a label for the end of the switch statement. generator.DefineLabelPosition(endOfSwitch); // Release the switch value variable for use elsewhere. generator.ReleaseTemporaryVariable(switchValue); // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals() { NonDefaultBreakStatementBehavior = true, NonDefaultSourceSpanBehavior = true }; GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // Construct a loop expression. // var iterator = TypeUtilities.GetIterator(obj); // while (true) { // continue-target: // if (enumerator.MoveNext() == false) // goto break-target; // lhs = enumerator.Current; // // <body statements> // } // break-target: // Call: ObjectInstance GetIterator(ScriptEngine engine, ObjectInstance iterable) // Then call: IEnumerable<object> Iterate(ScriptEngine engine, ObjectInstance iterator) optimizationInfo.MarkSequencePoint(generator, this.TargetObjectSourceSpan); EmitHelpers.LoadScriptEngine(generator); this.TargetObject.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.TargetObject.ResultType); generator.Call(ReflectionHelpers.TypeUtilities_ForOf); // Call IEnumerable<object>.GetEnumerator() generator.Call(ReflectionHelpers.IEnumerable_Object_GetEnumerator); // Store the enumerator in a temporary variable. var enumerator = generator.CreateTemporaryVariable(typeof(IEnumerator <object>)); generator.StoreVariable(enumerator); var breakTarget = generator.CreateLabel(); var continueTarget = generator.DefineLabelPosition(); // Emit debugging information. if (optimizationInfo.DebugDocument != null) { generator.MarkSequencePoint(optimizationInfo.DebugDocument, this.VariableSourceSpan); } // if (enumerator.MoveNext() == false) // goto break-target; generator.LoadVariable(enumerator); generator.Call(ReflectionHelpers.IEnumerator_MoveNext); generator.BranchIfFalse(breakTarget); // lhs = enumerator.Current; this.Variable.GenerateReference(generator, optimizationInfo); generator.LoadVariable(enumerator); generator.Call(ReflectionHelpers.IEnumerator_Object_Current); this.Variable.GenerateSet(generator, optimizationInfo, PrimitiveType.Any, false); // Emit the body statement(s). optimizationInfo.PushBreakOrContinueInfo(this.Labels, breakTarget, continueTarget, labelledOnly: false); this.Body.GenerateCode(generator, optimizationInfo); optimizationInfo.PopBreakOrContinueInfo(); generator.Branch(continueTarget); generator.DefineLabelPosition(breakTarget); // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Pushes the value of the reference onto the stack. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to output <c>null</c> instead. </param> public void GenerateGet(ILGenerator generator, OptimizationInfo optimizationInfo, bool throwIfUnresolvable) { string propertyName = null; bool isArrayIndex = false; // Right-hand-side can be a property name (a.b) if (this.OperatorType == OperatorType.MemberAccess) { var rhs = this.GetOperand(1) as NameExpression; if (rhs == null) { throw new JavaScriptException(optimizationInfo.Engine, "SyntaxError", "Invalid member access", optimizationInfo.SourceSpan.StartLine, optimizationInfo.Source.Path, optimizationInfo.FunctionName); } propertyName = rhs.Name; } // Or a constant indexer (a['b']) if (this.OperatorType == OperatorType.Index) { var rhs = this.GetOperand(1) as LiteralExpression; if (rhs != null && (PrimitiveTypeUtilities.IsNumeric(rhs.ResultType) || rhs.ResultType == PrimitiveType.String)) { propertyName = TypeConverter.ToString(rhs.Value); // Or a array index (a[0]) if (rhs.ResultType == PrimitiveType.Int32 || (propertyName != null && Library.ArrayInstance.ParseArrayIndex(propertyName) != uint.MaxValue)) { isArrayIndex = true; } } } if (isArrayIndex == true) { // Array indexer // ------------- // xxx = object[index] // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType, optimizationInfo); // Load the right-hand side and convert to a uint32. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToUInt32(generator, rhs.ResultType); // Call the indexer. generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_Int); } else if (propertyName != null) { //// Load the left-hand side and convert to an object instance. //var lhs = this.GetOperand(0); //lhs.GenerateCode(generator, optimizationInfo); //EmitConversion.ToObject(generator, lhs.ResultType); //// Call Get(string) //generator.LoadString(propertyName); //generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_String); // Named property access (e.g. x = y.property) // ------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // xxx = object.InlineGetPropertyValue("property", out __object_property_cachedIndex, out __object_cacheKey) // else // xxx = object.InlinePropertyValues[__object_property_cachedIndex]; // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType, optimizationInfo); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // value = object.InlineGetProperty("property", out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(propertyName); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineGetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // value = object.InlinePropertyValues[__object_property_cachedIndex]; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); } else { // Dynamic property access // ----------------------- // xxx = object.Get(x) // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType, optimizationInfo); // Load the property name and convert to a string. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToString(generator, rhs.ResultType); // Call Get(string) generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_String); } }
/// <summary> /// Stores the value on the top of the stack in the reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="valueType"> The primitive type of the value that is on the top of the stack. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to create a new property instead. </param> public void GenerateSet(ILGenerator generator, OptimizationInfo optimizationInfo, PrimitiveType valueType, bool throwIfUnresolvable) { string propertyName = null; bool isArrayIndex = false; //optimizationInfo = optimizationInfo.RemoveFlags(OptimizationFlags.SuppressReturnValue); // Right-hand-side can be a property name (a.b) if (this.OperatorType == OperatorType.MemberAccess) { var rhs = this.GetOperand(1) as NameExpression; if (rhs == null) throw new JavaScriptException(optimizationInfo.Engine, "SyntaxError", "Invalid member access"); propertyName = rhs.Name; } // Or a constant indexer (a['b']) if (this.OperatorType == OperatorType.Index) { var rhs = this.GetOperand(1) as LiteralExpression; if (rhs != null) { propertyName = TypeConverter.ToString(rhs.Value); // Or a array index (a[0]) if (rhs.ResultType == PrimitiveType.Int32 || (propertyName != null && Library.ArrayInstance.ParseArrayIndex(propertyName) != uint.MaxValue)) isArrayIndex = true; } } // Convert the value to an object and store it in a temporary variable. var value = generator.CreateTemporaryVariable(typeof(object)); EmitConversion.ToAny(generator, valueType); generator.StoreVariable(value); if (isArrayIndex == true) { // Array indexer // ------------- // xxx = object[index] // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType); // Load the right-hand side and convert to a uint32. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToUInt32(generator, rhs.ResultType); // Call the indexer. generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Int); } else if (propertyName != null) { //// Load the left-hand side and convert to an object instance. //var lhs = this.GetOperand(0); //lhs.GenerateCode(generator, optimizationInfo); //EmitConversion.ToObject(generator, lhs.ResultType); //// Call the indexer. //generator.LoadString(propertyName); //generator.LoadVariable(value); //generator.LoadBoolean(optimizationInfo.StrictMode); //generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_String); // Named property modification (e.g. x.property = y) // ------------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // object.InlineSetPropertyValue("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) // else // object.InlinePropertyValues[__object_property_cachedIndex] = value; // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // xxx = object.InlineSetPropertyValue("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(propertyName); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineSetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // object.InlinePropertyValues[__object_property_cachedIndex] = value; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadVariable(value); generator.StoreArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); } else { // Dynamic property access // ----------------------- // xxx = object.Get(x) // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType); // Load the property name and convert to a string. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToString(generator, rhs.ResultType); // Call the indexer. generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_String); } // The temporary variable is no longer needed. generator.ReleaseTemporaryVariable(value); }
/// <summary> /// Generates CIL for the in operator. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> private void GenerateIn(ILGenerator generator, OptimizationInfo optimizationInfo) { // Emit the left-hand side expression and convert it to a string. this.Left.GenerateCode(generator, optimizationInfo); EmitConversion.ToString(generator, this.Left.ResultType); // Store the left-hand side expression in a temporary variable. var temp = generator.CreateTemporaryVariable(typeof(string)); generator.StoreVariable(temp); // Emit the right-hand side expression. this.Right.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Right.ResultType); // Check the right-hand side is a javascript object - if not, throw an exception. generator.IsInstance(typeof(Library.ObjectInstance)); generator.Duplicate(); var endOfTypeCheck = generator.CreateLabel(); generator.BranchIfNotNull(endOfTypeCheck); // Throw an nicely formatted exception. var rightValue = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(rightValue); EmitHelpers.LoadScriptEngine(generator); generator.LoadString("TypeError"); generator.LoadString("The in operator expected an object, but found '{0}' instead"); generator.LoadInt32(1); generator.NewArray(typeof(object)); generator.Duplicate(); generator.LoadInt32(0); generator.LoadVariable(rightValue); generator.Call(ReflectionHelpers.TypeUtilities_TypeOf); generator.StoreArrayElement(typeof(object)); generator.Call(ReflectionHelpers.String_Format); generator.LoadInt32(optimizationInfo.SourceSpan.StartLine); generator.LoadStringOrNull(optimizationInfo.Source.Path); generator.LoadStringOrNull(optimizationInfo.FunctionName); generator.NewObject(ReflectionHelpers.JavaScriptException_Constructor_Error); generator.Throw(); generator.DefineLabelPosition(endOfTypeCheck); generator.ReleaseTemporaryVariable(rightValue); // Load the left-hand side expression from the temporary variable. generator.LoadVariable(temp); // Call ObjectInstance.HasProperty(object) generator.Call(ReflectionHelpers.ObjectInstance_HasProperty); // Allow the temporary variable to be reused. generator.ReleaseTemporaryVariable(temp); }
/// <summary> /// Generates CIL for the expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Check if this is a direct call to eval(). if (this.Target is NameExpression && ((NameExpression)this.Target).Name == "eval") { GenerateEval(generator, optimizationInfo); return; } // Emit the function instance first. ILLocalVariable targetBase = null; if (this.Target is MemberAccessExpression) { // The function is a member access expression (e.g. "Math.cos()"). // Evaluate the left part of the member access expression. var baseExpression = ((MemberAccessExpression)this.Target).Base; baseExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, baseExpression.ResultType); targetBase = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(targetBase); // Evaluate the right part of the member access expression. var memberAccessExpression = new MemberAccessExpression(((MemberAccessExpression)this.Target).Operator); memberAccessExpression.Push(new TemporaryVariableExpression(targetBase)); memberAccessExpression.Push(((MemberAccessExpression)this.Target).GetOperand(1)); memberAccessExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Target.ResultType); } else { // Something else (e.g. "eval()"). this.Target.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Target.ResultType); } // Check the object really is a function - if not, throw an exception. generator.IsInstance(typeof(Library.FunctionInstance)); generator.Duplicate(); var endOfTypeCheck = generator.CreateLabel(); generator.BranchIfNotNull(endOfTypeCheck); // Throw an nicely formatted exception. generator.Pop(); EmitHelpers.EmitThrow(generator, "TypeError", string.Format("'{0}' is not a function", this.Target.ToString())); generator.DefineLabelPosition(endOfTypeCheck); // Pass in the path, function name and line. generator.LoadStringOrNull(optimizationInfo.Source.Path); generator.LoadStringOrNull(optimizationInfo.FunctionName); generator.LoadInt32(optimizationInfo.SourceSpan.StartLine); // Generate code to produce the "this" value. There are three cases. if (this.Target is NameExpression) { // 1. The function is a name expression (e.g. "parseInt()"). // In this case this = scope.ImplicitThisValue, if there is one, otherwise undefined. ((NameExpression)this.Target).GenerateThis(generator); } else if (this.Target is MemberAccessExpression) { // 2. The function is a member access expression (e.g. "Math.cos()"). // In this case this = Math. //var baseExpression = ((MemberAccessExpression)this.Target).Base; //baseExpression.GenerateCode(generator, optimizationInfo); //EmitConversion.ToAny(generator, baseExpression.ResultType); generator.LoadVariable(targetBase); } else { // 3. Neither of the above (e.g. "(function() { return 5 })()") // In this case this = undefined. EmitHelpers.EmitUndefined(generator); } // Emit an array containing the function arguments. GenerateArgumentsArray(generator, optimizationInfo); // Call FunctionInstance.CallLateBound(thisValue, argumentValues) generator.Call(ReflectionHelpers.FunctionInstance_CallWithStackTrace); // Allow reuse of the temporary variable. if (targetBase != null) generator.ReleaseTemporaryVariable(targetBase); }
/// <summary> /// Generates a method that does type conversion and calls the bound method. /// </summary> /// <param name="generator"> The ILGenerator used to output the body of the method. </param> /// <param name="argumentCount"> The number of arguments that will be passed to the delegate. </param> /// <returns> A delegate that does type conversion and calls the method represented by this /// object. </returns> protected override void GenerateStub(ILGenerator generator, int argumentCount) { // Here is what we are going to generate. //private static object SampleBinder(ScriptEngine engine, object thisObject, object[] arguments) //{ // // Target function signature: int (bool, int, string, object). // bool param1; // int param2; // string param3; // object param4; // param1 = arguments[0] != 0; // param2 = TypeConverter.ToInt32(arguments[1]); // param3 = TypeConverter.ToString(arguments[2]); // param4 = Undefined.Value; // return thisObject.targetMethod(param1, param2, param3, param4); //} // Find the target method. var binderMethod = this.buckets[Math.Min(argumentCount, this.buckets.Length - 1)]; // Constrain the number of apparent arguments to within the required bounds. int minArgumentCount = binderMethod.RequiredParameterCount; int maxArgumentCount = binderMethod.RequiredParameterCount + binderMethod.OptionalParameterCount; if (binderMethod.HasParamArray == true) maxArgumentCount = int.MaxValue; foreach (var argument in binderMethod.GenerateArguments(generator, Math.Min(Math.Max(argumentCount, minArgumentCount), maxArgumentCount))) { switch (argument.Source) { case BinderArgumentSource.ScriptEngine: // Load the "engine" parameter passed by the client. generator.LoadArgument(0); break; case BinderArgumentSource.ThisValue: // Load the "this" parameter passed by the client. generator.LoadArgument(1); bool inheritsFromObjectInstance = typeof(ObjectInstance).IsAssignableFrom(argument.Type); if (argument.Type.IsClass == true && inheritsFromObjectInstance == false && argument.Type != typeof(string) && argument.Type != typeof(object)) { // If the "this" object is an unsupported class, pass it through unmodified. generator.CastClass(argument.Type); } else { if (argument.Type != typeof(object)) { // If the target "this" object type is not of type object, throw an error if // the value is undefined or null. generator.Duplicate(); var temp = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(temp); generator.LoadArgument(0); generator.LoadVariable(temp); generator.LoadString(binderMethod.Name); generator.Call(ReflectionHelpers.TypeUtilities_VerifyThisObject); generator.ReleaseTemporaryVariable(temp); } // Convert to the target type. EmitTypeConversion(generator, typeof(object), argument.Type); if (argument.Type != typeof(ObjectInstance) && inheritsFromObjectInstance == true) { // EmitConversionToObjectInstance can emit null if the toType is derived from ObjectInstance. // Therefore, if the value emitted is null it means that the "thisObject" is a type derived // from ObjectInstance (e.g. FunctionInstance) and the value provided is a different type // (e.g. ArrayInstance). In this case, throw an exception explaining that the function is // not generic. var endOfThrowLabel = generator.CreateLabel(); generator.Duplicate(); generator.BranchIfNotNull(endOfThrowLabel); generator.LoadArgument(0); EmitHelpers.EmitThrow(generator, "TypeError", string.Format("The method '{0}' is not generic", binderMethod.Name)); generator.DefineLabelPosition(endOfThrowLabel); } } break; case BinderArgumentSource.InputParameter: if (argument.InputParameterIndex < argumentCount) { // Load the argument onto the stack. generator.LoadArgument(2); generator.LoadInt32(argument.InputParameterIndex); generator.LoadArrayElement(typeof(object)); // Get some flags that apply to the parameter. var parameterFlags = JSParameterFlags.None; var parameterAttribute = argument.GetCustomAttribute<JSParameterAttribute>(); if (parameterAttribute != null) { if (argument.Type != typeof(ObjectInstance)) throw new NotImplementedException("[JSParameter] is only supported for arguments of type ObjectInstance."); parameterFlags = parameterAttribute.Flags; } if ((parameterFlags & JSParameterFlags.DoNotConvert) == 0) { // Convert the input parameter to the correct type. EmitTypeConversion(generator, typeof(object), argument); } else { // Don't do argument conversion. /*var endOfThrowLabel = generator.CreateLabel(); generator.IsInstance(typeof(ObjectInstance)); generator.Duplicate(); generator.BranchIfNotNull(endOfThrowLabel); EmitHelpers.EmitThrow(generator, "TypeError", string.Format("Parameter {1} parameter of '{0}' must be an object", binderMethod.Name, argument.InputParameterIndex)); generator.DefineLabelPosition(endOfThrowLabel);*/ } } else { // The target method has more parameters than we have input values. EmitUndefined(generator, argument); } break; } } // Emit the call. binderMethod.GenerateCall(generator); // Convert the return value. if (binderMethod.ReturnType == typeof(void)) EmitHelpers.EmitUndefined(generator); else { EmitTypeConversion(generator, binderMethod.ReturnType, typeof(object)); // Convert a null return value to Null.Value or Undefined.Value. var endOfSpecialCaseLabel = generator.CreateLabel(); generator.Duplicate(); generator.BranchIfNotNull(endOfSpecialCaseLabel); generator.Pop(); if ((binderMethod.Flags & JSFunctionFlags.ConvertNullReturnValueToUndefined) != 0) EmitHelpers.EmitUndefined(generator); else EmitHelpers.EmitNull(generator); generator.DefineLabelPosition(endOfSpecialCaseLabel); } // End the IL. generator.Complete(); }
/// <summary> /// Generates CIL for the expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Literals cannot have side-effects so if a return value is not expected then generate // nothing. //if (optimizationInfo.SuppressReturnValue == true) // return; if (this.Value is int) generator.LoadInt32((int)this.Value); else if (this.Value is double) generator.LoadDouble((double)this.Value); else if (this.Value is string) generator.LoadString((string)this.Value); else if (this.Value is bool) generator.LoadBoolean((bool)this.Value); else if (this.Value is RegularExpressionLiteral) { // RegExp var sharedRegExpVariable = optimizationInfo.GetRegExpVariable(generator, (RegularExpressionLiteral)this.Value); var label1 = generator.CreateLabel(); var label2 = generator.CreateLabel(); // if (sharedRegExp == null) { generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.BranchIfNotEqual(label1); // sharedRegExp = Global.RegExp.Construct(source, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadString(((RegularExpressionLiteral)this.Value).Pattern); generator.LoadString(((RegularExpressionLiteral)this.Value).Flags); generator.Call(ReflectionHelpers.RegExp_Construct); generator.Duplicate(); generator.StoreVariable(sharedRegExpVariable); // } else { generator.Branch(label2); generator.DefineLabelPosition(label1); // Global.RegExp.Construct(sharedRegExp, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.Call(ReflectionHelpers.RegExp_Construct); // } generator.DefineLabelPosition(label2); } else if (this.Value == Null.Value) { // Null. EmitHelpers.EmitNull(generator); } else if (this.Value == Undefined.Value) { // Undefined. EmitHelpers.EmitUndefined(generator); } else if (this.Value is List<Expression>) { // Construct an array literal. var arrayLiteral = (List<Expression>)this.Value; // Operands for ArrayConstructor.New() are: an ArrayConstructor instance (ArrayConstructor), an array (object[]) // ArrayConstructor EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Array); // object[] generator.LoadInt32(arrayLiteral.Count); generator.NewArray(typeof(object)); for (int i = 0; i < arrayLiteral.Count; i ++) { // Operands for StoreArrayElement() are: an array (object[]), index (int), value (object). // Array generator.Duplicate(); // Index generator.LoadInt32(i); // Value var elementExpression = arrayLiteral[i]; if (elementExpression == null) generator.LoadNull(); else { elementExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, elementExpression.ResultType); } // Store the element value. generator.StoreArrayElement(typeof(object)); } // ArrayConstructor.New(object[]) generator.Call(ReflectionHelpers.Array_New); } else if (this.Value is Dictionary<string, object>) { // This is an object literal. var properties = (Dictionary<string, object>)this.Value; // Create a new object. EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Object); generator.Call(ReflectionHelpers.Object_Construct); foreach (var keyValuePair in properties) { string propertyName = keyValuePair.Key; object propertyValue = keyValuePair.Value; generator.Duplicate(); generator.LoadString(propertyName); if (propertyValue is Expression) { // Add a new property to the object. var dataPropertyValue = (Expression)propertyValue; dataPropertyValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (dataPropertyValue is FunctionExpression) ((FunctionExpression)dataPropertyValue).GenerateDisplayName(generator, optimizationInfo, propertyName, false); EmitConversion.ToAny(generator, dataPropertyValue.ResultType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_String); } else if (propertyValue is Parser.ObjectLiteralAccessor) { // Add a new getter/setter to the object. var accessorValue = (Parser.ObjectLiteralAccessor)propertyValue; if (accessorValue.Getter != null) { accessorValue.Getter.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. accessorValue.Getter.GenerateDisplayName(generator, optimizationInfo, "get " + propertyName, true); EmitConversion.ToAny(generator, accessorValue.Getter.ResultType); } else generator.LoadNull(); if (accessorValue.Setter != null) { accessorValue.Setter.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. accessorValue.Setter.GenerateDisplayName(generator, optimizationInfo, "set " + propertyName, true); EmitConversion.ToAny(generator, accessorValue.Setter.ResultType); } else generator.LoadNull(); generator.LoadInt32((int)Library.PropertyAttributes.FullAccess); generator.NewObject(ReflectionHelpers.PropertyDescriptor_Constructor3); generator.LoadBoolean(false); generator.Call(ReflectionHelpers.ObjectInstance_DefineProperty); generator.Pop(); } else throw new InvalidOperationException("Invalid property value type in object literal."); } } else throw new NotImplementedException("Unknown literal type."); }
/// <summary> /// Pops the value on the stack, converts it to a javascript object, then pushes the result /// onto the stack. /// </summary> /// <param name="generator"> The IL generator. </param> /// <param name="fromType"> The type to convert from. </param> /// <param name="path"> The path of the javascript source file that is currently executing. </param> /// <param name="function"> The name of the currently executing function. </param> /// <param name="line"> The line number of the statement that is currently executing. </param> public static void ToObject(ILGenerator generator, PrimitiveType fromType, string path, string function, int line) { // Check that a conversion is actually necessary. if (fromType == PrimitiveType.Object) return; switch (fromType) { case PrimitiveType.Undefined: // Converting from undefined always throws an exception. EmitHelpers.EmitThrow(generator, ErrorType.TypeError, "Undefined cannot be converted to an object", path, function, line); break; case PrimitiveType.Null: // Converting from null always throws an exception. EmitHelpers.EmitThrow(generator, ErrorType.TypeError, "Null cannot be converted to an object", path, function, line); break; case PrimitiveType.Bool: case PrimitiveType.Int32: case PrimitiveType.UInt32: case PrimitiveType.Number: case PrimitiveType.String: case PrimitiveType.ConcatenatedString: case PrimitiveType.Any: // Otherwise, fall back to calling TypeConverter.ToObject() ToAny(generator, fromType); var temp = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(temp); EmitHelpers.LoadScriptEngine(generator); generator.LoadVariable(temp); generator.ReleaseTemporaryVariable(temp); generator.LoadInt32(line); generator.LoadStringOrNull(path); generator.LoadStringOrNull(function); generator.Call(ReflectionHelpers.TypeConverter_ToObject); break; default: throw new NotImplementedException(string.Format("Unsupported primitive type: {0}", fromType)); } }
/// <summary> /// Pushes the value of the reference onto the stack. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to output <c>null</c> instead. </param> public void GenerateGet(ILGenerator generator, OptimizationInfo optimizationInfo, bool throwIfUnresolvable) { // This method generates code to retrieve the value of a variable, given the name of // variable and scope in which the variable is being referenced. The variable was // not necessary declared in this scope - it might be declared in any of the parent // scopes (together called a scope chain). The general algorithm is to start at the // head of the chain and search backwards until the variable is found. There are // two types of scopes: declarative scopes and object scopes. Object scopes are hard - // it cannot be known at compile time whether the variable exists or not so runtime // checks have to be inserted. Declarative scopes are easier - variables have to be // declared and cannot be deleted. There is one tricky bit: new variables can be // introduced into a declarative scope at runtime by a non-strict eval() statement. // Even worse, variables that were introduced by means of an eval() *can* be deleted. var scope = this.Scope; ILLocalVariable scopeVariable = null; var endOfGet = generator.CreateLabel(); do { if (scope is DeclarativeScope) { // The variable was declared in this scope. var variable = scope.GetDeclaredVariable(this.Name); if (variable != null) { if (scope.ExistsAtRuntime == false) { // The scope has been optimized away. The value of the variable is stored // in an ILVariable. // Declare an IL local variable if no storage location has been allocated yet. if (variable.Store == null) { variable.Store = generator.DeclareVariable(typeof(object), variable.Name); } // Load the value from the variable. generator.LoadVariable(variable.Store); // Ensure that we match ResultType. EmitConversion.Convert(generator, variable.Type, this.ResultType, optimizationInfo); } else { // scope.Values[index] if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(DeclarativeScope)); generator.Call(ReflectionHelpers.DeclarativeScope_Values); generator.LoadInt32(variable.Index); generator.LoadArrayElement(typeof(object)); } // The variable was found - no need to search any more parent scopes. break; } else { // The variable was not defined at compile time, but may have been // introduced by an eval() statement. if (optimizationInfo.MethodOptimizationHints.HasEval == true) { // Check the variable exists: if (scope.HasValue(variableName) == true) { if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_HasValue); var hasValueClause = generator.CreateLabel(); generator.BranchIfFalse(hasValueClause); // Load the value of the variable. if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_GetValue); generator.Branch(endOfGet); // } generator.DefineLabelPosition(hasValueClause); } } } else { if (scope.ParentScope == null) { // Global variable access // ------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // xxx = object.InlineGetPropertyValue("variable", out __object_property_cachedIndex, out __object_cacheKey) // else // xxx = object.InlinePropertyValues[__object_property_cachedIndex]; // Get a reference to the global object. if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // value = object.InlineGetProperty("property", out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(this.Name); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineGetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // value = object.InlinePropertyValues[__object_property_cachedIndex]; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); // Check if the value is null. generator.Duplicate(); generator.BranchIfNotNull(endOfGet); if (scope.ParentScope != null) { generator.Pop(); } } else { // Gets the value of a variable in an object scope. if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_Object); // Check if the value is null. generator.Duplicate(); generator.BranchIfNotNull(endOfGet); if (scope.ParentScope != null) { generator.Pop(); } } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { if (scopeVariable == null) { scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // Throw an error if the name does not exist and throwIfUnresolvable is true. if (scope == null && throwIfUnresolvable == true) { EmitHelpers.EmitThrow(generator, ErrorType.ReferenceError, this.Name + " is not defined", optimizationInfo); } // Release the temporary variable. if (scopeVariable != null) { generator.ReleaseTemporaryVariable(scopeVariable); } // Define a label at the end. generator.DefineLabelPosition(endOfGet); // Object scope references may have side-effects (because of getters) so if the value // is to be ignored we evaluate the value then pop the value from the stack. //if (optimizationInfo.SuppressReturnValue == true) // generator.Pop(); }
/// <summary> /// Pops the value on the stack, converts it to an integer, then pushes the integer result /// onto the stack. /// </summary> /// <param name="generator"> The IL generator. </param> /// <param name="fromType"> The type to convert from. </param> public static void ToInteger(ILGenerator generator, PrimitiveType fromType) { // Check that a conversion is actually necessary. if (fromType == PrimitiveType.Int32 || fromType == PrimitiveType.UInt32 || fromType == PrimitiveType.Bool) return; switch (fromType) { case PrimitiveType.Undefined: case PrimitiveType.Null: // Converting from undefined or null produces 0. generator.Pop(); generator.LoadInt32(0); break; case PrimitiveType.Number: // Converting from a number produces the following: // Any number between -2147483648 and +2147483647 -> itself // Any number smaller than -2147483648 -> -2147483648 // Any number larger than +2147483647 -> +2147483647 // NaN -> 0 // bool isPositiveInfinity = input > 2147483647.0 var isPositiveInfinity = generator.CreateTemporaryVariable(typeof(bool)); generator.Duplicate(); generator.LoadDouble(2147483647.0); generator.CompareGreaterThan(); generator.StoreVariable(isPositiveInfinity); // bool notNaN = input == input var notNaN = generator.CreateTemporaryVariable(typeof(bool)); generator.Duplicate(); generator.Duplicate(); generator.CompareEqual(); generator.StoreVariable(notNaN); // input = (int)input // Infinity -> -2147483648 // -Infinity -> -2147483648 // NaN -> -2147483648 generator.ConvertToInteger(); // input = input & -((int)notNaN) generator.LoadVariable(notNaN); generator.Negate(); generator.BitwiseAnd(); // input = input - (int)isPositiveInfinity generator.LoadVariable(isPositiveInfinity); generator.Subtract(); // The temporary variables are no longer needed. generator.ReleaseTemporaryVariable(notNaN); generator.ReleaseTemporaryVariable(isPositiveInfinity); break; case PrimitiveType.String: case PrimitiveType.ConcatenatedString: case PrimitiveType.Any: case PrimitiveType.Object: // Otherwise, fall back to calling TypeConverter.ToInteger() generator.Call(ReflectionHelpers.TypeConverter_ToInteger); break; default: throw new NotImplementedException(string.Format("Unsupported primitive type: {0}", fromType)); } }
/// <summary> /// Pops the value on the stack, converts it to an object, then pushes the result onto the /// stack. /// </summary> /// <param name="generator"> The IL generator. </param> /// <param name="fromType"> The type to convert from. </param> internal static void EmitConversionToObject(ILGenerator generator, Type fromType) { // If the from type is a reference type, check for null. ILLabel endOfNullCheck = null; if (fromType.IsValueType == false) { var startOfElse = generator.CreateLabel(); endOfNullCheck = generator.CreateLabel(); generator.Duplicate(); generator.BranchIfNotNull(startOfElse); generator.Pop(); EmitHelpers.EmitNull(generator); generator.Branch(endOfNullCheck); generator.DefineLabelPosition(startOfElse); } switch (Type.GetTypeCode(fromType)) { case TypeCode.Boolean: generator.Box(typeof(bool)); break; case TypeCode.Byte: generator.Box(typeof(int)); break; case TypeCode.Char: generator.LoadInt32(1); generator.NewObject(ReflectionHelpers.String_Constructor_Char_Int); break; case TypeCode.DBNull: throw new NotSupportedException("DBNull is not a supported return type."); case TypeCode.Decimal: generator.Call(ReflectionHelpers.Decimal_ToDouble); generator.Box(typeof(double)); break; case TypeCode.Double: generator.Box(typeof(double)); break; case TypeCode.Empty: throw new NotSupportedException("Empty is not a supported return type."); case TypeCode.Int16: generator.Box(typeof(int)); break; case TypeCode.Int32: generator.Box(typeof(int)); break; case TypeCode.Int64: generator.ConvertToDouble(); generator.Box(typeof(double)); break; case TypeCode.DateTime: case TypeCode.Object: // Check if the type must be wrapped with a ClrInstanceWrapper. // Note: if the type is a value type it cannot be a primitive or it would // have been handled elsewhere in the switch. ILLabel endOfWrapCheck = null; if (fromType.IsValueType == false) { generator.Duplicate(); generator.Call(ReflectionHelpers.TypeUtilities_IsPrimitiveOrObject); endOfWrapCheck = generator.CreateLabel(); generator.BranchIfTrue(endOfWrapCheck); } // The type must be wrapped. var temp = generator.CreateTemporaryVariable(fromType); generator.StoreVariable(temp); generator.LoadArgument(0); generator.LoadVariable(temp); if (fromType.IsValueType == true) generator.Box(fromType); generator.ReleaseTemporaryVariable(temp); generator.NewObject(ReflectionHelpers.ClrInstanceWrapper_Constructor); // End of wrap check. if (fromType.IsValueType == false) generator.DefineLabelPosition(endOfWrapCheck); break; case TypeCode.SByte: generator.Box(typeof(int)); break; case TypeCode.Single: generator.Box(typeof(double)); break; case TypeCode.String: break; case TypeCode.UInt16: generator.Box(typeof(int)); break; case TypeCode.UInt32: generator.Box(typeof(uint)); break; case TypeCode.UInt64: generator.ConvertUnsignedToDouble(); generator.Box(typeof(double)); break; } // Label the end of the null check. if (fromType.IsValueType == false) generator.DefineLabelPosition(endOfNullCheck); }
/// <summary> /// Stores the value on the top of the stack in the reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="valueType"> The primitive type of the value that is on the top of the stack. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to create a new property instead. </param> public void GenerateSet(ILGenerator generator, OptimizationInfo optimizationInfo, PrimitiveType valueType, bool throwIfUnresolvable) { string propertyName = null; TypeOfMemberAccess memberAccessType = DetermineTypeOfMemberAccess(optimizationInfo, out propertyName); if (memberAccessType == TypeOfMemberAccess.ArrayIndex) { // Array indexer // ------------- // xxx = object[index] // Call the indexer. EmitConversion.ToAny(generator, valueType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Int); } else if (memberAccessType == TypeOfMemberAccess.Static) { // Named property modification (e.g. x.property = y) // ------------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // object.InlineSetPropertyValue("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) // else // object.InlinePropertyValues[__object_property_cachedIndex] = value; // Convert the value to an object and store it in a temporary variable. var value = generator.CreateTemporaryVariable(typeof(object)); EmitConversion.ToAny(generator, valueType); generator.StoreVariable(value); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // xxx = object.InlineSetPropertyValue("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(propertyName); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineSetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // object.InlinePropertyValues[__object_property_cachedIndex] = value; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadVariable(value); generator.StoreArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); // The temporary variable is no longer needed. generator.ReleaseTemporaryVariable(value); } else { // Dynamic property access // ----------------------- // xxx = object.Get(x) // Call the indexer. EmitConversion.ToAny(generator, valueType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object); } }
/// <summary> /// Stores the value on the top of the stack in the reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="valueType"> The primitive type of the value that is on the top of the stack. </param> public void GenerateSet(ILGenerator generator, OptimizationInfo optimizationInfo, PrimitiveType valueType) { string propertyName = null; TypeOfMemberAccess memberAccessType = DetermineTypeOfMemberAccess(optimizationInfo, out propertyName); if (memberAccessType == TypeOfMemberAccess.ArrayIndex) { // Array indexer // ------------- // xxx = object[index] // Call the indexer. EmitConversion.ToAny(generator, valueType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Int); generator.Pop(); } else if (memberAccessType == TypeOfMemberAccess.Static) { // Named property modification (e.g. object.property = value) // ---------------------------------------------------------- // object.SetPropertyValue(property, value, strictMode) // Convert the value to an object and store it in a temporary variable. var value = generator.CreateTemporaryVariable(typeof(object)); EmitConversion.ToAny(generator, valueType); generator.StoreVariable(value); // Use a PropertyReference to speed up access if we are inside a loop. if (optimizationInfo.InsideLoop) { ILLocalVariable propertyReference = optimizationInfo.GetPropertyReferenceVariable(generator, propertyName); generator.LoadVariable(propertyReference); generator.Duplicate(); var afterIf = generator.CreateLabel(); generator.BranchIfNotNull(afterIf); generator.Pop(); generator.LoadString(propertyName); generator.NewObject(ReflectionHelpers.PropertyName_Constructor); generator.Duplicate(); generator.StoreVariable(propertyReference); generator.DefineLabelPosition(afterIf); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_PropertyReference); generator.Pop(); } else { generator.LoadString(propertyName); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object); generator.Pop(); } generator.ReleaseTemporaryVariable(value); } else { // Dynamic property access // ----------------------- // object.SetPropertyValue(property, value, strictMode) EmitConversion.ToAny(generator, valueType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object); generator.Pop(); } }
/// <summary> /// Generates CIL for the expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Literals cannot have side-effects so if a return value is not expected then generate // nothing. //if (optimizationInfo.SuppressReturnValue == true) // return; if (this.Value is int) { generator.LoadInt32((int)this.Value); } else if (this.Value is double) { generator.LoadDouble((double)this.Value); } else if (this.Value is string) { generator.LoadString((string)this.Value); } else if (this.Value is bool) { generator.LoadBoolean((bool)this.Value); } else if (this.Value is RegularExpressionLiteral) { // RegExp var sharedRegExpVariable = optimizationInfo.GetRegExpVariable(generator, (RegularExpressionLiteral)this.Value); var label1 = generator.CreateLabel(); var label2 = generator.CreateLabel(); // if (sharedRegExp == null) { generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.BranchIfNotEqual(label1); // sharedRegExp = Global.RegExp.Construct(source, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadString(((RegularExpressionLiteral)this.Value).Pattern); generator.LoadString(((RegularExpressionLiteral)this.Value).Flags); generator.Call(ReflectionHelpers.RegExp_Construct); generator.Duplicate(); generator.StoreVariable(sharedRegExpVariable); // } else { generator.Branch(label2); generator.DefineLabelPosition(label1); // Global.RegExp.Construct(sharedRegExp, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.Call(ReflectionHelpers.RegExp_Construct); // } generator.DefineLabelPosition(label2); } else if (this.Value == Null.Value) { // Null. EmitHelpers.EmitNull(generator); } else if (this.Value == Undefined.Value) { // Undefined. EmitHelpers.EmitUndefined(generator); } else if (this.Value is List <Expression> ) { // Construct an array literal. var arrayLiteral = (List <Expression>) this.Value; // Operands for ArrayConstructor.New() are: an ArrayConstructor instance (ArrayConstructor), an array (object[]) // ArrayConstructor EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Array); // object[] generator.LoadInt32(arrayLiteral.Count); generator.NewArray(typeof(object)); for (int i = 0; i < arrayLiteral.Count; i++) { // Operands for StoreArrayElement() are: an array (object[]), index (int), value (object). // Array generator.Duplicate(); // Index generator.LoadInt32(i); // Value var elementExpression = arrayLiteral[i]; if (elementExpression == null) { generator.LoadNull(); } else { elementExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, elementExpression.ResultType); } // Store the element value. generator.StoreArrayElement(typeof(object)); } // ArrayConstructor.New(object[]) generator.Call(ReflectionHelpers.Array_New); } else if (this.Value is Dictionary <string, object> ) { // This is an object literal. var properties = (Dictionary <string, object>) this.Value; // Create a new object. EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Object); generator.Call(ReflectionHelpers.Object_Construct); foreach (var keyValuePair in properties) { string propertyName = keyValuePair.Key; object propertyValue = keyValuePair.Value; generator.Duplicate(); generator.LoadString(propertyName); if (propertyValue is Expression) { // Add a new property to the object. var dataPropertyValue = (Expression)propertyValue; dataPropertyValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (dataPropertyValue is FunctionExpression) { ((FunctionExpression)dataPropertyValue).GenerateDisplayName(generator, optimizationInfo, propertyName, false); } EmitConversion.ToAny(generator, dataPropertyValue.ResultType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_String); } else if (propertyValue is Parser.ObjectLiteralAccessor) { // Add a new getter/setter to the object. var accessorValue = (Parser.ObjectLiteralAccessor)propertyValue; if (accessorValue.Getter != null) { accessorValue.Getter.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. accessorValue.Getter.GenerateDisplayName(generator, optimizationInfo, "get " + propertyName, true); EmitConversion.ToAny(generator, accessorValue.Getter.ResultType); } else { generator.LoadNull(); } if (accessorValue.Setter != null) { accessorValue.Setter.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. accessorValue.Setter.GenerateDisplayName(generator, optimizationInfo, "set " + propertyName, true); EmitConversion.ToAny(generator, accessorValue.Setter.ResultType); } else { generator.LoadNull(); } generator.LoadInt32((int)Library.PropertyAttributes.FullAccess); generator.NewObject(ReflectionHelpers.PropertyDescriptor_Constructor3); generator.LoadBoolean(false); generator.Call(ReflectionHelpers.ObjectInstance_DefineProperty); generator.Pop(); } else { throw new InvalidOperationException("Invalid property value type in object literal."); } } } else { throw new NotImplementedException("Unknown literal type."); } }
/// <summary> /// Pushes the value of the reference onto the stack. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to output <c>null</c> instead. </param> public void GenerateGet(ILGenerator generator, OptimizationInfo optimizationInfo, bool throwIfUnresolvable) { string propertyName = null; TypeOfMemberAccess memberAccessType = DetermineTypeOfMemberAccess(optimizationInfo, out propertyName); if (memberAccessType == TypeOfMemberAccess.ArrayIndex) { // Array indexer // ------------- // xxx = object[index] // Call the indexer. generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_Int); } else if (memberAccessType == TypeOfMemberAccess.Static) { // Named property access (e.g. x = y.property) // ------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // xxx = object.InlineGetPropertyValue("property", out __object_property_cachedIndex, out __object_cacheKey) // else // xxx = object.InlinePropertyValues[__object_property_cachedIndex]; // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // value = object.InlineGetProperty("property", out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(propertyName); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineGetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // value = object.InlinePropertyValues[__object_property_cachedIndex]; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); } else { // Dynamic property access // ----------------------- // xxx = object.Get(x) // Call Get(object) generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_String); } }
/// <summary> /// Pushes the value of the reference onto the stack. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to output <c>null</c> instead. </param> public void GenerateGet(ILGenerator generator, OptimizationInfo optimizationInfo, bool throwIfUnresolvable) { string propertyName = null; TypeOfMemberAccess memberAccessType = DetermineTypeOfMemberAccess(optimizationInfo, out propertyName); if (memberAccessType == TypeOfMemberAccess.ArrayIndex) { // Array indexer // ------------- // xxx = object[index] // Call the indexer. generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_Int); } else if (memberAccessType == TypeOfMemberAccess.Static) { // Named property access (e.g. x = y.property) // ------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // xxx = object.InlineGetPropertyValue("property", out __object_property_cachedIndex, out __object_cacheKey) // else // xxx = object.InlinePropertyValues[__object_property_cachedIndex]; // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // value = object.InlineGetProperty("property", out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(propertyName); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineGetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // value = object.InlinePropertyValues[__object_property_cachedIndex]; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); } else { // Dynamic property access // ----------------------- // xxx = object.Get(x) // Call Get(object) generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_Object); } }
/// <summary> /// Generates code that creates a new scope. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> internal void GenerateScopeCreation(ILGenerator generator, OptimizationInfo optimizationInfo) { // Make sure we don't generate the scope twice. if (GenerateScopeCreationWasCalled) { return; } GenerateScopeCreationWasCalled = true; // We can optimize this away if there are zero variables declared in the scope, // UNLESS it's a with scope (as then we need something to bind to). if (this.variables.Count == 0 && Type != ScopeType.With) { return; } // If there is no eval(), no arguments usage and no nested functions, then we can use // IL variables instead of using RuntimeScope. if ((Type == ScopeType.TopLevelFunction || Type == ScopeType.Block) && optimizationInfo.OptimizeDeclarativeScopes) { foreach (var variable in this.variables.Values) { variable.Store = generator.DeclareVariable(variable.Type, variable.Name); if (variable.Type == PrimitiveType.Any) { generator.LoadNull(); generator.StoreVariable(variable.Store); } } return; } // The fallback: use RuntimeScope. EmitHelpers.LoadExecutionContext(generator); // parentScope if (ParentScope != null) { ParentScope.GenerateReference(generator, optimizationInfo); } else { generator.LoadNull(); } var varList = new List <DeclaredVariable>(); var letList = new List <DeclaredVariable>(); var constList = new List <DeclaredVariable>(); foreach (var variable in this.variables.Values) { if (variable.Keyword == KeywordToken.Var) { varList.Add(variable); } else if (variable.Keyword == KeywordToken.Const) { constList.Add(variable); } else { letList.Add(variable); } } varList.Sort((a, b) => a.Index - b.Index); letList.Sort((a, b) => a.Index - b.Index); constList.Sort((a, b) => a.Index - b.Index); int i; // scopeType generator.LoadEnumValue(Type); // varNames if (varList.Count == 0) { generator.LoadNull(); } else { generator.LoadInt32(varList.Count); generator.NewArray(typeof(string)); i = 0; foreach (var variable in varList) { generator.Duplicate(); generator.LoadInt32(i++); generator.LoadString(variable.Name); generator.StoreArrayElement(typeof(string)); } } // letNames if (letList.Count == 0) { generator.LoadNull(); } else { generator.LoadInt32(letList.Count); generator.NewArray(typeof(string)); i = 0; foreach (var variable in letList) { generator.Duplicate(); generator.LoadInt32(i++); generator.LoadString(variable.Name); generator.StoreArrayElement(typeof(string)); } } // constNames if (constList.Count == 0) { generator.LoadNull(); } else { generator.LoadInt32(constList.Count); generator.NewArray(typeof(string)); i = 0; foreach (var variable in constList) { generator.Duplicate(); generator.LoadInt32(i++); generator.LoadString(variable.Name); generator.StoreArrayElement(typeof(string)); } } // executionContext.CreateRuntimeScope(parentScope, varNames, letNames, constNames) generator.Call(ReflectionHelpers.ExecutionContext_CreateRuntimeScope); // Store the RuntimeScope instance in a variable. GeneratedRuntimeScope = generator.DeclareVariable(typeof(RuntimeScope), "scope"); generator.StoreVariable(GeneratedRuntimeScope); }
/// <summary> /// Generates CIL for an increment or decrement expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="target"> The target to modify. </param> /// <param name="postfix"> <c>true</c> if this is the postfix version of the operator; /// <c>false</c> otherwise. </param> /// <param name="increment"> <c>true</c> if this is the increment operator; <c>false</c> if /// this is the decrement operator. </param> private void GenerateIncrementOrDecrement(ILGenerator generator, OptimizationInfo optimizationInfo, IReferenceExpression target, bool postfix, bool increment) { // Note: increment and decrement can produce a number that is out of range if the // target is of type Int32. The only time this should happen is for a loop variable // where the range has been carefully checked to make sure an out of range condition // cannot happen. // Evaluate the left hand side only once. target.GenerateReference(generator, optimizationInfo); target.DuplicateReference(generator, optimizationInfo); // For the GenerateSet, later on. // Get the target value. target.GenerateGet(generator, optimizationInfo, true); // Convert it to a number. if (target.Type != PrimitiveType.Int32) { EmitConversion.ToNumber(generator, target.Type); } // If this is PostIncrement or PostDecrement, store the value so it can be returned later. var result = generator.CreateTemporaryVariable(target.Type == PrimitiveType.Int32 ? PrimitiveType.Int32 : PrimitiveType.Number); if (postfix == true) { generator.Duplicate(); generator.StoreVariable(result); } // Load the increment constant. if (target.Type == PrimitiveType.Int32) { generator.LoadInt32(1); } else { generator.LoadDouble(1.0); } // Add or subtract the constant to the target value. if (increment == true) { generator.Add(); } else { generator.Subtract(); } // If this is PreIncrement or PreDecrement, store the value so it can be returned later. if (postfix == false) { generator.Duplicate(); generator.StoreVariable(result); } // Store the value. target.GenerateSet(generator, optimizationInfo, target.Type == PrimitiveType.Int32 ? PrimitiveType.Int32 : PrimitiveType.Number, optimizationInfo.StrictMode); // Restore the expression result. generator.LoadVariable(result); generator.ReleaseTemporaryVariable(result); }
/// <summary> /// Deletes the reference and pushes <c>true</c> if the delete succeeded, or <c>false</c> /// if the delete failed. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public void GenerateDelete(ILGenerator generator, OptimizationInfo optimizationInfo) { // Deleting a variable is not allowed in strict mode. if (optimizationInfo.StrictMode == true) throw new JavaScriptException(optimizationInfo.Engine, ErrorType.SyntaxError, string.Format("Cannot delete {0} because deleting a variable or argument is not allowed in strict mode", this.Name), optimizationInfo.SourceSpan.StartLine, optimizationInfo.Source.Path, optimizationInfo.FunctionName); var endOfDelete = generator.CreateLabel(); var scope = this.Scope; ILLocalVariable scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); generator.StoreVariable(scopeVariable); do { if (scope is DeclarativeScope) { var variable = scope.GetDeclaredVariable(this.Name); if (variable != null) { // The variable is known at compile-time. if (variable.Deletable == false) { // The variable cannot be deleted - return false. generator.LoadBoolean(false); } else { // The variable can be deleted (it was declared inside an eval()). // Delete the variable. generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_Delete); } break; } else { // The variable was not defined at compile time, but may have been // introduced by an eval() statement. if (optimizationInfo.MethodOptimizationHints.HasEval == true) { // Check the variable exists: if (scope.HasValue(variableName) == true) { generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_HasValue); var hasValueClause = generator.CreateLabel(); generator.BranchIfFalse(hasValueClause); // If the variable does exist, return true. generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_Delete); generator.Branch(endOfDelete); // } generator.DefineLabelPosition(hasValueClause); } } } else { // Check if the property exists by calling scope.ScopeObject.HasProperty(propertyName) generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); generator.Duplicate(); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.ObjectInstance_HasProperty); // Jump past the delete if the property doesn't exist. var endOfExistsCheck = generator.CreateLabel(); generator.BranchIfFalse(endOfExistsCheck); // Call scope.ScopeObject.Delete(key, false) generator.LoadString(this.Name); generator.LoadBoolean(false); generator.Call(ReflectionHelpers.ObjectInstance_Delete); generator.Branch(endOfDelete); generator.DefineLabelPosition(endOfExistsCheck); generator.Pop(); // If the name is not defined, return true. if (scope.ParentScope == null) { generator.LoadBoolean(true); } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { generator.LoadVariable(scopeVariable); generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // Release the temporary variable. generator.ReleaseTemporaryVariable(scopeVariable); // Define a label at the end. generator.DefineLabelPosition(endOfDelete); // Delete obviously has side-effects so we evaluate the return value then pop it from // the stack. //if (optimizationInfo.SuppressReturnValue == true) // generator.Pop(); }
/// <summary> /// Pops the value on the stack, converts it to a boolean, then pushes the boolean result /// onto the stack. /// </summary> /// <param name="generator"> The IL generator. </param> /// <param name="fromType"> The type to convert from. </param> public static void ToBool(ILGenerator generator, PrimitiveType fromType) { // Check that a conversion is actually necessary. if (fromType == PrimitiveType.Bool) { return; } switch (fromType) { case PrimitiveType.Undefined: case PrimitiveType.Null: // Converting from undefined or null produces false. generator.Pop(); generator.LoadInt32(0); break; case PrimitiveType.Int32: case PrimitiveType.UInt32: // Converting from an integer produces true if the integer is non-zero. generator.LoadInt32(0); generator.CompareGreaterThanUnsigned(); break; case PrimitiveType.Number: // Converting from a number produces true if the number is non-zero and not NaN. var temp = generator.CreateTemporaryVariable(fromType); generator.StoreVariable(temp); // input != 0 generator.LoadVariable(temp); generator.LoadDouble(0.0); generator.CompareEqual(); generator.LoadInt32(0); generator.CompareEqual(); // input == input generator.LoadVariable(temp); generator.Duplicate(); generator.CompareEqual(); // && generator.CompareEqual(); // The temporary variable is no longer needed. generator.ReleaseTemporaryVariable(temp); break; case PrimitiveType.String: // Converting from a string produces true if the string is not empty. generator.Call(ReflectionHelpers.String_Length); generator.LoadInt32(0); generator.CompareGreaterThan(); break; case PrimitiveType.ConcatenatedString: // Converting from a string produces true if the string is not empty. generator.Call(ReflectionHelpers.ConcatenatedString_Length); generator.LoadInt32(0); generator.CompareGreaterThan(); break; case PrimitiveType.Any: case PrimitiveType.Object: // Otherwise, fall back to calling TypeConverter.ToBoolean() generator.Call(ReflectionHelpers.TypeConverter_ToBoolean); break; default: throw new NotImplementedException(string.Format("Unsupported primitive type: {0}", fromType)); } }
/// <summary> /// Stores the value on the top of the stack in the reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="valueType"> The primitive type of the value that is on the top of the stack. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to create a new property instead. </param> public void GenerateSet(ILGenerator generator, OptimizationInfo optimizationInfo, PrimitiveType valueType, bool throwIfUnresolvable) { // The value is initially on the top of the stack but is stored in this variable // at the last possible moment. ILLocalVariable value = null; var scope = this.Scope; ILLocalVariable scopeVariable = null; var endOfSet = generator.CreateLabel(); do { if (scope is DeclarativeScope) { // Get information about the variable. var variable = scope.GetDeclaredVariable(this.Name); if (variable != null) { // The variable was declared in this scope. if (scope.ExistsAtRuntime == false) { // The scope has been optimized away. The value of the variable is stored // in an ILVariable. // Declare an IL local variable if no storage location has been allocated yet. if (variable.Store == null) variable.Store = generator.DeclareVariable(typeof(object), variable.Name); if (value == null) { // The value to store is on the top of the stack - convert it to the // storage type of the variable. EmitConversion.Convert(generator, valueType, variable.Type, optimizationInfo); } else { // The value to store is in a temporary variable. generator.LoadVariable(value); EmitConversion.Convert(generator, PrimitiveType.Any, variable.Type, optimizationInfo); } // Store the value in the variable. generator.StoreVariable(variable.Store); } else if (variable.Writable == true) { if (value == null) { // The value to store is on the top of the stack - convert it to an // object and store it in a temporary variable. EmitConversion.Convert(generator, valueType, PrimitiveType.Any, optimizationInfo); value = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(value); } // scope.Values[index] = value if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.Call(ReflectionHelpers.DeclarativeScope_Values); generator.LoadInt32(variable.Index); generator.LoadVariable(value); generator.StoreArrayElement(typeof(object)); } else { // The variable exists, but is read-only. // Pop the value off the stack (if it is still there). if (value == null) generator.Pop(); } // The variable was found - no need to search any more parent scopes. break; } else { // The variable was not defined at compile time, but may have been // introduced by an eval() statement. if (optimizationInfo.MethodOptimizationHints.HasEval == true) { if (value == null) { // The value to store is on the top of the stack - convert it to an // object and store it in a temporary variable. EmitConversion.Convert(generator, valueType, PrimitiveType.Any, optimizationInfo); value = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(value); } // Check the variable exists: if (scope.HasValue(variableName) == true) { if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_HasValue); var hasValueClause = generator.CreateLabel(); generator.BranchIfFalse(hasValueClause); // Set the value of the variable. if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.LoadVariable(value); generator.Call(ReflectionHelpers.Scope_SetValue); generator.Branch(endOfSet); // } generator.DefineLabelPosition(hasValueClause); } } } else { if (value == null) { // The value to store is on the top of the stack - convert it to an // object and store it in a temporary variable. EmitConversion.Convert(generator, valueType, PrimitiveType.Any, optimizationInfo); value = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(value); } if (scope.ParentScope == null) { // Optimization: if this is the global scope, use hidden classes to // optimize variable access. // Global variable modification // ---------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // object.InlineSetPropertyValueIfExists("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) // else // object.InlinePropertyValues[__object_property_cachedIndex] = value; // Get a reference to the global object. if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // xxx = object.InlineSetPropertyValueIfExists("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(this.Name); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); if (throwIfUnresolvable == false) { // Set the property value unconditionally. generator.Call(ReflectionHelpers.ObjectInstance_InlineSetPropertyValue); } else { // Set the property value if the property exists. generator.Call(ReflectionHelpers.ObjectInstance_InlineSetPropertyValueIfExists); // The return value is true if the property was defined, and false if it wasn't. generator.BranchIfTrue(endOfSet); } var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // object.InlinePropertyValues[__object_property_cachedIndex] = value; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadVariable(value); generator.StoreArrayElement(typeof(object)); generator.Branch(endOfSet); // End of the if statement generator.DefineLabelPosition(endOfIf); } else { // Slow route. if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); generator.LoadString(this.Name); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); if (scope.ParentScope == null && throwIfUnresolvable == false) { // Set the property value unconditionally. generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object); } else { // Set the property value if the property exists. generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValueIfExists); // The return value is true if the property was defined, and false if it wasn't. generator.BranchIfTrue(endOfSet); } } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { if (scopeVariable == null) { scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // The value might be still on top of the stack. if (value == null && scope == null) generator.Pop(); // Throw an error if the name does not exist and throwIfUnresolvable is true. if (scope == null && throwIfUnresolvable == true) EmitHelpers.EmitThrow(generator, ErrorType.ReferenceError, this.Name + " is not defined", optimizationInfo); // Release the temporary variables. if (value != null) generator.ReleaseTemporaryVariable(value); if (scopeVariable != null) generator.ReleaseTemporaryVariable(scopeVariable); // Define a label at the end. generator.DefineLabelPosition(endOfSet); }
/// <summary> /// Stores the value on the top of the stack in the reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="valueType"> The primitive type of the value that is on the top of the stack. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to create a new property instead. </param> public void GenerateSet(ILGenerator generator, OptimizationInfo optimizationInfo, PrimitiveType valueType, bool throwIfUnresolvable) { // The value is initially on the top of the stack but is stored in this variable // at the last possible moment. ILLocalVariable value = null; var scope = this.Scope; ILLocalVariable scopeVariable = null; var endOfSet = generator.CreateLabel(); do { if (scope is DeclarativeScope) { // Get information about the variable. var variable = scope.GetDeclaredVariable(this.Name); if (variable != null) { // The variable was declared in this scope. if (scope.ExistsAtRuntime == false) { // The scope has been optimized away. The value of the variable is stored // in an ILVariable. // Declare an IL local variable if no storage location has been allocated yet. if (variable.Store == null) { variable.Store = generator.DeclareVariable(typeof(object), variable.Name); } if (value == null) { // The value to store is on the top of the stack - convert it to the // storage type of the variable. EmitConversion.Convert(generator, valueType, variable.Type, optimizationInfo); } else { // The value to store is in a temporary variable. generator.LoadVariable(value); EmitConversion.Convert(generator, PrimitiveType.Any, variable.Type, optimizationInfo); } // Store the value in the variable. generator.StoreVariable(variable.Store); } else if (variable.Writable == true) { if (value == null) { // The value to store is on the top of the stack - convert it to an // object and store it in a temporary variable. EmitConversion.Convert(generator, valueType, PrimitiveType.Any, optimizationInfo); value = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(value); } // scope.Values[index] = value if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(DeclarativeScope)); generator.Call(ReflectionHelpers.DeclarativeScope_Values); generator.LoadInt32(variable.Index); generator.LoadVariable(value); generator.StoreArrayElement(typeof(object)); } else { // The variable exists, but is read-only. // Pop the value off the stack (if it is still there). if (value == null) { generator.Pop(); } } // The variable was found - no need to search any more parent scopes. break; } else { // The variable was not defined at compile time, but may have been // introduced by an eval() statement. if (optimizationInfo.MethodOptimizationHints.HasEval == true) { if (value == null) { // The value to store is on the top of the stack - convert it to an // object and store it in a temporary variable. EmitConversion.Convert(generator, valueType, PrimitiveType.Any, optimizationInfo); value = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(value); } // Check the variable exists: if (scope.HasValue(variableName) == true) { if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_HasValue); var hasValueClause = generator.CreateLabel(); generator.BranchIfFalse(hasValueClause); // Set the value of the variable. if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.LoadVariable(value); generator.Call(ReflectionHelpers.Scope_SetValue); generator.Branch(endOfSet); // } generator.DefineLabelPosition(hasValueClause); } } } else { if (value == null) { // The value to store is on the top of the stack - convert it to an // object and store it in a temporary variable. EmitConversion.Convert(generator, valueType, PrimitiveType.Any, optimizationInfo); value = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(value); } if (scope.ParentScope == null) { // Optimization: if this is the global scope, use hidden classes to // optimize variable access. // Global variable modification // ---------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // object.InlineSetPropertyValueIfExists("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) // else // object.InlinePropertyValues[__object_property_cachedIndex] = value; // Get a reference to the global object. if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // xxx = object.InlineSetPropertyValueIfExists("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(this.Name); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); if (throwIfUnresolvable == false) { // Set the property value unconditionally. generator.Call(ReflectionHelpers.ObjectInstance_InlineSetPropertyValue); } else { // Set the property value if the property exists. generator.Call(ReflectionHelpers.ObjectInstance_InlineSetPropertyValueIfExists); // The return value is true if the property was defined, and false if it wasn't. generator.BranchIfTrue(endOfSet); } var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // object.InlinePropertyValues[__object_property_cachedIndex] = value; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadVariable(value); generator.StoreArrayElement(typeof(object)); generator.Branch(endOfSet); // End of the if statement generator.DefineLabelPosition(endOfIf); } else { // Slow route. if (scopeVariable == null) { EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); generator.LoadString(this.Name); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); if (scope.ParentScope == null && throwIfUnresolvable == false) { // Set the property value unconditionally. generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object); } else { // Set the property value if the property exists. generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValueIfExists); // The return value is true if the property was defined, and false if it wasn't. generator.BranchIfTrue(endOfSet); } } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { if (scopeVariable == null) { scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // The value might be still on top of the stack. if (value == null && scope == null) { generator.Pop(); } // Throw an error if the name does not exist and throwIfUnresolvable is true. if (scope == null && throwIfUnresolvable == true) { EmitHelpers.EmitThrow(generator, ErrorType.ReferenceError, this.Name + " is not defined", optimizationInfo); } // Release the temporary variables. if (value != null) { generator.ReleaseTemporaryVariable(value); } if (scopeVariable != null) { generator.ReleaseTemporaryVariable(scopeVariable); } // Define a label at the end. generator.DefineLabelPosition(endOfSet); }
/// <summary> /// Generates CIL for the expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Literals cannot have side-effects so if a return value is not expected then generate // nothing. //if (optimizationInfo.SuppressReturnValue == true) // return; if (this.Value is int) { generator.LoadInt32((int)this.Value); } else if (this.Value is double) { generator.LoadDouble((double)this.Value); } else if (this.Value is string) { generator.LoadString((string)this.Value); } else if (this.Value is bool) { generator.LoadBoolean((bool)this.Value); } else if (this.Value is RegularExpressionLiteral) { // RegExp var sharedRegExpVariable = optimizationInfo.GetRegExpVariable(generator, (RegularExpressionLiteral)this.Value); var label1 = generator.CreateLabel(); var label2 = generator.CreateLabel(); // if (sharedRegExp == null) { generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.BranchIfNotEqual(label1); // sharedRegExp = Global.RegExp.Construct(source, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadString(((RegularExpressionLiteral)this.Value).Pattern); generator.LoadString(((RegularExpressionLiteral)this.Value).Flags); generator.Call(ReflectionHelpers.RegExp_Construct); generator.Duplicate(); generator.StoreVariable(sharedRegExpVariable); // } else { generator.Branch(label2); generator.DefineLabelPosition(label1); // Global.RegExp.Construct(sharedRegExp, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.Call(ReflectionHelpers.RegExp_Construct); // } generator.DefineLabelPosition(label2); } else if (this.Value == Null.Value) { // Null. EmitHelpers.EmitNull(generator); } else if (this.Value == Undefined.Value) { // Undefined. EmitHelpers.EmitUndefined(generator); } else if (this.Value is List <Expression> ) { // Construct an array literal. var arrayLiteral = (List <Expression>) this.Value; // Operands for ArrayConstructor.New() are: an ArrayConstructor instance (ArrayConstructor), an array (object[]) // ArrayConstructor EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Array); // object[] generator.LoadInt32(arrayLiteral.Count); generator.NewArray(typeof(object)); for (int i = 0; i < arrayLiteral.Count; i++) { // Operands for StoreArrayElement() are: an array (object[]), index (int), value (object). // Array generator.Duplicate(); // Index generator.LoadInt32(i); // Value var elementExpression = arrayLiteral[i]; if (elementExpression == null) { generator.LoadNull(); } else { elementExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, elementExpression.ResultType); } // Store the element value. generator.StoreArrayElement(typeof(object)); } // ArrayConstructor.New(object[]) generator.Call(ReflectionHelpers.Array_New); } else if (this.Value is List <KeyValuePair <Expression, Expression> > ) { // This is an object literal. var properties = (List <KeyValuePair <Expression, Expression> >) this.Value; // Create a new object. EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Object); generator.Call(ReflectionHelpers.Object_Construct); foreach (var keyValuePair in properties) { Expression propertyName = keyValuePair.Key; Expression propertyValue = keyValuePair.Value; generator.Duplicate(); // The key can be a property name or an expression that evaluates to a name. propertyName.GenerateCode(generator, optimizationInfo); EmitConversion.ToPropertyKey(generator, propertyName.ResultType); var functionValue = propertyValue as FunctionExpression; if (functionValue != null && functionValue.DeclarationType == FunctionDeclarationType.Getter) { // Add a getter to the object. functionValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (propertyName is LiteralExpression && ((LiteralExpression)propertyName).Value is string) { functionValue.GenerateDisplayName(generator, optimizationInfo, "get " + (string)((LiteralExpression)propertyName).Value, true); } generator.Call(ReflectionHelpers.ReflectionHelpers_SetObjectLiteralGetter); } else if (functionValue != null && functionValue.DeclarationType == FunctionDeclarationType.Setter) { // Add a setter to the object. functionValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (propertyName is LiteralExpression && ((LiteralExpression)propertyName).Value is string) { functionValue.GenerateDisplayName(generator, optimizationInfo, "set " + (string)((LiteralExpression)propertyName).Value, true); } generator.Call(ReflectionHelpers.ReflectionHelpers_SetObjectLiteralSetter); } else { // Add a new property to the object. propertyValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (propertyValue is FunctionExpression && propertyName is LiteralExpression && ((LiteralExpression)propertyName).Value is string) { ((FunctionExpression)propertyValue).GenerateDisplayName(generator, optimizationInfo, (string)((LiteralExpression)propertyName).Value, false); } EmitConversion.ToAny(generator, propertyValue.ResultType); generator.Call(ReflectionHelpers.ReflectionHelpers_SetObjectLiteralValue); } } } else { throw new NotImplementedException("Unknown literal type."); } }
/// <summary> /// Generates code to push the "this" value for a function call. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> public void GenerateThis(ILGenerator generator) { // Optimization: if there are no with scopes, simply emit undefined. bool scopeChainHasWithScope = false; var scope = this.Scope; do { if (scope is ObjectScope && ((ObjectScope)scope).ProvidesImplicitThisValue == true) { scopeChainHasWithScope = true; break; } scope = scope.ParentScope; } while (scope != null); if (scopeChainHasWithScope == false) { // No with scopes in the scope chain, use undefined as the "this" value. EmitHelpers.EmitUndefined(generator); return; } var end = generator.CreateLabel(); scope = this.Scope; ILLocalVariable scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); generator.StoreVariable(scopeVariable); do { if (scope is DeclarativeScope) { if (scope.HasDeclaredVariable(this.Name)) { // The variable exists but declarative scopes always produce undefined for // the "this" value. EmitHelpers.EmitUndefined(generator); break; } } else { var objectScope = (ObjectScope)scope; // Check if the property exists by calling scope.ScopeObject.HasProperty(propertyName) if (objectScope.ProvidesImplicitThisValue == false) { EmitHelpers.EmitUndefined(generator); } generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); if (objectScope.ProvidesImplicitThisValue == true) { generator.Duplicate(); } generator.LoadString(this.Name); generator.Call(ReflectionHelpers.ObjectInstance_HasProperty); generator.BranchIfTrue(end); generator.Pop(); // If the name is not defined, use undefined for the "this" value. if (scope.ParentScope == null) { EmitHelpers.EmitUndefined(generator); } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { generator.LoadVariable(scopeVariable); generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // Release the temporary variable. generator.ReleaseTemporaryVariable(scopeVariable); // Define a label at the end. generator.DefineLabelPosition(end); }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals() { NonDefaultBreakStatementBehavior = true, NonDefaultDebugInfoBehavior = true }; GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // Construct a loop expression. // var enumerator = TypeUtilities.EnumeratePropertyNames(rhs).GetEnumerator(); // while (true) { // continue-target: // if (enumerator.MoveNext() == false) // goto break-target; // lhs = enumerator.Current; // // <body statements> // } // break-target: // Call IEnumerable<string> EnumeratePropertyNames(ScriptEngine engine, object obj) EmitHelpers.LoadScriptEngine(generator); this.TargetObject.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.TargetObject.ResultType); generator.Call(ReflectionHelpers.TypeUtilities_EnumeratePropertyNames); // Call IEnumerable<string>.GetEnumerator() generator.Call(ReflectionHelpers.IEnumerable_GetEnumerator); // Store the enumerator in a temporary variable. var enumerator = generator.CreateTemporaryVariable(typeof(IEnumerator<string>)); generator.StoreVariable(enumerator); var breakTarget = generator.CreateLabel(); var continueTarget = generator.DefineLabelPosition(); #if !XBOX // Emit debugging information. if (optimizationInfo.DebugDocument != null) generator.MarkSequencePoint(optimizationInfo.DebugDocument, this.VariableDebugInfo); #endif // if (enumerator.MoveNext() == false) // goto break-target; generator.LoadVariable(enumerator); generator.Call(ReflectionHelpers.IEnumerator_MoveNext); generator.BranchIfFalse(breakTarget); // lhs = enumerator.Current; generator.LoadVariable(enumerator); generator.Call(ReflectionHelpers.IEnumerator_Current); this.Variable.GenerateSet(generator, optimizationInfo, PrimitiveType.String, false); // Emit the body statement(s). optimizationInfo.PushBreakOrContinueInfo(this.Labels, breakTarget, continueTarget, labelledOnly: false); this.Body.GenerateCode(generator, optimizationInfo); optimizationInfo.PopBreakOrContinueInfo(); generator.Branch(continueTarget); generator.DefineLabelPosition(breakTarget); // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Pops the value on the stack, converts it to a boolean, then pushes the boolean result /// onto the stack. /// </summary> /// <param name="generator"> The IL generator. </param> /// <param name="fromType"> The type to convert from. </param> public static void ToBool(ILGenerator generator, PrimitiveType fromType) { // Check that a conversion is actually necessary. if (fromType == PrimitiveType.Bool) return; switch (fromType) { case PrimitiveType.Undefined: case PrimitiveType.Null: // Converting from undefined or null produces false. generator.Pop(); generator.LoadInt32(0); break; case PrimitiveType.Int32: case PrimitiveType.UInt32: // Converting from an integer produces true if the integer is non-zero. generator.LoadInt32(0); generator.CompareGreaterThanUnsigned(); break; case PrimitiveType.Number: // Converting from a number produces true if the number is non-zero and not NaN. var temp = generator.CreateTemporaryVariable(fromType); generator.StoreVariable(temp); // input != 0 generator.LoadVariable(temp); generator.LoadDouble(0.0); generator.CompareEqual(); generator.LoadInt32(0); generator.CompareEqual(); // input == input generator.LoadVariable(temp); generator.Duplicate(); generator.CompareEqual(); // && generator.CompareEqual(); // The temporary variable is no longer needed. generator.ReleaseTemporaryVariable(temp); break; case PrimitiveType.String: // Converting from a string produces true if the string is not empty. generator.Call(ReflectionHelpers.String_Length); generator.LoadInt32(0); generator.CompareGreaterThan(); break; case PrimitiveType.ConcatenatedString: // Converting from a string produces true if the string is not empty. generator.Call(ReflectionHelpers.ConcatenatedString_Length); generator.LoadInt32(0); generator.CompareGreaterThan(); break; case PrimitiveType.Any: case PrimitiveType.Object: // Otherwise, fall back to calling TypeConverter.ToBoolean() generator.Call(ReflectionHelpers.TypeConverter_ToBoolean); break; default: throw new NotImplementedException(string.Format("Unsupported primitive type: {0}", fromType)); } }
/// <summary> /// Stores the value on the top of the stack in the reference. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="valueType"> The primitive type of the value that is on the top of the stack. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to create a new property instead. </param> public void GenerateSet(ILGenerator generator, OptimizationInfo optimizationInfo, PrimitiveType valueType, bool throwIfUnresolvable) { string propertyName = null; TypeOfMemberAccess memberAccessType = DetermineTypeOfMemberAccess(optimizationInfo, out propertyName); if (memberAccessType == TypeOfMemberAccess.ArrayIndex) { // Array indexer // ------------- // xxx = object[index] // Call the indexer. EmitConversion.ToAny(generator, valueType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Int); } else if (memberAccessType == TypeOfMemberAccess.Static) { // Named property modification (e.g. x.property = y) // ------------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // object.InlineSetPropertyValue("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) // else // object.InlinePropertyValues[__object_property_cachedIndex] = value; // Convert the value to an object and store it in a temporary variable. var value = generator.CreateTemporaryVariable(typeof(object)); EmitConversion.ToAny(generator, valueType); generator.StoreVariable(value); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // xxx = object.InlineSetPropertyValue("property", value, strictMode, out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(propertyName); generator.LoadVariable(value); generator.LoadBoolean(optimizationInfo.StrictMode); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineSetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // object.InlinePropertyValues[__object_property_cachedIndex] = value; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadVariable(value); generator.StoreArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); // The temporary variable is no longer needed. generator.ReleaseTemporaryVariable(value); } else { // Dynamic property access // ----------------------- // xxx = object.Get(x) // Call the indexer. EmitConversion.ToAny(generator, valueType); generator.LoadBoolean(optimizationInfo.StrictMode); generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_String); } }
/// <summary> /// Pushes the value of the reference onto the stack. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to output <c>null</c> instead. </param> public void GenerateGet(ILGenerator generator, OptimizationInfo optimizationInfo, bool throwIfUnresolvable) { string propertyName = null; bool isArrayIndex = false; // Right-hand-side can be a property name (a.b) if (this.OperatorType == OperatorType.MemberAccess) { var rhs = this.GetOperand(1) as NameExpression; if (rhs == null) throw new JavaScriptException(optimizationInfo.Engine, "SyntaxError", "Invalid member access", optimizationInfo.SourceSpan.StartLine, optimizationInfo.Source.Path, optimizationInfo.FunctionName); propertyName = rhs.Name; } // Or a constant indexer (a['b']) if (this.OperatorType == OperatorType.Index) { var rhs = this.GetOperand(1) as LiteralExpression; if (rhs != null && (PrimitiveTypeUtilities.IsNumeric(rhs.ResultType) || rhs.ResultType == PrimitiveType.String)) { propertyName = TypeConverter.ToString(rhs.Value); // Or a array index (a[0]) if (rhs.ResultType == PrimitiveType.Int32 || (propertyName != null && Library.ArrayInstance.ParseArrayIndex(propertyName) != uint.MaxValue)) isArrayIndex = true; } } if (isArrayIndex == true) { // Array indexer // ------------- // xxx = object[index] // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType, optimizationInfo); // Load the right-hand side and convert to a uint32. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToUInt32(generator, rhs.ResultType); // Call the indexer. generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_Int); } else if (propertyName != null) { //// Load the left-hand side and convert to an object instance. //var lhs = this.GetOperand(0); //lhs.GenerateCode(generator, optimizationInfo); //EmitConversion.ToObject(generator, lhs.ResultType); //// Call Get(string) //generator.LoadString(propertyName); //generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_String); // Named property access (e.g. x = y.property) // ------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // xxx = object.InlineGetPropertyValue("property", out __object_property_cachedIndex, out __object_cacheKey) // else // xxx = object.InlinePropertyValues[__object_property_cachedIndex]; // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType, optimizationInfo); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // value = object.InlineGetProperty("property", out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(propertyName); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineGetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // value = object.InlinePropertyValues[__object_property_cachedIndex]; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); } else { // Dynamic property access // ----------------------- // xxx = object.Get(x) // Load the left-hand side and convert to an object instance. var lhs = this.GetOperand(0); lhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToObject(generator, lhs.ResultType, optimizationInfo); // Load the property name and convert to a string. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); EmitConversion.ToString(generator, rhs.ResultType); // Call Get(string) generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_String); } }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals() { NonDefaultSourceSpanBehavior = true }; GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // Unlike in .NET, in javascript there are no restrictions on what can appear inside // try, catch and finally blocks. The one restriction which causes problems is the // inability to jump out of .NET finally blocks. This is required when break, continue // or return statements appear inside of a finally block. To work around this, when // inside a finally block these instructions throw an exception instead. // Setting the InsideTryCatchOrFinally flag converts BR instructions into LEAVE // instructions so that the finally block is executed correctly. var previousInsideTryCatchOrFinally = optimizationInfo.InsideTryCatchOrFinally; optimizationInfo.InsideTryCatchOrFinally = true; // Finally requires two exception nested blocks. if (this.FinallyBlock != null) generator.BeginExceptionBlock(); // Begin the exception block. generator.BeginExceptionBlock(); // Generate code for the try block. this.TryBlock.GenerateCode(generator, optimizationInfo); // Generate code for the catch block. ILLocalVariable skipFinallyBlock = null; // Begin a catch block. The exception is on the top of the stack. generator.BeginCatchBlock(typeof(Exception)); // Check the exception is catchable by calling CanCatchException(ex). // We need to handle the case where JS code calls into .NET code which then throws // a JavaScriptException from a different ScriptEngine. // If CatchBlock is null, we need to rethrow the exception in every case. var endOfIfLabel = generator.CreateLabel(); generator.Duplicate(); // ex var exceptionTemporary = generator.CreateTemporaryVariable(typeof(Exception)); generator.StoreVariable(exceptionTemporary); EmitHelpers.LoadScriptEngine(generator); generator.LoadVariable(exceptionTemporary); generator.ReleaseTemporaryVariable(exceptionTemporary); generator.Call(ReflectionHelpers.ScriptEngine_CanCatchException); generator.BranchIfTrue(endOfIfLabel); if (this.FinallyBlock != null) { generator.LoadBoolean(true); skipFinallyBlock = generator.DeclareVariable(typeof(bool), "skipFinallyBlock"); generator.StoreVariable(skipFinallyBlock); } if (this.CatchBlock == null) generator.DefineLabelPosition(endOfIfLabel); generator.Rethrow(); if (this.CatchBlock != null) generator.DefineLabelPosition(endOfIfLabel); if (this.CatchBlock != null) { // Create a new DeclarativeScope. this.CatchScope.GenerateScopeCreation(generator, optimizationInfo); // Store the error object in the variable provided. generator.Call(ReflectionHelpers.JavaScriptException_ErrorObject); var catchVariable = new NameExpression(this.CatchScope, this.CatchVariableName); catchVariable.GenerateSet(generator, optimizationInfo, PrimitiveType.Any, false); // Make sure the scope is reverted even if an exception is thrown. generator.BeginExceptionBlock(); // Emit code for the statements within the catch block. this.CatchBlock.GenerateCode(generator, optimizationInfo); // Revert the scope. generator.BeginFinallyBlock(); this.CatchScope.GenerateScopeDestruction(generator, optimizationInfo); generator.EndExceptionBlock(); } // Generate code for the finally block. if (this.FinallyBlock != null) { generator.BeginFinallyBlock(); // If an exception was thrown that wasn't handled by the catch block, then don't // run the finally block either. This prevents user code from being run when a // ThreadAbortException is thrown. var endOfFinallyBlock = generator.CreateLabel(); generator.LoadVariable(skipFinallyBlock); generator.BranchIfTrue(endOfFinallyBlock); var branches = new List<ILLabel>(); var previousStackSize = optimizationInfo.LongJumpStackSizeThreshold; optimizationInfo.LongJumpStackSizeThreshold = optimizationInfo.BreakOrContinueStackSize; var previousCallback = optimizationInfo.LongJumpCallback; optimizationInfo.LongJumpCallback = (generator2, label) => { // It is not possible to branch out of a finally block - therefore instead of // generating LEAVE instructions we throw an exception then catch it to transfer // control out of the finally block. generator2.LoadInt32(branches.Count); generator2.NewObject(ReflectionHelpers.LongJumpException_Constructor); generator2.Throw(); // Record any branches that are made within the finally code. branches.Add(label); }; // Emit code for the finally block. this.FinallyBlock.GenerateCode(generator, optimizationInfo); // Define the position at the end of the finally block. generator.DefineLabelPosition(endOfFinallyBlock); // End the main exception block. generator.EndExceptionBlock(); // Begin a catch block to catch any LongJumpExceptions. The exception object is on // the top of the stack. generator.BeginCatchBlock(typeof(LongJumpException)); if (branches.Count > 0) { // switch (exception.RouteID) // { // case 0: goto label1; // case 1: goto label2; // } ILLabel[] switchLabels = new ILLabel[branches.Count]; for (int i = 0; i < branches.Count; i++) switchLabels[i] = generator.CreateLabel(); generator.Call(ReflectionHelpers.LongJumpException_RouteID); generator.Switch(switchLabels); for (int i = 0; i < branches.Count; i++) { generator.DefineLabelPosition(switchLabels[i]); generator.Leave(branches[i]); } } // Reset the state we clobbered. optimizationInfo.LongJumpStackSizeThreshold = previousStackSize; optimizationInfo.LongJumpCallback = previousCallback; } // End the exception block. generator.EndExceptionBlock(); // Reset the InsideTryCatchOrFinally flag. optimizationInfo.InsideTryCatchOrFinally = previousInsideTryCatchOrFinally; // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Generates CIL for an assignment expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="target"> The target to modify. </param> private void GenerateAssignment(ILGenerator generator, OptimizationInfo optimizationInfo, IReferenceExpression target) { // Evaluate the left hand side first! target.GenerateReference(generator, optimizationInfo); // Load the value to assign. var rhs = this.GetOperand(1); rhs.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (rhs is FunctionExpression) ((FunctionExpression)rhs).GenerateDisplayName(generator, optimizationInfo, target.ToString(), false); // Store the RHS value so we can return it as the result of the expression. var result = generator.CreateTemporaryVariable(rhs.ResultType); generator.Duplicate(); generator.StoreVariable(result); // Store the value. target.GenerateSet(generator, optimizationInfo, rhs.ResultType, optimizationInfo.StrictMode); // Restore the RHS value. generator.LoadVariable(result); generator.ReleaseTemporaryVariable(result); }
/// <summary> /// Pushes the value of the reference onto the stack. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="throwIfUnresolvable"> <c>true</c> to throw a ReferenceError exception if /// the name is unresolvable; <c>false</c> to output <c>null</c> instead. </param> public void GenerateGet(ILGenerator generator, OptimizationInfo optimizationInfo, bool throwIfUnresolvable) { // This method generates code to retrieve the value of a variable, given the name of // variable and scope in which the variable is being referenced. The variable was // not necessary declared in this scope - it might be declared in any of the parent // scopes (together called a scope chain). The general algorithm is to start at the // head of the chain and search backwards until the variable is found. There are // two types of scopes: declarative scopes and object scopes. Object scopes are hard - // it cannot be known at compile time whether the variable exists or not so runtime // checks have to be inserted. Declarative scopes are easier - variables have to be // declared and cannot be deleted. There is one tricky bit: new variables can be // introduced into a declarative scope at runtime by a non-strict eval() statement. // Even worse, variables that were introduced by means of an eval() *can* be deleted. var scope = this.Scope; ILLocalVariable scopeVariable = null; var endOfGet = generator.CreateLabel(); do { if (scope is DeclarativeScope) { // The variable was declared in this scope. var variable = scope.GetDeclaredVariable(this.Name); if (variable != null) { if (scope.ExistsAtRuntime == false) { // The scope has been optimized away. The value of the variable is stored // in an ILVariable. // Declare an IL local variable if no storage location has been allocated yet. if (variable.Store == null) variable.Store = generator.DeclareVariable(typeof(object), variable.Name); // Load the value from the variable. generator.LoadVariable(variable.Store); // Ensure that we match ResultType. EmitConversion.Convert(generator, variable.Type, this.ResultType, optimizationInfo); } else { // scope.Values[index] if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.Call(ReflectionHelpers.DeclarativeScope_Values); generator.LoadInt32(variable.Index); generator.LoadArrayElement(typeof(object)); } // The variable was found - no need to search any more parent scopes. break; } else { // The variable was not defined at compile time, but may have been // introduced by an eval() statement. if (optimizationInfo.MethodOptimizationHints.HasEval == true) { // Check the variable exists: if (scope.HasValue(variableName) == true) { if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_HasValue); var hasValueClause = generator.CreateLabel(); generator.BranchIfFalse(hasValueClause); // Load the value of the variable. if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(DeclarativeScope)); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.Scope_GetValue); generator.Branch(endOfGet); // } generator.DefineLabelPosition(hasValueClause); } } } else { if (scope.ParentScope == null) { // Global variable access // ------------------------------------------- // __object_cacheKey = null; // __object_property_cachedIndex = 0; // ... // if (__object_cacheKey != object.InlineCacheKey) // xxx = object.InlineGetPropertyValue("variable", out __object_property_cachedIndex, out __object_cacheKey) // else // xxx = object.InlinePropertyValues[__object_property_cachedIndex]; // Get a reference to the global object. if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); // TODO: share these variables somehow. var cacheKey = generator.DeclareVariable(typeof(object)); var cachedIndex = generator.DeclareVariable(typeof(int)); // Store the object into a temp variable. var objectInstance = generator.DeclareVariable(PrimitiveType.Object); generator.StoreVariable(objectInstance); // if (__object_cacheKey != object.InlineCacheKey) generator.LoadVariable(cacheKey); generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlineCacheKey); var elseClause = generator.CreateLabel(); generator.BranchIfEqual(elseClause); // value = object.InlineGetProperty("property", out __object_property_cachedIndex, out __object_cacheKey) generator.LoadVariable(objectInstance); generator.LoadString(this.Name); generator.LoadAddressOfVariable(cachedIndex); generator.LoadAddressOfVariable(cacheKey); generator.Call(ReflectionHelpers.ObjectInstance_InlineGetPropertyValue); var endOfIf = generator.CreateLabel(); generator.Branch(endOfIf); // else generator.DefineLabelPosition(elseClause); // value = object.InlinePropertyValues[__object_property_cachedIndex]; generator.LoadVariable(objectInstance); generator.Call(ReflectionHelpers.ObjectInstance_InlinePropertyValues); generator.LoadVariable(cachedIndex); generator.LoadArrayElement(typeof(object)); // End of the if statement generator.DefineLabelPosition(endOfIf); // Check if the value is null. generator.Duplicate(); generator.BranchIfNotNull(endOfGet); if (scope.ParentScope != null) generator.Pop(); } else { // Gets the value of a variable in an object scope. if (scopeVariable == null) EmitHelpers.LoadScope(generator); else generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.ObjectInstance_GetPropertyValue_Object); // Check if the value is null. generator.Duplicate(); generator.BranchIfNotNull(endOfGet); if (scope.ParentScope != null) generator.Pop(); } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { if (scopeVariable == null) { scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); } else { generator.LoadVariable(scopeVariable); } generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // Throw an error if the name does not exist and throwIfUnresolvable is true. if (scope == null && throwIfUnresolvable == true) EmitHelpers.EmitThrow(generator, ErrorType.ReferenceError, this.Name + " is not defined", optimizationInfo); // Release the temporary variable. if (scopeVariable != null) generator.ReleaseTemporaryVariable(scopeVariable); // Define a label at the end. generator.DefineLabelPosition(endOfGet); // Object scope references may have side-effects (because of getters) so if the value // is to be ignored we evaluate the value then pop the value from the stack. //if (optimizationInfo.SuppressReturnValue == true) // generator.Pop(); }
/// <summary> /// Generates CIL for a compound assignment expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="target"> The target to modify. </param> private void GenerateCompoundAssignment(ILGenerator generator, OptimizationInfo optimizationInfo, IReferenceExpression target) { // Evaluate the left hand side only once. target.GenerateReference(generator, optimizationInfo); target.DuplicateReference(generator, optimizationInfo); // For the GenerateSet, later on. // Load the value to assign. var compoundOperator = new BinaryExpression(GetCompoundBaseOperator(this.OperatorType), new ReferenceGetExpression(target), this.GetOperand(1)); compoundOperator.GenerateCode(generator, optimizationInfo); // Store the resulting value so we can return it as the result of the expression. var result = generator.CreateTemporaryVariable(compoundOperator.ResultType); generator.Duplicate(); generator.StoreVariable(result); // Store the value. target.GenerateSet(generator, optimizationInfo, compoundOperator.ResultType, optimizationInfo.StrictMode); // Restore the expression result. generator.LoadVariable(result); generator.ReleaseTemporaryVariable(result); }
/// <summary> /// Generates code to push the "this" value for a function call. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> public void GenerateThis(ILGenerator generator) { // Optimization: if there are no with scopes, simply emit undefined. bool scopeChainHasWithScope = false; var scope = this.Scope; do { if (scope is ObjectScope && ((ObjectScope)scope).ProvidesImplicitThisValue == true) { scopeChainHasWithScope = true; break; } scope = scope.ParentScope; } while (scope != null); if (scopeChainHasWithScope == false) { // No with scopes in the scope chain, use undefined as the "this" value. EmitHelpers.EmitUndefined(generator); return; } var end = generator.CreateLabel(); scope = this.Scope; ILLocalVariable scopeVariable = generator.CreateTemporaryVariable(typeof(Scope)); EmitHelpers.LoadScope(generator); generator.StoreVariable(scopeVariable); do { if (scope is DeclarativeScope) { if (scope.HasDeclaredVariable(this.Name)) { // The variable exists but declarative scopes always produce undefined for // the "this" value. EmitHelpers.EmitUndefined(generator); break; } } else { var objectScope = (ObjectScope)scope; // Check if the property exists by calling scope.ScopeObject.HasProperty(propertyName) if (objectScope.ProvidesImplicitThisValue == false) EmitHelpers.EmitUndefined(generator); generator.LoadVariable(scopeVariable); generator.CastClass(typeof(ObjectScope)); generator.Call(ReflectionHelpers.ObjectScope_ScopeObject); if (objectScope.ProvidesImplicitThisValue == true) generator.Duplicate(); generator.LoadString(this.Name); generator.Call(ReflectionHelpers.ObjectInstance_HasProperty); generator.BranchIfTrue(end); generator.Pop(); // If the name is not defined, use undefined for the "this" value. if (scope.ParentScope == null) { EmitHelpers.EmitUndefined(generator); } } // Try the parent scope. if (scope.ParentScope != null && scope.ExistsAtRuntime == true) { generator.LoadVariable(scopeVariable); generator.Call(ReflectionHelpers.Scope_ParentScope); generator.StoreVariable(scopeVariable); } scope = scope.ParentScope; } while (scope != null); // Release the temporary variable. generator.ReleaseTemporaryVariable(scopeVariable); // Define a label at the end. generator.DefineLabelPosition(end); }
/// <summary> /// Generates CIL for an increment or decrement expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> /// <param name="target"> The target to modify. </param> /// <param name="postfix"> <c>true</c> if this is the postfix version of the operator; /// <c>false</c> otherwise. </param> /// <param name="increment"> <c>true</c> if this is the increment operator; <c>false</c> if /// this is the decrement operator. </param> private void GenerateIncrementOrDecrement(ILGenerator generator, OptimizationInfo optimizationInfo, IReferenceExpression target, bool postfix, bool increment) { // Note: increment and decrement can produce a number that is out of range if the // target is of type Int32. The only time this should happen is for a loop variable // where the range has been carefully checked to make sure an out of range condition // cannot happen. // Evaluate the left hand side only once. target.GenerateReference(generator, optimizationInfo); target.DuplicateReference(generator, optimizationInfo); // For the GenerateSet, later on. // Get the target value. target.GenerateGet(generator, optimizationInfo, true); // Convert it to a number. if (target.Type != PrimitiveType.Int32) EmitConversion.ToNumber(generator, target.Type); // If this is PostIncrement or PostDecrement, store the value so it can be returned later. var result = generator.CreateTemporaryVariable(target.Type == PrimitiveType.Int32 ? PrimitiveType.Int32 : PrimitiveType.Number); if (postfix == true) { generator.Duplicate(); generator.StoreVariable(result); } // Load the increment constant. if (target.Type == PrimitiveType.Int32) generator.LoadInt32(1); else generator.LoadDouble(1.0); // Add or subtract the constant to the target value. if (increment == true) generator.Add(); else generator.Subtract(); // If this is PreIncrement or PreDecrement, store the value so it can be returned later. if (postfix == false) { generator.Duplicate(); generator.StoreVariable(result); } // Store the value. target.GenerateSet(generator, optimizationInfo, target.Type == PrimitiveType.Int32 ? PrimitiveType.Int32 : PrimitiveType.Number, optimizationInfo.StrictMode); // Restore the expression result. generator.LoadVariable(result); generator.ReleaseTemporaryVariable(result); }
/// <summary> /// Generates CIL for the expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Check if this is a direct call to eval(). if (this.Target is NameExpression && ((NameExpression)this.Target).Name == "eval") { GenerateEval(generator, optimizationInfo); return; } // Emit the function instance first. ILLocalVariable targetBase = null; if (this.Target is MemberAccessExpression) { // The function is a member access expression (e.g. "Math.cos()"). // Evaluate the left part of the member access expression. var baseExpression = ((MemberAccessExpression)this.Target).Base; baseExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, baseExpression.ResultType); targetBase = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(targetBase); // Evaluate the right part of the member access expression. var memberAccessExpression = new MemberAccessExpression(((MemberAccessExpression)this.Target).Operator); memberAccessExpression.Push(new TemporaryVariableExpression(targetBase)); memberAccessExpression.Push(((MemberAccessExpression)this.Target).GetOperand(1)); memberAccessExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Target.ResultType); } else { // Something else (e.g. "eval()"). this.Target.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Target.ResultType); } // Check the object really is a function - if not, throw an exception. generator.IsInstance(typeof(Library.FunctionInstance)); generator.Duplicate(); var endOfTypeCheck = generator.CreateLabel(); generator.BranchIfNotNull(endOfTypeCheck); // Throw an nicely formatted exception. generator.Pop(); EmitHelpers.EmitThrow(generator, "TypeError", string.Format("'{0}' is not a function", this.Target.ToString())); generator.DefineLabelPosition(endOfTypeCheck); // Generate code to produce the "this" value. There are three cases. if (this.Target is NameExpression) { // 1. The function is a name expression (e.g. "parseInt()"). // In this case this = scope.ImplicitThisValue, if there is one, otherwise undefined. ((NameExpression)this.Target).GenerateThis(generator); } else if (this.Target is MemberAccessExpression) { // 2. The function is a member access expression (e.g. "Math.cos()"). // In this case this = Math. //var baseExpression = ((MemberAccessExpression)this.Target).Base; //baseExpression.GenerateCode(generator, optimizationInfo); //EmitConversion.ToAny(generator, baseExpression.ResultType); generator.LoadVariable(targetBase); } else { // 3. Neither of the above (e.g. "(function() { return 5 })()") // In this case this = undefined. EmitHelpers.EmitUndefined(generator); } // Emit an array containing the function arguments. GenerateArgumentsArray(generator, optimizationInfo); // Call FunctionInstance.CallLateBound(thisValue, argumentValues) generator.Call(ReflectionHelpers.FunctionInstance_CallLateBound); // Allow reuse of the temporary variable. if (targetBase != null) { generator.ReleaseTemporaryVariable(targetBase); } }
/// <summary> /// Generates CIL for the expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Note: we use GetRawOperand() so that grouping operators are not ignored. var operand = this.GetRawOperand(0); // There is only one operand, and it can be either a reference or a function call. // We need to split the operand into a function and some arguments. // If the operand is a reference, it is equivalent to a function call with no arguments. if (operand is FunctionCallExpression) { // Emit the function instance first. var function = ((FunctionCallExpression)operand).Target; function.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, function.ResultType); } else { // Emit the function instance first. operand.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, operand.ResultType); } // Check the object really is a function - if not, throw an exception. generator.IsInstance(typeof(Library.FunctionInstance)); generator.Duplicate(); var endOfTypeCheck = generator.CreateLabel(); generator.BranchIfNotNull(endOfTypeCheck); // Throw an nicely formatted exception. var targetValue = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(targetValue); EmitHelpers.LoadScriptEngine(generator); generator.LoadString("TypeError"); generator.LoadString("The new operator requires a function, found a '{0}' instead"); generator.LoadInt32(1); generator.NewArray(typeof(object)); generator.Duplicate(); generator.LoadInt32(0); generator.LoadVariable(targetValue); generator.Call(ReflectionHelpers.TypeUtilities_TypeOf); generator.StoreArrayElement(typeof(object)); generator.Call(ReflectionHelpers.String_Format); generator.LoadInt32(optimizationInfo.SourceSpan.StartLine); generator.LoadStringOrNull(optimizationInfo.Source.Path); generator.LoadStringOrNull(optimizationInfo.FunctionName); generator.NewObject(ReflectionHelpers.JavaScriptException_Constructor_Error); generator.Throw(); generator.DefineLabelPosition(endOfTypeCheck); generator.ReleaseTemporaryVariable(targetValue); if (operand is FunctionCallExpression) { // Emit an array containing the function arguments. ((FunctionCallExpression)operand).GenerateArgumentsArray(generator, optimizationInfo); } else { // Emit an empty array. generator.LoadInt32(0); generator.NewArray(typeof(object)); } // Call FunctionInstance.ConstructLateBound(argumentValues) generator.Call(ReflectionHelpers.FunctionInstance_ConstructLateBound); }
/// <summary> /// Generates CIL for the statement. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Generate code for the start of the statement. var statementLocals = new StatementLocals() { NonDefaultBreakStatementBehavior = true }; GenerateStartOfStatement(generator, optimizationInfo, statementLocals); // We need a label for each case clause and one for the default case. var jumpTargets = new ILLabel[this.CaseClauses.Count]; int defaultIndex = -1; ILLabel endOfSwitch = generator.CreateLabel(); // Generate code for the switch value. var startOfSwitch = generator.CreateLabel(); this.Value.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, this.Value.ResultType); // Save the switch value in a variable. var switchValue = generator.CreateTemporaryVariable(typeof(object)); generator.StoreVariable(switchValue); for (int i = 0; i < this.CaseClauses.Count; i ++) { var caseClause = this.CaseClauses[i]; // Create a label for each clause. jumpTargets[i] = generator.CreateLabel(); if (caseClause.Value == null) { // This is a default clause. defaultIndex = i; continue; } // TypeComparer.StrictEquals(switchValue, caseValue) generator.LoadVariable(switchValue); caseClause.Value.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, caseClause.Value.ResultType); generator.Call(ReflectionHelpers.TypeComparer_StrictEquals); // if (TypeComparer.StrictEquals(switchValue, caseValue) == true) // goto case i generator.BranchIfTrue(jumpTargets[i]); } // None of the cases matched, jump to the default clause or the end of the switch. if (defaultIndex >= 0) generator.Branch(jumpTargets[defaultIndex]); else generator.Branch(endOfSwitch); for (int i = 0; i < this.CaseClauses.Count; i++) { // Define a label at the start of the case clause. generator.DefineLabelPosition(jumpTargets[i]); // Set up the information needed by the break statement. optimizationInfo.PushBreakOrContinueInfo(this.Labels, endOfSwitch, null, labelledOnly: false); // Emit the case clause statements. foreach (var statement in this.CaseClauses[i].BodyStatements) statement.GenerateCode(generator, optimizationInfo); // Revert the information needed by the break statement. optimizationInfo.PopBreakOrContinueInfo(); } // Define a label for the end of the switch statement. generator.DefineLabelPosition(endOfSwitch); // Release the switch value variable for use elsewhere. generator.ReleaseTemporaryVariable(switchValue); // Generate code for the end of the statement. GenerateEndOfStatement(generator, optimizationInfo, statementLocals); }
/// <summary> /// Generates CIL for the expression. /// </summary> /// <param name="generator"> The generator to output the CIL to. </param> /// <param name="optimizationInfo"> Information about any optimizations that should be performed. </param> public override void GenerateCode(ILGenerator generator, OptimizationInfo optimizationInfo) { // Literals cannot have side-effects so if a return value is not expected then generate // nothing. //if (optimizationInfo.SuppressReturnValue == true) // return; if (this.Value is int) generator.LoadInt32((int)this.Value); else if (this.Value is double) generator.LoadDouble((double)this.Value); else if (this.Value is string) generator.LoadString((string)this.Value); else if (this.Value is bool) generator.LoadBoolean((bool)this.Value); else if (this.Value is RegularExpressionLiteral) { // RegExp var sharedRegExpVariable = optimizationInfo.GetRegExpVariable(generator, (RegularExpressionLiteral)this.Value); var label1 = generator.CreateLabel(); var label2 = generator.CreateLabel(); // if (sharedRegExp == null) { generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.BranchIfNotEqual(label1); // sharedRegExp = Global.RegExp.Construct(source, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadString(((RegularExpressionLiteral)this.Value).Pattern); generator.LoadString(((RegularExpressionLiteral)this.Value).Flags); generator.Call(ReflectionHelpers.RegExp_Construct); generator.Duplicate(); generator.StoreVariable(sharedRegExpVariable); // } else { generator.Branch(label2); generator.DefineLabelPosition(label1); // Global.RegExp.Construct(sharedRegExp, flags) EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_RegExp); generator.LoadVariable(sharedRegExpVariable); generator.LoadNull(); generator.Call(ReflectionHelpers.RegExp_Construct); // } generator.DefineLabelPosition(label2); } else if (this.Value == Null.Value) { // Null. EmitHelpers.EmitNull(generator); } else if (this.Value == Undefined.Value) { // Undefined. EmitHelpers.EmitUndefined(generator); } else if (this.Value is List<Expression>) { // Construct an array literal. var arrayLiteral = (List<Expression>)this.Value; // Operands for ArrayConstructor.New() are: an ArrayConstructor instance (ArrayConstructor), an array (object[]) // ArrayConstructor EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Array); // object[] generator.LoadInt32(arrayLiteral.Count); generator.NewArray(typeof(object)); for (int i = 0; i < arrayLiteral.Count; i ++) { // Operands for StoreArrayElement() are: an array (object[]), index (int), value (object). // Array generator.Duplicate(); // Index generator.LoadInt32(i); // Value var elementExpression = arrayLiteral[i]; if (elementExpression == null) generator.LoadNull(); else { elementExpression.GenerateCode(generator, optimizationInfo); EmitConversion.ToAny(generator, elementExpression.ResultType); } // Store the element value. generator.StoreArrayElement(typeof(object)); } // ArrayConstructor.New(object[]) generator.Call(ReflectionHelpers.Array_New); } else if (this.Value is List<KeyValuePair<Expression, Expression>>) { // This is an object literal. var properties = (List<KeyValuePair<Expression, Expression>>)this.Value; // Create a new object. EmitHelpers.LoadScriptEngine(generator); generator.Call(ReflectionHelpers.ScriptEngine_Object); generator.Call(ReflectionHelpers.Object_Construct); foreach (var keyValuePair in properties) { Expression propertyName = keyValuePair.Key; Expression propertyValue = keyValuePair.Value; generator.Duplicate(); // The key can be a property name or an expression that evaluates to a name. propertyName.GenerateCode(generator, optimizationInfo); EmitConversion.ToPropertyKey(generator, propertyName.ResultType); var functionValue = propertyValue as FunctionExpression; if (functionValue != null && functionValue.DeclarationType == FunctionDeclarationType.Getter) { // Add a getter to the object. functionValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (propertyName is LiteralExpression && ((LiteralExpression)propertyName).Value is string) functionValue.GenerateDisplayName(generator, optimizationInfo, "get " + (string)((LiteralExpression)propertyName).Value, true); generator.Call(ReflectionHelpers.ReflectionHelpers_SetObjectLiteralGetter); } else if(functionValue != null && functionValue.DeclarationType == FunctionDeclarationType.Setter) { // Add a setter to the object. functionValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (propertyName is LiteralExpression && ((LiteralExpression)propertyName).Value is string) functionValue.GenerateDisplayName(generator, optimizationInfo, "set " + (string)((LiteralExpression)propertyName).Value, true); generator.Call(ReflectionHelpers.ReflectionHelpers_SetObjectLiteralSetter); } else { // Add a new property to the object. propertyValue.GenerateCode(generator, optimizationInfo); // Support the inferred function displayName property. if (propertyValue is FunctionExpression && propertyName is LiteralExpression && ((LiteralExpression)propertyName).Value is string) ((FunctionExpression)propertyValue).GenerateDisplayName(generator, optimizationInfo, (string)((LiteralExpression)propertyName).Value, false); EmitConversion.ToAny(generator, propertyValue.ResultType); generator.Call(ReflectionHelpers.ReflectionHelpers_SetObjectLiteralValue); } } } else throw new NotImplementedException("Unknown literal type."); }