| public LoadBoolean ( bool value ) : void | ||
| value | bool | The boolean to push onto the stack. |
| return | void | |
/// <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)
{
// 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);
if (this.OperatorType == OperatorType.MemberAccess && rhs is NameExpression)
{
generator.LoadString((rhs as NameExpression).Name);
}
else
{
rhs.GenerateCode(generator, optimizationInfo);
EmitConversion.ToString(generator, rhs.ResultType);
}
// Call Delete()
generator.LoadBoolean(optimizationInfo.StrictMode);
generator.Call(ReflectionHelpers.ObjectInstance_Delete);
// If the return value is not wanted then pop it from the stack.
//if (optimizationInfo.SuppressReturnValue == true)
// generator.Pop();
}
/// <summary>
/// Generates CIL for a call to eval().
/// </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 GenerateEval(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// engine
EmitHelpers.LoadScriptEngine(generator);
// code
if (this.OperandCount < 2)
{
// No arguments were supplied.
generator.LoadNull();
}
else
{
// Take the first argument and convert it to a string.
GenerateArgumentsArray(generator, optimizationInfo);
generator.LoadInt32(0);
generator.LoadArrayElement(typeof(object));
}
// scope
EmitHelpers.LoadScope(generator);
// thisObject
EmitHelpers.LoadThis(generator);
// strictMode
generator.LoadBoolean(optimizationInfo.StrictMode);
// Call Global.Eval(engine, code, scope, thisValue, strictMode)
generator.Call(ReflectionHelpers.Global_Eval);
}
/// <summary>
/// Emits the given value. Only possible for certain types.
/// </summary>
/// <param name="generator"> The IL generator. </param>
/// <param name="value"> The value to emit. </param>
public static void EmitValue(ILGenerator generator, object value)
{
if (value == null)
generator.LoadNull();
else
{
switch (Type.GetTypeCode(value.GetType()))
{
case TypeCode.Boolean:
generator.LoadBoolean((bool)value);
break;
case TypeCode.Byte:
generator.LoadInt32((byte)value);
break;
case TypeCode.Char:
generator.LoadInt32((char)value);
break;
case TypeCode.Double:
generator.LoadDouble((double)value);
break;
case TypeCode.Int16:
generator.LoadInt32((short)value);
break;
case TypeCode.Int32:
generator.LoadInt32((int)value);
break;
case TypeCode.Int64:
generator.LoadInt64((long)value);
break;
case TypeCode.SByte:
generator.LoadInt32((sbyte)value);
break;
case TypeCode.Single:
generator.LoadDouble((float)value);
break;
case TypeCode.String:
generator.LoadString((string)value);
break;
case TypeCode.UInt16:
generator.LoadInt32((ushort)value);
break;
case TypeCode.UInt32:
generator.LoadInt32((uint)value);
break;
case TypeCode.UInt64:
generator.LoadInt64((ulong)value);
break;
case TypeCode.Object:
case TypeCode.Empty:
case TypeCode.DateTime:
case TypeCode.DBNull:
case TypeCode.Decimal:
throw new NotImplementedException(string.Format("Cannot emit the value '{0}'", value));
}
}
}
/// <summary>
/// Generates an array containing the argument values for a tagged template literal.
/// </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="templateLiteral"> The template literal expression containing the parameter
/// values. </param>
internal void GenerateTemplateArgumentsArray(ILGenerator generator, OptimizationInfo optimizationInfo, TemplateLiteralExpression templateLiteral)
{
// Generate an array containing the value of each argument.
generator.LoadInt32(templateLiteral.Values.Count + 1);
generator.NewArray(typeof(object));
// Load the first parameter.
generator.Duplicate();
generator.LoadInt32(0);
// The first parameter to the tag function is an array of strings.
var stringsExpression = new List <Expression>(templateLiteral.Strings.Count);
foreach (var templateString in templateLiteral.Strings)
{
stringsExpression.Add(new LiteralExpression(templateString));
}
new LiteralExpression(stringsExpression).GenerateCode(generator, optimizationInfo);
generator.Duplicate();
// Now we need the name of the property.
generator.LoadString("raw");
// Now generate an array of raw strings.
var rawStringsExpression = new List <Expression>(templateLiteral.RawStrings.Count);
foreach (var rawString in templateLiteral.RawStrings)
{
rawStringsExpression.Add(new LiteralExpression(rawString));
}
new LiteralExpression(rawStringsExpression).GenerateCode(generator, optimizationInfo);
// Freeze array by calling ObjectInstance Freeze(ObjectInstance).
generator.CallStatic(ReflectionHelpers.ObjectConstructor_Freeze);
// Now store the raw strings as a property of the base strings array.
generator.LoadBoolean(optimizationInfo.StrictMode);
generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object);
// Freeze array by calling ObjectInstance Freeze(ObjectInstance).
generator.CallStatic(ReflectionHelpers.ObjectConstructor_Freeze);
// Store in the array.
generator.StoreArrayElement(typeof(object));
// Values are passed as subsequent parameters.
for (int i = 0; i < templateLiteral.Values.Count; i++)
{
generator.Duplicate();
generator.LoadInt32(i + 1);
templateLiteral.Values[i].GenerateCode(generator, optimizationInfo);
EmitConversion.ToAny(generator, templateLiteral.Values[i].ResultType);
generator.StoreArrayElement(typeof(object));
}
}
/// <summary>
/// Generates code that initializes the variable and function declarations.
/// </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 virtual void GenerateDeclarations(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Initialize the declared variables and functions.
foreach (var variable in this.variables.Values)
{
// Emit the initialization code.
if (this is ObjectScope)
{
// Determine the property attributes.
var attributes = Library.PropertyAttributes.Enumerable;
if (variable.Writable == true)
{
attributes |= Library.PropertyAttributes.Writable;
}
if (variable.Deletable == true)
{
attributes |= Library.PropertyAttributes.Configurable;
}
if (variable.ValueAtTopOfScope == null)
{
// void InitializeMissingProperty(object key, PropertyAttributes attributes)
EmitHelpers.LoadScope(generator);
generator.CastClass(typeof(ObjectScope));
generator.Call(ReflectionHelpers.ObjectScope_ScopeObject);
generator.LoadString(variable.Name);
generator.LoadInt32((int)attributes);
generator.Call(ReflectionHelpers.ObjectInstance_InitializeMissingProperty);
}
else
{
// bool DefineProperty(string propertyName, PropertyDescriptor descriptor, bool throwOnError)
EmitHelpers.LoadScope(generator);
generator.CastClass(typeof(ObjectScope));
generator.Call(ReflectionHelpers.ObjectScope_ScopeObject);
generator.LoadString(variable.Name);
variable.ValueAtTopOfScope.GenerateCode(generator, optimizationInfo);
EmitConversion.Convert(generator, variable.ValueAtTopOfScope.ResultType, PrimitiveType.Any, optimizationInfo);
generator.LoadInt32((int)attributes);
generator.NewObject(ReflectionHelpers.PropertyDescriptor_Constructor2);
generator.LoadBoolean(false);
generator.Call(ReflectionHelpers.ObjectInstance_DefineProperty);
generator.Pop();
}
}
else if (variable.ValueAtTopOfScope != null)
{
variable.ValueAtTopOfScope.GenerateCode(generator, optimizationInfo);
var name = new NameExpression(this, variable.Name);
name.GenerateSet(generator, optimizationInfo, variable.ValueAtTopOfScope.ResultType, false);
}
}
}
/// <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 override void GenerateScopeCreation(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Create a new runtime object scope.
EmitHelpers.LoadScope(generator); // parent scope
if (this.ScopeObjectExpression == null)
{
EmitHelpers.LoadScriptEngine(generator);
generator.Call(ReflectionHelpers.ScriptEngine_Global);
}
else
{
this.ScopeObjectExpression.GenerateCode(generator, optimizationInfo);
EmitConversion.ToObject(generator, this.ScopeObjectExpression.ResultType, optimizationInfo);
}
generator.LoadBoolean(this.ProvidesImplicitThisValue);
generator.LoadBoolean(this.CanDeclareVariables);
generator.Call(ReflectionHelpers.ObjectScope_CreateRuntimeScope);
// Save the new scope.
EmitHelpers.StoreScope(generator);
}
/// <summary>
/// Generates CIL for the delete 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>
private void GenerateDelete(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Attempting to delete something that isn't a reference returns true but otherwise does nothing.
if ((this.Operand is IReferenceExpression) == false)
{
// Make sure the expression is evaluated.
this.Operand.GenerateCode(generator, optimizationInfo);
// Discard the result and return true.
generator.Pop();
generator.LoadBoolean(true);
return;
}
// The operand is a variable or property reference.
((IReferenceExpression)this.Operand).GenerateDelete(generator, optimizationInfo);
}
/// <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)
{
// Load the left-hand side and convert to an object instance.
var lhs = this.GetOperand(0);
if (lhs is SuperExpression)
{
// Deleting a super reference is not allowed.
EmitHelpers.EmitThrow(generator, ErrorType.ReferenceError, "Unsupported reference to 'super'.");
generator.LoadNull(); // Extraneous, but helps with verification.
return;
}
lhs.GenerateCode(generator, optimizationInfo);
EmitConversion.ToObject(generator, lhs.ResultType, optimizationInfo);
// Load the property name and convert to a string.
var rhs = this.GetOperand(1);
if (this.OperatorType == OperatorType.MemberAccess)
{
// delete a.b
if (rhs is NameExpression nameExpession)
{
generator.LoadString(nameExpession.Name);
}
else
{
throw new SyntaxErrorException("Invalid member access", optimizationInfo.SourceSpan.StartLine, optimizationInfo.Source.Path, optimizationInfo.FunctionName);
}
}
else
{
// delete a['1']
rhs.GenerateCode(generator, optimizationInfo);
EmitConversion.ToPropertyKey(generator, rhs.ResultType);
}
// Call Delete()
generator.LoadBoolean(optimizationInfo.StrictMode);
generator.Call(ReflectionHelpers.ObjectInstance_Delete);
// If the return value is not wanted then pop it from the stack.
//if (optimizationInfo.SuppressReturnValue == true)
// generator.Pop();
}
/// <summary>
/// Generates CIL to set the display name of the function. The function should be on top of 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="displayName"> The display name of the function. </param>
/// <param name="force"> <c>true</c> to set the displayName property, even if the function has a name already. </param>
public void GenerateDisplayName(ILGenerator generator, OptimizationInfo optimizationInfo, string displayName, bool force)
{
if (displayName == null)
{
throw new ArgumentNullException(nameof(displayName));
}
// We only infer names for functions if the function doesn't have a name.
if (force == true || string.IsNullOrEmpty(this.FunctionName))
{
// Statically set the display name.
this.context.DisplayName = displayName;
// Generate code to set the display name at runtime.
generator.Duplicate();
generator.LoadString("displayName");
generator.LoadString(displayName);
generator.LoadBoolean(false);
generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object);
}
}
/// <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 SyntaxErrorException($"Cannot delete {Name} because deleting a variable or argument is not allowed in strict mode", optimizationInfo.SourceSpan.StartLine, optimizationInfo.Source.Path, optimizationInfo.FunctionName);
}
// If we have allocated an IL variable, then always return false, as we don't support
// optimizing deletable variables.
var variableInfo = Scope.FindStaticVariable(Name);
if (variableInfo != null && variableInfo.Store != null)
{
generator.LoadBoolean(false);
return;
}
Scope.GenerateReference(generator, optimizationInfo);
generator.LoadString(Name);
generator.Call(ReflectionHelpers.RuntimeScope_Delete);
}
/// <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>
/// 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>
/// 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>
/// Generates CIL for the relational operators.
/// </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 GenerateRelational(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Get the statically-determined types of the left and right operands.
PrimitiveType leftType = this.Left.ResultType;
PrimitiveType rightType = this.Right.ResultType;
// The relational operators compare strings if both of the operands are strings.
if (leftType == PrimitiveType.String && rightType == PrimitiveType.String)
{
// Both of the operands are strings.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Compare the two strings.
generator.Call(ReflectionHelpers.String_CompareOrdinal);
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.LoadInt32(0);
generator.CompareLessThan();
break;
case OperatorType.LessThanOrEqual:
generator.LoadInt32(1);
generator.CompareLessThan();
break;
case OperatorType.GreaterThan:
generator.LoadInt32(0);
generator.CompareGreaterThan();
break;
case OperatorType.GreaterThanOrEqual:
generator.LoadInt32(-1);
generator.CompareGreaterThan();
break;
}
}
else if (leftType == PrimitiveType.Int32 && rightType == PrimitiveType.Int32)
{
// Both of the operands are integers.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Compare the two numbers.
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.CompareLessThan();
break;
case OperatorType.GreaterThan:
generator.CompareGreaterThan();
break;
case OperatorType.LessThanOrEqual:
// a <= b <--> (a > b) == false
generator.CompareGreaterThan();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.GreaterThanOrEqual:
// a >= b <--> (a < b) == false
generator.CompareLessThan();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
}
}
else if (PrimitiveTypeUtilities.IsNumeric(leftType) || PrimitiveTypeUtilities.IsNumeric(rightType))
{
// At least one of the operands is a number.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Convert the operand to a number.
EmitConversion.ToNumber(generator, leftType);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Convert the operand to a number.
EmitConversion.ToNumber(generator, rightType);
// Compare the two numbers.
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.CompareLessThan();
break;
case OperatorType.GreaterThan:
generator.CompareGreaterThan();
break;
case OperatorType.LessThanOrEqual:
// a <= b <--> (a > b) == false
generator.CompareGreaterThanUnsigned();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.GreaterThanOrEqual:
// a >= b <--> (a < b) == false
generator.CompareLessThanUnsigned();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
}
}
else
{
// It is unknown whether one of the operands is a string.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
EmitConversion.ToAny(generator, leftType);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
EmitConversion.ToAny(generator, rightType);
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.Call(ReflectionHelpers.TypeComparer_LessThan);
break;
case OperatorType.LessThanOrEqual:
generator.Call(ReflectionHelpers.TypeComparer_LessThanOrEqual);
break;
case OperatorType.GreaterThan:
generator.Call(ReflectionHelpers.TypeComparer_GreaterThan);
break;
case OperatorType.GreaterThanOrEqual:
generator.Call(ReflectionHelpers.TypeComparer_GreaterThanOrEqual);
break;
}
}
}
/// <summary>
/// Generates code that initializes the variable and function declarations.
/// </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 virtual void GenerateDeclarations(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Initialize the declared variables and functions.
foreach (var variable in this.variables.Values)
{
// When a scope is reused, i.e. with an eval(), do not reinitialize the variables.
if (variable.Initialized == true)
continue;
if (variable.ValueAtTopOfScope != null)
{
// Emit the initialization code.
if (this is ObjectScope)
{
// Determine the property attributes.
var attributes = Library.PropertyAttributes.Enumerable;
if (variable.Writable == true)
attributes |= Library.PropertyAttributes.Writable;
if (variable.Deletable == true)
attributes |= Library.PropertyAttributes.Configurable;
// bool DefineProperty(string propertyName, PropertyDescriptor descriptor, bool throwOnError)
EmitHelpers.LoadScope(generator);
generator.CastClass(typeof(ObjectScope));
generator.Call(ReflectionHelpers.ObjectScope_ScopeObject);
generator.LoadString(variable.Name);
variable.ValueAtTopOfScope.GenerateCode(generator, optimizationInfo);
EmitConversion.Convert(generator, variable.ValueAtTopOfScope.ResultType, PrimitiveType.Any, optimizationInfo);
generator.LoadInt32((int)attributes);
generator.NewObject(ReflectionHelpers.PropertyDescriptor_Constructor2);
generator.LoadBoolean(false);
generator.Call(ReflectionHelpers.ObjectInstance_DefineProperty);
generator.Pop();
}
else
{
variable.ValueAtTopOfScope.GenerateCode(generator, optimizationInfo);
var name = new NameExpression(this, variable.Name);
name.GenerateSet(generator, optimizationInfo, variable.ValueAtTopOfScope.ResultType, false);
}
// Mark the variable as having been initialized.
variable.Initialized = true;
}
}
}
/// <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", 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)
{
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, 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.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, 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);
// 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, 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 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 to set the display name of the function. The function should be on top of 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="displayName"> The display name of the function. </param>
/// <param name="force"> <c>true</c> to set the displayName property, even if the function has a name already. </param>
public void GenerateDisplayName(ILGenerator generator, OptimizationInfo optimizationInfo, string displayName, bool force)
{
if (displayName == null)
throw new ArgumentNullException("displayName");
// We only infer names for functions if the function doesn't have a name.
if (force == true || string.IsNullOrEmpty(this.FunctionName))
{
// Statically set the display name.
this.context.DisplayName = displayName;
// Generate code to set the display name at runtime.
generator.Duplicate();
generator.LoadString("displayName");
generator.LoadString(displayName);
generator.LoadBoolean(false);
generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_String);
}
}
/// <summary>
/// Generates CIL for the relational operators.
/// </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 GenerateRelational(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Get the statically-determined types of the left and right operands.
PrimitiveType leftType = this.Left.ResultType;
PrimitiveType rightType = this.Right.ResultType;
// The relational operators compare strings if both of the operands are strings.
if (leftType == PrimitiveType.String && rightType == PrimitiveType.String)
{
// Both of the operands are strings.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Compare the two strings.
generator.Call(ReflectionHelpers.String_CompareOrdinal);
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.LoadInt32(0);
generator.CompareLessThan();
break;
case OperatorType.LessThanOrEqual:
generator.LoadInt32(1);
generator.CompareLessThan();
break;
case OperatorType.GreaterThan:
generator.LoadInt32(0);
generator.CompareGreaterThan();
break;
case OperatorType.GreaterThanOrEqual:
generator.LoadInt32(-1);
generator.CompareGreaterThan();
break;
}
}
else if (leftType == PrimitiveType.Int32 && rightType == PrimitiveType.Int32)
{
// Both of the operands are integers.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Compare the two numbers.
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.CompareLessThan();
break;
case OperatorType.GreaterThan:
generator.CompareGreaterThan();
break;
case OperatorType.LessThanOrEqual:
// a <= b <--> (a > b) == false
generator.CompareGreaterThan();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.GreaterThanOrEqual:
// a >= b <--> (a < b) == false
generator.CompareLessThan();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
}
}
else if (PrimitiveTypeUtilities.IsNumeric(leftType) || PrimitiveTypeUtilities.IsNumeric(rightType))
{
// At least one of the operands is a number.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Convert the operand to a number.
EmitConversion.ToNumber(generator, leftType);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Convert the operand to a number.
EmitConversion.ToNumber(generator, rightType);
// Compare the two numbers.
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.CompareLessThan();
break;
case OperatorType.GreaterThan:
generator.CompareGreaterThan();
break;
case OperatorType.LessThanOrEqual:
// a <= b <--> (a > b) == false
generator.CompareGreaterThanUnsigned();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.GreaterThanOrEqual:
// a >= b <--> (a < b) == false
generator.CompareLessThanUnsigned();
generator.LoadBoolean(false);
generator.CompareEqual();
break;
}
}
else
{
// It is unknown whether one of the operands is a string.
// Load the left hand side operand onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
EmitConversion.ToAny(generator, leftType);
// Load the right hand side operand onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
EmitConversion.ToAny(generator, rightType);
switch (this.OperatorType)
{
case OperatorType.LessThan:
generator.Call(ReflectionHelpers.TypeComparer_LessThan);
break;
case OperatorType.LessThanOrEqual:
generator.Call(ReflectionHelpers.TypeComparer_LessThanOrEqual);
break;
case OperatorType.GreaterThan:
generator.Call(ReflectionHelpers.TypeComparer_GreaterThan);
break;
case OperatorType.GreaterThanOrEqual:
generator.Call(ReflectionHelpers.TypeComparer_GreaterThanOrEqual);
break;
}
}
}
/// <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)
{
// If a return value is not expected, generate only the side-effects.
/*if (optimizationInfo.SuppressReturnValue == true)
{
this.GenerateSideEffects(generator, optimizationInfo);
return;
}*/
// Special case the addition operator.
if (this.OperatorType == OperatorType.Add)
{
GenerateAdd(generator, optimizationInfo);
return;
}
// Special case the instanceof operator.
if (this.OperatorType == OperatorType.InstanceOf)
{
GenerateInstanceOf(generator, optimizationInfo);
return;
}
// Special case the in operator.
if (this.OperatorType == OperatorType.In)
{
GenerateIn(generator, optimizationInfo);
return;
}
// Special case the relational operators.
if (this.OperatorType == OperatorType.LessThan ||
this.OperatorType == OperatorType.LessThanOrEqual ||
this.OperatorType == OperatorType.GreaterThan ||
this.OperatorType == OperatorType.GreaterThanOrEqual)
{
GenerateRelational(generator, optimizationInfo);
return;
}
// Special case the logical operators.
if (this.OperatorType == OperatorType.LogicalAnd ||
this.OperatorType == OperatorType.LogicalOr)
{
GenerateLogical(generator, optimizationInfo);
return;
}
// Load the left hand side onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Convert the left argument.
switch (this.OperatorType)
{
// Arithmetic operations.
case OperatorType.Subtract:
case OperatorType.Multiply:
case OperatorType.Divide:
case OperatorType.Modulo:
EmitConversion.ToNumber(generator, this.Left.ResultType);
break;
// Bitwise operations.
case OperatorType.BitwiseAnd:
case OperatorType.BitwiseOr:
case OperatorType.BitwiseXor:
case OperatorType.LeftShift:
case OperatorType.SignedRightShift:
case OperatorType.UnsignedRightShift:
EmitConversion.ToInt32(generator, this.Left.ResultType);
break;
// Equality operations.
case OperatorType.Equal:
case OperatorType.StrictlyEqual:
case OperatorType.NotEqual:
case OperatorType.StrictlyNotEqual:
EmitConversion.ToAny(generator, this.Left.ResultType);
break;
}
// Load the right hand side onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Convert the right argument.
switch (this.OperatorType)
{
// Arithmetic operations.
case OperatorType.Subtract:
case OperatorType.Multiply:
case OperatorType.Divide:
case OperatorType.Modulo:
EmitConversion.ToNumber(generator, this.Right.ResultType);
break;
// Bitwise operations.
case OperatorType.BitwiseAnd:
case OperatorType.BitwiseOr:
case OperatorType.BitwiseXor:
EmitConversion.ToInt32(generator, this.Right.ResultType);
break;
case OperatorType.LeftShift:
case OperatorType.SignedRightShift:
case OperatorType.UnsignedRightShift:
EmitConversion.ToUInt32(generator, this.Right.ResultType);
generator.LoadInt32(0x1F);
generator.BitwiseAnd();
break;
// Equality operations.
case OperatorType.Equal:
case OperatorType.StrictlyEqual:
case OperatorType.NotEqual:
case OperatorType.StrictlyNotEqual:
EmitConversion.ToAny(generator, this.Right.ResultType);
break;
}
// Apply the operator.
switch (this.OperatorType)
{
// Arithmetic operations.
case OperatorType.Subtract:
generator.Subtract();
break;
case OperatorType.Multiply:
generator.Multiply();
break;
case OperatorType.Divide:
generator.Divide();
break;
case OperatorType.Modulo:
generator.Remainder();
break;
// Bitwise operations.
case OperatorType.BitwiseAnd:
generator.BitwiseAnd();
break;
case OperatorType.BitwiseOr:
generator.BitwiseOr();
break;
case OperatorType.BitwiseXor:
generator.BitwiseXor();
break;
// Shift operations.
case OperatorType.LeftShift:
generator.ShiftLeft();
break;
case OperatorType.SignedRightShift:
generator.ShiftRight();
break;
case OperatorType.UnsignedRightShift:
generator.ShiftRightUnsigned();
EmitConversion.ToNumber(generator, PrimitiveType.UInt32);
break;
// Equality operations.
case OperatorType.Equal:
generator.Call(ReflectionHelpers.TypeComparer_Equals);
break;
case OperatorType.StrictlyEqual:
generator.Call(ReflectionHelpers.TypeComparer_StrictEquals);
break;
case OperatorType.NotEqual:
generator.Call(ReflectionHelpers.TypeComparer_Equals);
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.StrictlyNotEqual:
generator.Call(ReflectionHelpers.TypeComparer_StrictEquals);
generator.LoadBoolean(false);
generator.CompareEqual();
break;
default:
throw new NotImplementedException(string.Format("Unsupported operator {0}", this.OperatorType));
}
}
/// <summary>
/// Generates an array containing the argument values for a tagged template literal.
/// </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="templateLiteral"> The template literal expression containing the parameter
/// values. </param>
internal void GenerateTemplateArgumentsArray(ILGenerator generator, OptimizationInfo optimizationInfo, TemplateLiteralExpression templateLiteral)
{
// Generate an array containing the value of each argument.
generator.LoadInt32(templateLiteral.Values.Count + 1);
generator.NewArray(typeof(object));
// Load the first parameter.
generator.Duplicate();
generator.LoadInt32(0);
// The first parameter to the tag function is an array of strings.
var stringsExpression = new List<Expression>(templateLiteral.Strings.Count);
foreach (var templateString in templateLiteral.Strings)
{
stringsExpression.Add(new LiteralExpression(templateString));
}
new LiteralExpression(stringsExpression).GenerateCode(generator, optimizationInfo);
generator.Duplicate();
// Now we need the name of the property.
generator.LoadString("raw");
// Now generate an array of raw strings.
var rawStringsExpression = new List<Expression>(templateLiteral.RawStrings.Count);
foreach (var rawString in templateLiteral.RawStrings)
{
rawStringsExpression.Add(new LiteralExpression(rawString));
}
new LiteralExpression(rawStringsExpression).GenerateCode(generator, optimizationInfo);
// Freeze array by calling ObjectInstance Freeze(ObjectInstance).
generator.CallStatic(ReflectionHelpers.ObjectConstructor_Freeze);
// Now store the raw strings as a property of the base strings array.
generator.LoadBoolean(optimizationInfo.StrictMode);
generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_Object);
// Freeze array by calling ObjectInstance Freeze(ObjectInstance).
generator.CallStatic(ReflectionHelpers.ObjectConstructor_Freeze);
// Store in the array.
generator.StoreArrayElement(typeof(object));
// Values are passed as subsequent parameters.
for (int i = 0; i < templateLiteral.Values.Count; i++)
{
generator.Duplicate();
generator.LoadInt32(i + 1);
templateLiteral.Values[i].GenerateCode(generator, optimizationInfo);
EmitConversion.ToAny(generator, templateLiteral.Values[i].ResultType);
generator.StoreArrayElement(typeof(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>
/// <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 (scopeVariable == null)
{
EmitHelpers.LoadScope(generator);
}
else
{
generator.LoadVariable(scopeVariable);
}
generator.CastClass(typeof(ObjectScope));
generator.Call(ReflectionHelpers.ObjectScope_ScopeObject);
if (scope.ParentScope == null && throwIfUnresolvable == false)
{
// Sets the value of a global variable.
// JS: object.property = value
// C# ==>
// if (propertyName == null)
// propertyName = new PropertyName("property");
// object.SetPropertyValue(propertyName, value, strictMode);
ILLocalVariable propertyName = optimizationInfo.GetGlobalPropertyReferenceVariable(generator, this.Name);
generator.LoadVariable(propertyName);
generator.Duplicate();
var afterIf = generator.CreateLabel();
generator.BranchIfNotNull(afterIf);
generator.Pop();
generator.LoadString(this.Name);
generator.NewObject(ReflectionHelpers.PropertyName_Constructor);
generator.Duplicate();
generator.StoreVariable(propertyName);
generator.DefineLabelPosition(afterIf);
generator.LoadVariable(value);
generator.LoadBoolean(optimizationInfo.StrictMode);
generator.Call(ReflectionHelpers.ObjectInstance_SetPropertyValue_PropertyReference);
}
else
{
// Setting a variable within a "with" scope.
generator.LoadString(this.Name);
generator.LoadVariable(value);
generator.LoadBoolean(optimizationInfo.StrictMode);
// 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)
{
// Special-case the delete operator.
if (this.OperatorType == OperatorType.Delete)
{
GenerateDelete(generator, optimizationInfo);
return;
}
// If a return value is not expected, generate only the side-effects.
/*if (optimizationInfo.SuppressReturnValue == true)
* {
* this.GenerateSideEffects(generator, optimizationInfo);
* return;
* }*/
// Special-case the typeof operator.
if (this.OperatorType == OperatorType.Typeof)
{
GenerateTypeof(generator, optimizationInfo);
return;
}
// Load the operand onto the stack.
this.Operand.GenerateCode(generator, optimizationInfo);
// Convert the operand to the correct type.
switch (this.OperatorType)
{
case OperatorType.Plus:
case OperatorType.Minus:
EmitConversion.ToNumber(generator, this.Operand.ResultType);
break;
case OperatorType.BitwiseNot:
EmitConversion.ToInt32(generator, this.Operand.ResultType);
break;
case OperatorType.LogicalNot:
EmitConversion.ToBool(generator, this.Operand.ResultType);
break;
}
// Apply the operator.
switch (this.OperatorType)
{
case OperatorType.Plus:
break;
case OperatorType.Minus:
generator.Negate();
break;
case OperatorType.BitwiseNot:
generator.BitwiseNot();
break;
case OperatorType.LogicalNot:
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.Void:
generator.Pop();
EmitHelpers.EmitUndefined(generator);
break;
default:
throw new NotImplementedException(string.Format("Unsupported operator {0}", this.OperatorType));
}
}
/// <summary>
/// Generates CIL for a call to eval().
/// </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 GenerateEval(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// engine
EmitHelpers.LoadScriptEngine(generator);
// code
if (this.OperandCount < 2)
{
// No arguments were supplied.
generator.LoadNull();
}
else
{
// Take the first argument and convert it to a string.
GenerateArgumentsArray(generator, optimizationInfo);
generator.LoadInt32(0);
generator.LoadArrayElement(typeof(object));
}
// scope
EmitHelpers.LoadScope(generator);
// thisObject
EmitHelpers.LoadThis(generator);
// strictMode
generator.LoadBoolean(optimizationInfo.StrictMode);
// Call Global.Eval(engine, code, scope, thisValue, strictMode)
generator.Call(ReflectionHelpers.Global_Eval);
}
/// <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>
/// 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 delete 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>
private void GenerateDelete(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Attempting to delete something that isn't a reference returns true but otherwise does nothing.
if ((this.Operand is IReferenceExpression) == false)
{
// Make sure the expression is evaluated.
this.Operand.GenerateCode(generator, optimizationInfo);
// Discard the result and return true.
generator.Pop();
generator.LoadBoolean(true);
return;
}
// The operand is a variable or property reference.
((IReferenceExpression)this.Operand).GenerateDelete(generator, optimizationInfo);
}
/// <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)
{
// Generate a new method.
this.context.GenerateCode();
// Add the generated method to the nested function list.
if (optimizationInfo.NestedFunctions == null)
{
optimizationInfo.NestedFunctions = new List <GeneratedMethod>();
}
optimizationInfo.NestedFunctions.Add(this.context.GeneratedMethod);
// Add all the nested methods to the parent list.
if (this.context.GeneratedMethod.Dependencies != null)
{
foreach (var nestedFunctionExpression in this.context.GeneratedMethod.Dependencies)
{
optimizationInfo.NestedFunctions.Add(nestedFunctionExpression);
}
}
// Store the generated method in the cache.
long generatedMethodID = GeneratedMethod.Save(this.context.GeneratedMethod);
// Create a UserDefinedFunction.
// prototype
EmitHelpers.LoadScriptEngine(generator);
generator.Call(ReflectionHelpers.ScriptEngine_Function);
generator.Call(ReflectionHelpers.FunctionInstance_InstancePrototype);
// name
string prefix = null;
if (Name.IsGetter)
{
prefix = "get ";
}
else if (Name.IsSetter)
{
prefix = "set ";
}
if (Name.HasStaticName)
{
generator.LoadString(prefix + Name.StaticName);
}
else
{
// Compute the name at runtime.
if (prefix != null)
{
generator.LoadString(prefix);
}
Name.ComputedName.GenerateCode(generator, optimizationInfo);
EmitConversion.ToString(generator, Name.ComputedName.ResultType);
if (prefix != null)
{
generator.CallStatic(ReflectionHelpers.String_Concat_String_String);
}
}
// argumentNames
generator.LoadInt32(this.Arguments.Count);
generator.NewArray(typeof(string));
for (int i = 0; i < this.Arguments.Count; i++)
{
generator.Duplicate();
generator.LoadInt32(i);
generator.LoadString(this.Arguments[i].Name);
generator.StoreArrayElement(typeof(string));
}
// scope
Scope.GenerateReference(generator, optimizationInfo);
// bodyText
generator.LoadString(this.BodyText);
// body
generator.LoadInt64(generatedMethodID);
generator.Call(ReflectionHelpers.GeneratedMethod_Load);
// strictMode
generator.LoadBoolean(this.context.StrictMode);
// container
if (ContainerVariable != null)
{
generator.LoadVariable(ContainerVariable);
}
else
{
generator.LoadNull();
}
// CreateFunction(ObjectInstance prototype, string name, IList<string> argumentNames,
// RuntimeScope scope, Func<Scope, object, object[], object> body,
// bool strictMode, FunctionInstance container)
generator.CallStatic(ReflectionHelpers.ReflectionHelpers_CreateFunction);
}
/// <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)
{
// Generate a new method.
this.context.GenerateCode();
// Add the generated method to the nested function list.
if (optimizationInfo.NestedFunctions == null)
optimizationInfo.NestedFunctions = new List<GeneratedMethod>();
optimizationInfo.NestedFunctions.Add(this.context.GeneratedMethod);
// Add all the nested methods to the parent list.
if (this.context.GeneratedMethod.Dependencies != null)
{
foreach (var nestedFunctionExpression in this.context.GeneratedMethod.Dependencies)
optimizationInfo.NestedFunctions.Add(nestedFunctionExpression);
}
// Store the generated method in the cache.
long generatedMethodID = GeneratedMethod.Save(this.context.GeneratedMethod);
// Create a UserDefinedFunction.
// prototype
EmitHelpers.LoadScriptEngine(generator);
generator.Call(ReflectionHelpers.ScriptEngine_Function);
generator.Call(ReflectionHelpers.FunctionInstance_InstancePrototype);
// name
generator.LoadString(this.FunctionName);
// argumentNames
generator.LoadInt32(this.ArgumentNames.Count);
generator.NewArray(typeof(string));
for (int i = 0; i < this.ArgumentNames.Count; i++)
{
generator.Duplicate();
generator.LoadInt32(i);
generator.LoadString(this.ArgumentNames[i]);
generator.StoreArrayElement(typeof(string));
}
// scope
EmitHelpers.LoadScope(generator);
// bodyText
generator.LoadString(this.BodyText);
// body
generator.LoadInt64(generatedMethodID);
generator.Call(ReflectionHelpers.GeneratedMethod_Load);
// strictMode
generator.LoadBoolean(this.context.StrictMode);
// new UserDefinedFunction(ObjectInstance prototype, string name, IList<string> argumentNames, DeclarativeScope scope, Func<Scope, object, object[], object> body, bool strictMode)
generator.NewObject(ReflectionHelpers.UserDefinedFunction_Constructor);
}
/// <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 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>
/// 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.BranchIfNotNull(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
{
throw new NotImplementedException("Unknown literal type.");
}
}
/// <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)
{
// If a return value is not expected, generate only the side-effects.
/*if (optimizationInfo.SuppressReturnValue == true)
* {
* this.GenerateSideEffects(generator, optimizationInfo);
* return;
* }*/
// Special case the addition operator.
if (this.OperatorType == OperatorType.Add)
{
GenerateAdd(generator, optimizationInfo);
return;
}
// Special case the instanceof operator.
if (this.OperatorType == OperatorType.InstanceOf)
{
GenerateInstanceOf(generator, optimizationInfo);
return;
}
// Special case the in operator.
if (this.OperatorType == OperatorType.In)
{
GenerateIn(generator, optimizationInfo);
return;
}
// Special case the relational operators.
if (this.OperatorType == OperatorType.LessThan ||
this.OperatorType == OperatorType.LessThanOrEqual ||
this.OperatorType == OperatorType.GreaterThan ||
this.OperatorType == OperatorType.GreaterThanOrEqual)
{
GenerateRelational(generator, optimizationInfo);
return;
}
// Special case the logical operators.
if (this.OperatorType == OperatorType.LogicalAnd ||
this.OperatorType == OperatorType.LogicalOr)
{
GenerateLogical(generator, optimizationInfo);
return;
}
// Load the left hand side onto the stack.
this.Left.GenerateCode(generator, optimizationInfo);
// Convert the left argument.
switch (this.OperatorType)
{
// Arithmetic operations.
case OperatorType.Subtract:
case OperatorType.Multiply:
case OperatorType.Divide:
case OperatorType.Modulo:
case OperatorType.Exponentiation:
EmitConversion.ToNumber(generator, this.Left.ResultType);
break;
// Bitwise operations.
case OperatorType.BitwiseAnd:
case OperatorType.BitwiseOr:
case OperatorType.BitwiseXor:
case OperatorType.LeftShift:
case OperatorType.SignedRightShift:
case OperatorType.UnsignedRightShift:
EmitConversion.ToInt32(generator, this.Left.ResultType);
break;
// Equality operations.
case OperatorType.Equal:
case OperatorType.StrictlyEqual:
case OperatorType.NotEqual:
case OperatorType.StrictlyNotEqual:
EmitConversion.ToAny(generator, this.Left.ResultType);
break;
}
// Load the right hand side onto the stack.
this.Right.GenerateCode(generator, optimizationInfo);
// Convert the right argument.
switch (this.OperatorType)
{
// Arithmetic operations.
case OperatorType.Subtract:
case OperatorType.Multiply:
case OperatorType.Divide:
case OperatorType.Modulo:
case OperatorType.Exponentiation:
EmitConversion.ToNumber(generator, this.Right.ResultType);
break;
// Bitwise operations.
case OperatorType.BitwiseAnd:
case OperatorType.BitwiseOr:
case OperatorType.BitwiseXor:
EmitConversion.ToInt32(generator, this.Right.ResultType);
break;
case OperatorType.LeftShift:
case OperatorType.SignedRightShift:
case OperatorType.UnsignedRightShift:
EmitConversion.ToUInt32(generator, this.Right.ResultType);
generator.LoadInt32(0x1F);
generator.BitwiseAnd();
break;
// Equality operations.
case OperatorType.Equal:
case OperatorType.StrictlyEqual:
case OperatorType.NotEqual:
case OperatorType.StrictlyNotEqual:
EmitConversion.ToAny(generator, this.Right.ResultType);
break;
}
// Apply the operator.
switch (this.OperatorType)
{
// Arithmetic operations.
case OperatorType.Subtract:
generator.Subtract();
break;
case OperatorType.Multiply:
generator.Multiply();
break;
case OperatorType.Divide:
generator.Divide();
break;
case OperatorType.Modulo:
generator.Remainder();
break;
case OperatorType.Exponentiation:
generator.CallStatic(ReflectionHelpers.Math_Pow);
break;
// Bitwise operations.
case OperatorType.BitwiseAnd:
generator.BitwiseAnd();
break;
case OperatorType.BitwiseOr:
generator.BitwiseOr();
break;
case OperatorType.BitwiseXor:
generator.BitwiseXor();
break;
// Shift operations.
case OperatorType.LeftShift:
generator.ShiftLeft();
break;
case OperatorType.SignedRightShift:
generator.ShiftRight();
break;
case OperatorType.UnsignedRightShift:
generator.ShiftRightUnsigned();
EmitConversion.ToNumber(generator, PrimitiveType.UInt32);
break;
// Equality operations.
case OperatorType.Equal:
generator.Call(ReflectionHelpers.TypeComparer_Equals);
break;
case OperatorType.StrictlyEqual:
generator.Call(ReflectionHelpers.TypeComparer_StrictEquals);
break;
case OperatorType.NotEqual:
generator.Call(ReflectionHelpers.TypeComparer_Equals);
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.StrictlyNotEqual:
generator.Call(ReflectionHelpers.TypeComparer_StrictEquals);
generator.LoadBoolean(false);
generator.CompareEqual();
break;
default:
throw new NotImplementedException(string.Format("Unsupported operator {0}", this.OperatorType));
}
}
/// <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", 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)
{
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, 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.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, 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);
// 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, 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 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>
/// 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>
/// 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)
{
// 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);
if (this.OperatorType == OperatorType.MemberAccess && rhs is NameExpression)
generator.LoadString((rhs as NameExpression).Name);
else
{
rhs.GenerateCode(generator, optimizationInfo);
EmitConversion.ToString(generator, rhs.ResultType);
}
// Call Delete()
generator.LoadBoolean(optimizationInfo.StrictMode);
generator.Call(ReflectionHelpers.ObjectInstance_Delete);
// If the return value is not wanted then pop it from the stack.
//if (optimizationInfo.SuppressReturnValue == true)
// generator.Pop();
}
/// <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>
/// Emits the given value. Only possible for certain types.
/// </summary>
/// <param name="generator"> The IL generator. </param>
/// <param name="value"> The value to emit. </param>
public static void EmitValue(ILGenerator generator, object value)
{
if (value == null)
{
generator.LoadNull();
}
else
{
switch (Type.GetTypeCode(value.GetType()))
{
case TypeCode.Boolean:
generator.LoadBoolean((bool)value);
break;
case TypeCode.Byte:
generator.LoadInt32((byte)value);
break;
case TypeCode.Char:
generator.LoadInt32((char)value);
break;
case TypeCode.Double:
generator.LoadDouble((double)value);
break;
case TypeCode.Int16:
generator.LoadInt32((short)value);
break;
case TypeCode.Int32:
generator.LoadInt32((int)value);
break;
case TypeCode.Int64:
generator.LoadInt64((long)value);
break;
case TypeCode.SByte:
generator.LoadInt32((sbyte)value);
break;
case TypeCode.Single:
generator.LoadDouble((float)value);
break;
case TypeCode.String:
generator.LoadString((string)value);
break;
case TypeCode.UInt16:
generator.LoadInt32((ushort)value);
break;
case TypeCode.UInt32:
generator.LoadInt32((uint)value);
break;
case TypeCode.UInt64:
generator.LoadInt64((ulong)value);
break;
case TypeCode.Object:
case TypeCode.Empty:
case TypeCode.DateTime:
case TypeCode.DBNull:
case TypeCode.Decimal:
throw new NotImplementedException(string.Format("Cannot emit the value '{0}'", value));
}
}
}
/// <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 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)
{
// Special-case the delete operator.
if (this.OperatorType == OperatorType.Delete)
{
GenerateDelete(generator, optimizationInfo);
return;
}
// If a return value is not expected, generate only the side-effects.
/*if (optimizationInfo.SuppressReturnValue == true)
{
this.GenerateSideEffects(generator, optimizationInfo);
return;
}*/
// Special-case the typeof operator.
if (this.OperatorType == OperatorType.Typeof)
{
GenerateTypeof(generator, optimizationInfo);
return;
}
// Load the operand onto the stack.
this.Operand.GenerateCode(generator, optimizationInfo);
// Convert the operand to the correct type.
switch (this.OperatorType)
{
case OperatorType.Plus:
case OperatorType.Minus:
EmitConversion.ToNumber(generator, this.Operand.ResultType);
break;
case OperatorType.BitwiseNot:
EmitConversion.ToInt32(generator, this.Operand.ResultType);
break;
case OperatorType.LogicalNot:
EmitConversion.ToBool(generator, this.Operand.ResultType);
break;
}
// Apply the operator.
switch (this.OperatorType)
{
case OperatorType.Plus:
break;
case OperatorType.Minus:
generator.Negate();
break;
case OperatorType.BitwiseNot:
generator.BitwiseNot();
break;
case OperatorType.LogicalNot:
generator.LoadBoolean(false);
generator.CompareEqual();
break;
case OperatorType.Void:
generator.Pop();
EmitHelpers.EmitUndefined(generator);
break;
default:
throw new NotImplementedException(string.Format("Unsupported operator {0}", this.OperatorType));
}
}
/// <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 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 override void GenerateScopeCreation(ILGenerator generator, OptimizationInfo optimizationInfo)
{
// Create a new runtime object scope.
EmitHelpers.LoadScope(generator); // parent scope
if (this.ScopeObjectExpression == null)
{
EmitHelpers.LoadScriptEngine(generator);
generator.Call(ReflectionHelpers.ScriptEngine_Global);
}
else
{
this.ScopeObjectExpression.GenerateCode(generator, optimizationInfo);
EmitConversion.ToObject(generator, this.ScopeObjectExpression.ResultType);
}
generator.LoadBoolean(this.ProvidesImplicitThisValue);
generator.LoadBoolean(this.CanDeclareVariables);
generator.Call(ReflectionHelpers.ObjectScope_CreateRuntimeScope);
// Save the new scope.
EmitHelpers.StoreScope(generator);
}
/// <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)
{
// Generate a new method.
this.context.GenerateCode();
// Add the generated method to the nested function list.
if (optimizationInfo.NestedFunctions == null)
{
optimizationInfo.NestedFunctions = new List <GeneratedMethod>();
}
optimizationInfo.NestedFunctions.Add(this.context.GeneratedMethod);
// Add all the nested methods to the parent list.
if (this.context.GeneratedMethod.Dependencies != null)
{
foreach (var nestedFunctionExpression in this.context.GeneratedMethod.Dependencies)
{
optimizationInfo.NestedFunctions.Add(nestedFunctionExpression);
}
}
// Store the generated method in the cache.
long generatedMethodID = GeneratedMethod.Save(this.context.GeneratedMethod);
// Create a UserDefinedFunction.
// prototype
EmitHelpers.LoadScriptEngine(generator);
generator.Call(ReflectionHelpers.ScriptEngine_Function);
generator.Call(ReflectionHelpers.FunctionInstance_InstancePrototype);
// name
if (this.context.DeclarationType == FunctionDeclarationType.Getter)
{
generator.LoadString("get " + this.FunctionName);
}
else if (this.context.DeclarationType == FunctionDeclarationType.Setter)
{
generator.LoadString("set " + this.FunctionName);
}
else
{
generator.LoadString(this.FunctionName);
}
// argumentNames
generator.LoadInt32(this.Arguments.Count);
generator.NewArray(typeof(string));
for (int i = 0; i < this.Arguments.Count; i++)
{
generator.Duplicate();
generator.LoadInt32(i);
generator.LoadString(this.Arguments[i].Name);
generator.StoreArrayElement(typeof(string));
}
// scope
EmitHelpers.LoadScope(generator);
// bodyText
generator.LoadString(this.BodyText);
// body
generator.LoadInt64(generatedMethodID);
generator.Call(ReflectionHelpers.GeneratedMethod_Load);
// strictMode
generator.LoadBoolean(this.context.StrictMode);
// new UserDefinedFunction(ObjectInstance prototype, string name, IList<string> argumentNames, DeclarativeScope scope, Func<Scope, object, object[], object> body, bool strictMode)
generator.NewObject(ReflectionHelpers.UserDefinedFunction_Constructor);
}
/// <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.");
}
