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Whitespace reformatting of TransformByteCode

pull/70/head
David Srbecký 15 years ago
parent
74b6624c5e
commit
fe0b0130e4
1 changed files with 189 additions and 229 deletions
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  1. 418
      ICSharpCode.Decompiler/Ast/AstMethodBodyBuilder.cs

418
ICSharpCode.Decompiler/Ast/AstMethodBodyBuilder.cs
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@ -79,9 +79,7 @@ namespace ICSharpCode.Decompiler.Ast @@ -79,9 +79,7 @@ namespace ICSharpCode.Decompiler.Ast
{
Ast.BlockStatement astBlock = new BlockStatement();
if (block != null) {
if (block.EntryGoto != null)
astBlock.Add((Statement)TransformExpression(block.EntryGoto));
foreach(ILNode node in block.Body) {
foreach(ILNode node in block.GetChildren()) {
astBlock.AddRange(TransformNode(node));
}
}
@ -154,41 +152,6 @@ namespace ICSharpCode.Decompiler.Ast @@ -154,41 +152,6 @@ namespace ICSharpCode.Decompiler.Ast
}
}
List<Ast.Expression> TransformExpressionArguments(ILExpression expr)
{
List<Ast.Expression> args = new List<Ast.Expression>();
// Args generated by nested expressions (which must be closed)
foreach(ILExpression arg in expr.Arguments) {
args.Add((Ast.Expression)TransformExpression(arg));
}
return args;
}
static string FormatByteCodeOperand(object operand)
{
if (operand == null) {
return string.Empty;
//} else if (operand is ILExpression) {
// return string.Format("IL_{0:X2}", ((ILExpression)operand).Offset);
} else if (operand is MethodReference) {
return ((MethodReference)operand).Name + "()";
} else if (operand is Cecil.TypeReference) {
return ((Cecil.TypeReference)operand).FullName;
} else if (operand is VariableDefinition) {
return ((VariableDefinition)operand).Name;
} else if (operand is ParameterDefinition) {
return ((ParameterDefinition)operand).Name;
} else if (operand is FieldReference) {
return ((FieldReference)operand).Name;
} else if (operand is string) {
return "\"" + operand + "\"";
} else if (operand is int) {
return operand.ToString();
} else {
return operand.ToString();
}
}
AstNode TransformExpression(ILExpression expr)
{
AstNode node = TransformByteCode(expr);
@ -204,57 +167,57 @@ namespace ICSharpCode.Decompiler.Ast @@ -204,57 +167,57 @@ namespace ICSharpCode.Decompiler.Ast
object operand = byteCode.Operand;
AstType operandAsTypeRef = AstBuilder.ConvertType(operand as Cecil.TypeReference);
List<Ast.Expression> args = TransformExpressionArguments(byteCode);
List<Ast.Expression> args = new List<Expression>();
foreach(ILExpression arg in byteCode.Arguments) {
args.Add((Ast.Expression)TransformExpression(arg));
}
Ast.Expression arg1 = args.Count >= 1 ? args[0] : null;
Ast.Expression arg2 = args.Count >= 2 ? args[1] : null;
Ast.Expression arg3 = args.Count >= 3 ? args[2] : null;
switch(byteCode.Code) {
#region Arithmetic
case ILCode.Add: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Add, arg2);
case ILCode.Add_Ovf: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Add, arg2);
case ILCode.Add_Ovf_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Add, arg2);
case ILCode.Div: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Divide, arg2);
case ILCode.Div_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Divide, arg2);
case ILCode.Mul: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Multiply, arg2);
case ILCode.Mul_Ovf: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Multiply, arg2);
case ILCode.Mul_Ovf_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Multiply, arg2);
case ILCode.Rem: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Modulus, arg2);
case ILCode.Rem_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Modulus, arg2);
case ILCode.Sub: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Subtract, arg2);
case ILCode.Sub_Ovf: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Subtract, arg2);
case ILCode.Sub_Ovf_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Subtract, arg2);
case ILCode.And: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.BitwiseAnd, arg2);
case ILCode.Or: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.BitwiseOr, arg2);
case ILCode.Xor: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ExclusiveOr, arg2);
case ILCode.Shl: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ShiftLeft, arg2);
case ILCode.Shr: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ShiftRight, arg2);
case ILCode.Shr_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ShiftRight, arg2);
case ILCode.Neg: return new Ast.UnaryOperatorExpression(UnaryOperatorType.Minus, arg1);
case ILCode.Not: return new Ast.UnaryOperatorExpression(UnaryOperatorType.BitNot, arg1);
#endregion
#region Arrays
#region Arithmetic
case ILCode.Add: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Add, arg2);
case ILCode.Add_Ovf: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Add, arg2);
case ILCode.Add_Ovf_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Add, arg2);
case ILCode.Div: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Divide, arg2);
case ILCode.Div_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Divide, arg2);
case ILCode.Mul: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Multiply, arg2);
case ILCode.Mul_Ovf: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Multiply, arg2);
case ILCode.Mul_Ovf_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Multiply, arg2);
case ILCode.Rem: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Modulus, arg2);
case ILCode.Rem_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Modulus, arg2);
case ILCode.Sub: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Subtract, arg2);
case ILCode.Sub_Ovf: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Subtract, arg2);
case ILCode.Sub_Ovf_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Subtract, arg2);
case ILCode.And: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.BitwiseAnd, arg2);
case ILCode.Or: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.BitwiseOr, arg2);
case ILCode.Xor: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ExclusiveOr, arg2);
case ILCode.Shl: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ShiftLeft, arg2);
case ILCode.Shr: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ShiftRight, arg2);
case ILCode.Shr_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ShiftRight, arg2);
case ILCode.Neg: return new Ast.UnaryOperatorExpression(UnaryOperatorType.Minus, arg1);
case ILCode.Not: return new Ast.UnaryOperatorExpression(UnaryOperatorType.BitNot, arg1);
#endregion
#region Arrays
case ILCode.Newarr:
case ILCode.InitArray:
{
var ace = new Ast.ArrayCreateExpression();
ace.Type = operandAsTypeRef;
ComposedType ct = operandAsTypeRef as ComposedType;
if (ct != null) {
// change "new (int[,])[10] to new int[10][,]"
ct.ArraySpecifiers.MoveTo(ace.AdditionalArraySpecifiers);
}
if (byteCode.Code == ILCode.InitArray) {
ace.Initializer = new ArrayInitializerExpression();
ace.Initializer.Elements.AddRange(args);
} else {
ace.Arguments.Add(arg1);
}
return ace;
case ILCode.InitArray: {
var ace = new Ast.ArrayCreateExpression();
ace.Type = operandAsTypeRef;
ComposedType ct = operandAsTypeRef as ComposedType;
if (ct != null) {
// change "new (int[,])[10] to new int[10][,]"
ct.ArraySpecifiers.MoveTo(ace.AdditionalArraySpecifiers);
}
if (byteCode.Code == ILCode.InitArray) {
ace.Initializer = new ArrayInitializerExpression();
ace.Initializer.Elements.AddRange(args);
} else {
ace.Arguments.Add(arg1);
}
case ILCode.Ldlen:
return arg1.Member("Length");
return ace;
}
case ILCode.Ldlen: return arg1.Member("Length");
case ILCode.Ldelem_I:
case ILCode.Ldelem_I1:
case ILCode.Ldelem_I2:
@ -268,9 +231,7 @@ namespace ICSharpCode.Decompiler.Ast @@ -268,9 +231,7 @@ namespace ICSharpCode.Decompiler.Ast
case ILCode.Ldelem_Ref:
case ILCode.Ldelem_Any:
return arg1.Indexer(arg2);
case ILCode.Ldelema:
return MakeRef(arg1.Indexer(arg2));
case ILCode.Ldelema: return MakeRef(arg1.Indexer(arg2));
case ILCode.Stelem_I:
case ILCode.Stelem_I1:
case ILCode.Stelem_I2:
@ -281,33 +242,28 @@ namespace ICSharpCode.Decompiler.Ast @@ -281,33 +242,28 @@ namespace ICSharpCode.Decompiler.Ast
case ILCode.Stelem_Ref:
case ILCode.Stelem_Any:
return new Ast.AssignmentExpression(arg1.Indexer(arg2), arg3);
#endregion
#region Comparison
case ILCode.Ceq:
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Equality, arg2);
case ILCode.Cgt:
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.GreaterThan, arg2);
case ILCode.Cgt_Un:
#endregion
#region Comparison
case ILCode.Ceq: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.Equality, arg2);
case ILCode.Cgt: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.GreaterThan, arg2);
case ILCode.Cgt_Un: {
// can also mean Inequality, when used with object references
{
TypeReference arg1Type = byteCode.Arguments[0].InferredType;
if (arg1Type != null && !arg1Type.IsValueType)
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.InEquality, arg2);
else
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.GreaterThan, arg2);
}
case ILCode.Clt:
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.LessThan, arg2);
case ILCode.Clt_Un:
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.LessThan, arg2);
#endregion
#region Logical
TypeReference arg1Type = byteCode.Arguments[0].InferredType;
if (arg1Type != null && !arg1Type.IsValueType)
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.InEquality, arg2);
else
return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.GreaterThan, arg2);
}
case ILCode.Clt: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.LessThan, arg2);
case ILCode.Clt_Un: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.LessThan, arg2);
#endregion
#region Logical
case ILCode.LogicNot: return new Ast.UnaryOperatorExpression(UnaryOperatorType.Not, arg1);
case ILCode.LogicAnd: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ConditionalAnd, arg2);
case ILCode.LogicOr: return new Ast.BinaryOperatorExpression(arg1, BinaryOperatorType.ConditionalOr, arg2);
case ILCode.TernaryOp: return new Ast.ConditionalExpression() { Condition = arg1, TrueExpression = arg2, FalseExpression = arg3 };
#endregion
#region Branch
#endregion
#region Branch
case ILCode.Br: return new Ast.GotoStatement(((ILLabel)byteCode.Operand).Name);
case ILCode.Brtrue:
return new Ast.IfElseStatement() {
@ -316,10 +272,10 @@ namespace ICSharpCode.Decompiler.Ast @@ -316,10 +272,10 @@ namespace ICSharpCode.Decompiler.Ast
new Ast.GotoStatement(((ILLabel)byteCode.Operand).Name)
}
};
case ILCode.LoopOrSwitchBreak: return new Ast.BreakStatement();
case ILCode.LoopContinue: return new Ast.ContinueStatement();
#endregion
#region Conversions
case ILCode.LoopOrSwitchBreak: return new Ast.BreakStatement();
case ILCode.LoopContinue: return new Ast.ContinueStatement();
#endregion
#region Conversions
case ILCode.Conv_I1:
case ILCode.Conv_I2:
case ILCode.Conv_I4:
@ -329,12 +285,11 @@ namespace ICSharpCode.Decompiler.Ast @@ -329,12 +285,11 @@ namespace ICSharpCode.Decompiler.Ast
case ILCode.Conv_U4:
case ILCode.Conv_U8:
return arg1; // conversion is handled by Convert() function using the info from type analysis
case ILCode.Conv_I: return arg1.CastTo(typeof(IntPtr)); // TODO
case ILCode.Conv_U: return arg1.CastTo(typeof(UIntPtr)); // TODO
case ILCode.Conv_R4: return arg1.CastTo(typeof(float));
case ILCode.Conv_R8: return arg1.CastTo(typeof(double));
case ILCode.Conv_R_Un: return arg1.CastTo(typeof(double)); // TODO
case ILCode.Conv_I: return arg1.CastTo(typeof(IntPtr)); // TODO
case ILCode.Conv_U: return arg1.CastTo(typeof(UIntPtr)); // TODO
case ILCode.Conv_R4: return arg1.CastTo(typeof(float));
case ILCode.Conv_R8: return arg1.CastTo(typeof(double));
case ILCode.Conv_R_Un: return arg1.CastTo(typeof(double)); // TODO
case ILCode.Conv_Ovf_I1:
case ILCode.Conv_Ovf_I2:
case ILCode.Conv_Ovf_I4:
@ -352,22 +307,17 @@ namespace ICSharpCode.Decompiler.Ast @@ -352,22 +307,17 @@ namespace ICSharpCode.Decompiler.Ast
case ILCode.Conv_Ovf_U4_Un:
case ILCode.Conv_Ovf_U8_Un:
return arg1; // conversion was handled by Convert() function using the info from type analysis
case ILCode.Conv_Ovf_I: return arg1.CastTo(typeof(IntPtr)); // TODO
case ILCode.Conv_Ovf_U: return arg1.CastTo(typeof(UIntPtr));
case ILCode.Conv_Ovf_I_Un: return arg1.CastTo(typeof(IntPtr));
case ILCode.Conv_Ovf_U_Un: return arg1.CastTo(typeof(UIntPtr));
case ILCode.Castclass:
case ILCode.Unbox_Any:
return arg1.CastTo(operandAsTypeRef);
case ILCode.Isinst:
return arg1.CastAs(operandAsTypeRef);
case ILCode.Box:
return arg1;
case ILCode.Unbox:
return InlineAssembly(byteCode, args);
#endregion
#region Indirect
case ILCode.Conv_Ovf_I: return arg1.CastTo(typeof(IntPtr)); // TODO
case ILCode.Conv_Ovf_U: return arg1.CastTo(typeof(UIntPtr));
case ILCode.Conv_Ovf_I_Un: return arg1.CastTo(typeof(IntPtr));
case ILCode.Conv_Ovf_U_Un: return arg1.CastTo(typeof(UIntPtr));
case ILCode.Castclass: return arg1.CastTo(operandAsTypeRef);
case ILCode.Unbox_Any: return arg1.CastTo(operandAsTypeRef);
case ILCode.Isinst: return arg1.CastAs(operandAsTypeRef);
case ILCode.Box: return arg1;
case ILCode.Unbox: return InlineAssembly(byteCode, args);
#endregion
#region Indirect
case ILCode.Ldind_I:
case ILCode.Ldind_I1:
case ILCode.Ldind_I2:
@ -384,7 +334,6 @@ namespace ICSharpCode.Decompiler.Ast @@ -384,7 +334,6 @@ namespace ICSharpCode.Decompiler.Ast
return ((DirectionExpression)args[0]).Expression.Detach();
else
return InlineAssembly(byteCode, args);
case ILCode.Stind_I:
case ILCode.Stind_I1:
case ILCode.Stind_I2:
@ -398,49 +347,43 @@ namespace ICSharpCode.Decompiler.Ast @@ -398,49 +347,43 @@ namespace ICSharpCode.Decompiler.Ast
return new AssignmentExpression(((DirectionExpression)args[0]).Expression.Detach(), args[1]);
else
return InlineAssembly(byteCode, args);
#endregion
case ILCode.Arglist: return InlineAssembly(byteCode, args);
case ILCode.Break: return InlineAssembly(byteCode, args);
case ILCode.Call:
return TransformCall(false, operand, methodDef, args);
case ILCode.Callvirt:
return TransformCall(true, operand, methodDef, args);
case ILCode.Ldftn:
{
Cecil.MethodReference cecilMethod = ((MethodReference)operand);
var expr = new Ast.IdentifierExpression(cecilMethod.Name);
expr.TypeArguments.AddRange(ConvertTypeArguments(cecilMethod));
expr.AddAnnotation(cecilMethod);
return new IdentifierExpression("ldftn").Invoke(expr)
.WithAnnotation(new Transforms.DelegateConstruction.Annotation(false));
}
case ILCode.Ldvirtftn:
{
Cecil.MethodReference cecilMethod = ((MethodReference)operand);
var expr = new Ast.IdentifierExpression(cecilMethod.Name);
expr.TypeArguments.AddRange(ConvertTypeArguments(cecilMethod));
expr.AddAnnotation(cecilMethod);
return new IdentifierExpression("ldvirtftn").Invoke(expr)
.WithAnnotation(new Transforms.DelegateConstruction.Annotation(true));
}
case ILCode.Calli: return InlineAssembly(byteCode, args);
case ILCode.Ckfinite: return InlineAssembly(byteCode, args);
case ILCode.Constrained: return InlineAssembly(byteCode, args);
case ILCode.Cpblk: return InlineAssembly(byteCode, args);
case ILCode.Cpobj: return InlineAssembly(byteCode, args);
case ILCode.Dup: return arg1;
case ILCode.Endfilter: return InlineAssembly(byteCode, args);
case ILCode.Endfinally: return null;
case ILCode.Initblk: return InlineAssembly(byteCode, args);
#endregion
case ILCode.Arglist: return InlineAssembly(byteCode, args);
case ILCode.Break: return InlineAssembly(byteCode, args);
case ILCode.Call: return TransformCall(false, operand, methodDef, args);
case ILCode.Callvirt: return TransformCall(true, operand, methodDef, args);
case ILCode.Ldftn: {
Cecil.MethodReference cecilMethod = ((MethodReference)operand);
var expr = new Ast.IdentifierExpression(cecilMethod.Name);
expr.TypeArguments.AddRange(ConvertTypeArguments(cecilMethod));
expr.AddAnnotation(cecilMethod);
return new IdentifierExpression("ldftn").Invoke(expr)
.WithAnnotation(new Transforms.DelegateConstruction.Annotation(false));
}
case ILCode.Ldvirtftn: {
Cecil.MethodReference cecilMethod = ((MethodReference)operand);
var expr = new Ast.IdentifierExpression(cecilMethod.Name);
expr.TypeArguments.AddRange(ConvertTypeArguments(cecilMethod));
expr.AddAnnotation(cecilMethod);
return new IdentifierExpression("ldvirtftn").Invoke(expr)
.WithAnnotation(new Transforms.DelegateConstruction.Annotation(true));
}
case ILCode.Calli: return InlineAssembly(byteCode, args);
case ILCode.Ckfinite: return InlineAssembly(byteCode, args);
case ILCode.Constrained: return InlineAssembly(byteCode, args);
case ILCode.Cpblk: return InlineAssembly(byteCode, args);
case ILCode.Cpobj: return InlineAssembly(byteCode, args);
case ILCode.Dup: return arg1;
case ILCode.Endfilter: return InlineAssembly(byteCode, args);
case ILCode.Endfinally: return null;
case ILCode.Initblk: return InlineAssembly(byteCode, args);
case ILCode.Initobj:
if (args[0] is DirectionExpression)
return new AssignmentExpression(((DirectionExpression)args[0]).Expression.Detach(), new DefaultValueExpression { Type = operandAsTypeRef });
else
return InlineAssembly(byteCode, args);
case ILCode.Jmp:
return InlineAssembly(byteCode, args);
case ILCode.Ldarg:
case ILCode.Jmp: return InlineAssembly(byteCode, args);
case ILCode.Ldarg: {
if (methodDef.HasThis && ((ParameterDefinition)operand).Index < 0) {
if (context.CurrentMethod.DeclaringType.IsValueType)
return MakeRef(new Ast.ThisReferenceExpression());
@ -453,14 +396,14 @@ namespace ICSharpCode.Decompiler.Ast @@ -453,14 +396,14 @@ namespace ICSharpCode.Decompiler.Ast
else
return expr;
}
}
case ILCode.Ldarga:
if (methodDef.HasThis && ((ParameterDefinition)operand).Index < 0) {
return MakeRef(new Ast.ThisReferenceExpression());
} else {
return MakeRef(new Ast.IdentifierExpression(((ParameterDefinition)operand).Name).WithAnnotation(operand));
}
case ILCode.Ldc_I4:
return AstBuilder.MakePrimitive((int)operand, byteCode.InferredType);
case ILCode.Ldc_I4: return AstBuilder.MakePrimitive((int)operand, byteCode.InferredType);
case ILCode.Ldc_I8:
case ILCode.Ldc_R4:
case ILCode.Ldc_R8:
@ -482,8 +425,7 @@ namespace ICSharpCode.Decompiler.Ast @@ -482,8 +425,7 @@ namespace ICSharpCode.Decompiler.Ast
AstBuilder.ConvertType(((FieldReference)operand).DeclaringType)
.Member(((FieldReference)operand).Name).WithAnnotation(operand),
arg1);
case ILCode.Ldflda:
return MakeRef(arg1.Member(((FieldReference) operand).Name).WithAnnotation(operand));
case ILCode.Ldflda: return MakeRef(arg1.Member(((FieldReference) operand).Name).WithAnnotation(operand));
case ILCode.Ldsflda:
return MakeRef(
AstBuilder.ConvertType(((FieldReference)operand).DeclaringType)
@ -494,68 +436,61 @@ namespace ICSharpCode.Decompiler.Ast @@ -494,68 +436,61 @@ namespace ICSharpCode.Decompiler.Ast
case ILCode.Ldloca:
localVariablesToDefine.Add((ILVariable)operand);
return MakeRef(new Ast.IdentifierExpression(((ILVariable)operand).Name).WithAnnotation(operand));
case ILCode.Ldnull:
return new Ast.NullReferenceExpression();
case ILCode.Ldstr:
return new Ast.PrimitiveExpression(operand);
case ILCode.Ldnull: return new Ast.NullReferenceExpression();
case ILCode.Ldstr: return new Ast.PrimitiveExpression(operand);
case ILCode.Ldtoken:
if (operand is Cecil.TypeReference) {
return new Ast.TypeOfExpression { Type = operandAsTypeRef }.Member("TypeHandle");
} else {
return InlineAssembly(byteCode, args);
}
case ILCode.Leave: return new GotoStatement() { Label = ((ILLabel)operand).Name };
case ILCode.Localloc: return InlineAssembly(byteCode, args);
case ILCode.Mkrefany: return InlineAssembly(byteCode, args);
case ILCode.Newobj:
{
Cecil.TypeReference declaringType = ((MethodReference)operand).DeclaringType;
if (declaringType is ArrayType) {
ComposedType ct = AstBuilder.ConvertType((ArrayType)declaringType) as ComposedType;
if (ct != null && ct.ArraySpecifiers.Count >= 1) {
var ace = new Ast.ArrayCreateExpression();
ct.ArraySpecifiers.First().Remove();
ct.ArraySpecifiers.MoveTo(ace.AdditionalArraySpecifiers);
ace.Type = ct;
ace.Arguments.AddRange(args);
return ace;
}
}
var oce = new Ast.ObjectCreateExpression();
oce.Type = AstBuilder.ConvertType(declaringType);
oce.Arguments.AddRange(args);
return oce.WithAnnotation(operand);
}
case ILCode.No: return InlineAssembly(byteCode, args);
case ILCode.Nop: return null;
case ILCode.Pop: return arg1;
case ILCode.Readonly: return InlineAssembly(byteCode, args);
case ILCode.Refanytype: return InlineAssembly(byteCode, args);
case ILCode.Refanyval: return InlineAssembly(byteCode, args);
case ILCode.Ret: {
if (methodDef.ReturnType.FullName != "System.Void") {
return new Ast.ReturnStatement { Expression = arg1 };
} else {
return new Ast.ReturnStatement();
case ILCode.Leave: return new GotoStatement() { Label = ((ILLabel)operand).Name };
case ILCode.Localloc: return InlineAssembly(byteCode, args);
case ILCode.Mkrefany: return InlineAssembly(byteCode, args);
case ILCode.Newobj: {
Cecil.TypeReference declaringType = ((MethodReference)operand).DeclaringType;
if (declaringType is ArrayType) {
ComposedType ct = AstBuilder.ConvertType((ArrayType)declaringType) as ComposedType;
if (ct != null && ct.ArraySpecifiers.Count >= 1) {
var ace = new Ast.ArrayCreateExpression();
ct.ArraySpecifiers.First().Remove();
ct.ArraySpecifiers.MoveTo(ace.AdditionalArraySpecifiers);
ace.Type = ct;
ace.Arguments.AddRange(args);
return ace;
}
}
case ILCode.Rethrow: return new Ast.ThrowStatement();
case ILCode.Sizeof:
return new Ast.SizeOfExpression { Type = operandAsTypeRef };
case ILCode.Starg:
return new Ast.AssignmentExpression(new Ast.IdentifierExpression(((ParameterDefinition)operand).Name).WithAnnotation(operand), arg1);
case ILCode.Stloc: {
ILVariable locVar = (ILVariable)operand;
localVariablesToDefine.Add(locVar);
return new Ast.AssignmentExpression(new Ast.IdentifierExpression(locVar.Name).WithAnnotation(locVar), arg1);
var oce = new Ast.ObjectCreateExpression();
oce.Type = AstBuilder.ConvertType(declaringType);
oce.Arguments.AddRange(args);
return oce.WithAnnotation(operand);
}
case ILCode.No: return InlineAssembly(byteCode, args);
case ILCode.Nop: return null;
case ILCode.Pop: return arg1;
case ILCode.Readonly: return InlineAssembly(byteCode, args);
case ILCode.Refanytype: return InlineAssembly(byteCode, args);
case ILCode.Refanyval: return InlineAssembly(byteCode, args);
case ILCode.Ret:
if (methodDef.ReturnType.FullName != "System.Void") {
return new Ast.ReturnStatement { Expression = arg1 };
} else {
return new Ast.ReturnStatement();
}
case ILCode.Switch: return InlineAssembly(byteCode, args);
case ILCode.Tail: return InlineAssembly(byteCode, args);
case ILCode.Throw: return new Ast.ThrowStatement { Expression = arg1 };
case ILCode.Unaligned: return InlineAssembly(byteCode, args);
case ILCode.Volatile: return InlineAssembly(byteCode, args);
default: throw new Exception("Unknown OpCode: " + byteCode.Code);
case ILCode.Rethrow: return new Ast.ThrowStatement();
case ILCode.Sizeof: return new Ast.SizeOfExpression { Type = operandAsTypeRef };
case ILCode.Starg: return new Ast.AssignmentExpression(new Ast.IdentifierExpression(((ParameterDefinition)operand).Name).WithAnnotation(operand), arg1);
case ILCode.Stloc: {
ILVariable locVar = (ILVariable)operand;
localVariablesToDefine.Add(locVar);
return new Ast.AssignmentExpression(new Ast.IdentifierExpression(locVar.Name).WithAnnotation(locVar), arg1);
}
case ILCode.Switch: return InlineAssembly(byteCode, args);
case ILCode.Tail: return InlineAssembly(byteCode, args);
case ILCode.Throw: return new Ast.ThrowStatement { Expression = arg1 };
case ILCode.Unaligned: return InlineAssembly(byteCode, args);
case ILCode.Volatile: return InlineAssembly(byteCode, args);
default: throw new Exception("Unknown OpCode: " + byteCode.Code);
}
}
@ -707,6 +642,31 @@ namespace ICSharpCode.Decompiler.Ast @@ -707,6 +642,31 @@ namespace ICSharpCode.Decompiler.Ast
return new IdentifierExpression(byteCode.Code.GetName()).Invoke(args);
}
static string FormatByteCodeOperand(object operand)
{
if (operand == null) {
return string.Empty;
//} else if (operand is ILExpression) {
// return string.Format("IL_{0:X2}", ((ILExpression)operand).Offset);
} else if (operand is MethodReference) {
return ((MethodReference)operand).Name + "()";
} else if (operand is Cecil.TypeReference) {
return ((Cecil.TypeReference)operand).FullName;
} else if (operand is VariableDefinition) {
return ((VariableDefinition)operand).Name;
} else if (operand is ParameterDefinition) {
return ((ParameterDefinition)operand).Name;
} else if (operand is FieldReference) {
return ((FieldReference)operand).Name;
} else if (operand is string) {
return "\"" + operand + "\"";
} else if (operand is int) {
return operand.ToString();
} else {
return operand.ToString();
}
}
static IEnumerable<AstType> ConvertTypeArguments(MethodReference cecilMethod)
{
GenericInstanceMethod g = cecilMethod as GenericInstanceMethod;

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