//
// expression.cs: Expression representation for the IL tree.
//
// Author:
// Miguel de Icaza (miguel@ximian.com)
//
// (C) 2001 Ximian, Inc.
//
//
#define USE_OLD
namespace Mono.MonoBASIC {
using System;
using System.Collections;
using System.Reflection;
using System.Reflection.Emit;
using System.Text;
///
/// This is just a helper class, it is generated by Unary, UnaryMutator
/// when an overloaded method has been found. It just emits the code for a
/// static call.
///
public class StaticCallExpr : ExpressionStatement {
ArrayList args;
MethodInfo mi;
StaticCallExpr (MethodInfo m, ArrayList a, Location l)
{
mi = m;
args = a;
type = m.ReturnType;
eclass = ExprClass.Value;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
//
// We are born fully resolved
//
return this;
}
public override void Emit (EmitContext ec)
{
if (args != null)
Invocation.EmitArguments (ec, mi, args);
ec.ig.Emit (OpCodes.Call, mi);
return;
}
static public Expression MakeSimpleCall (EmitContext ec, MethodGroupExpr mg,
Expression e, Location loc)
{
ArrayList args;
MethodBase method;
args = new ArrayList (1);
args.Add (new Argument (e, Argument.AType.Expression));
method = Invocation.OverloadResolve (ec, (MethodGroupExpr) mg, args, loc);
if (method == null)
return null;
return new StaticCallExpr ((MethodInfo) method, args, loc);
}
public override void EmitStatement (EmitContext ec)
{
Emit (ec);
if (TypeManager.TypeToCoreType (type) != TypeManager.void_type)
ec.ig.Emit (OpCodes.Pop);
}
}
///
/// Unary expressions.
///
///
///
/// Unary implements unary expressions. It derives from
/// ExpressionStatement becuase the pre/post increment/decrement
/// operators can be used in a statement context.
///
public class Unary : Expression {
public enum Operator : byte {
UnaryPlus, UnaryNegation, LogicalNot, OnesComplement,
Indirection, AddressOf, TOP
}
public Operator Oper;
public Expression Expr;
public Unary (Operator op, Expression expr, Location loc)
{
this.Oper = op;
this.Expr = expr;
this.loc = loc;
}
///
/// Returns a stringified representation of the Operator
///
static public string OperName (Operator oper)
{
switch (oper){
case Operator.UnaryPlus:
return "+";
case Operator.UnaryNegation:
return "-";
case Operator.LogicalNot:
return "!";
case Operator.OnesComplement:
return "~";
case Operator.AddressOf:
return "&";
case Operator.Indirection:
return "*";
}
return oper.ToString ();
}
static string [] oper_names;
static Unary ()
{
oper_names = new string [(int)Operator.TOP];
oper_names [(int) Operator.UnaryPlus] = "op_UnaryPlus";
oper_names [(int) Operator.UnaryNegation] = "op_UnaryNegation";
oper_names [(int) Operator.LogicalNot] = "op_LogicalNot";
oper_names [(int) Operator.OnesComplement] = "op_OnesComplement";
oper_names [(int) Operator.Indirection] = "op_Indirection";
oper_names [(int) Operator.AddressOf] = "op_AddressOf";
}
void Error23 (Type t)
{
Error (
23, "Operator " + OperName (Oper) +
" cannot be applied to operand of type '" +
TypeManager.MonoBASIC_Name (t) + "'");
}
///
/// The result has been already resolved:
///
/// FIXME: a minus constant -128 sbyte cant be turned into a
/// constant byte.
///
static Expression TryReduceNegative (Constant expr)
{
Expression e = null;
if (expr is IntConstant)
e = new IntConstant (-((IntConstant) expr).Value);
else if (expr is UIntConstant){
uint value = ((UIntConstant) expr).Value;
if (value < 2147483649)
return new IntConstant (-(int)value);
else
e = new LongConstant (value);
}
else if (expr is LongConstant)
e = new LongConstant (-((LongConstant) expr).Value);
else if (expr is ULongConstant){
ulong value = ((ULongConstant) expr).Value;
if (value < 9223372036854775809)
return new LongConstant(-(long)value);
}
else if (expr is FloatConstant)
e = new FloatConstant (-((FloatConstant) expr).Value);
else if (expr is DoubleConstant)
e = new DoubleConstant (-((DoubleConstant) expr).Value);
else if (expr is DecimalConstant)
e = new DecimalConstant (-((DecimalConstant) expr).Value);
else if (expr is ShortConstant)
e = new IntConstant (-((ShortConstant) expr).Value);
else if (expr is UShortConstant)
e = new IntConstant (-((UShortConstant) expr).Value);
return e;
}
//
// This routine will attempt to simplify the unary expression when the
// argument is a constant. The result is returned in 'result' and the
// function returns true or false depending on whether a reduction
// was performed or not
//
bool Reduce (EmitContext ec, Constant e, out Expression result)
{
Type expr_type = e.Type;
switch (Oper){
case Operator.UnaryPlus:
result = e;
return true;
case Operator.UnaryNegation:
result = TryReduceNegative (e);
return true;
case Operator.LogicalNot:
if (expr_type != TypeManager.bool_type) {
result = null;
Error23 (expr_type);
return false;
}
BoolConstant b = (BoolConstant) e;
result = new BoolConstant (!(b.Value));
return true;
case Operator.OnesComplement:
if (!((expr_type == TypeManager.int32_type) ||
(expr_type == TypeManager.uint32_type) ||
(expr_type == TypeManager.int64_type) ||
(expr_type == TypeManager.uint64_type) ||
(expr_type.IsSubclassOf (TypeManager.enum_type)))){
result = null;
Error23 (expr_type);
return false;
}
if (e is EnumConstant){
EnumConstant enum_constant = (EnumConstant) e;
Expression reduced;
if (Reduce (ec, enum_constant.Child, out reduced)){
result = new EnumConstant ((Constant) reduced, enum_constant.Type);
return true;
} else {
result = null;
return false;
}
}
if (expr_type == TypeManager.int32_type){
result = new IntConstant (~ ((IntConstant) e).Value);
} else if (expr_type == TypeManager.uint32_type){
result = new UIntConstant (~ ((UIntConstant) e).Value);
} else if (expr_type == TypeManager.int64_type){
result = new LongConstant (~ ((LongConstant) e).Value);
} else if (expr_type == TypeManager.uint64_type){
result = new ULongConstant (~ ((ULongConstant) e).Value);
} else {
result = null;
Error23 (expr_type);
return false;
}
return true;
case Operator.AddressOf:
result = this;
return false;
case Operator.Indirection:
result = this;
return false;
}
throw new Exception ("Can not constant fold: " + Oper.ToString());
}
Expression ResolveOperator (EmitContext ec)
{
Type expr_type = Expr.Type;
//
// Step 1: Perform Operator Overload location
//
Expression mg;
string op_name;
op_name = oper_names [(int) Oper];
mg = MemberLookup (ec, expr_type, op_name, MemberTypes.Method, AllBindingFlags, loc);
if (mg != null) {
Expression e = StaticCallExpr.MakeSimpleCall (
ec, (MethodGroupExpr) mg, Expr, loc);
if (e == null){
Error23 (expr_type);
return null;
}
return e;
}
// Only perform numeric promotions on:
// +, -
if (expr_type == null)
return null;
//
// Step 2: Default operations on CLI native types.
//
// Attempt to use a constant folding operation.
if (Expr is Constant){
Expression result;
if (Reduce (ec, (Constant) Expr, out result))
return result;
}
switch (Oper){
case Operator.LogicalNot:
if (expr_type != TypeManager.bool_type) {
Error23 (Expr.Type);
return null;
}
type = TypeManager.bool_type;
return this;
case Operator.OnesComplement:
if (!((expr_type == TypeManager.int32_type) ||
(expr_type == TypeManager.uint32_type) ||
(expr_type == TypeManager.int64_type) ||
(expr_type == TypeManager.uint64_type) ||
(expr_type.IsSubclassOf (TypeManager.enum_type)))){
Expression e;
e = ConvertImplicit (ec, Expr, TypeManager.int32_type, loc);
if (e != null){
type = TypeManager.int32_type;
return this;
}
e = ConvertImplicit (ec, Expr, TypeManager.uint32_type, loc);
if (e != null){
type = TypeManager.uint32_type;
return this;
}
e = ConvertImplicit (ec, Expr, TypeManager.int64_type, loc);
if (e != null){
type = TypeManager.int64_type;
return this;
}
e = ConvertImplicit (ec, Expr, TypeManager.uint64_type, loc);
if (e != null){
type = TypeManager.uint64_type;
return this;
}
Error23 (expr_type);
return null;
}
type = expr_type;
return this;
case Operator.AddressOf:
if (Expr.eclass != ExprClass.Variable){
Error (211, "Cannot take the address of non-variables");
return null;
}
if (!ec.InUnsafe) {
UnsafeError (loc);
return null;
}
if (!TypeManager.VerifyUnManaged (Expr.Type, loc)){
return null;
}
string ptr_type_name = Expr.Type.FullName + "*";
type = TypeManager.LookupType (ptr_type_name);
return this;
case Operator.Indirection:
if (!ec.InUnsafe){
UnsafeError (loc);
return null;
}
if (!expr_type.IsPointer){
Error (
193,
"The * or -> operator can only be applied to pointers");
return null;
}
//
// We create an Indirection expression, because
// it can implement the IMemoryLocation.
//
return new Indirection (Expr, loc);
case Operator.UnaryPlus:
//
// A plus in front of something is just a no-op, so return the child.
//
return Expr;
case Operator.UnaryNegation:
//
// Deals with -literals
// int operator- (int x)
// long operator- (long x)
// float operator- (float f)
// double operator- (double d)
// decimal operator- (decimal d)
//
Expression expr = null;
//
// transform - - expr into expr
//
if (Expr is Unary){
Unary unary = (Unary) Expr;
if (unary.Oper == Operator.UnaryNegation)
return unary.Expr;
}
//
// perform numeric promotions to int,
// long, double.
//
//
// The following is inneficient, because we call
// ConvertImplicit too many times.
//
// It is also not clear if we should convert to Float
// or Double initially.
//
if (expr_type == TypeManager.uint32_type){
//
// FIXME: handle exception to this rule that
// permits the int value -2147483648 (-2^31) to
// bt wrote as a decimal interger literal
//
type = TypeManager.int64_type;
Expr = ConvertImplicit (ec, Expr, type, loc);
return this;
}
if (expr_type == TypeManager.uint64_type){
//
// FIXME: Handle exception of 'long value'
// -92233720368547758087 (-2^63) to be wrote as
// decimal integer literal.
//
Error23 (expr_type);
return null;
}
if (expr_type == TypeManager.float_type){
type = expr_type;
return this;
}
expr = ConvertImplicit (ec, Expr, TypeManager.int32_type, loc);
if (expr != null){
Expr = expr;
type = expr.Type;
return this;
}
expr = ConvertImplicit (ec, Expr, TypeManager.int64_type, loc);
if (expr != null){
Expr = expr;
type = expr.Type;
return this;
}
expr = ConvertImplicit (ec, Expr, TypeManager.double_type, loc);
if (expr != null){
Expr = expr;
type = expr.Type;
return this;
}
Error23 (expr_type);
return null;
}
Error (187, "No such operator '" + OperName (Oper) + "' defined for type '" +
TypeManager.MonoBASIC_Name (expr_type) + "'");
return null;
}
public override Expression DoResolve (EmitContext ec)
{
if (Oper == Operator.AddressOf)
Expr = Expr.ResolveLValue (ec, new EmptyExpression ());
else
Expr = Expr.Resolve (ec);
if (Expr == null)
return null;
eclass = ExprClass.Value;
return ResolveOperator (ec);
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
Type expr_type = Expr.Type;
switch (Oper) {
case Operator.UnaryPlus:
throw new Exception ("This should be caught by Resolve");
case Operator.UnaryNegation:
Expr.Emit (ec);
ig.Emit (OpCodes.Neg);
break;
case Operator.LogicalNot:
Expr.Emit (ec);
ig.Emit (OpCodes.Ldc_I4_0);
ig.Emit (OpCodes.Ceq);
break;
case Operator.OnesComplement:
Expr.Emit (ec);
ig.Emit (OpCodes.Not);
break;
case Operator.AddressOf:
((IMemoryLocation)Expr).AddressOf (ec, AddressOp.LoadStore);
break;
default:
throw new Exception ("This should not happen: Operator = "
+ Oper.ToString ());
}
}
///
/// This will emit the child expression for 'ec' avoiding the logical
/// not. The parent will take care of changing brfalse/brtrue
///
public void EmitLogicalNot (EmitContext ec)
{
if (Oper != Operator.LogicalNot)
throw new Exception ("EmitLogicalNot can only be called with !expr");
Expr.Emit (ec);
}
public override string ToString ()
{
return "Unary (" + Oper + ", " + Expr + ")";
}
}
//
// Unary operators are turned into Indirection expressions
// after semantic analysis (this is so we can take the address
// of an indirection).
//
public class Indirection : Expression, IMemoryLocation, IAssignMethod {
Expression expr;
LocalTemporary temporary;
bool have_temporary;
public Indirection (Expression expr, Location l)
{
this.expr = expr;
this.type = TypeManager.TypeToCoreType (expr.Type.GetElementType ());
eclass = ExprClass.Variable;
loc = l;
}
void LoadExprValue (EmitContext ec)
{
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
if (temporary != null){
if (have_temporary){
temporary.Emit (ec);
return;
}
expr.Emit (ec);
ec.ig.Emit (OpCodes.Dup);
temporary.Store (ec);
have_temporary = true;
} else
expr.Emit (ec);
LoadFromPtr (ig, Type);
}
public void EmitAssign (EmitContext ec, Expression source)
{
if (temporary != null){
if (have_temporary){
temporary.Emit (ec);
return;
}
expr.Emit (ec);
ec.ig.Emit (OpCodes.Dup);
temporary.Store (ec);
have_temporary = true;
} else
expr.Emit (ec);
source.Emit (ec);
StoreFromPtr (ec.ig, type);
}
public void AddressOf (EmitContext ec, AddressOp Mode)
{
if (temporary != null){
if (have_temporary){
temporary.Emit (ec);
return;
}
expr.Emit (ec);
ec.ig.Emit (OpCodes.Dup);
temporary.Store (ec);
have_temporary = true;
} else
expr.Emit (ec);
}
public override Expression DoResolve (EmitContext ec)
{
//
// Born fully resolved
//
return this;
}
public new void CacheTemporaries (EmitContext ec)
{
temporary = new LocalTemporary (ec, type);
}
}
///
/// Unary Mutator expressions (pre and post ++ and --)
///
///
///
/// UnaryMutator implements ++ and -- expressions. It derives from
/// ExpressionStatement becuase the pre/post increment/decrement
/// operators can be used in a statement context.
///
/// FIXME: Idea, we could split this up in two classes, one simpler
/// for the common case, and one with the extra fields for more complex
/// classes (indexers require temporary access; overloaded require method)
///
/// Maybe we should have classes PreIncrement, PostIncrement, PreDecrement,
/// PostDecrement, that way we could save the 'Mode' byte as well.
///
public class UnaryMutator : ExpressionStatement {
public enum Mode : byte {
PreIncrement, PreDecrement, PostIncrement, PostDecrement
}
Mode mode;
Expression expr;
LocalTemporary temp_storage;
//
// This is expensive for the simplest case.
//
Expression method;
public UnaryMutator (Mode m, Expression e, Location l)
{
mode = m;
loc = l;
expr = e;
}
static string OperName (Mode mode)
{
return (mode == Mode.PreIncrement || mode == Mode.PostIncrement) ?
"++" : "--";
}
void Error23 (Type t)
{
Error (
23, "Operator " + OperName (mode) +
" cannot be applied to operand of type '" +
TypeManager.MonoBASIC_Name (t) + "'");
}
///
/// Returns whether an object of type 't' can be incremented
/// or decremented with add/sub (ie, basically whether we can
/// use pre-post incr-decr operations on it, but it is not a
/// System.Decimal, which we require operator overloading to catch)
///
static bool IsIncrementableNumber (Type t)
{
return (t == TypeManager.sbyte_type) ||
(t == TypeManager.byte_type) ||
(t == TypeManager.short_type) ||
(t == TypeManager.ushort_type) ||
(t == TypeManager.int32_type) ||
(t == TypeManager.uint32_type) ||
(t == TypeManager.int64_type) ||
(t == TypeManager.uint64_type) ||
(t == TypeManager.char_type) ||
(t.IsSubclassOf (TypeManager.enum_type)) ||
(t == TypeManager.float_type) ||
(t == TypeManager.double_type) ||
(t.IsPointer && t != TypeManager.void_ptr_type);
}
Expression ResolveOperator (EmitContext ec)
{
Type expr_type = expr.Type;
//
// Step 1: Perform Operator Overload location
//
Expression mg;
string op_name;
if (mode == Mode.PreIncrement || mode == Mode.PostIncrement)
op_name = "op_Increment";
else
op_name = "op_Decrement";
mg = MemberLookup (ec, expr_type, op_name, MemberTypes.Method, AllBindingFlags, loc);
if (mg == null && expr_type.BaseType != null)
mg = MemberLookup (ec, expr_type.BaseType, op_name,
MemberTypes.Method, AllBindingFlags, loc);
if (mg != null) {
method = StaticCallExpr.MakeSimpleCall (
ec, (MethodGroupExpr) mg, expr, loc);
type = method.Type;
return this;
}
//
// The operand of the prefix/postfix increment decrement operators
// should be an expression that is classified as a variable,
// a property access or an indexer access
//
type = expr_type;
if (expr.eclass == ExprClass.Variable){
if (IsIncrementableNumber (expr_type) ||
expr_type == TypeManager.decimal_type){
return this;
}
} else if (expr.eclass == ExprClass.IndexerAccess){
IndexerAccess ia = (IndexerAccess) expr;
temp_storage = new LocalTemporary (ec, expr.Type);
expr = ia.ResolveLValue (ec, temp_storage);
if (expr == null)
return null;
return this;
} else if (expr.eclass == ExprClass.PropertyAccess){
PropertyExpr pe = (PropertyExpr) expr;
if (pe.VerifyAssignable ())
return this;
return null;
} else {
expr.Error118 ("variable, indexer or property access");
return null;
}
Error (187, "No such operator '" + OperName (mode) + "' defined for type '" +
TypeManager.MonoBASIC_Name (expr_type) + "'");
return null;
}
public override Expression DoResolve (EmitContext ec)
{
expr = expr.Resolve (ec);
if (expr == null)
return null;
eclass = ExprClass.Value;
return ResolveOperator (ec);
}
static int PtrTypeSize (Type t)
{
return GetTypeSize (t.GetElementType ());
}
//
// Loads the proper "1" into the stack based on the type
//
static void LoadOne (ILGenerator ig, Type t)
{
if (t == TypeManager.uint64_type || t == TypeManager.int64_type)
ig.Emit (OpCodes.Ldc_I8, 1L);
else if (t == TypeManager.double_type)
ig.Emit (OpCodes.Ldc_R8, 1.0);
else if (t == TypeManager.float_type)
ig.Emit (OpCodes.Ldc_R4, 1.0F);
else if (t.IsPointer){
int n = PtrTypeSize (t);
if (n == 0)
ig.Emit (OpCodes.Sizeof, t);
else
IntConstant.EmitInt (ig, n);
} else
ig.Emit (OpCodes.Ldc_I4_1);
}
//
// FIXME: We need some way of avoiding the use of temp_storage
// for some types of storage (parameters, local variables,
// static fields) and single-dimension array access.
//
void EmitCode (EmitContext ec, bool is_expr)
{
ILGenerator ig = ec.ig;
IAssignMethod ia = (IAssignMethod) expr;
Type expr_type = expr.Type;
if (temp_storage == null)
temp_storage = new LocalTemporary (ec, expr_type);
ia.CacheTemporaries (ec);
ig.Emit (OpCodes.Nop);
switch (mode){
case Mode.PreIncrement:
case Mode.PreDecrement:
if (method == null){
expr.Emit (ec);
LoadOne (ig, expr_type);
//
// Select the opcode based on the check state (then the type)
// and the actual operation
//
if (ec.CheckState){
if (expr_type == TypeManager.int32_type ||
expr_type == TypeManager.int64_type){
if (mode == Mode.PreDecrement)
ig.Emit (OpCodes.Sub_Ovf);
else
ig.Emit (OpCodes.Add_Ovf);
} else if (expr_type == TypeManager.uint32_type ||
expr_type == TypeManager.uint64_type){
if (mode == Mode.PreDecrement)
ig.Emit (OpCodes.Sub_Ovf_Un);
else
ig.Emit (OpCodes.Add_Ovf_Un);
} else {
if (mode == Mode.PreDecrement)
ig.Emit (OpCodes.Sub_Ovf);
else
ig.Emit (OpCodes.Add_Ovf);
}
} else {
if (mode == Mode.PreDecrement)
ig.Emit (OpCodes.Sub);
else
ig.Emit (OpCodes.Add);
}
} else
method.Emit (ec);
temp_storage.Store (ec);
ia.EmitAssign (ec, temp_storage);
if (is_expr)
temp_storage.Emit (ec);
break;
case Mode.PostIncrement:
case Mode.PostDecrement:
if (is_expr)
expr.Emit (ec);
if (method == null){
if (!is_expr)
expr.Emit (ec);
else
ig.Emit (OpCodes.Dup);
LoadOne (ig, expr_type);
if (ec.CheckState){
if (expr_type == TypeManager.int32_type ||
expr_type == TypeManager.int64_type){
if (mode == Mode.PostDecrement)
ig.Emit (OpCodes.Sub_Ovf);
else
ig.Emit (OpCodes.Add_Ovf);
} else if (expr_type == TypeManager.uint32_type ||
expr_type == TypeManager.uint64_type){
if (mode == Mode.PostDecrement)
ig.Emit (OpCodes.Sub_Ovf_Un);
else
ig.Emit (OpCodes.Add_Ovf_Un);
} else {
if (mode == Mode.PostDecrement)
ig.Emit (OpCodes.Sub_Ovf);
else
ig.Emit (OpCodes.Add_Ovf);
}
} else {
if (mode == Mode.PostDecrement)
ig.Emit (OpCodes.Sub);
else
ig.Emit (OpCodes.Add);
}
} else {
method.Emit (ec);
}
temp_storage.Store (ec);
ia.EmitAssign (ec, temp_storage);
break;
}
}
public override void Emit (EmitContext ec)
{
EmitCode (ec, true);
}
public override void EmitStatement (EmitContext ec)
{
EmitCode (ec, false);
}
}
///
/// Base class for the 'Is' and 'As' classes.
///
///
///
/// FIXME: Split this in two, and we get to save the 'Operator' Oper
/// size.
///
public abstract class Probe : Expression {
public readonly Expression ProbeType;
protected Expression expr;
protected Type probe_type;
public Probe (Expression expr, Expression probe_type, Location l)
{
ProbeType = probe_type;
loc = l;
this.expr = expr;
}
public Expression Expr {
get {
return expr;
}
}
public override Expression DoResolve (EmitContext ec)
{
probe_type = ec.DeclSpace.ResolveType (ProbeType, false, loc);
if (probe_type == null)
return null;
expr = expr.Resolve (ec);
return this;
}
}
///
/// Implementation of the 'is' operator.
///
public class Is : Probe {
public Is (Expression expr, Expression probe_type, Location l)
: base (expr, probe_type, l)
{
}
enum Action {
AlwaysTrue, AlwaysNull, AlwaysFalse, LeaveOnStack, Probe
}
Action action;
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
expr.Emit (ec);
switch (action){
case Action.AlwaysFalse:
ig.Emit (OpCodes.Pop);
IntConstant.EmitInt (ig, 0);
return;
case Action.AlwaysTrue:
ig.Emit (OpCodes.Pop);
ig.Emit (OpCodes.Nop);
IntConstant.EmitInt (ig, 1);
return;
case Action.LeaveOnStack:
// the 'e != null' rule.
return;
case Action.Probe:
ig.Emit (OpCodes.Isinst, probe_type);
ig.Emit (OpCodes.Ldnull);
ig.Emit (OpCodes.Cgt_Un);
return;
}
throw new Exception ("never reached");
}
public override Expression DoResolve (EmitContext ec)
{
Expression e = base.DoResolve (ec);
if ((e == null) || (expr == null))
return null;
Type etype = expr.Type;
bool warning_always_matches = false;
bool warning_never_matches = false;
type = TypeManager.bool_type;
eclass = ExprClass.Value;
//
// First case, if at compile time, there is an implicit conversion
// then e != null (objects) or true (value types)
//
e = ConvertImplicitStandard (ec, expr, probe_type, loc);
if (e != null){
expr = e;
if (etype.IsValueType)
action = Action.AlwaysTrue;
else
action = Action.LeaveOnStack;
warning_always_matches = true;
} else if (ExplicitReferenceConversionExists (etype, probe_type)){
//
// Second case: explicit reference convresion
//
if (expr is NullLiteral)
action = Action.AlwaysFalse;
else
action = Action.Probe;
} else {
action = Action.AlwaysFalse;
warning_never_matches = true;
}
if (RootContext.WarningLevel >= 1){
if (warning_always_matches)
Warning (
183,
"The expression is always of type '" +
TypeManager.MonoBASIC_Name (probe_type) + "'");
else if (warning_never_matches){
if (!(probe_type.IsInterface || expr.Type.IsInterface))
Warning (
184,
"The expression is never of type '" +
TypeManager.MonoBASIC_Name (probe_type) + "'");
}
}
return this;
}
}
///
/// Implementation of the 'as' operator.
///
public class As : Probe {
public As (Expression expr, Expression probe_type, Location l)
: base (expr, probe_type, l)
{
}
bool do_isinst = false;
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
expr.Emit (ec);
if (do_isinst)
ig.Emit (OpCodes.Isinst, probe_type);
}
static void Error_CannotConvertType (Type source, Type target, Location loc)
{
Report.Error (
39, loc, "as operator can not convert from '" +
TypeManager.MonoBASIC_Name (source) + "' to '" +
TypeManager.MonoBASIC_Name (target) + "'");
}
public override Expression DoResolve (EmitContext ec)
{
Expression e = base.DoResolve (ec);
if (e == null)
return null;
type = probe_type;
eclass = ExprClass.Value;
Type etype = expr.Type;
if (TypeManager.IsValueType (probe_type)){
Report.Error (77, loc, "The as operator should be used with a reference type only (" +
TypeManager.MonoBASIC_Name (probe_type) + " is a value type)");
return null;
}
e = ConvertImplicit (ec, expr, probe_type, loc);
if (e != null){
expr = e;
do_isinst = false;
return this;
}
if (ExplicitReferenceConversionExists (etype, probe_type)){
do_isinst = true;
return this;
}
Error_CannotConvertType (etype, probe_type, loc);
return null;
}
}
///
/// This represents a typecast in the source language.
///
/// FIXME: Cast expressions have an unusual set of parsing
/// rules, we need to figure those out.
///
public class Cast : Expression {
Expression target_type;
Expression expr;
public Cast (Expression cast_type, Expression expr, Location loc)
{
this.target_type = cast_type;
this.expr = expr;
this.loc = loc;
}
public Expression TargetType {
get {
return target_type;
}
}
public Expression Expr {
get {
return expr;
}
set {
expr = value;
}
}
///
/// Attempts to do a compile-time folding of a constant cast.
///
Expression TryReduce (EmitContext ec, Type target_type)
{
if (expr is ByteConstant){
byte v = ((ByteConstant) expr).Value;
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is SByteConstant){
sbyte v = ((SByteConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is ShortConstant){
short v = ((ShortConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is UShortConstant){
ushort v = ((UShortConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is IntConstant){
int v = ((IntConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is UIntConstant){
uint v = ((UIntConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is LongConstant){
long v = ((LongConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is ULongConstant){
ulong v = ((ULongConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is FloatConstant){
float v = ((FloatConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.double_type)
return new DoubleConstant ((double) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
if (expr is DoubleConstant){
double v = ((DoubleConstant) expr).Value;
if (target_type == TypeManager.byte_type)
return new ByteConstant ((byte) v);
if (target_type == TypeManager.sbyte_type)
return new SByteConstant ((sbyte) v);
if (target_type == TypeManager.short_type)
return new ShortConstant ((short) v);
if (target_type == TypeManager.ushort_type)
return new UShortConstant ((ushort) v);
if (target_type == TypeManager.int32_type)
return new IntConstant ((int) v);
if (target_type == TypeManager.uint32_type)
return new UIntConstant ((uint) v);
if (target_type == TypeManager.int64_type)
return new LongConstant ((long) v);
if (target_type == TypeManager.uint64_type)
return new ULongConstant ((ulong) v);
if (target_type == TypeManager.float_type)
return new FloatConstant ((float) v);
if (target_type == TypeManager.char_type)
return new CharConstant ((char) v);
if (target_type == TypeManager.decimal_type)
return new DecimalConstant ((decimal) v);
}
return null;
}
public override Expression DoResolve (EmitContext ec)
{
expr = expr.Resolve (ec);
if (expr == null)
return null;
int errors = Report.Errors;
type = ec.DeclSpace.ResolveType (target_type, false, Location);
if (type == null)
return null;
eclass = ExprClass.Value;
if (expr is Constant){
Expression e = TryReduce (ec, type);
if (e != null)
return e;
}
expr = ConvertExplicit (ec, expr, type, loc);
return expr;
}
public override void Emit (EmitContext ec)
{
//
// This one will never happen
//
throw new Exception ("Should not happen");
}
}
///
/// Binary operators
///
public class Binary : Expression {
public enum Operator : byte {
Multiply, Division, Modulus,
Addition, Subtraction,
LeftShift, RightShift,
LessThan, GreaterThan, LessThanOrEqual, GreaterThanOrEqual,
Equality, Inequality,
BitwiseAnd,
ExclusiveOr,
BitwiseOr,
LogicalAnd,
LogicalOr,
TOP
}
Operator oper;
Expression left, right;
//
// After resolution, method might contain the operator overload
// method.
//
protected MethodBase method;
ArrayList Arguments;
bool DelegateOperation;
// This must be kept in sync with Operator!!!
static string [] oper_names;
static Binary ()
{
oper_names = new string [(int) Operator.TOP];
oper_names [(int) Operator.Multiply] = "op_Multiply";
oper_names [(int) Operator.Division] = "op_Division";
oper_names [(int) Operator.Modulus] = "op_Modulus";
oper_names [(int) Operator.Addition] = "op_Addition";
oper_names [(int) Operator.Subtraction] = "op_Subtraction";
oper_names [(int) Operator.LeftShift] = "op_LeftShift";
oper_names [(int) Operator.RightShift] = "op_RightShift";
oper_names [(int) Operator.LessThan] = "op_LessThan";
oper_names [(int) Operator.GreaterThan] = "op_GreaterThan";
oper_names [(int) Operator.LessThanOrEqual] = "op_LessThanOrEqual";
oper_names [(int) Operator.GreaterThanOrEqual] = "op_GreaterThanOrEqual";
oper_names [(int) Operator.Equality] = "op_Equality";
oper_names [(int) Operator.Inequality] = "op_Inequality";
oper_names [(int) Operator.BitwiseAnd] = "op_BitwiseAnd";
oper_names [(int) Operator.BitwiseOr] = "op_BitwiseOr";
oper_names [(int) Operator.ExclusiveOr] = "op_ExclusiveOr";
oper_names [(int) Operator.LogicalOr] = "op_LogicalOr";
oper_names [(int) Operator.LogicalAnd] = "op_LogicalAnd";
}
public Binary (Operator oper, Expression left, Expression right, Location loc)
{
this.oper = oper;
this.left = left;
this.right = right;
this.loc = loc;
}
public Operator Oper {
get {
return oper;
}
set {
oper = value;
}
}
public Expression Left {
get {
return left;
}
set {
left = value;
}
}
public Expression Right {
get {
return right;
}
set {
right = value;
}
}
///
/// Returns a stringified representation of the Operator
///
static string OperName (Operator oper)
{
switch (oper){
case Operator.Multiply:
return "*";
case Operator.Division:
return "/";
case Operator.Modulus:
return "%";
case Operator.Addition:
return "+";
case Operator.Subtraction:
return "-";
case Operator.LeftShift:
return "<<";
case Operator.RightShift:
return ">>";
case Operator.LessThan:
return "<";
case Operator.GreaterThan:
return ">";
case Operator.LessThanOrEqual:
return "<=";
case Operator.GreaterThanOrEqual:
return ">=";
case Operator.Equality:
return "==";
case Operator.Inequality:
return "!=";
case Operator.BitwiseAnd:
return "&";
case Operator.BitwiseOr:
return "|";
case Operator.ExclusiveOr:
return "^";
case Operator.LogicalOr:
return "||";
case Operator.LogicalAnd:
return "&&";
}
return oper.ToString ();
}
public override string ToString ()
{
return "operator " + OperName (oper) + "(" + left.ToString () + ", " +
right.ToString () + ")";
}
Expression ForceConversion (EmitContext ec, Expression expr, Type target_type)
{
if (expr.Type == target_type)
return expr;
return ConvertImplicit (ec, expr, target_type, Location.Null);
}
public static void Error_OperatorAmbiguous (Location loc, Operator oper, Type l, Type r)
{
Report.Error (
34, loc, "Operator '" + OperName (oper)
+ "' is ambiguous on operands of type '"
+ TypeManager.MonoBASIC_Name (l) + "' "
+ "and '" + TypeManager.MonoBASIC_Name (r)
+ "'");
}
//
// Note that handling the case l == Decimal || r == Decimal
// is taken care of by the Step 1 Operator Overload resolution.
//
bool DoNumericPromotions (EmitContext ec, Type l, Type r)
{
if (l == TypeManager.double_type || r == TypeManager.double_type){
//
// If either operand is of type double, the other operand is
// conveted to type double.
//
if (r != TypeManager.double_type)
right = ConvertImplicit (ec, right, TypeManager.double_type, loc);
if (l != TypeManager.double_type)
left = ConvertImplicit (ec, left, TypeManager.double_type, loc);
type = TypeManager.double_type;
} else if (l == TypeManager.float_type || r == TypeManager.float_type){
//
// if either operand is of type float, the other operand is
// converted to type float.
//
if (r != TypeManager.double_type)
right = ConvertImplicit (ec, right, TypeManager.float_type, loc);
if (l != TypeManager.double_type)
left = ConvertImplicit (ec, left, TypeManager.float_type, loc);
type = TypeManager.float_type;
} else if (l == TypeManager.uint64_type || r == TypeManager.uint64_type){
Expression e;
Type other;
//
// If either operand is of type ulong, the other operand is
// converted to type ulong. or an error ocurrs if the other
// operand is of type sbyte, short, int or long
//
if (l == TypeManager.uint64_type){
if (r != TypeManager.uint64_type){
if (right is IntConstant){
IntConstant ic = (IntConstant) right;
e = TryImplicitIntConversion (l, ic);
if (e != null)
right = e;
} else if (right is LongConstant){
long ll = ((LongConstant) right).Value;
if (ll > 0)
right = new ULongConstant ((ulong) ll);
} else {
e = ImplicitNumericConversion (ec, right, l, loc);
if (e != null)
right = e;
}
}
other = right.Type;
} else {
if (left is IntConstant){
e = TryImplicitIntConversion (r, (IntConstant) left);
if (e != null)
left = e;
} else if (left is LongConstant){
long ll = ((LongConstant) left).Value;
if (ll > 0)
left = new ULongConstant ((ulong) ll);
} else {
e = ImplicitNumericConversion (ec, left, r, loc);
if (e != null)
left = e;
}
other = left.Type;
}
if ((other == TypeManager.sbyte_type) ||
(other == TypeManager.short_type) ||
(other == TypeManager.int32_type) ||
(other == TypeManager.int64_type))
Error_OperatorAmbiguous (loc, oper, l, r);
type = TypeManager.uint64_type;
} else if (l == TypeManager.int64_type || r == TypeManager.int64_type){
//
// If either operand is of type long, the other operand is converted
// to type long.
//
if (l != TypeManager.int64_type)
left = ConvertImplicit (ec, left, TypeManager.int64_type, loc);
if (r != TypeManager.int64_type)
right = ConvertImplicit (ec, right, TypeManager.int64_type, loc);
type = TypeManager.int64_type;
} else if (l == TypeManager.uint32_type || r == TypeManager.uint32_type){
//
// If either operand is of type uint, and the other
// operand is of type sbyte, short or int, othe operands are
// converted to type long.
//
Type other = null;
if (l == TypeManager.uint32_type){
if (right is IntConstant){
IntConstant ic = (IntConstant) right;
int val = ic.Value;
if (val >= 0)
right = new UIntConstant ((uint) val);
type = l;
return true;
}
other = r;
}
else if (r == TypeManager.uint32_type){
if (left is IntConstant){
IntConstant ic = (IntConstant) left;
int val = ic.Value;
if (val >= 0)
left = new UIntConstant ((uint) val);
type = r;
return true;
}
other = l;
}
if ((other == TypeManager.sbyte_type) ||
(other == TypeManager.short_type) ||
(other == TypeManager.int32_type)){
left = ForceConversion (ec, left, TypeManager.int64_type);
right = ForceConversion (ec, right, TypeManager.int64_type);
type = TypeManager.int64_type;
} else {
//
// if either operand is of type uint, the other
// operand is converd to type uint
//
left = ForceConversion (ec, left, TypeManager.uint32_type);
right = ForceConversion (ec, right, TypeManager.uint32_type);
type = TypeManager.uint32_type;
}
} else if (l == TypeManager.decimal_type || r == TypeManager.decimal_type){
if (l != TypeManager.decimal_type)
left = ConvertImplicit (ec, left, TypeManager.decimal_type, loc);
if (r != TypeManager.decimal_type)
right = ConvertImplicit (ec, right, TypeManager.decimal_type, loc);
type = TypeManager.decimal_type;
} else {
left = ForceConversion (ec, left, TypeManager.int32_type);
right = ForceConversion (ec, right, TypeManager.int32_type);
type = TypeManager.int32_type;
}
return (left != null) && (right != null);
}
static public void Error_OperatorCannotBeApplied (Location loc, string name, Type l, Type r)
{
Report.Error (19, loc,
"Operator " + name + " cannot be applied to operands of type '" +
TypeManager.MonoBASIC_Name (l) + "' and '" +
TypeManager.MonoBASIC_Name (r) + "'");
}
void Error_OperatorCannotBeApplied ()
{
Error_OperatorCannotBeApplied (loc, OperName (oper), left.Type, right.Type);
}
static bool is_32_or_64 (Type t)
{
return (t == TypeManager.int32_type || t == TypeManager.uint32_type ||
t == TypeManager.int64_type || t == TypeManager.uint64_type);
}
static bool is_unsigned (Type t)
{
return (t == TypeManager.uint32_type || t == TypeManager.uint64_type ||
t == TypeManager.short_type || t == TypeManager.byte_type);
}
Expression CheckShiftArguments (EmitContext ec)
{
Expression e;
Type l = left.Type;
Type r = right.Type;
e = ForceConversion (ec, right, TypeManager.int32_type);
if (e == null){
Error_OperatorCannotBeApplied ();
return null;
}
right = e;
if (((e = ConvertImplicit (ec, left, TypeManager.int32_type, loc)) != null) ||
((e = ConvertImplicit (ec, left, TypeManager.uint32_type, loc)) != null) ||
((e = ConvertImplicit (ec, left, TypeManager.int64_type, loc)) != null) ||
((e = ConvertImplicit (ec, left, TypeManager.uint64_type, loc)) != null)){
left = e;
type = e.Type;
return this;
}
Error_OperatorCannotBeApplied ();
return null;
}
Expression ResolveOperator (EmitContext ec)
{
Type l = left.Type;
Type r = right.Type;
bool overload_failed = false;
//
// Step 1: Perform Operator Overload location
//
Expression left_expr, right_expr;
string op = oper_names [(int) oper];
MethodGroupExpr union;
left_expr = MemberLookup (ec, l, op, MemberTypes.Method, AllBindingFlags, loc);
if (r != l){
right_expr = MemberLookup (
ec, r, op, MemberTypes.Method, AllBindingFlags, loc);
union = Invocation.MakeUnionSet (left_expr, right_expr, loc);
} else
union = (MethodGroupExpr) left_expr;
if (union != null) {
Arguments = new ArrayList ();
Arguments.Add (new Argument (left, Argument.AType.Expression));
Arguments.Add (new Argument (right, Argument.AType.Expression));
method = Invocation.OverloadResolve (ec, union, Arguments, Location.Null);
if (method != null) {
MethodInfo mi = (MethodInfo) method;
type = mi.ReturnType;
return this;
} else {
overload_failed = true;
}
}
//
// Step 2: Default operations on CLI native types.
//
//
// Step 0: String concatenation (because overloading will get this wrong)
//
if (oper == Operator.Addition){
//
// If any of the arguments is a string, cast to string
//
if (l == TypeManager.string_type){
if (r == TypeManager.void_type) {
Error_OperatorCannotBeApplied ();
return null;
}
if (r == TypeManager.string_type){
if (left is Constant && right is Constant){
StringConstant ls = (StringConstant) left;
StringConstant rs = (StringConstant) right;
return new StringConstant (
ls.Value + rs.Value);
}
// string + string
method = TypeManager.string_concat_string_string;
} else {
// string + object
method = TypeManager.string_concat_object_object;
right = ConvertImplicit (ec, right,
TypeManager.object_type, loc);
if (right == null){
Error_OperatorCannotBeApplied (loc, OperName (oper), l, r);
return null;
}
}
type = TypeManager.string_type;
Arguments = new ArrayList ();
Arguments.Add (new Argument (left, Argument.AType.Expression));
Arguments.Add (new Argument (right, Argument.AType.Expression));
return this;
} else if (r == TypeManager.string_type){
// object + string
if (l == TypeManager.void_type) {
Error_OperatorCannotBeApplied ();
return null;
}
method = TypeManager.string_concat_object_object;
left = ConvertImplicit (ec, left, TypeManager.object_type, loc);
if (left == null){
Error_OperatorCannotBeApplied (loc, OperName (oper), l, r);
return null;
}
Arguments = new ArrayList ();
Arguments.Add (new Argument (left, Argument.AType.Expression));
Arguments.Add (new Argument (right, Argument.AType.Expression));
type = TypeManager.string_type;
return this;
}
//
// Transform a + ( - b) into a - b
//
if (right is Unary){
Unary right_unary = (Unary) right;
if (right_unary.Oper == Unary.Operator.UnaryNegation){
oper = Operator.Subtraction;
right = right_unary.Expr;
r = right.Type;
}
}
}
if (oper == Operator.Equality || oper == Operator.Inequality){
if (l == TypeManager.bool_type || r == TypeManager.bool_type){
if (r != TypeManager.bool_type || l != TypeManager.bool_type){
Error_OperatorCannotBeApplied ();
return null;
}
type = TypeManager.bool_type;
return this;
}
//
// operator != (object a, object b)
// operator == (object a, object b)
//
// For this to be used, both arguments have to be reference-types.
// Read the rationale on the spec (14.9.6)
//
// Also, if at compile time we know that the classes do not inherit
// one from the other, then we catch the error there.
//
if (!(l.IsValueType || r.IsValueType)){
type = TypeManager.bool_type;
if (l == r)
return this;
if (l.IsSubclassOf (r) || r.IsSubclassOf (l))
return this;
//
// Also, a standard conversion must exist from either one
//
if (!(StandardConversionExists (left, r) ||
StandardConversionExists (right, l))){
Error_OperatorCannotBeApplied ();
return null;
}
//
// We are going to have to convert to an object to compare
//
if (l != TypeManager.object_type)
left = new EmptyCast (left, TypeManager.object_type);
if (r != TypeManager.object_type)
right = new EmptyCast (right, TypeManager.object_type);
//
// FIXME: CSC here catches errors cs254 and cs252
//
return this;
}
//
// One of them is a valuetype, but the other one is not.
//
if (!l.IsValueType || !r.IsValueType) {
Error_OperatorCannotBeApplied ();
return null;
}
}
// Only perform numeric promotions on:
// +, -, *, /, %, &, |, ^, ==, !=, <, >, <=, >=
//
if (oper == Operator.Addition || oper == Operator.Subtraction) {
if (l.IsSubclassOf (TypeManager.delegate_type) &&
r.IsSubclassOf (TypeManager.delegate_type)) {
Arguments = new ArrayList ();
Arguments.Add (new Argument (left, Argument.AType.Expression));
Arguments.Add (new Argument (right, Argument.AType.Expression));
if (oper == Operator.Addition)
method = TypeManager.delegate_combine_delegate_delegate;
else
method = TypeManager.delegate_remove_delegate_delegate;
if (l != r) {
Error_OperatorCannotBeApplied ();
return null;
}
DelegateOperation = true;
type = l;
return this;
}
//
// Pointer arithmetic:
//
// T* operator + (T* x, int y);
// T* operator + (T* x, uint y);
// T* operator + (T* x, long y);
// T* operator + (T* x, ulong y);
//
// T* operator + (int y, T* x);
// T* operator + (uint y, T *x);
// T* operator + (long y, T *x);
// T* operator + (ulong y, T *x);
//
// T* operator - (T* x, int y);
// T* operator - (T* x, uint y);
// T* operator - (T* x, long y);
// T* operator - (T* x, ulong y);
//
// long operator - (T* x, T *y)
//
if (l.IsPointer){
if (r.IsPointer && oper == Operator.Subtraction){
if (r == l)
return new PointerArithmetic (
false, left, right, TypeManager.int64_type,
loc);
} else if (is_32_or_64 (r))
return new PointerArithmetic (
oper == Operator.Addition, left, right, l, loc);
} else if (r.IsPointer && is_32_or_64 (l) && oper == Operator.Addition)
return new PointerArithmetic (
true, right, left, r, loc);
}
//
// Enumeration operators
//
bool lie = TypeManager.IsEnumType (l);
bool rie = TypeManager.IsEnumType (r);
if (lie || rie){
Expression temp;
// U operator - (E e, E f)
if (lie && rie && oper == Operator.Subtraction){
if (l == r){
type = TypeManager.EnumToUnderlying (l);
return this;
}
Error_OperatorCannotBeApplied ();
return null;
}
//
// operator + (E e, U x)
// operator - (E e, U x)
//
if (oper == Operator.Addition || oper == Operator.Subtraction){
Type enum_type = lie ? l : r;
Type other_type = lie ? r : l;
Type underlying_type = TypeManager.EnumToUnderlying (enum_type);
;
if (underlying_type != other_type){
Error_OperatorCannotBeApplied ();
return null;
}
type = enum_type;
return this;
}
if (!rie){
temp = ConvertImplicit (ec, right, l, loc);
if (temp != null)
right = temp;
else {
Error_OperatorCannotBeApplied ();
return null;
}
} if (!lie){
temp = ConvertImplicit (ec, left, r, loc);
if (temp != null){
left = temp;
l = r;
} else {
Error_OperatorCannotBeApplied ();
return null;
}
}
if (oper == Operator.Equality || oper == Operator.Inequality ||
oper == Operator.LessThanOrEqual || oper == Operator.LessThan ||
oper == Operator.GreaterThanOrEqual || oper == Operator.GreaterThan){
type = TypeManager.bool_type;
return this;
}
if (oper == Operator.BitwiseAnd ||
oper == Operator.BitwiseOr ||
oper == Operator.ExclusiveOr){
type = l;
return this;
}
Error_OperatorCannotBeApplied ();
return null;
}
if (oper == Operator.LeftShift || oper == Operator.RightShift)
return CheckShiftArguments (ec);
if (oper == Operator.LogicalOr || oper == Operator.LogicalAnd){
if (l != TypeManager.bool_type || r != TypeManager.bool_type){
Error_OperatorCannotBeApplied ();
return null;
}
type = TypeManager.bool_type;
return this;
}
//
// operator & (bool x, bool y)
// operator | (bool x, bool y)
// operator ^ (bool x, bool y)
//
if (l == TypeManager.bool_type && r == TypeManager.bool_type){
if (oper == Operator.BitwiseAnd ||
oper == Operator.BitwiseOr ||
oper == Operator.ExclusiveOr){
type = l;
return this;
}
}
//
// Pointer comparison
//
if (l.IsPointer && r.IsPointer){
if (oper == Operator.Equality || oper == Operator.Inequality ||
oper == Operator.LessThan || oper == Operator.LessThanOrEqual ||
oper == Operator.GreaterThan || oper == Operator.GreaterThanOrEqual){
type = TypeManager.bool_type;
return this;
}
}
//
// We are dealing with numbers
//
if (overload_failed){
Error_OperatorCannotBeApplied ();
return null;
}
//
// This will leave left or right set to null if there is an error
//
DoNumericPromotions (ec, l, r);
if (left == null || right == null){
Error_OperatorCannotBeApplied (loc, OperName (oper), l, r);
return null;
}
//
// reload our cached types if required
//
l = left.Type;
r = right.Type;
if (oper == Operator.BitwiseAnd ||
oper == Operator.BitwiseOr ||
oper == Operator.ExclusiveOr){
if (l == r){
if (!((l == TypeManager.int32_type) ||
(l == TypeManager.uint32_type) ||
(l == TypeManager.int64_type) ||
(l == TypeManager.uint64_type)))
type = l;
} else {
Error_OperatorCannotBeApplied ();
return null;
}
}
if (oper == Operator.Equality ||
oper == Operator.Inequality ||
oper == Operator.LessThanOrEqual ||
oper == Operator.LessThan ||
oper == Operator.GreaterThanOrEqual ||
oper == Operator.GreaterThan){
type = TypeManager.bool_type;
}
return this;
}
public override Expression DoResolve (EmitContext ec)
{
left = left.Resolve (ec);
right = right.Resolve (ec);
if (left == null || right == null)
return null;
if (left.Type == null)
throw new Exception (
"Resolve returned non null, but did not set the type! (" +
left + ") at Line: " + loc.Row);
if (right.Type == null)
throw new Exception (
"Resolve returned non null, but did not set the type! (" +
right + ") at Line: "+ loc.Row);
eclass = ExprClass.Value;
if (left is Constant && right is Constant){
Expression e = ConstantFold.BinaryFold (
ec, oper, (Constant) left, (Constant) right, loc);
if (e != null)
return e;
}
return ResolveOperator (ec);
}
///
/// EmitBranchable is called from Statement.EmitBoolExpression in the
/// context of a conditional bool expression. This function will return
/// false if it is was possible to use EmitBranchable, or true if it was.
///
/// The expression's code is generated, and we will generate a branch to 'target'
/// if the resulting expression value is equal to isTrue
///
public bool EmitBranchable (EmitContext ec, Label target, bool onTrue)
{
if (method != null)
return false;
ILGenerator ig = ec.ig;
//
// This is more complicated than it looks, but its just to avoid
// duplicated tests: basically, we allow ==, !=, >, <, >= and <=
// but on top of that we want for == and != to use a special path
// if we are comparing against null
//
if (oper == Operator.Equality || oper == Operator.Inequality){
bool my_on_true = oper == Operator.Inequality ? onTrue : !onTrue;
if (left is NullLiteral){
right.Emit (ec);
if (my_on_true)
ig.Emit (OpCodes.Brtrue, target);
else
ig.Emit (OpCodes.Brfalse, target);
return true;
} else if (right is NullLiteral){
left.Emit (ec);
if (my_on_true)
ig.Emit (OpCodes.Brtrue, target);
else
ig.Emit (OpCodes.Brfalse, target);
return true;
}
} else if (!(oper == Operator.LessThan ||
oper == Operator.GreaterThan ||
oper == Operator.LessThanOrEqual ||
oper == Operator.GreaterThanOrEqual))
return false;
left.Emit (ec);
right.Emit (ec);
bool isUnsigned = is_unsigned (left.Type);
switch (oper){
case Operator.Equality:
if (onTrue)
ig.Emit (OpCodes.Beq, target);
else
ig.Emit (OpCodes.Bne_Un, target);
break;
case Operator.Inequality:
if (onTrue)
ig.Emit (OpCodes.Bne_Un, target);
else
ig.Emit (OpCodes.Beq, target);
break;
case Operator.LessThan:
if (onTrue)
if (isUnsigned)
ig.Emit (OpCodes.Blt_Un, target);
else
ig.Emit (OpCodes.Blt, target);
else
if (isUnsigned)
ig.Emit (OpCodes.Bge_Un, target);
else
ig.Emit (OpCodes.Bge, target);
break;
case Operator.GreaterThan:
if (onTrue)
if (isUnsigned)
ig.Emit (OpCodes.Bgt_Un, target);
else
ig.Emit (OpCodes.Bgt, target);
else
if (isUnsigned)
ig.Emit (OpCodes.Ble_Un, target);
else
ig.Emit (OpCodes.Ble, target);
break;
case Operator.LessThanOrEqual:
if (onTrue)
if (isUnsigned)
ig.Emit (OpCodes.Ble_Un, target);
else
ig.Emit (OpCodes.Ble, target);
else
if (isUnsigned)
ig.Emit (OpCodes.Bgt_Un, target);
else
ig.Emit (OpCodes.Bgt, target);
break;
case Operator.GreaterThanOrEqual:
if (onTrue)
if (isUnsigned)
ig.Emit (OpCodes.Bge_Un, target);
else
ig.Emit (OpCodes.Bge, target);
else
if (isUnsigned)
ig.Emit (OpCodes.Blt_Un, target);
else
ig.Emit (OpCodes.Blt, target);
break;
default:
return false;
}
return true;
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
Type l = left.Type;
Type r = right.Type;
OpCode opcode;
if (method != null) {
// Note that operators are static anyway
if (Arguments != null)
Invocation.EmitArguments (ec, method, Arguments);
if (method is MethodInfo)
ig.Emit (OpCodes.Call, (MethodInfo) method);
else
ig.Emit (OpCodes.Call, (ConstructorInfo) method);
if (DelegateOperation)
ig.Emit (OpCodes.Castclass, type);
return;
}
//
// Handle short-circuit operators differently
// than the rest
//
if (oper == Operator.LogicalAnd){
Label load_zero = ig.DefineLabel ();
Label end = ig.DefineLabel ();
left.Emit (ec);
ig.Emit (OpCodes.Brfalse, load_zero);
right.Emit (ec);
ig.Emit (OpCodes.Br, end);
ig.MarkLabel (load_zero);
ig.Emit (OpCodes.Ldc_I4_0);
ig.MarkLabel (end);
return;
} else if (oper == Operator.LogicalOr){
Label load_one = ig.DefineLabel ();
Label end = ig.DefineLabel ();
left.Emit (ec);
ig.Emit (OpCodes.Brtrue, load_one);
right.Emit (ec);
ig.Emit (OpCodes.Br, end);
ig.MarkLabel (load_one);
ig.Emit (OpCodes.Ldc_I4_1);
ig.MarkLabel (end);
return;
}
left.Emit (ec);
right.Emit (ec);
switch (oper){
case Operator.Multiply:
if (ec.CheckState){
if (l == TypeManager.int32_type || l == TypeManager.int64_type)
opcode = OpCodes.Mul_Ovf;
else if (l==TypeManager.uint32_type || l==TypeManager.uint64_type)
opcode = OpCodes.Mul_Ovf_Un;
else
opcode = OpCodes.Mul;
} else
opcode = OpCodes.Mul;
break;
case Operator.Division:
if (l == TypeManager.uint32_type || l == TypeManager.uint64_type)
opcode = OpCodes.Div_Un;
else
opcode = OpCodes.Div;
break;
case Operator.Modulus:
if (l == TypeManager.uint32_type || l == TypeManager.uint64_type)
opcode = OpCodes.Rem_Un;
else
opcode = OpCodes.Rem;
break;
case Operator.Addition:
if (ec.CheckState){
if (l == TypeManager.int32_type || l == TypeManager.int64_type)
opcode = OpCodes.Add_Ovf;
else if (l==TypeManager.uint32_type || l==TypeManager.uint64_type)
opcode = OpCodes.Add_Ovf_Un;
else
opcode = OpCodes.Add;
} else
opcode = OpCodes.Add;
break;
case Operator.Subtraction:
if (ec.CheckState){
if (l == TypeManager.int32_type || l == TypeManager.int64_type)
opcode = OpCodes.Sub_Ovf;
else if (l==TypeManager.uint32_type || l==TypeManager.uint64_type)
opcode = OpCodes.Sub_Ovf_Un;
else
opcode = OpCodes.Sub;
} else
opcode = OpCodes.Sub;
break;
case Operator.RightShift:
if (l == TypeManager.uint32_type || l == TypeManager.uint64_type)
opcode = OpCodes.Shr_Un;
else
opcode = OpCodes.Shr;
break;
case Operator.LeftShift:
opcode = OpCodes.Shl;
break;
case Operator.Equality:
opcode = OpCodes.Ceq;
break;
case Operator.Inequality:
ec.ig.Emit (OpCodes.Ceq);
ec.ig.Emit (OpCodes.Ldc_I4_0);
opcode = OpCodes.Ceq;
break;
case Operator.LessThan:
opcode = OpCodes.Clt;
break;
case Operator.GreaterThan:
opcode = OpCodes.Cgt;
break;
case Operator.LessThanOrEqual:
ec.ig.Emit (OpCodes.Cgt);
ec.ig.Emit (OpCodes.Ldc_I4_0);
opcode = OpCodes.Ceq;
break;
case Operator.GreaterThanOrEqual:
ec.ig.Emit (OpCodes.Clt);
ec.ig.Emit (OpCodes.Ldc_I4_1);
opcode = OpCodes.Sub;
break;
case Operator.BitwiseOr:
opcode = OpCodes.Or;
break;
case Operator.BitwiseAnd:
opcode = OpCodes.And;
break;
case Operator.ExclusiveOr:
opcode = OpCodes.Xor;
break;
default:
throw new Exception ("This should not happen: Operator = "
+ oper.ToString ());
}
ig.Emit (opcode);
}
public bool IsBuiltinOperator {
get {
return method == null;
}
}
}
public class PointerArithmetic : Expression {
Expression left, right;
bool is_add;
//
// We assume that 'l' is always a pointer
//
public PointerArithmetic (bool is_addition, Expression l, Expression r, Type t,
Location loc)
{
type = t;
eclass = ExprClass.Variable;
this.loc = loc;
left = l;
right = r;
is_add = is_addition;
}
public override Expression DoResolve (EmitContext ec)
{
//
// We are born fully resolved
//
return this;
}
public override void Emit (EmitContext ec)
{
Type op_type = left.Type;
ILGenerator ig = ec.ig;
int size = GetTypeSize (op_type.GetElementType ());
if (right.Type.IsPointer){
//
// handle (pointer - pointer)
//
left.Emit (ec);
right.Emit (ec);
ig.Emit (OpCodes.Sub);
if (size != 1){
if (size == 0)
ig.Emit (OpCodes.Sizeof, op_type);
else
IntLiteral.EmitInt (ig, size);
ig.Emit (OpCodes.Div);
}
ig.Emit (OpCodes.Conv_I8);
} else {
//
// handle + and - on (pointer op int)
//
left.Emit (ec);
ig.Emit (OpCodes.Conv_I);
right.Emit (ec);
if (size != 1){
if (size == 0)
ig.Emit (OpCodes.Sizeof, op_type);
else
IntLiteral.EmitInt (ig, size);
ig.Emit (OpCodes.Mul);
}
if (is_add)
ig.Emit (OpCodes.Add);
else
ig.Emit (OpCodes.Sub);
}
}
}
///
/// Implements the ternary conditional operator (?:)
///
public class Conditional : Expression {
Expression expr, trueExpr, falseExpr;
public Conditional (Expression expr, Expression trueExpr, Expression falseExpr, Location l)
{
this.expr = expr;
this.trueExpr = trueExpr;
this.falseExpr = falseExpr;
this.loc = l;
}
public Expression Expr {
get {
return expr;
}
}
public Expression TrueExpr {
get {
return trueExpr;
}
}
public Expression FalseExpr {
get {
return falseExpr;
}
}
public override Expression DoResolve (EmitContext ec)
{
expr = expr.Resolve (ec);
if (expr == null)
return null;
if (expr.Type != TypeManager.bool_type)
expr = Expression.ConvertImplicitRequired (
ec, expr, TypeManager.bool_type, loc);
trueExpr = trueExpr.Resolve (ec);
falseExpr = falseExpr.Resolve (ec);
if (trueExpr == null || falseExpr == null)
return null;
eclass = ExprClass.Value;
if (trueExpr.Type == falseExpr.Type)
type = trueExpr.Type;
else {
Expression conv;
Type true_type = trueExpr.Type;
Type false_type = falseExpr.Type;
if (trueExpr is NullLiteral){
type = false_type;
return this;
} else if (falseExpr is NullLiteral){
type = true_type;
return this;
}
//
// First, if an implicit conversion exists from trueExpr
// to falseExpr, then the result type is of type falseExpr.Type
//
conv = ConvertImplicit (ec, trueExpr, false_type, loc);
if (conv != null){
//
// Check if both can convert implicitl to each other's type
//
if (ConvertImplicit (ec, falseExpr, true_type, loc) != null){
Error (172,
"Can not compute type of conditional expression " +
"as '" + TypeManager.MonoBASIC_Name (trueExpr.Type) +
"' and '" + TypeManager.MonoBASIC_Name (falseExpr.Type) +
"' convert implicitly to each other");
return null;
}
type = false_type;
trueExpr = conv;
} else if ((conv = ConvertImplicit(ec, falseExpr, true_type,loc))!= null){
type = true_type;
falseExpr = conv;
} else {
Error (173, "The type of the conditional expression can " +
"not be computed because there is no implicit conversion" +
" from '" + TypeManager.MonoBASIC_Name (trueExpr.Type) + "'" +
" and '" + TypeManager.MonoBASIC_Name (falseExpr.Type) + "'");
return null;
}
}
if (expr is BoolConstant){
BoolConstant bc = (BoolConstant) expr;
if (bc.Value)
return trueExpr;
else
return falseExpr;
}
return this;
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
Label false_target = ig.DefineLabel ();
Label end_target = ig.DefineLabel ();
Statement.EmitBoolExpression (ec, expr, false_target, false);
trueExpr.Emit (ec);
ig.Emit (OpCodes.Br, end_target);
ig.MarkLabel (false_target);
falseExpr.Emit (ec);
ig.MarkLabel (end_target);
}
}
///
/// Local variables
///
public class LocalVariableReference : Expression, IAssignMethod, IMemoryLocation, IVariable {
public readonly string Name;
public readonly Block Block;
VariableInfo variable_info;
bool is_readonly;
public LocalVariableReference (Block block, string name, Location l)
{
Block = block;
Name = name;
loc = l;
eclass = ExprClass.Variable;
}
// Setting 'is_readonly' to false will allow you to create a writable
// reference to a read-only variable. This is used by foreach and using.
public LocalVariableReference (Block block, string name, Location l,
VariableInfo variable_info, bool is_readonly)
: this (block, name, l)
{
this.variable_info = variable_info;
this.is_readonly = is_readonly;
}
public VariableInfo VariableInfo {
get {
if (variable_info == null) {
variable_info = Block.GetVariableInfo (Name);
is_readonly = variable_info.ReadOnly;
}
return variable_info;
}
}
public bool IsAssigned (EmitContext ec, Location loc)
{
return VariableInfo.IsAssigned (ec, loc);
}
public bool IsFieldAssigned (EmitContext ec, string name, Location loc)
{
return VariableInfo.IsFieldAssigned (ec, name, loc);
}
public void SetAssigned (EmitContext ec)
{
VariableInfo.SetAssigned (ec);
}
public void SetFieldAssigned (EmitContext ec, string name)
{
VariableInfo.SetFieldAssigned (ec, name);
}
public bool IsReadOnly {
get {
if (variable_info == null) {
variable_info = Block.GetVariableInfo (Name);
is_readonly = variable_info.ReadOnly;
}
return is_readonly;
}
}
public override Expression DoResolve (EmitContext ec)
{
VariableInfo vi = VariableInfo;
if (Block.IsConstant (Name)) {
Expression e = Block.GetConstantExpression (Name);
vi.Used = true;
return e;
}
if (ec.DoFlowAnalysis && !IsAssigned (ec, loc))
return null;
type = vi.VariableType;
return this;
}
override public Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
VariableInfo vi = VariableInfo;
if (ec.DoFlowAnalysis)
ec.SetVariableAssigned (vi);
Expression e = DoResolve (ec);
if (e == null)
return null;
if (is_readonly){
Error (1604, "cannot assign to '" + Name + "' because it is readonly");
return null;
}
return this;
}
public override void Emit (EmitContext ec)
{
VariableInfo vi = VariableInfo;
ILGenerator ig = ec.ig;
ig.Emit (OpCodes.Ldloc, vi.LocalBuilder);
vi.Used = true;
}
public void EmitAssign (EmitContext ec, Expression source)
{
ILGenerator ig = ec.ig;
VariableInfo vi = VariableInfo;
vi.Assigned = true;
source.Emit (ec);
ig.Emit (OpCodes.Stloc, vi.LocalBuilder);
}
public void AddressOf (EmitContext ec, AddressOp mode)
{
VariableInfo vi = VariableInfo;
ec.ig.Emit (OpCodes.Ldloca, vi.LocalBuilder);
}
}
///
/// This represents a reference to a parameter in the intermediate
/// representation.
///
public class ParameterReference : Expression, IAssignMethod, IMemoryLocation, IVariable {
Parameters pars;
String name;
int idx;
public Parameter.Modifier mod;
public bool is_ref, is_out;
public ParameterReference (Parameters pars, int idx, string name, Location loc)
{
this.pars = pars;
this.idx = idx;
this.name = name;
this.loc = loc;
eclass = ExprClass.Variable;
}
public bool IsAssigned (EmitContext ec, Location loc)
{
if (!is_out || !ec.DoFlowAnalysis)
return true;
if (!ec.CurrentBranching.IsParameterAssigned (idx)) {
Report.Error (165, loc,
"Use of unassigned local variable '" + name + "'");
return false;
}
return true;
}
public bool IsFieldAssigned (EmitContext ec, string field_name, Location loc)
{
if (!is_out || !ec.DoFlowAnalysis)
return true;
if (ec.CurrentBranching.IsParameterAssigned (idx))
return true;
if (!ec.CurrentBranching.IsParameterAssigned (idx, field_name)) {
Report.Error (170, loc,
"Use of possibly unassigned field '" + field_name + "'");
return false;
}
return true;
}
public void SetAssigned (EmitContext ec)
{
if (is_out && ec.DoFlowAnalysis)
ec.CurrentBranching.SetParameterAssigned (idx);
}
public void SetFieldAssigned (EmitContext ec, string field_name)
{
if (is_out && ec.DoFlowAnalysis)
ec.CurrentBranching.SetParameterAssigned (idx, field_name);
}
//
// Notice that for ref/out parameters, the type exposed is not the
// same type exposed externally.
//
// for "ref int a":
// externally we expose "int&"
// here we expose "int".
//
// We record this in "is_ref". This means that the type system can treat
// the type as it is expected, but when we generate the code, we generate
// the alternate kind of code.
//
public override Expression DoResolve (EmitContext ec)
{
type = pars.GetParameterInfo (ec.DeclSpace, idx, out mod);
is_ref = (mod & Parameter.Modifier.ISBYREF) != 0;
is_out = (mod & Parameter.Modifier.OUT) != 0;
eclass = ExprClass.Variable;
if (is_out && ec.DoFlowAnalysis && !IsAssigned (ec, loc))
return null;
return this;
}
override public Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
type = pars.GetParameterInfo (ec.DeclSpace, idx, out mod);
is_ref = (mod & Parameter.Modifier.ISBYREF) != 0;
is_out = (mod & Parameter.Modifier.OUT) != 0;
eclass = ExprClass.Variable;
if (is_out && ec.DoFlowAnalysis)
ec.SetParameterAssigned (idx);
return this;
}
static void EmitLdArg (ILGenerator ig, int x)
{
if (x <= 255){
switch (x){
case 0: ig.Emit (OpCodes.Ldarg_0); break;
case 1: ig.Emit (OpCodes.Ldarg_1); break;
case 2: ig.Emit (OpCodes.Ldarg_2); break;
case 3: ig.Emit (OpCodes.Ldarg_3); break;
default: ig.Emit (OpCodes.Ldarg_S, (byte) x); break;
}
} else
ig.Emit (OpCodes.Ldarg, x);
}
//
// This method is used by parameters that are references, that are
// being passed as references: we only want to pass the pointer (that
// is already stored in the parameter, not the address of the pointer,
// and not the value of the variable).
//
public void EmitLoad (EmitContext ec)
{
ILGenerator ig = ec.ig;
int arg_idx = idx;
if (!ec.IsStatic)
arg_idx++;
EmitLdArg (ig, arg_idx);
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
int arg_idx = idx;
if (!ec.IsStatic)
arg_idx++;
EmitLdArg (ig, arg_idx);
if (!is_ref)
return;
//
// If we are a reference, we loaded on the stack a pointer
// Now lets load the real value
//
LoadFromPtr (ig, type);
}
public void EmitAssign (EmitContext ec, Expression source)
{
ILGenerator ig = ec.ig;
int arg_idx = idx;
if (!ec.IsStatic)
arg_idx++;
if (is_ref)
EmitLdArg (ig, arg_idx);
source.Emit (ec);
if (is_ref)
StoreFromPtr (ig, type);
else {
if (arg_idx <= 255)
ig.Emit (OpCodes.Starg_S, (byte) arg_idx);
else
ig.Emit (OpCodes.Starg, arg_idx);
}
}
public void AddressOf (EmitContext ec, AddressOp mode)
{
int arg_idx = idx;
if (!ec.IsStatic)
arg_idx++;
if (is_ref){
if (arg_idx <= 255)
ec.ig.Emit (OpCodes.Ldarg_S, (byte) arg_idx);
else
ec.ig.Emit (OpCodes.Ldarg, arg_idx);
} else {
if (arg_idx <= 255)
ec.ig.Emit (OpCodes.Ldarga_S, (byte) arg_idx);
else
ec.ig.Emit (OpCodes.Ldarga, arg_idx);
}
}
}
///
/// Invocation of methods or delegates.
///
public class Invocation : ExpressionStatement {
public ArrayList Arguments;
public Expression expr;
MethodBase method = null;
bool is_base;
bool is_left_hand; // Needed for late bound calls
static Hashtable method_parameter_cache;
static MemberFilter CompareName;
static Invocation ()
{
method_parameter_cache = new PtrHashtable ();
}
//
// arguments is an ArrayList, but we do not want to typecast,
// as it might be null.
//
// FIXME: only allow expr to be a method invocation or a
// delegate invocation (7.5.5)
//
public Invocation (Expression expr, ArrayList arguments, Location l)
{
this.expr = expr;
Arguments = arguments;
loc = l;
CompareName = new MemberFilter (compare_name_filter);
}
public Expression Expr {
get {
return expr;
}
}
///
/// Returns the Parameters (a ParameterData interface) for the
/// Method 'mb'
///
public static ParameterData GetParameterData (MethodBase mb)
{
object pd = method_parameter_cache [mb];
object ip;
if (pd != null)
return (ParameterData) pd;
ip = TypeManager.LookupParametersByBuilder (mb);
if (ip != null){
method_parameter_cache [mb] = ip;
return (ParameterData) ip;
} else {
ParameterInfo [] pi = mb.GetParameters ();
ReflectionParameters rp = new ReflectionParameters (pi);
method_parameter_cache [mb] = rp;
return (ParameterData) rp;
}
}
///
/// Determines "better conversion" as specified in 7.4.2.3
/// Returns : 1 if a->p is better
/// 0 if a->q or neither is better
///
static int BetterConversion (EmitContext ec, Argument a, Type p, Type q, Location loc)
{
Type argument_type = a.Type;
Expression argument_expr = a.Expr;
if (argument_type == null)
throw new Exception ("Expression of type " + a.Expr + " does not resolve its type");
//
// This is a special case since csc behaves this way. I can't find
// it anywhere in the spec but oh well ...
//
if (argument_expr is NullLiteral && p == TypeManager.string_type && q == TypeManager.object_type)
return 1;
else if (argument_expr is NullLiteral && p == TypeManager.object_type && q == TypeManager.string_type)
return 0;
if (p == q)
return 0;
if (argument_type == p)
return 1;
if (argument_type == q)
return 0;
//
// Now probe whether an implicit constant expression conversion
// can be used.
//
// An implicit constant expression conversion permits the following
// conversions:
//
// * A constant-expression of type 'int' can be converted to type
// sbyte, byute, short, ushort, uint, ulong provided the value of
// of the expression is withing the range of the destination type.
//
// * A constant-expression of type long can be converted to type
// ulong, provided the value of the constant expression is not negative
//
// FIXME: Note that this assumes that constant folding has
// taken place. We dont do constant folding yet.
//
if (argument_expr is IntConstant){
IntConstant ei = (IntConstant) argument_expr;
int value = ei.Value;
if (p == TypeManager.sbyte_type){
if (value >= SByte.MinValue && value <= SByte.MaxValue)
return 1;
} else if (p == TypeManager.byte_type){
if (Byte.MinValue >= 0 && value <= Byte.MaxValue)
return 1;
} else if (p == TypeManager.short_type){
if (value >= Int16.MinValue && value <= Int16.MaxValue)
return 1;
} else if (p == TypeManager.ushort_type){
if (value >= UInt16.MinValue && value <= UInt16.MaxValue)
return 1;
} else if (p == TypeManager.uint32_type){
//
// we can optimize this case: a positive int32
// always fits on a uint32
//
if (value >= 0)
return 1;
} else if (p == TypeManager.uint64_type){
//
// we can optimize this case: a positive int32
// always fits on a uint64
//
if (value >= 0)
return 1;
}
} else if (argument_type == TypeManager.int64_type && argument_expr is LongConstant){
LongConstant lc = (LongConstant) argument_expr;
if (p == TypeManager.uint64_type){
if (lc.Value > 0)
return 1;
}
}
if (q == null) {
Expression tmp = ConvertImplicit (ec, argument_expr, p, loc);
if (tmp != null)
return 1;
else
return 0;
}
Expression p_tmp = new EmptyExpression (p);
Expression q_tmp = new EmptyExpression (q);
if (StandardConversionExists (p_tmp, q) == true &&
StandardConversionExists (q_tmp, p) == false)
return 1;
if (p == TypeManager.sbyte_type)
if (q == TypeManager.byte_type || q == TypeManager.ushort_type ||
q == TypeManager.uint32_type || q == TypeManager.uint64_type)
return 1;
if (p == TypeManager.short_type)
if (q == TypeManager.ushort_type || q == TypeManager.uint32_type ||
q == TypeManager.uint64_type)
return 1;
if (p == TypeManager.int32_type)
if (q == TypeManager.uint32_type || q == TypeManager.uint64_type)
return 1;
if (p == TypeManager.int64_type)
if (q == TypeManager.uint64_type)
return 1;
return 0;
}
///
/// Determines "Better function"
///
///
/// and returns an integer indicating :
/// 0 if candidate ain't better
/// 1 if candidate is better than the current best match
///
static int BetterFunction (EmitContext ec, ArrayList args,
MethodBase candidate, MethodBase best,
bool expanded_form, Location loc)
{
ParameterData candidate_pd = GetParameterData (candidate);
ParameterData best_pd;
int argument_count;
if (args == null)
argument_count = 0;
else
argument_count = args.Count;
int cand_count = candidate_pd.Count;
if (cand_count == 0 && argument_count == 0)
return 1;
if (candidate_pd.ParameterModifier (cand_count - 1) != Parameter.Modifier.PARAMS)
if (cand_count != argument_count)
return 0;
if (best == null) {
int x = 0;
if (argument_count == 0 && cand_count == 1 &&
candidate_pd.ParameterModifier (cand_count - 1) == Parameter.Modifier.PARAMS)
return 1;
for (int j = argument_count; j > 0;) {
j--;
Argument a = (Argument) args [j];
Type t = candidate_pd.ParameterType (j);
if (candidate_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
if (expanded_form)
t = t.GetElementType ();
x = BetterConversion (ec, a, t, null, loc);
if (x <= 0)
break;
}
if (x > 0)
return 1;
else
return 0;
}
best_pd = GetParameterData (best);
int rating1 = 0, rating2 = 0;
for (int j = 0; j < argument_count; ++j) {
int x, y;
Argument a = (Argument) args [j];
Type ct = candidate_pd.ParameterType (j);
Type bt = best_pd.ParameterType (j);
if (candidate_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
if (expanded_form)
ct = ct.GetElementType ();
if (best_pd.ParameterModifier (j) == Parameter.Modifier.PARAMS)
if (expanded_form)
bt = bt.GetElementType ();
x = BetterConversion (ec, a, ct, bt, loc);
y = BetterConversion (ec, a, bt, ct, loc);
if (x < y)
return 0;
rating1 += x;
rating2 += y;
}
if (rating1 > rating2)
return 1;
else
return 0;
}
public static string FullMethodDesc (MethodBase mb)
{
string ret_type = "";
if (mb is MethodInfo)
ret_type = TypeManager.MonoBASIC_Name (((MethodInfo) mb).ReturnType) + " ";
StringBuilder sb = new StringBuilder (ret_type + mb.Name);
ParameterData pd = GetParameterData (mb);
int count = pd.Count;
sb.Append (" (");
for (int i = count; i > 0; ) {
i--;
sb.Append (pd.ParameterDesc (count - i - 1));
if (i != 0)
sb.Append (", ");
}
sb.Append (")");
return sb.ToString ();
}
public static MethodGroupExpr MakeUnionSet (Expression mg1, Expression mg2, Location loc)
{
MemberInfo [] miset;
MethodGroupExpr union;
if (mg1 == null){
if (mg2 == null)
return null;
return (MethodGroupExpr) mg2;
} else {
if (mg2 == null)
return (MethodGroupExpr) mg1;
}
MethodGroupExpr left_set = null, right_set = null;
int length1 = 0, length2 = 0;
left_set = (MethodGroupExpr) mg1;
length1 = left_set.Methods.Length;
right_set = (MethodGroupExpr) mg2;
length2 = right_set.Methods.Length;
ArrayList common = new ArrayList ();
foreach (MethodBase l in left_set.Methods){
foreach (MethodBase r in right_set.Methods){
if (l != r)
continue;
common.Add (r);
break;
}
}
miset = new MemberInfo [length1 + length2 - common.Count];
left_set.Methods.CopyTo (miset, 0);
int k = length1;
foreach (MemberInfo mi in right_set.Methods){
if (!common.Contains (mi))
miset [k++] = mi;
}
union = new MethodGroupExpr (miset, loc);
return union;
}
///
/// Determines is the candidate method, if a params method, is applicable
/// in its expanded form to the given set of arguments
///
static bool IsParamsMethodApplicable (EmitContext ec, ArrayList arguments, MethodBase candidate)
{
int arg_count;
if (arguments == null)
arg_count = 0;
else
arg_count = arguments.Count;
ParameterData pd = GetParameterData (candidate);
int pd_count = pd.Count;
if (pd_count == 0)
return false;
if (pd.ParameterModifier (pd_count - 1) != Parameter.Modifier.PARAMS)
return false;
if (pd_count - 1 > arg_count)
return false;
if (pd_count == 1 && arg_count == 0)
return true;
//
// If we have come this far, the case which remains is when the number of parameters
// is less than or equal to the argument count.
//
for (int i = 0; i < pd_count - 1; ++i) {
Argument a = (Argument) arguments [i];
Parameter.Modifier a_mod = a.GetParameterModifier () &
~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
Parameter.Modifier p_mod = pd.ParameterModifier (i) &
~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
if (a_mod == p_mod) {
if (a_mod == Parameter.Modifier.NONE)
if (!ImplicitConversionExists (ec, a.Expr, pd.ParameterType (i)))
return false;
if ((a_mod & Parameter.Modifier.ISBYREF) != 0) {
Type pt = pd.ParameterType (i);
if (!pt.IsByRef)
pt = TypeManager.LookupType (pt.FullName + "&");
if (pt != a.Type)
return false;
}
} else
return false;
}
Type element_type = pd.ParameterType (pd_count - 1).GetElementType ();
for (int i = pd_count - 1; i < arg_count; i++) {
Argument a = (Argument) arguments [i];
if (!StandardConversionExists (a.Expr, element_type))
return false;
}
return true;
}
static bool CheckParameterAgainstArgument (EmitContext ec, ParameterData pd, int i, Argument a, Type ptype)
{
Parameter.Modifier a_mod = a.GetParameterModifier () &
~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
Parameter.Modifier p_mod = pd.ParameterModifier (i) &
~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
if (a_mod == p_mod || (a_mod == Parameter.Modifier.NONE && p_mod == Parameter.Modifier.PARAMS)) {
if (a_mod == Parameter.Modifier.NONE)
if (! (ImplicitConversionExists (ec, a.Expr, ptype) || RuntimeConversionExists (ec, a.Expr, ptype)) )
return false;
if ((a_mod & Parameter.Modifier.ISBYREF) != 0) {
Type pt = pd.ParameterType (i);
if (!pt.IsByRef)
pt = TypeManager.LookupType (pt.FullName + "&");
if (pt != a.Type)
return false;
}
} else
return false;
return true;
}
///
/// Determines if the candidate method is applicable (section 14.4.2.1)
/// to the given set of arguments
///
static bool IsApplicable (EmitContext ec, ref ArrayList arguments, MethodBase candidate)
{
int arg_count, ps_count, po_count;
Type param_type;
if (arguments == null)
arg_count = 0;
else
arg_count = arguments.Count;
ParameterData pd = GetParameterData (candidate);
Parameters ps = GetFullParameters (candidate);
if (ps == null) {
ps_count = 0;
po_count = 0;
}
else
{
ps_count = ps.CountStandardParams();
po_count = ps.CountOptionalParams();
}
int pd_count = pd.Count;
// Validate argument count
if (po_count == 0) {
if (arg_count != pd.Count)
return false;
}
else
{
if ((arg_count < ps_count) || (arg_count > pd_count))
return false;
}
if (arg_count > 0) {
for (int i = arg_count; i > 0 ; ) {
i--;
Argument a = (Argument) arguments [i];
if (a.ArgType == Argument.AType.NoArg)
{
Parameter p = (Parameter) ps.FixedParameters[i];
a = new Argument (p.ParameterInitializer, Argument.AType.Expression);
param_type = p.ParameterInitializer.Type;
}
else
{
param_type = pd.ParameterType (i);
if (ps != null) {
Parameter p = (Parameter) ps.FixedParameters[i];
if ((p.ModFlags & Parameter.Modifier.REF) != 0)
{
a = new Argument (a.Expr, Argument.AType.Ref);
if (!a.Resolve(ec,Location.Null))
return false;
}
}
}
if (!CheckParameterAgainstArgument (ec, pd, i, a, param_type))
return (false);
}
}
else
{
// If we have no arguments AND the first parameter is optional
// we must check for a candidate (the loop above wouldn't)
if (po_count > 0) {
ArrayList arglist = new ArrayList();
// Since we got so far, there's no need to check if
// arguments are optional; we simply retrieve
// parameter default values and build a brand-new
// argument list.
for (int i = 0; i < ps.FixedParameters.Length; i++) {
Parameter p = ps.FixedParameters[i];
Argument a = new Argument (p.ParameterInitializer, Argument.AType.Expression);
a.Resolve(ec, Location.Null);
arglist.Add (a);
}
arguments = arglist;
return true;
}
}
// We've found a candidate, so we exchange the dummy NoArg arguments
// with new arguments containing the default value for that parameter
ArrayList newarglist = new ArrayList();
for (int i = 0; i < arg_count; i++) {
Argument a = (Argument) arguments [i];
Parameter p = null;
if (ps != null)
p = (Parameter) ps.FixedParameters[i];
if (a.ArgType == Argument.AType.NoArg){
a = new Argument (p.ParameterInitializer, Argument.AType.Expression);
a.Resolve(ec, Location.Null);
}
if ((p != null) && ((p.ModFlags & Parameter.Modifier.REF) != 0))
{
a.ArgType = Argument.AType.Ref;
a.Resolve(ec, Location.Null);
}
newarglist.Add(a);
int n = pd_count - arg_count;
if (n > 0)
{
for (int x = 0; x < n; x++)
{
Parameter op = (Parameter) ps.FixedParameters[x + arg_count];
Argument b = new Argument (op.ParameterInitializer, Argument.AType.Expression);
b.Resolve(ec, Location.Null);
newarglist.Add (b);
}
}
}
arguments = newarglist;
return true;
}
static bool compare_name_filter (MemberInfo m, object filterCriteria)
{
return (m.Name == ((string) filterCriteria));
}
static Parameters GetFullParameters (MethodBase mb)
{
TypeContainer tc = TypeManager.LookupTypeContainer (mb.DeclaringType);
InternalParameters ip = TypeManager.LookupParametersByBuilder(mb);
return (ip != null) ? ip.Parameters : null;
}
// We need an overload for OverloadResolve because Invocation.DoResolve
// must pass Arguments by reference, since a later call to IsApplicable
// can change the argument list if optional parameters are defined
// in the method declaration
public static MethodBase OverloadResolve (EmitContext ec, MethodGroupExpr me,
ArrayList Arguments, Location loc)
{
ArrayList a = Arguments;
return OverloadResolve (ec, me, ref a, loc);
}
///
/// Find the Applicable Function Members (7.4.2.1)
///
/// me: Method Group expression with the members to select.
/// it might contain constructors or methods (or anything
/// that maps to a method).
///
/// Arguments: ArrayList containing resolved Argument objects.
///
/// loc: The location if we want an error to be reported, or a Null
/// location for "probing" purposes.
///
/// Returns: The MethodBase (either a ConstructorInfo or a MethodInfo)
/// that is the best match of me on Arguments.
///
///
public static MethodBase OverloadResolve (EmitContext ec, MethodGroupExpr me,
ref ArrayList Arguments, Location loc)
{
ArrayList afm = new ArrayList ();
MethodBase method = null;
Type current_type = null;
int argument_count;
ArrayList candidates = new ArrayList ();
foreach (MethodBase candidate in me.Methods){
int x;
// If we're going one level higher in the class hierarchy, abort if
// we already found an applicable method.
if (candidate.DeclaringType != current_type) {
current_type = candidate.DeclaringType;
if (method != null)
break;
}
// Check if candidate is applicable (section 14.4.2.1)
if (!IsApplicable (ec, ref Arguments, candidate))
continue;
candidates.Add (candidate);
x = BetterFunction (ec, Arguments, candidate, method, false, loc);
if (x == 0)
continue;
method = candidate;
}
if (Arguments == null)
argument_count = 0;
else
argument_count = Arguments.Count;
//
// Now we see if we can find params functions, applicable in their expanded form
// since if they were applicable in their normal form, they would have been selected
// above anyways
//
bool chose_params_expanded = false;
if (method == null) {
candidates = new ArrayList ();
foreach (MethodBase candidate in me.Methods){
if (!IsParamsMethodApplicable (ec, Arguments, candidate))
continue;
candidates.Add (candidate);
int x = BetterFunction (ec, Arguments, candidate, method, true, loc);
if (x == 0)
continue;
method = candidate;
chose_params_expanded = true;
}
}
if (method == null) {
//
// Okay so we have failed to find anything so we
// return by providing info about the closest match
//
for (int i = 0; i < me.Methods.Length; ++i) {
MethodBase c = (MethodBase) me.Methods [i];
ParameterData pd = GetParameterData (c);
if (pd.Count != argument_count)
continue;
VerifyArgumentsCompat (ec, Arguments, argument_count, c, false,
null, loc);
}
return null;
}
//
// Now check that there are no ambiguities i.e the selected method
// should be better than all the others
//
foreach (MethodBase candidate in candidates){
if (candidate == method)
continue;
//
// If a normal method is applicable in the sense that it has the same
// number of arguments, then the expanded params method is never applicable
// so we debar the params method.
//
if (IsParamsMethodApplicable (ec, Arguments, candidate) &&
IsApplicable (ec, ref Arguments, method))
continue;
int x = BetterFunction (ec, Arguments, method, candidate,
chose_params_expanded, loc);
if (x != 1) {
Report.Error (
121, loc,
"Ambiguous call when selecting function due to implicit casts");
return null;
}
}
//
// And now check if the arguments are all compatible, perform conversions
// if necessary etc. and return if everything is all right
//
if (VerifyArgumentsCompat (ec, Arguments, argument_count, method,
chose_params_expanded, null, loc))
return method;
else
return null;
}
public static bool VerifyArgumentsCompat (EmitContext ec, ArrayList Arguments,
int argument_count,
MethodBase method,
bool chose_params_expanded,
Type delegate_type,
Location loc)
{
return (VerifyArgumentsCompat (ec, Arguments, argument_count,
method, chose_params_expanded, delegate_type, loc, null));
}
public static bool VerifyArgumentsCompat (EmitContext ec,
ArrayList Arguments,
int argument_count,
MethodBase method,
bool chose_params_expanded,
Type delegate_type,
Location loc,
string InvokingProperty)
{
ParameterData pd = GetParameterData (method);
int pd_count = pd.Count;
for (int j = 0; j < argument_count; j++) {
Argument a = (Argument) Arguments [j];
Expression a_expr = a.Expr;
Type parameter_type = pd.ParameterType(j);
if (parameter_type == null)
{
Error_WrongNumArguments(loc, (InvokingProperty == null)?((delegate_type == null)?FullMethodDesc (method):delegate_type.ToString ()):InvokingProperty, argument_count);
return false;
}
if (pd.ParameterModifier (j) == Parameter.Modifier.PARAMS &&
chose_params_expanded)
parameter_type = TypeManager.TypeToCoreType (parameter_type.GetElementType ());
if (a.Type != parameter_type){
Expression conv;
conv = ConvertImplicit (ec, a_expr, parameter_type, loc);
if (conv == null) {
if (!Location.IsNull (loc)) {
if (delegate_type == null)
if (InvokingProperty == null)
Report.Error (1502, loc,
"The best overloaded match for method '" +
FullMethodDesc (method) +
"' has some invalid arguments");
else
Report.Error (1502, loc,
"Property '" +
InvokingProperty +
"' has some invalid arguments");
else
Report.Error (1594, loc,
"Delegate '" + delegate_type.ToString () +
"' has some invalid arguments.");
Report.Error (1503, loc,
"Argument " + (j+1) +
": Cannot convert from '" + Argument.FullDesc (a)
+ "' to '" + pd.ParameterDesc (j) + "'");
}
return false;
}
//
// Update the argument with the implicit conversion
//
if (a_expr != conv)
a.Expr = conv;
}
Parameter.Modifier a_mod = a.GetParameterModifier () &
~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
Parameter.Modifier p_mod = pd.ParameterModifier (j) &
~(Parameter.Modifier.OUT | Parameter.Modifier.REF);
if (a_mod != p_mod &&
pd.ParameterModifier (pd_count - 1) != Parameter.Modifier.PARAMS) {
if (!Location.IsNull (loc)) {
Report.Error (1502, loc,
"The best overloaded match for method '" + FullMethodDesc (method)+
"' has some invalid arguments");
Report.Error (1503, loc,
"Argument " + (j+1) +
": Cannot convert from '" + Argument.FullDesc (a)
+ "' to '" + pd.ParameterDesc (j) + "'");
}
return false;
}
}
return true;
}
public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
this.is_left_hand = true;
return DoResolve (ec);
}
public override Expression DoResolve (EmitContext ec)
{
//
// First, resolve the expression that is used to
// trigger the invocation
//
Expression expr_to_return = null;
if (expr is BaseAccess)
is_base = true;
if ((ec.ReturnType != null) && (expr.ToString() == ec.BlockName)) {
ec.InvokingOwnOverload = true;
expr = expr.Resolve (ec, ResolveFlags.MethodGroup);
ec.InvokingOwnOverload = false;
}
else
{
ec.InvokingOwnOverload = false;
expr = expr.Resolve (ec, ResolveFlags.VariableOrValue | ResolveFlags.MethodGroup);
}
if (expr == null)
return null;
if (expr is Invocation) {
// FIXME Calls which return an Array are not resolved (here or in the grammar)
expr = expr.Resolve(ec);
}
if (!(expr is MethodGroupExpr))
{
Type expr_type = expr.Type;
if (expr_type != null)
{
bool IsDelegate = TypeManager.IsDelegateType (expr_type);
if (IsDelegate)
return (new DelegateInvocation (
this.expr, Arguments, loc)).Resolve (ec);
}
}
//
// Next, evaluate all the expressions in the argument list
//
if (Arguments != null)
{
foreach (Argument a in Arguments)
{
if ((a.ArgType == Argument.AType.NoArg) && (!(expr is MethodGroupExpr)))
Report.Error (999, "This item cannot have empty arguments");
if (!a.Resolve (ec, loc))
return null;
}
}
if (expr is MethodGroupExpr)
{
MethodGroupExpr mg = (MethodGroupExpr) expr;
method = OverloadResolve (ec, mg, ref Arguments, loc);
if (method == null)
{
Error (30455,
"Could not find any applicable function to invoke for this argument list");
return null;
}
if ((method as MethodInfo) != null)
{
MethodInfo mi = method as MethodInfo;
type = TypeManager.TypeToCoreType (mi.ReturnType);
if (!mi.IsStatic && !mg.IsExplicitImpl && (mg.InstanceExpression == null))
SimpleName.Error_ObjectRefRequired (ec, loc, mi.Name);
}
if ((method as ConstructorInfo) != null)
{
ConstructorInfo ci = method as ConstructorInfo;
type = TypeManager.void_type;
if (!ci.IsStatic && !mg.IsExplicitImpl && (mg.InstanceExpression == null))
SimpleName.Error_ObjectRefRequired (ec, loc, ci.Name);
}
if (type.IsPointer)
{
if (!ec.InUnsafe)
{
UnsafeError (loc);
return null;
}
}
eclass = ExprClass.Value;
expr_to_return = this;
}
if (expr is PropertyExpr)
{
PropertyExpr pe = ((PropertyExpr) expr);
pe.PropertyArgs = (ArrayList) Arguments.Clone();
Arguments.Clear();
Arguments = new ArrayList();
MethodBase mi = pe.PropertyInfo.GetGetMethod(true);
if(VerifyArgumentsCompat (ec, pe.PropertyArgs,
pe.PropertyArgs.Count, mi, false, null, loc, pe.Name))
{
expr_to_return = pe.DoResolve (ec);
expr_to_return.eclass = ExprClass.PropertyAccess;
}
else
{
throw new Exception("Error resolving Property Access expression\n" + pe.ToString());
}
}
if (expr is FieldExpr || expr is LocalVariableReference || expr is ParameterReference) {
if (expr.Type.IsArray) {
// If we are here, expr must be an ArrayAccess
ArrayList idxs = new ArrayList();
foreach (Argument a in Arguments)
{
idxs.Add (a.Expr);
}
ElementAccess ea = new ElementAccess (expr, idxs, expr.Location);
ArrayAccess aa = new ArrayAccess (ea, expr.Location);
expr_to_return = aa.DoResolve(ec);
expr_to_return.eclass = ExprClass.Variable;
}
else
{
// We can't resolve now, but we
// have to try to access the array with a call
// to LateIndexGet/Set in the runtime
Expression lig_call_expr;
if (!is_left_hand)
lig_call_expr = Mono.MonoBASIC.Parser.DecomposeQI("Microsoft.VisualBasic.CompilerServices.LateBinding.LateIndexGet", Location.Null);
else
lig_call_expr = Mono.MonoBASIC.Parser.DecomposeQI("Microsoft.VisualBasic.CompilerServices.LateBinding.LateIndexSet", Location.Null);
Expression obj_type = Mono.MonoBASIC.Parser.DecomposeQI("System.Object", Location.Null);
ArrayList adims = new ArrayList();
ArrayList ainit = new ArrayList();
foreach (Argument a in Arguments)
ainit.Add ((Expression) a.Expr);
adims.Add ((Expression) new IntLiteral (Arguments.Count));
Expression oace = new ArrayCreation (obj_type, adims, "", ainit, Location.Null);
ArrayList args = new ArrayList();
args.Add (new Argument(expr, Argument.AType.Expression));
args.Add (new Argument(oace, Argument.AType.Expression));
args.Add (new Argument(NullLiteral.Null, Argument.AType.Expression));
Expression lig_call = new Invocation (lig_call_expr, args, Location.Null);
expr_to_return = lig_call.Resolve(ec);
expr_to_return.eclass = ExprClass.Variable;
}
}
return expr_to_return;
}
static void Error_WrongNumArguments (Location loc, String name, int arg_count)
{
Report.Error (1501, loc, "No overload for method `" + name + "' takes `" +
arg_count + "' arguments");
}
//
// Emits the list of arguments as an array
//
static void EmitParams (EmitContext ec, int idx, ArrayList arguments)
{
ILGenerator ig = ec.ig;
int count = arguments.Count - idx;
Argument a = (Argument) arguments [idx];
Type t = a.Expr.Type;
string array_type = t.FullName + "[]";
LocalBuilder array;
array = ig.DeclareLocal (TypeManager.LookupType (array_type));
IntConstant.EmitInt (ig, count);
ig.Emit (OpCodes.Newarr, TypeManager.TypeToCoreType (t));
ig.Emit (OpCodes.Stloc, array);
int top = arguments.Count;
for (int j = idx; j < top; j++){
a = (Argument) arguments [j];
ig.Emit (OpCodes.Ldloc, array);
IntConstant.EmitInt (ig, j - idx);
a.Emit (ec);
ArrayAccess.EmitStoreOpcode (ig, t);
}
ig.Emit (OpCodes.Ldloc, array);
}
///
/// Emits a list of resolved Arguments that are in the arguments
/// ArrayList.
///
/// The MethodBase argument might be null if the
/// emission of the arguments is known not to contain
/// a 'params' field (for example in constructors or other routines
/// that keep their arguments in this structure)
///
public static void EmitArguments (EmitContext ec, MethodBase mb, ArrayList arguments)
{
ParameterData pd;
if (mb != null)
pd = GetParameterData (mb);
else
pd = null;
//
// If we are calling a params method with no arguments, special case it
//
if (arguments == null){
if (pd != null && pd.Count > 0 &&
pd.ParameterModifier (0) == Parameter.Modifier.PARAMS){
ILGenerator ig = ec.ig;
IntConstant.EmitInt (ig, 0);
ig.Emit (OpCodes.Newarr, pd.ParameterType (0).GetElementType ());
}
return;
}
int top = arguments.Count;
for (int i = 0; i < top; i++){
Argument a = (Argument) arguments [i];
if (pd != null){
if (pd.ParameterModifier (i) == Parameter.Modifier.PARAMS){
//
// Special case if we are passing the same data as the
// params argument, do not put it in an array.
//
if (pd.ParameterType (i) == a.Type)
a.Emit (ec);
else
EmitParams (ec, i, arguments);
return;
}
}
a.Emit (ec);
}
if (pd != null && pd.Count > top &&
pd.ParameterModifier (top) == Parameter.Modifier.PARAMS){
ILGenerator ig = ec.ig;
IntConstant.EmitInt (ig, 0);
ig.Emit (OpCodes.Newarr, pd.ParameterType (top).GetElementType ());
}
}
///
/// is_base tells whether we want to force the use of the 'call'
/// opcode instead of using callvirt. Call is required to call
/// a specific method, while callvirt will always use the most
/// recent method in the vtable.
///
/// is_static tells whether this is an invocation on a static method
///
/// instance_expr is an expression that represents the instance
/// it must be non-null if is_static is false.
///
/// method is the method to invoke.
///
/// Arguments is the list of arguments to pass to the method or constructor.
///
public static void EmitCall (EmitContext ec, bool is_base,
bool is_static, Expression instance_expr,
MethodBase method, ArrayList Arguments, Location loc)
{
EmitCall (ec, is_base, is_static, instance_expr, method, Arguments, null, loc);
}
public static void EmitCall (EmitContext ec, bool is_base,
bool is_static, Expression instance_expr,
MethodBase method, ArrayList Arguments, ArrayList prop_args, Location loc)
{
ILGenerator ig = ec.ig;
bool struct_call = false;
Type decl_type = method.DeclaringType;
if (!RootContext.StdLib)
{
// Replace any calls to the system's System.Array type with calls to
// the newly created one.
if (method == TypeManager.system_int_array_get_length)
method = TypeManager.int_array_get_length;
else if (method == TypeManager.system_int_array_get_rank)
method = TypeManager.int_array_get_rank;
else if (method == TypeManager.system_object_array_clone)
method = TypeManager.object_array_clone;
else if (method == TypeManager.system_int_array_get_length_int)
method = TypeManager.int_array_get_length_int;
else if (method == TypeManager.system_int_array_get_lower_bound_int)
method = TypeManager.int_array_get_lower_bound_int;
else if (method == TypeManager.system_int_array_get_upper_bound_int)
method = TypeManager.int_array_get_upper_bound_int;
else if (method == TypeManager.system_void_array_copyto_array_int)
method = TypeManager.void_array_copyto_array_int;
}
//
// This checks the 'ConditionalAttribute' on the method, and the
// ObsoleteAttribute
//
TypeManager.MethodFlags flags = TypeManager.GetMethodFlags (method, loc);
if ((flags & TypeManager.MethodFlags.IsObsoleteError) != 0)
return;
if ((flags & TypeManager.MethodFlags.ShouldIgnore) != 0)
return;
if (!is_static)
{
if (decl_type.IsValueType)
struct_call = true;
//
// If this is ourselves, push "this"
//
if (instance_expr == null)
{
ig.Emit (OpCodes.Ldarg_0);
}
else
{
//
// Push the instance expression
//
if (instance_expr.Type.IsValueType)
{
//
// Special case: calls to a function declared in a
// reference-type with a value-type argument need
// to have their value boxed.
struct_call = true;
if (decl_type.IsValueType)
{
//
// If the expression implements IMemoryLocation, then
// we can optimize and use AddressOf on the
// return.
//
// If not we have to use some temporary storage for
// it.
if (instance_expr is IMemoryLocation)
{
((IMemoryLocation)instance_expr).
AddressOf (ec, AddressOp.LoadStore);
}
else
{
Type t = instance_expr.Type;
instance_expr.Emit (ec);
LocalBuilder temp = ig.DeclareLocal (t);
ig.Emit (OpCodes.Stloc, temp);
ig.Emit (OpCodes.Ldloca, temp);
}
}
else
{
instance_expr.Emit (ec);
ig.Emit (OpCodes.Box, instance_expr.Type);
}
}
else
instance_expr.Emit (ec);
}
}
if (prop_args != null && prop_args.Count > 0)
{
if (Arguments == null)
Arguments = new ArrayList();
for (int i = prop_args.Count-1; i >=0 ; i--)
{
Arguments.Insert (0,prop_args[i]);
}
}
EmitArguments (ec, method, Arguments);
if (is_static || struct_call || is_base)
{
if (method is MethodInfo)
{
ig.Emit (OpCodes.Call, (MethodInfo) method);
}
else
ig.Emit (OpCodes.Call, (ConstructorInfo) method);
}
else
{
if (method is MethodInfo)
ig.Emit (OpCodes.Callvirt, (MethodInfo) method);
else
ig.Emit (OpCodes.Callvirt, (ConstructorInfo) method);
}
}
static void EmitPropertyArgs (EmitContext ec, ArrayList prop_args)
{
int top = prop_args.Count;
for (int i = 0; i < top; i++)
{
Argument a = (Argument) prop_args [i];
a.Emit (ec);
}
}
public override void Emit (EmitContext ec)
{
MethodGroupExpr mg = (MethodGroupExpr) this.expr;
EmitCall (
ec, is_base, method.IsStatic, mg.InstanceExpression, method, Arguments, loc);
}
public override void EmitStatement (EmitContext ec)
{
Emit (ec);
//
// Pop the return value if there is one
//
if (method is MethodInfo){
Type ret = ((MethodInfo)method).ReturnType;
if (TypeManager.TypeToCoreType (ret) != TypeManager.void_type)
ec.ig.Emit (OpCodes.Pop);
}
}
}
//
// This class is used to "disable" the code generation for the
// temporary variable when initializing value types.
//
class EmptyAddressOf : EmptyExpression, IMemoryLocation {
public void AddressOf (EmitContext ec, AddressOp Mode)
{
// nothing
}
}
///
/// Implements the new expression
///
public class New : ExpressionStatement {
public readonly ArrayList Arguments;
public readonly Expression RequestedType;
MethodBase method = null;
//
// If set, the new expression is for a value_target, and
// we will not leave anything on the stack.
//
Expression value_target;
bool value_target_set = false;
public New (Expression requested_type, ArrayList arguments, Location l)
{
RequestedType = requested_type;
Arguments = arguments;
loc = l;
}
public Expression ValueTypeVariable {
get {
return value_target;
}
set {
value_target = value;
value_target_set = true;
}
}
//
// This function is used to disable the following code sequence for
// value type initialization:
//
// AddressOf (temporary)
// Construct/Init
// LoadTemporary
//
// Instead the provide will have provided us with the address on the
// stack to store the results.
//
static Expression MyEmptyExpression;
public void DisableTemporaryValueType ()
{
if (MyEmptyExpression == null)
MyEmptyExpression = new EmptyAddressOf ();
//
// To enable this, look into:
// test-34 and test-89 and self bootstrapping.
//
// For instance, we can avoid a copy by using 'newobj'
// instead of Call + Push-temp on value types.
// value_target = MyEmptyExpression;
}
public override Expression DoResolve (EmitContext ec)
{
type = ec.DeclSpace.ResolveType (RequestedType, false, loc);
if (type == null)
return null;
bool IsDelegate = TypeManager.IsDelegateType (type);
if (IsDelegate)
return (new NewDelegate (type, Arguments, loc)).Resolve (ec);
if (type.IsInterface || type.IsAbstract){
Error (
30376, "It is not possible to create instances of Interfaces " +
"or classes marked as MustInherit");
return null;
}
bool is_struct = false;
is_struct = type.IsValueType;
eclass = ExprClass.Value;
//
// SRE returns a match for .ctor () on structs (the object constructor),
// so we have to manually ignore it.
//
if (is_struct && Arguments == null)
return this;
Expression ml;
ml = MemberLookupFinal (ec, type, ".ctor",
MemberTypes.Constructor,
AllBindingFlags | BindingFlags.Public, loc);
if (ml == null)
return null;
if (! (ml is MethodGroupExpr)){
if (!is_struct){
ml.Error118 ("method group");
return null;
}
}
if (ml != null) {
if (Arguments != null){
foreach (Argument a in Arguments){
if (!a.Resolve (ec, loc))
return null;
}
}
method = Invocation.OverloadResolve (ec, (MethodGroupExpr) ml,
Arguments, loc);
}
if (method == null) {
if (!is_struct || Arguments.Count > 0) {
Error (1501,
"New invocation: Can not find a constructor for " +
"this argument list");
return null;
}
}
return this;
}
//
// This DoEmit can be invoked in two contexts:
// * As a mechanism that will leave a value on the stack (new object)
// * As one that wont (init struct)
//
// You can control whether a value is required on the stack by passing
// need_value_on_stack. The code *might* leave a value on the stack
// so it must be popped manually
//
// If we are dealing with a ValueType, we have a few
// situations to deal with:
//
// * The target is a ValueType, and we have been provided
// the instance (this is easy, we are being assigned).
//
// * The target of New is being passed as an argument,
// to a boxing operation or a function that takes a
// ValueType.
//
// In this case, we need to create a temporary variable
// that is the argument of New.
//
// Returns whether a value is left on the stack
//
bool DoEmit (EmitContext ec, bool need_value_on_stack)
{
bool is_value_type = type.IsValueType;
ILGenerator ig = ec.ig;
if (is_value_type){
IMemoryLocation ml;
// Allow DoEmit() to be called multiple times.
// We need to create a new LocalTemporary each time since
// you can't share LocalBuilders among ILGeneators.
if (!value_target_set)
value_target = new LocalTemporary (ec, type);
ml = (IMemoryLocation) value_target;
ml.AddressOf (ec, AddressOp.Store);
}
if (method != null)
Invocation.EmitArguments (ec, method, Arguments);
if (is_value_type){
if (method == null)
ig.Emit (OpCodes.Initobj, type);
else
ig.Emit (OpCodes.Call, (ConstructorInfo) method);
if (need_value_on_stack){
value_target.Emit (ec);
return true;
}
return false;
} else {
ig.Emit (OpCodes.Newobj, (ConstructorInfo) method);
return true;
}
}
public override void Emit (EmitContext ec)
{
DoEmit (ec, true);
}
public override void EmitStatement (EmitContext ec)
{
if (DoEmit (ec, false))
ec.ig.Emit (OpCodes.Pop);
}
}
///
/// 14.5.10.2: Represents an array creation expression.
///
///
///
/// There are two possible scenarios here: one is an array creation
/// expression that specifies the dimensions and optionally the
/// initialization data and the other which does not need dimensions
/// specified but where initialization data is mandatory.
///
public class ArrayCreation : ExpressionStatement {
Expression requested_base_type;
ArrayList initializers;
//
// The list of Argument types.
// This is used to construct the 'newarray' or constructor signature
//
ArrayList arguments;
//
// Method used to create the array object.
//
MethodBase new_method = null;
Type array_element_type;
Type underlying_type;
bool is_one_dimensional = false;
bool is_builtin_type = false;
bool expect_initializers = false;
int num_arguments = 0;
int dimensions = 0;
string rank;
ArrayList array_data;
Hashtable bounds;
//
// The number of array initializers that we can handle
// via the InitializeArray method - through EmitStaticInitializers
//
int num_automatic_initializers;
public ArrayCreation (Expression requested_base_type, ArrayList exprs, string rank, ArrayList initializers, Location l)
{
this.requested_base_type = requested_base_type;
this.initializers = initializers;
this.rank = rank;
loc = l;
arguments = new ArrayList ();
foreach (Expression e in exprs) {
arguments.Add (new Argument (e, Argument.AType.Expression));
num_arguments++;
}
}
public ArrayCreation (Expression requested_base_type, string rank, ArrayList initializers, Location l)
{
this.requested_base_type = requested_base_type;
this.initializers = initializers;
this.rank = rank;
loc = l;
//this.rank = rank.Substring (0, rank.LastIndexOf ("["));
//
//string tmp = rank.Substring (rank.LastIndexOf ("["));
//
//dimensions = tmp.Length - 1;
expect_initializers = true;
}
public Expression FormArrayType (Expression base_type, int idx_count, string rank)
{
StringBuilder sb = new StringBuilder (rank);
sb.Append ("[");
for (int i = 1; i < idx_count; i++)
sb.Append (",");
sb.Append ("]");
return new ComposedCast (base_type, sb.ToString (), loc);
}
void Error_IncorrectArrayInitializer ()
{
Error (30567, "Incorrectly structured array initializer");
}
public bool CheckIndices (EmitContext ec, ArrayList probe, int idx, bool specified_dims)
{
if (specified_dims) {
Argument a = (Argument) arguments [idx];
if (!a.Resolve (ec, loc))
return false;
if (!(a.Expr is Constant)) {
Error (150, "A constant value is expected");
return false;
}
int value = (int) ((Constant) a.Expr).GetValue ();
if (value != probe.Count) {
Error_IncorrectArrayInitializer ();
return false;
}
bounds [idx] = value;
}
int child_bounds = -1;
foreach (object o in probe) {
if (o is ArrayList) {
int current_bounds = ((ArrayList) o).Count;
if (child_bounds == -1)
child_bounds = current_bounds;
else if (child_bounds != current_bounds){
Error_IncorrectArrayInitializer ();
return false;
}
bool ret = CheckIndices (ec, (ArrayList) o, idx + 1, specified_dims);
if (!ret)
return false;
} else {
if (child_bounds != -1){
Error_IncorrectArrayInitializer ();
return false;
}
Expression tmp = (Expression) o;
tmp = tmp.Resolve (ec);
if (tmp == null)
continue;
// Console.WriteLine ("I got: " + tmp);
// Handle initialization from vars, fields etc.
Expression conv = ConvertImplicitRequired (
ec, tmp, underlying_type, loc);
if (conv == null)
return false;
if (conv is StringConstant)
array_data.Add (conv);
else if (conv is Constant) {
array_data.Add (conv);
num_automatic_initializers++;
} else
array_data.Add (conv);
}
}
return true;
}
public void UpdateIndices (EmitContext ec)
{
int i = 0;
for (ArrayList probe = initializers; probe != null;) {
if (probe.Count > 0 && probe [0] is ArrayList) {
Expression e = new IntConstant (probe.Count);
arguments.Add (new Argument (e, Argument.AType.Expression));
bounds [i++] = probe.Count;
probe = (ArrayList) probe [0];
} else {
Expression e = new IntConstant (probe.Count);
arguments.Add (new Argument (e, Argument.AType.Expression));
bounds [i++] = probe.Count;
probe = null;
}
}
}
public bool ValidateInitializers (EmitContext ec, Type array_type)
{
if (initializers == null) {
if (expect_initializers)
return false;
else
return true;
}
if (underlying_type == null)
return false;
//
// We use this to store all the date values in the order in which we
// will need to store them in the byte blob later
//
array_data = new ArrayList ();
bounds = new Hashtable ();
bool ret;
if (arguments != null) {
ret = CheckIndices (ec, initializers, 0, true);
return ret;
} else {
arguments = new ArrayList ();
ret = CheckIndices (ec, initializers, 0, false);
if (!ret)
return false;
UpdateIndices (ec);
if (arguments.Count != dimensions) {
Error_IncorrectArrayInitializer ();
return false;
}
return ret;
}
}
void Error_NegativeArrayIndex ()
{
Error (284, "Can not create array with a negative size");
}
//
// Converts 'source' to an int, uint, long or ulong.
//
Expression ExpressionToArrayArgument (EmitContext ec, Expression source)
{
Expression target;
bool old_checked = ec.CheckState;
ec.CheckState = true;
target = ConvertImplicit (ec, source, TypeManager.int32_type, loc);
if (target == null){
target = ConvertImplicit (ec, source, TypeManager.uint32_type, loc);
if (target == null){
target = ConvertImplicit (ec, source, TypeManager.int64_type, loc);
if (target == null){
target = ConvertImplicit (ec, source, TypeManager.uint64_type, loc);
if (target == null)
Expression.Error_CannotConvertImplicit (loc, source.Type, TypeManager.int32_type);
}
}
}
ec.CheckState = old_checked;
//
// Only positive constants are allowed at compile time
//
if (target is Constant){
if (target is IntConstant){
if (((IntConstant) target).Value < 0){
Error_NegativeArrayIndex ();
return null;
}
}
if (target is LongConstant){
if (((LongConstant) target).Value < 0){
Error_NegativeArrayIndex ();
return null;
}
}
}
return target;
}
//
// Creates the type of the array
//
bool LookupType (EmitContext ec)
{
StringBuilder array_qualifier = new StringBuilder (rank);
//
// 'In the first form allocates an array instace of the type that results
// from deleting each of the individual expression from the expression list'
//
if (num_arguments > 0) {
array_qualifier.Append ("[");
for (int i = num_arguments-1; i > 0; i--)
array_qualifier.Append (",");
array_qualifier.Append ("]");
}
//
// Lookup the type
//
Expression array_type_expr;
array_type_expr = new ComposedCast (requested_base_type, array_qualifier.ToString (), loc);
string sss = array_qualifier.ToString ();
type = ec.DeclSpace.ResolveType (array_type_expr, false, loc);
if (type == null)
return false;
underlying_type = type;
if (underlying_type.IsArray)
underlying_type = TypeManager.TypeToCoreType (underlying_type.GetElementType ());
dimensions = type.GetArrayRank ();
return true;
}
public override Expression DoResolve (EmitContext ec)
{
int arg_count;
if (!LookupType (ec))
return null;
//
// First step is to validate the initializers and fill
// in any missing bits
//
if (!ValidateInitializers (ec, type))
return null;
if (arguments == null)
arg_count = 0;
else {
arg_count = arguments.Count;
foreach (Argument a in arguments){
if (!a.Resolve (ec, loc))
return null;
Expression real_arg = ExpressionToArrayArgument (ec, a.Expr, loc);
if (real_arg == null)
return null;
a.Expr = real_arg;
}
}
array_element_type = TypeManager.TypeToCoreType (type.GetElementType ());
if (arg_count == 1) {
is_one_dimensional = true;
eclass = ExprClass.Value;
return this;
}
is_builtin_type = TypeManager.IsBuiltinType (type);
if (is_builtin_type) {
Expression ml;
ml = MemberLookup (ec, type, ".ctor", MemberTypes.Constructor,
AllBindingFlags, loc);
if (!(ml is MethodGroupExpr)) {
ml.Error118 ("method group");
return null;
}
if (ml == null) {
Error (-6, "New invocation: Can not find a constructor for " +
"this argument list");
return null;
}
new_method = Invocation.OverloadResolve (ec, (MethodGroupExpr) ml, arguments, loc);
if (new_method == null) {
Error (-6, "New invocation: Can not find a constructor for " +
"this argument list");
return null;
}
eclass = ExprClass.Value;
return this;
} else {
ModuleBuilder mb = CodeGen.ModuleBuilder;
ArrayList args = new ArrayList ();
if (arguments != null) {
for (int i = 0; i < arg_count; i++)
args.Add (TypeManager.int32_type);
}
Type [] arg_types = null;
if (args.Count > 0)
arg_types = new Type [args.Count];
args.CopyTo (arg_types, 0);
new_method = mb.GetArrayMethod (type, ".ctor", CallingConventions.HasThis, null,
arg_types);
if (new_method == null) {
Error (-6, "New invocation: Can not find a constructor for " +
"this argument list");
return null;
}
eclass = ExprClass.Value;
return this;
}
}
public static byte [] MakeByteBlob (ArrayList array_data, Type underlying_type, Location loc)
{
int factor;
byte [] data;
byte [] element;
int count = array_data.Count;
if (underlying_type.IsEnum)
underlying_type = TypeManager.EnumToUnderlying (underlying_type);
factor = GetTypeSize (underlying_type);
if (factor == 0)
throw new Exception ("unrecognized type in MakeByteBlob: " + underlying_type);
data = new byte [(count * factor + 4) & ~3];
int idx = 0;
for (int i = 0; i < count; ++i) {
object v = array_data [i];
if (v is EnumConstant)
v = ((EnumConstant) v).Child;
if (v is Constant && !(v is StringConstant))
v = ((Constant) v).GetValue ();
else {
idx += factor;
continue;
}
if (underlying_type == TypeManager.int64_type){
if (!(v is Expression)){
long val = (long) v;
for (int j = 0; j < factor; ++j) {
data [idx + j] = (byte) (val & 0xFF);
val = (val >> 8);
}
}
} else if (underlying_type == TypeManager.uint64_type){
if (!(v is Expression)){
ulong val = (ulong) v;
for (int j = 0; j < factor; ++j) {
data [idx + j] = (byte) (val & 0xFF);
val = (val >> 8);
}
}
} else if (underlying_type == TypeManager.float_type) {
if (!(v is Expression)){
element = BitConverter.GetBytes ((float) v);
for (int j = 0; j < factor; ++j)
data [idx + j] = element [j];
}
} else if (underlying_type == TypeManager.double_type) {
if (!(v is Expression)){
element = BitConverter.GetBytes ((double) v);
for (int j = 0; j < factor; ++j)
data [idx + j] = element [j];
}
} else if (underlying_type == TypeManager.char_type){
if (!(v is Expression)){
int val = (int) ((char) v);
data [idx] = (byte) (val & 0xff);
data [idx+1] = (byte) (val >> 8);
}
} else if (underlying_type == TypeManager.short_type){
if (!(v is Expression)){
int val = (int) ((short) v);
data [idx] = (byte) (val & 0xff);
data [idx+1] = (byte) (val >> 8);
}
} else if (underlying_type == TypeManager.ushort_type){
if (!(v is Expression)){
int val = (int) ((ushort) v);
data [idx] = (byte) (val & 0xff);
data [idx+1] = (byte) (val >> 8);
}
} else if (underlying_type == TypeManager.int32_type) {
if (!(v is Expression)){
int val = (int) v;
data [idx] = (byte) (val & 0xff);
data [idx+1] = (byte) ((val >> 8) & 0xff);
data [idx+2] = (byte) ((val >> 16) & 0xff);
data [idx+3] = (byte) (val >> 24);
}
} else if (underlying_type == TypeManager.uint32_type) {
if (!(v is Expression)){
uint val = (uint) v;
data [idx] = (byte) (val & 0xff);
data [idx+1] = (byte) ((val >> 8) & 0xff);
data [idx+2] = (byte) ((val >> 16) & 0xff);
data [idx+3] = (byte) (val >> 24);
}
} else if (underlying_type == TypeManager.sbyte_type) {
if (!(v is Expression)){
sbyte val = (sbyte) v;
data [idx] = (byte) val;
}
} else if (underlying_type == TypeManager.byte_type) {
if (!(v is Expression)){
byte val = (byte) v;
data [idx] = (byte) val;
}
} else if (underlying_type == TypeManager.bool_type) {
if (!(v is Expression)){
bool val = (bool) v;
data [idx] = (byte) (val ? 1 : 0);
}
} else if (underlying_type == TypeManager.decimal_type){
if (!(v is Expression)){
int [] bits = Decimal.GetBits ((decimal) v);
int p = idx;
for (int j = 0; j < 4; j++){
data [p++] = (byte) (bits [j] & 0xff);
data [p++] = (byte) ((bits [j] >> 8) & 0xff);
data [p++] = (byte) ((bits [j] >> 16) & 0xff);
data [p++] = (byte) (bits [j] >> 24);
}
}
} else
throw new Exception ("Unrecognized type in MakeByteBlob: " + underlying_type);
idx += factor;
}
return data;
}
//
// Emits the initializers for the array
//
void EmitStaticInitializers (EmitContext ec, bool is_expression)
{
//
// First, the static data
//
FieldBuilder fb;
ILGenerator ig = ec.ig;
byte [] data = MakeByteBlob (array_data, underlying_type, loc);
fb = RootContext.MakeStaticData (data);
if (is_expression)
ig.Emit (OpCodes.Dup);
ig.Emit (OpCodes.Ldtoken, fb);
ig.Emit (OpCodes.Call,
TypeManager.void_initializearray_array_fieldhandle);
}
//
// Emits pieces of the array that can not be computed at compile
// time (variables and string locations).
//
// This always expect the top value on the stack to be the array
//
void EmitDynamicInitializers (EmitContext ec, bool is_expression)
{
ILGenerator ig = ec.ig;
int dims = bounds.Count;
int [] current_pos = new int [dims];
int top = array_data.Count;
LocalBuilder temp = ig.DeclareLocal (type);
ig.Emit (OpCodes.Stloc, temp);
MethodInfo set = null;
if (dims != 1){
Type [] args;
ModuleBuilder mb = null;
mb = CodeGen.ModuleBuilder;
args = new Type [dims + 1];
int j;
for (j = 0; j < dims; j++)
args [j] = TypeManager.int32_type;
args [j] = array_element_type;
set = mb.GetArrayMethod (
type, "Set",
CallingConventions.HasThis | CallingConventions.Standard,
TypeManager.void_type, args);
}
for (int i = 0; i < top; i++){
Expression e = null;
if (array_data [i] is Expression)
e = (Expression) array_data [i];
if (e != null) {
//
// Basically we do this for string literals and
// other non-literal expressions
//
if (e is StringConstant || !(e is Constant) ||
num_automatic_initializers <= 2) {
Type etype = e.Type;
ig.Emit (OpCodes.Ldloc, temp);
for (int idx = 0; idx < dims; idx++)
IntConstant.EmitInt (ig, current_pos [idx]);
//
// If we are dealing with a struct, get the
// address of it, so we can store it.
//
if ((dims == 1) &&
etype.IsSubclassOf (TypeManager.value_type) &&
(!TypeManager.IsBuiltinType (etype) ||
etype == TypeManager.decimal_type)) {
if (e is New){
New n = (New) e;
//
// Let new know that we are providing
// the address where to store the results
//
n.DisableTemporaryValueType ();
}
ig.Emit (OpCodes.Ldelema, etype);
}
e.Emit (ec);
if (dims == 1)
ArrayAccess.EmitStoreOpcode (ig, array_element_type);
else
ig.Emit (OpCodes.Call, set);
}
}
//
// Advance counter
//
for (int j = dims - 1; j >= 0; j--){
current_pos [j]++;
if (current_pos [j] < (int) bounds [j])
break;
current_pos [j] = 0;
}
}
if (is_expression)
ig.Emit (OpCodes.Ldloc, temp);
}
void EmitArrayArguments (EmitContext ec)
{
ILGenerator ig = ec.ig;
foreach (Argument a in arguments) {
Type atype = a.Type;
a.Emit (ec);
if (atype == TypeManager.uint64_type)
ig.Emit (OpCodes.Conv_Ovf_U4);
else if (atype == TypeManager.int64_type)
ig.Emit (OpCodes.Conv_Ovf_I4);
}
}
void DoEmit (EmitContext ec, bool is_statement)
{
ILGenerator ig = ec.ig;
EmitArrayArguments (ec);
if (is_one_dimensional)
ig.Emit (OpCodes.Newarr, array_element_type);
else {
if (is_builtin_type)
ig.Emit (OpCodes.Newobj, (ConstructorInfo) new_method);
else
ig.Emit (OpCodes.Newobj, (MethodInfo) new_method);
}
if (initializers != null){
//
// FIXME: Set this variable correctly.
//
bool dynamic_initializers = true;
if (underlying_type != TypeManager.string_type &&
underlying_type != TypeManager.object_type) {
if (num_automatic_initializers > 2)
EmitStaticInitializers (ec, dynamic_initializers || !is_statement);
}
if (dynamic_initializers)
EmitDynamicInitializers (ec, !is_statement);
}
}
public override void Emit (EmitContext ec)
{
DoEmit (ec, false);
}
public override void EmitStatement (EmitContext ec)
{
DoEmit (ec, true);
}
}
///
/// Represents the 'this' construct
///
public class This : Expression, IAssignMethod, IMemoryLocation, IVariable {
Block block;
VariableInfo vi;
public This (Block block, Location loc)
{
this.loc = loc;
this.block = block;
}
public This (Location loc)
{
this.loc = loc;
}
public bool IsAssigned (EmitContext ec, Location loc)
{
if (vi == null)
return true;
return vi.IsAssigned (ec, loc);
}
public bool IsFieldAssigned (EmitContext ec, string field_name, Location loc)
{
if (vi == null)
return true;
return vi.IsFieldAssigned (ec, field_name, loc);
}
public void SetAssigned (EmitContext ec)
{
if (vi != null)
vi.SetAssigned (ec);
}
public void SetFieldAssigned (EmitContext ec, string field_name)
{
if (vi != null)
vi.SetFieldAssigned (ec, field_name);
}
public override Expression DoResolve (EmitContext ec)
{
eclass = ExprClass.Variable;
type = ec.ContainerType;
if (ec.IsStatic){
Error (26, "Keyword this not valid in static code");
return null;
}
if (block != null)
vi = block.ThisVariable;
return this;
}
override public Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
DoResolve (ec);
VariableInfo vi = ec.CurrentBlock.ThisVariable;
if (vi != null)
vi.SetAssigned (ec);
if (ec.TypeContainer is Class){
Error (1604, "Cannot assign to 'this'");
return null;
}
return this;
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
ig.Emit (OpCodes.Ldarg_0);
if (ec.TypeContainer is Struct)
ig.Emit (OpCodes.Ldobj, type);
}
public void EmitAssign (EmitContext ec, Expression source)
{
ILGenerator ig = ec.ig;
if (ec.TypeContainer is Struct){
ig.Emit (OpCodes.Ldarg_0);
source.Emit (ec);
ig.Emit (OpCodes.Stobj, type);
} else {
source.Emit (ec);
ig.Emit (OpCodes.Starg, 0);
}
}
public void AddressOf (EmitContext ec, AddressOp mode)
{
ec.ig.Emit (OpCodes.Ldarg_0);
// FIMXE
// FIGURE OUT WHY LDARG_S does not work
//
// consider: struct X { int val; int P { set { val = value; }}}
//
// Yes, this looks very bad. Look at 'NOTAS' for
// an explanation.
// ec.ig.Emit (OpCodes.Ldarga_S, (byte) 0);
}
}
///
/// Implements the typeof operator
///
public class TypeOf : Expression {
public readonly Expression QueriedType;
Type typearg;
public TypeOf (Expression queried_type, Location l)
{
QueriedType = queried_type;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
typearg = ec.DeclSpace.ResolveType (QueriedType, false, loc);
if (typearg == null)
return null;
type = TypeManager.type_type;
eclass = ExprClass.Type;
return this;
}
public override void Emit (EmitContext ec)
{
ec.ig.Emit (OpCodes.Ldtoken, typearg);
ec.ig.Emit (OpCodes.Call, TypeManager.system_type_get_type_from_handle);
}
public Type TypeArg {
get { return typearg; }
}
}
///
/// Implements the sizeof expression
///
public class SizeOf : Expression {
public readonly Expression QueriedType;
Type type_queried;
public SizeOf (Expression queried_type, Location l)
{
this.QueriedType = queried_type;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
if (!ec.InUnsafe) {
Error (233, "Sizeof may only be used in an unsafe context " +
"(consider using System.Runtime.InteropServices.Marshal.Sizeof");
return null;
}
type_queried = ec.DeclSpace.ResolveType (QueriedType, false, loc);
if (type_queried == null)
return null;
if (!TypeManager.IsUnmanagedType (type_queried)){
Report.Error (208, "Cannot take the size of an unmanaged type (" + TypeManager.MonoBASIC_Name (type_queried) + ")");
return null;
}
type = TypeManager.int32_type;
eclass = ExprClass.Value;
return this;
}
public override void Emit (EmitContext ec)
{
int size = GetTypeSize (type_queried);
if (size == 0)
ec.ig.Emit (OpCodes.Sizeof, type_queried);
else
IntConstant.EmitInt (ec.ig, size);
}
}
///
/// Implements the member access expression
///
public class MemberAccess : Expression, ITypeExpression {
public readonly string Identifier;
Expression expr;
Expression member_lookup;
public MemberAccess (Expression expr, string id, Location l)
{
this.expr = expr;
Identifier = id;
loc = l;
}
public Expression Expr {
get {
return expr;
}
}
static void error176 (Location loc, string name)
{
Report.Error (176, loc, "Static member '" +
name + "' cannot be accessed " +
"with an instance reference, qualify with a " +
"type name instead");
}
static bool IdenticalNameAndTypeName (EmitContext ec, Expression left_original, Location loc)
{
if (left_original == null)
return false;
if (!(left_original is SimpleName))
return false;
SimpleName sn = (SimpleName) left_original;
Type t = RootContext.LookupType (ec.DeclSpace, sn.Name, true, loc);
if (t != null)
return true;
return false;
}
public static Expression ResolveMemberAccess (EmitContext ec, Expression member_lookup,
Expression left, Location loc,
Expression left_original)
{
bool left_is_type, left_is_explicit;
// If 'left' is null, then we're called from SimpleNameResolve and this is
// a member in the currently defining class.
if (left == null) {
left_is_type = ec.IsStatic || ec.IsFieldInitializer;
left_is_explicit = false;
// Implicitly default to 'this' unless we're static.
if (!ec.IsStatic && !ec.IsFieldInitializer && !ec.InEnumContext)
left = ec.This;
} else {
left_is_type = left is TypeExpr;
left_is_explicit = true;
}
if (member_lookup is FieldExpr){
FieldExpr fe = (FieldExpr) member_lookup;
FieldInfo fi = fe.FieldInfo;
Type decl_type = fi.DeclaringType;
if (fi is FieldBuilder) {
Const c = TypeManager.LookupConstant ((FieldBuilder) fi);
if (c != null) {
object o = c.LookupConstantValue (ec);
object real_value = ((Constant) c.Expr).GetValue ();
return Constantify (real_value, fi.FieldType);
}
}
if (fi.IsLiteral) {
Type t = fi.FieldType;
object o;
if (fi is FieldBuilder)
o = TypeManager.GetValue ((FieldBuilder) fi);
else
o = fi.GetValue (fi);
if (decl_type.IsSubclassOf (TypeManager.enum_type)) {
if (left_is_explicit && !left_is_type &&
!IdenticalNameAndTypeName (ec, left_original, loc)) {
error176 (loc, fe.FieldInfo.Name);
return null;
}
Expression enum_member = MemberLookup (
ec, decl_type, "value__", MemberTypes.Field,
AllBindingFlags, loc);
Enum en = TypeManager.LookupEnum (decl_type);
Constant c;
if (en != null) {
c = Constantify (o, en.UnderlyingType);
return new EnumConstant (c, en.UnderlyingType);
}
else {
c = Constantify (o, enum_member.Type);
return new EnumConstant (c, enum_member.Type);
}
}
Expression exp = Constantify (o, t);
if (left_is_explicit && !left_is_type) {
error176 (loc, fe.FieldInfo.Name);
return null;
}
return exp;
}
if (fi.FieldType.IsPointer && !ec.InUnsafe){
UnsafeError (loc);
return null;
}
}
if (member_lookup is EventExpr) {
EventExpr ee = (EventExpr) member_lookup;
//
// If the event is local to this class, we transform ourselves into
// a FieldExpr
//
if (ee.EventInfo.DeclaringType == ec.ContainerType) {
MemberInfo mi = GetFieldFromEvent (ee);
if (mi == null) {
//
// If this happens, then we have an event with its own
// accessors and private field etc so there's no need
// to transform ourselves : we should instead flag an error
//
Assign.error70 (ee.EventInfo, loc);
return null;
}
Expression ml = ExprClassFromMemberInfo (ec, mi, loc);
if (ml == null) {
Report.Error (-200, loc, "Internal error!!");
return null;
}
return ResolveMemberAccess (ec, ml, left, loc, left_original);
}
}
if (member_lookup is IMemberExpr) {
IMemberExpr me = (IMemberExpr) member_lookup;
if (left_is_type){
MethodGroupExpr mg = me as MethodGroupExpr;
if ((mg != null) && left_is_explicit && left.Type.IsInterface)
mg.IsExplicitImpl = left_is_explicit;
if (!me.IsStatic){
if (IdenticalNameAndTypeName (ec, left_original, loc))
return member_lookup;
SimpleName.Error_ObjectRefRequired (ec, loc, me.Name);
return null;
}
} else {
if (!me.IsInstance){
if (IdenticalNameAndTypeName (ec, left_original, loc))
return member_lookup;
/*if (left_is_explicit) {
error176 (loc, me.Name);
return null;
}*/
}
//
// Since we can not check for instance objects in SimpleName,
// becaue of the rule that allows types and variables to share
// the name (as long as they can be de-ambiguated later, see
// IdenticalNameAndTypeName), we have to check whether left
// is an instance variable in a static context
//
// However, if the left-hand value is explicitly given, then
// it is already our instance expression, so we aren't in
// static context.
//
if (ec.IsStatic && !left_is_explicit && left is IMemberExpr){
IMemberExpr mexp = (IMemberExpr) left;
if (!mexp.IsStatic){
SimpleName.Error_ObjectRefRequired (ec, loc, mexp.Name);
return null;
}
}
me.InstanceExpression = left;
}
return member_lookup;
}
if (member_lookup is TypeExpr){
member_lookup.Resolve (ec, ResolveFlags.Type);
return member_lookup;
}
Console.WriteLine ("Left is: " + left);
Report.Error (-100, loc, "Support for [" + member_lookup + "] is not present yet");
Environment.Exit (0);
return null;
}
public Expression DoResolve (EmitContext ec, Expression right_side, ResolveFlags flags)
{
if (type != null)
throw new Exception ();
//
// Resolve the expression with flow analysis turned off, we'll do the definite
// assignment checks later. This is because we don't know yet what the expression
// will resolve to - it may resolve to a FieldExpr and in this case we must do the
// definite assignment check on the actual field and not on the whole struct.
//
Expression original = expr;
expr = expr.Resolve (ec, flags | ResolveFlags.DisableFlowAnalysis);
if (expr == null)
return null;
if (expr is SimpleName){
SimpleName child_expr = (SimpleName) expr;
Expression new_expr = new SimpleName (child_expr.Name + "." + Identifier, loc);
return new_expr.Resolve (ec, flags);
}
int errors = Report.Errors;
Type expr_type = expr.Type;
if (expr_type.IsPointer){
Error (23, "The '.' operator can not be applied to pointer operands (" +
TypeManager.MonoBASIC_Name (expr_type) + ")");
return null;
}
member_lookup = MemberLookup (ec, expr_type, Identifier, loc);
if (member_lookup == null)
{
// Error has already been reported.
if (errors < Report.Errors)
return null;
//
// Try looking the member up from the same type, if we find
// it, we know that the error was due to limited visibility
//
object lookup = TypeManager.MemberLookup (
expr_type, expr_type, AllMemberTypes, AllBindingFlags |
BindingFlags.NonPublic, Identifier);
if (lookup == null)
Error (30456, "'" + expr_type + "' does not contain a definition for '" + Identifier + "'");
else
{
if ((expr_type != ec.ContainerType) &&
ec.ContainerType.IsSubclassOf (expr_type))
{
// Although a derived class can access protected members of
// its base class it cannot do so through an instance of the
// base class (CS1540). If the expr_type is a parent of the
// ec.ContainerType and the lookup succeeds with the latter one,
// then we are in this situation.
lookup = TypeManager.MemberLookup(
ec.ContainerType, ec.ContainerType, AllMemberTypes,
AllBindingFlags, Identifier);
if (lookup != null)
Error (1540, "Cannot access protected member '" +
expr_type + "." + Identifier + "' " +
"via a qualifier of type '" + TypeManager.MonoBASIC_Name (expr_type) + "'; the " +
"qualifier must be of type '" + TypeManager.MonoBASIC_Name (ec.ContainerType) + "' " +
"(or derived from it)");
else
Error (30390, "'" + expr_type + "." + Identifier + "' " +
"is inaccessible because of its protection level");
} else
Error (30390, "'" + expr_type + "." + Identifier + "' " +
"is inaccessible because of its protection level");
}
return null;
}
if ((expr is TypeExpr) && (expr_type.IsSubclassOf (TypeManager.enum_type))) {
Enum en = TypeManager.LookupEnum (expr_type);
if (en != null) {
object value = en.LookupEnumValue (ec, Identifier, loc);
expr_type = TypeManager.int32_type;
if (value != null) {
Constant c = Constantify (value, en.UnderlyingType);
return new EnumConstant (c, en.UnderlyingType);
}
}
}
if (member_lookup is TypeExpr){
member_lookup.Resolve (ec, ResolveFlags.Type);
return member_lookup;
} else if ((flags & ResolveFlags.MaskExprClass) == ResolveFlags.Type)
return null;
member_lookup = ResolveMemberAccess (ec, member_lookup, expr, loc, original);
if (member_lookup == null)
return null;
// The following DoResolve/DoResolveLValue will do the definite assignment
// check.
if (right_side != null)
member_lookup = member_lookup.DoResolveLValue (ec, right_side);
else
member_lookup = member_lookup.DoResolve (ec);
return member_lookup;
}
public override Expression DoResolve (EmitContext ec)
{
return DoResolve (ec, null, ResolveFlags.VariableOrValue |
ResolveFlags.SimpleName | ResolveFlags.Type);
}
public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
return DoResolve (ec, right_side, ResolveFlags.VariableOrValue |
ResolveFlags.SimpleName | ResolveFlags.Type);
}
public Expression DoResolveType (EmitContext ec)
{
return DoResolve (ec, null, ResolveFlags.Type);
}
public override void Emit (EmitContext ec)
{
throw new Exception ("Should not happen");
}
public override string ToString ()
{
return expr + "." + Identifier;
}
}
///
/// Implements checked expressions
///
public class CheckedExpr : Expression {
public Expression Expr;
public CheckedExpr (Expression e, Location l)
{
Expr = e;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
bool last_const_check = ec.ConstantCheckState;
ec.ConstantCheckState = true;
Expr = Expr.Resolve (ec);
ec.ConstantCheckState = last_const_check;
if (Expr == null)
return null;
if (Expr is Constant)
return Expr;
eclass = Expr.eclass;
type = Expr.Type;
return this;
}
public override void Emit (EmitContext ec)
{
bool last_check = ec.CheckState;
bool last_const_check = ec.ConstantCheckState;
ec.CheckState = true;
ec.ConstantCheckState = true;
Expr.Emit (ec);
ec.CheckState = last_check;
ec.ConstantCheckState = last_const_check;
}
}
///
/// Implements the unchecked expression
///
public class UnCheckedExpr : Expression {
public Expression Expr;
public UnCheckedExpr (Expression e, Location l)
{
Expr = e;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
bool last_const_check = ec.ConstantCheckState;
ec.ConstantCheckState = false;
Expr = Expr.Resolve (ec);
ec.ConstantCheckState = last_const_check;
if (Expr == null)
return null;
if (Expr is Constant)
return Expr;
eclass = Expr.eclass;
type = Expr.Type;
return this;
}
public override void Emit (EmitContext ec)
{
bool last_check = ec.CheckState;
bool last_const_check = ec.ConstantCheckState;
ec.CheckState = false;
ec.ConstantCheckState = false;
Expr.Emit (ec);
ec.CheckState = last_check;
ec.ConstantCheckState = last_const_check;
}
}
///
/// An Element Access expression.
///
/// During semantic analysis these are transformed into
/// IndexerAccess or ArrayAccess
///
public class ElementAccess : Expression {
public ArrayList Arguments;
public Expression Expr;
public ElementAccess (Expression e, ArrayList e_list, Location l)
{
Expr = e;
loc = l;
if (e_list == null)
return;
Arguments = new ArrayList ();
foreach (Expression tmp in e_list)
Arguments.Add (new Argument (tmp, Argument.AType.Expression));
}
bool CommonResolve (EmitContext ec)
{
Expr = Expr.Resolve (ec);
if (Expr == null)
return false;
if (Arguments == null)
return false;
foreach (Argument a in Arguments){
if (!a.Resolve (ec, loc))
return false;
}
return true;
}
Expression MakePointerAccess ()
{
Type t = Expr.Type;
if (t == TypeManager.void_ptr_type){
Error (
242,
"The array index operation is not valid for void pointers");
return null;
}
if (Arguments.Count != 1){
Error (
196,
"A pointer must be indexed by a single value");
return null;
}
Expression p = new PointerArithmetic (true, Expr, ((Argument)Arguments [0]).Expr,
t, loc);
return new Indirection (p, loc);
}
public override Expression DoResolve (EmitContext ec)
{
if (!CommonResolve (ec))
return null;
//
// We perform some simple tests, and then to "split" the emit and store
// code we create an instance of a different class, and return that.
//
// I am experimenting with this pattern.
//
Type t = Expr.Type;
if (t.IsArray)
return (new ArrayAccess (this, loc)).Resolve (ec);
else if (t.IsPointer)
return MakePointerAccess ();
else
return (new IndexerAccess (this, loc)).Resolve (ec);
}
public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
if (!CommonResolve (ec))
return null;
Type t = Expr.Type;
if (t.IsArray)
return (new ArrayAccess (this, loc)).ResolveLValue (ec, right_side);
else if (t.IsPointer)
return MakePointerAccess ();
else
return (new IndexerAccess (this, loc)).ResolveLValue (ec, right_side);
}
public override void Emit (EmitContext ec)
{
throw new Exception ("Should never be reached");
}
}
///
/// Implements array access
///
public class ArrayAccess : Expression, IAssignMethod, IMemoryLocation {
//
// Points to our "data" repository
//
ElementAccess ea;
LocalTemporary [] cached_locations;
public ArrayAccess (ElementAccess ea_data, Location l)
{
ea = ea_data;
eclass = ExprClass.Variable;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
ExprClass eclass = ea.Expr.eclass;
#if false
// As long as the type is valid
if (!(eclass == ExprClass.Variable || eclass == ExprClass.PropertyAccess ||
eclass == ExprClass.Value)) {
ea.Expr.Error118 ("variable or value");
return null;
}
#endif
Type t = ea.Expr.Type;
/*
if (t == typeof (System.Object))
{
// We can't resolve now, but we
// have to try to access the array with a call
// to LateIndexGet in the runtime
Expression lig_call_expr = Mono.MonoBASIC.Parser.DecomposeQI("Microsoft.VisualBasic.CompilerServices.LateBinding.LateIndexGet", Location.Null);
Expression obj_type = Mono.MonoBASIC.Parser.DecomposeQI("System.Object", Location.Null);
ArrayList adims = new ArrayList();
ArrayList ainit = new ArrayList();
foreach (Argument a in ea.Arguments)
ainit.Add ((Expression) a.Expr);
adims.Add ((Expression) new IntLiteral (ea.Arguments.Count));
Expression oace = new ArrayCreation (obj_type, adims, "", ainit, Location.Null);
ArrayList args = new ArrayList();
args.Add (new Argument(ea.Expr, Argument.AType.Expression));
args.Add (new Argument(oace, Argument.AType.Expression));
args.Add (new Argument(NullLiteral.Null, Argument.AType.Expression));
Expression lig_call = new Invocation (lig_call_expr, args, Location.Null);
lig_call = lig_call.Resolve(ec);
return lig_call;
}
*/
if (t.GetArrayRank () != ea.Arguments.Count){
ea.Error (22,
"Incorrect number of indexes for array " +
" expected: " + t.GetArrayRank () + " got: " +
ea.Arguments.Count);
return null;
}
type = TypeManager.TypeToCoreType (t.GetElementType ());
if (type.IsPointer && !ec.InUnsafe){
UnsafeError (ea.Location);
return null;
}
foreach (Argument a in ea.Arguments){
Type argtype = a.Type;
if (argtype == TypeManager.int32_type ||
argtype == TypeManager.uint32_type ||
argtype == TypeManager.int64_type ||
argtype == TypeManager.uint64_type)
continue;
//
// Mhm. This is strage, because the Argument.Type is not the same as
// Argument.Expr.Type: the value changes depending on the ref/out setting.
//
// Wonder if I will run into trouble for this.
//
a.Expr = ExpressionToArrayArgument (ec, a.Expr, ea.Location);
if (a.Expr == null)
return null;
}
eclass = ExprClass.Variable;
return this;
}
///
/// Emits the right opcode to load an object of Type 't'
/// from an array of T
///
static public void EmitLoadOpcode (ILGenerator ig, Type type)
{
if (type == TypeManager.byte_type || type == TypeManager.bool_type)
ig.Emit (OpCodes.Ldelem_U1);
else if (type == TypeManager.sbyte_type)
ig.Emit (OpCodes.Ldelem_I1);
else if (type == TypeManager.short_type)
ig.Emit (OpCodes.Ldelem_I2);
else if (type == TypeManager.ushort_type || type == TypeManager.char_type)
ig.Emit (OpCodes.Ldelem_U2);
else if (type == TypeManager.int32_type)
ig.Emit (OpCodes.Ldelem_I4);
else if (type == TypeManager.uint32_type)
ig.Emit (OpCodes.Ldelem_U4);
else if (type == TypeManager.uint64_type)
ig.Emit (OpCodes.Ldelem_I8);
else if (type == TypeManager.int64_type)
ig.Emit (OpCodes.Ldelem_I8);
else if (type == TypeManager.float_type)
ig.Emit (OpCodes.Ldelem_R4);
else if (type == TypeManager.double_type)
ig.Emit (OpCodes.Ldelem_R8);
else if (type == TypeManager.intptr_type)
ig.Emit (OpCodes.Ldelem_I);
else if (type.IsValueType){
ig.Emit (OpCodes.Ldelema, type);
ig.Emit (OpCodes.Ldobj, type);
} else
ig.Emit (OpCodes.Ldelem_Ref);
}
///
/// Emits the right opcode to store an object of Type 't'
/// from an array of T.
///
static public void EmitStoreOpcode (ILGenerator ig, Type t)
{
t = TypeManager.TypeToCoreType (t);
if (TypeManager.IsEnumType (t) && t != TypeManager.enum_type)
t = TypeManager.EnumToUnderlying (t);
if (t == TypeManager.byte_type || t == TypeManager.sbyte_type ||
t == TypeManager.bool_type)
ig.Emit (OpCodes.Stelem_I1);
else if (t == TypeManager.short_type || t == TypeManager.ushort_type || t == TypeManager.char_type)
ig.Emit (OpCodes.Stelem_I2);
else if (t == TypeManager.int32_type || t == TypeManager.uint32_type)
ig.Emit (OpCodes.Stelem_I4);
else if (t == TypeManager.int64_type || t == TypeManager.uint64_type)
ig.Emit (OpCodes.Stelem_I8);
else if (t == TypeManager.float_type)
ig.Emit (OpCodes.Stelem_R4);
else if (t == TypeManager.double_type)
ig.Emit (OpCodes.Stelem_R8);
else if (t == TypeManager.intptr_type)
ig.Emit (OpCodes.Stelem_I);
else if (t.IsValueType){
ig.Emit (OpCodes.Stobj, t);
} else
ig.Emit (OpCodes.Stelem_Ref);
}
MethodInfo FetchGetMethod ()
{
ModuleBuilder mb = CodeGen.ModuleBuilder;
int arg_count = ea.Arguments.Count;
Type [] args = new Type [arg_count];
MethodInfo get;
for (int i = 0; i < arg_count; i++){
//args [i++] = a.Type;
args [i] = TypeManager.int32_type;
}
get = mb.GetArrayMethod (
ea.Expr.Type, "Get",
CallingConventions.HasThis |
CallingConventions.Standard,
type, args);
return get;
}
MethodInfo FetchAddressMethod ()
{
ModuleBuilder mb = CodeGen.ModuleBuilder;
int arg_count = ea.Arguments.Count;
Type [] args = new Type [arg_count];
MethodInfo address;
string ptr_type_name;
Type ret_type;
ptr_type_name = type.FullName + "&";
ret_type = Type.GetType (ptr_type_name);
//
// It is a type defined by the source code we are compiling
//
if (ret_type == null){
ret_type = mb.GetType (ptr_type_name);
}
for (int i = 0; i < arg_count; i++){
//args [i++] = a.Type;
args [i] = TypeManager.int32_type;
}
address = mb.GetArrayMethod (
ea.Expr.Type, "Address",
CallingConventions.HasThis |
CallingConventions.Standard,
ret_type, args);
return address;
}
//
// Load the array arguments into the stack.
//
// If we have been requested to cache the values (cached_locations array
// initialized), then load the arguments the first time and store them
// in locals. otherwise load from local variables.
//
void LoadArrayAndArguments (EmitContext ec)
{
ILGenerator ig = ec.ig;
if (cached_locations == null){
ea.Expr.Emit (ec);
foreach (Argument a in ea.Arguments){
Type argtype = a.Expr.Type;
a.Expr.Emit (ec);
if (argtype == TypeManager.int64_type)
ig.Emit (OpCodes.Conv_Ovf_I);
else if (argtype == TypeManager.uint64_type)
ig.Emit (OpCodes.Conv_Ovf_I_Un);
}
return;
}
if (cached_locations [0] == null){
cached_locations [0] = new LocalTemporary (ec, ea.Expr.Type);
ea.Expr.Emit (ec);
ig.Emit (OpCodes.Dup);
cached_locations [0].Store (ec);
int j = 1;
foreach (Argument a in ea.Arguments){
Type argtype = a.Expr.Type;
cached_locations [j] = new LocalTemporary (ec, TypeManager.intptr_type /* a.Expr.Type */);
a.Expr.Emit (ec);
if (argtype == TypeManager.int64_type)
ig.Emit (OpCodes.Conv_Ovf_I);
else if (argtype == TypeManager.uint64_type)
ig.Emit (OpCodes.Conv_Ovf_I_Un);
ig.Emit (OpCodes.Dup);
cached_locations [j].Store (ec);
j++;
}
return;
}
foreach (LocalTemporary lt in cached_locations)
lt.Emit (ec);
}
public new void CacheTemporaries (EmitContext ec)
{
cached_locations = new LocalTemporary [ea.Arguments.Count + 1];
}
public override void Emit (EmitContext ec)
{
int rank = ea.Expr.Type.GetArrayRank ();
ILGenerator ig = ec.ig;
LoadArrayAndArguments (ec);
if (rank == 1)
EmitLoadOpcode (ig, type);
else {
MethodInfo method;
method = FetchGetMethod ();
ig.Emit (OpCodes.Call, method);
}
}
public void EmitAssign (EmitContext ec, Expression source)
{
int rank = ea.Expr.Type.GetArrayRank ();
ILGenerator ig = ec.ig;
Type t = source.Type;
LoadArrayAndArguments (ec);
//
// The stobj opcode used by value types will need
// an address on the stack, not really an array/array
// pair
//
if (rank == 1){
if (t == TypeManager.enum_type || t == TypeManager.decimal_type ||
(t.IsSubclassOf (TypeManager.value_type) && !TypeManager.IsEnumType (t) && !TypeManager.IsBuiltinType (t)))
ig.Emit (OpCodes.Ldelema, t);
}
source.Emit (ec);
if (rank == 1)
EmitStoreOpcode (ig, t);
else {
ModuleBuilder mb = CodeGen.ModuleBuilder;
int arg_count = ea.Arguments.Count;
Type [] args = new Type [arg_count + 1];
MethodInfo set;
for (int i = 0; i < arg_count; i++){
//args [i++] = a.Type;
args [i] = TypeManager.int32_type;
}
args [arg_count] = type;
set = mb.GetArrayMethod (
ea.Expr.Type, "Set",
CallingConventions.HasThis |
CallingConventions.Standard,
TypeManager.void_type, args);
ig.Emit (OpCodes.Call, set);
}
}
public void AddressOf (EmitContext ec, AddressOp mode)
{
int rank = ea.Expr.Type.GetArrayRank ();
ILGenerator ig = ec.ig;
LoadArrayAndArguments (ec);
if (rank == 1){
ig.Emit (OpCodes.Ldelema, type);
} else {
MethodInfo address = FetchAddressMethod ();
ig.Emit (OpCodes.Call, address);
}
}
}
class Indexers {
public ArrayList getters, setters;
static Hashtable map;
static Indexers ()
{
map = new Hashtable ();
}
Indexers (MemberInfo [] mi)
{
foreach (PropertyInfo property in mi){
MethodInfo get, set;
get = property.GetGetMethod (true);
if (get != null){
if (getters == null)
getters = new ArrayList ();
getters.Add (get);
}
set = property.GetSetMethod (true);
if (set != null){
if (setters == null)
setters = new ArrayList ();
setters.Add (set);
}
}
}
static private Indexers GetIndexersForTypeOrInterface (Type caller_type, Type lookup_type)
{
Indexers ix = (Indexers) map [lookup_type];
if (ix != null)
return ix;
string p_name = TypeManager.IndexerPropertyName (lookup_type);
MemberInfo [] mi = TypeManager.MemberLookup (
caller_type, lookup_type, MemberTypes.Property,
BindingFlags.Public | BindingFlags.Instance, p_name);
if (mi == null || mi.Length == 0)
return null;
ix = new Indexers (mi);
map [lookup_type] = ix;
return ix;
}
static public Indexers GetIndexersForType (Type caller_type, Type lookup_type, Location loc)
{
Indexers ix = (Indexers) map [lookup_type];
if (ix != null)
return ix;
ix = GetIndexersForTypeOrInterface (caller_type, lookup_type);
if (ix != null)
return ix;
Type [] ifaces = TypeManager.GetInterfaces (lookup_type);
if (ifaces != null) {
foreach (Type itype in ifaces) {
ix = GetIndexersForTypeOrInterface (caller_type, itype);
if (ix != null)
return ix;
}
}
Report.Error (21, loc,
"Type '" + TypeManager.MonoBASIC_Name (lookup_type) +
"' does not have any indexers defined");
return null;
}
}
///
/// Expressions that represent an indexer call.
///
public class IndexerAccess : Expression, IAssignMethod {
//
// Points to our "data" repository
//
MethodInfo get, set;
Indexers ilist;
ArrayList set_arguments;
bool is_base_indexer;
protected Type indexer_type;
protected Type current_type;
protected Expression instance_expr;
protected ArrayList arguments;
public IndexerAccess (ElementAccess ea, Location loc)
: this (ea.Expr, false, loc)
{
this.arguments = ea.Arguments;
}
protected IndexerAccess (Expression instance_expr, bool is_base_indexer,
Location loc)
{
this.instance_expr = instance_expr;
this.is_base_indexer = is_base_indexer;
this.eclass = ExprClass.Value;
this.loc = loc;
}
protected virtual bool CommonResolve (EmitContext ec)
{
indexer_type = instance_expr.Type;
current_type = ec.ContainerType;
return true;
}
public override Expression DoResolve (EmitContext ec)
{
if (!CommonResolve (ec))
return null;
//
// Step 1: Query for all 'Item' *properties*. Notice
// that the actual methods are pointed from here.
//
// This is a group of properties, piles of them.
if (ilist == null)
ilist = Indexers.GetIndexersForType (
current_type, indexer_type, loc);
//
// Step 2: find the proper match
//
if (ilist != null && ilist.getters != null && ilist.getters.Count > 0)
get = (MethodInfo) Invocation.OverloadResolve (
ec, new MethodGroupExpr (ilist.getters, loc), arguments, loc);
if (get == null){
Error (154, "indexer can not be used in this context, because " +
"it lacks a 'get' accessor");
return null;
}
type = get.ReturnType;
if (type.IsPointer && !ec.InUnsafe){
UnsafeError (loc);
return null;
}
eclass = ExprClass.IndexerAccess;
return this;
}
public override Expression DoResolveLValue (EmitContext ec, Expression right_side)
{
if (!CommonResolve (ec))
return null;
Type right_type = right_side.Type;
if (ilist == null)
ilist = Indexers.GetIndexersForType (
current_type, indexer_type, loc);
if (ilist != null && ilist.setters != null && ilist.setters.Count > 0){
set_arguments = (ArrayList) arguments.Clone ();
set_arguments.Add (new Argument (right_side, Argument.AType.Expression));
set = (MethodInfo) Invocation.OverloadResolve (
ec, new MethodGroupExpr (ilist.setters, loc), set_arguments, loc);
}
if (set == null){
Error (200, "indexer X.this [" + TypeManager.MonoBASIC_Name (right_type) +
"] lacks a 'set' accessor");
return null;
}
type = TypeManager.void_type;
eclass = ExprClass.IndexerAccess;
return this;
}
public override void Emit (EmitContext ec)
{
Invocation.EmitCall (ec, false, false, instance_expr, get, arguments, loc);
}
//
// source is ignored, because we already have a copy of it from the
// LValue resolution and we have already constructed a pre-cached
// version of the arguments (ea.set_arguments);
//
public void EmitAssign (EmitContext ec, Expression source)
{
Invocation.EmitCall (ec, false, false, instance_expr, set, set_arguments, loc);
}
}
///
/// The base operator for method names
///
public class BaseAccess : Expression {
public string member;
public BaseAccess (string member, Location l)
{
this.member = member;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
Expression member_lookup;
Type current_type = ec.ContainerType;
Type base_type = current_type.BaseType;
Expression e;
if (ec.IsStatic){
Error (1511, "Keyword MyBase is not allowed in static method");
return null;
}
if (member == "New")
member = ".ctor";
member_lookup = MemberLookup (ec, base_type, base_type, member,
AllMemberTypes, AllBindingFlags, loc);
if (member_lookup == null) {
Error (30456,
TypeManager.MonoBASIC_Name (base_type) + " does not " +
"contain a definition for '" + member + "'");
return null;
}
Expression left;
if (ec.IsStatic)
left = new TypeExpr (base_type, loc);
else
left = ec.This;
e = MemberAccess.ResolveMemberAccess (ec, member_lookup, left, loc, null);
if (e is PropertyExpr){
PropertyExpr pe = (PropertyExpr) e;
pe.IsBase = true;
}
return e;
}
public override void Emit (EmitContext ec)
{
throw new Exception ("Should never be called");
}
}
///
/// The base indexer operator
///
public class BaseIndexerAccess : IndexerAccess {
public BaseIndexerAccess (ArrayList args, Location loc)
: base (null, true, loc)
{
arguments = new ArrayList ();
foreach (Expression tmp in args)
arguments.Add (new Argument (tmp, Argument.AType.Expression));
}
protected override bool CommonResolve (EmitContext ec)
{
instance_expr = ec.This;
current_type = ec.ContainerType.BaseType;
indexer_type = current_type;
foreach (Argument a in arguments){
if (!a.Resolve (ec, loc))
return false;
}
return true;
}
}
///
/// This class exists solely to pass the Type around and to be a dummy
/// that can be passed to the conversion functions (this is used by
/// foreach implementation to typecast the object return value from
/// get_Current into the proper type. All code has been generated and
/// we only care about the side effect conversions to be performed
///
/// This is also now used as a placeholder where a no-action expression
/// is needed (the 'New' class).
///
public class EmptyExpression : Expression {
public EmptyExpression ()
{
type = TypeManager.object_type;
eclass = ExprClass.Value;
loc = Location.Null;
}
public EmptyExpression (Type t)
{
type = t;
eclass = ExprClass.Value;
loc = Location.Null;
}
public override Expression DoResolve (EmitContext ec)
{
return this;
}
public override void Emit (EmitContext ec)
{
// nothing, as we only exist to not do anything.
}
//
// This is just because we might want to reuse this bad boy
// instead of creating gazillions of EmptyExpressions.
// (CanConvertImplicit uses it)
//
public void SetType (Type t)
{
type = t;
}
}
public class UserCast : Expression {
MethodBase method;
Expression source;
public UserCast (MethodInfo method, Expression source, Location l)
{
this.method = method;
this.source = source;
type = method.ReturnType;
eclass = ExprClass.Value;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
//
// We are born fully resolved
//
return this;
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
source.Emit (ec);
if (method is MethodInfo)
ig.Emit (OpCodes.Call, (MethodInfo) method);
else
ig.Emit (OpCodes.Call, (ConstructorInfo) method);
}
}
//
// This class is used to "construct" the type during a typecast
// operation. Since the Type.GetType class in .NET can parse
// the type specification, we just use this to construct the type
// one bit at a time.
//
public class ComposedCast : Expression, ITypeExpression {
Expression left;
string dim;
public ComposedCast (Expression left, string dim, Location l)
{
this.left = left;
this.dim = dim;
loc = l;
}
public Expression DoResolveType (EmitContext ec)
{
Type ltype = ec.DeclSpace.ResolveType (left, false, loc);
if (ltype == null)
return null;
//
// ltype.Fullname is already fully qualified, so we can skip
// a lot of probes, and go directly to TypeManager.LookupType
//
string cname = ltype.FullName + dim;
type = TypeManager.LookupTypeDirect (cname);
if (type == null){
//
// For arrays of enumerations we are having a problem
// with the direct lookup. Need to investigate.
//
// For now, fall back to the full lookup in that case.
//
type = RootContext.LookupType (
ec.DeclSpace, cname, false, loc);
if (type == null)
return null;
}
if (!ec.ResolvingTypeTree){
//
// If the above flag is set, this is being invoked from the ResolveType function.
// Upper layers take care of the type validity in this context.
//
if (!ec.InUnsafe && type.IsPointer){
UnsafeError (loc);
return null;
}
}
eclass = ExprClass.Type;
return this;
}
public override Expression DoResolve (EmitContext ec)
{
return DoResolveType (ec);
}
public override void Emit (EmitContext ec)
{
throw new Exception ("This should never be called");
}
public override string ToString ()
{
return left + dim;
}
}
//
// This class is used to represent the address of an array, used
// only by the Fixed statement, this is like the C "&a [0]" construct.
//
public class ArrayPtr : Expression {
Expression array;
public ArrayPtr (Expression array, Location l)
{
Type array_type = array.Type.GetElementType ();
this.array = array;
string array_ptr_type_name = array_type.FullName + "*";
type = Type.GetType (array_ptr_type_name);
if (type == null){
ModuleBuilder mb = CodeGen.ModuleBuilder;
type = mb.GetType (array_ptr_type_name);
}
eclass = ExprClass.Value;
loc = l;
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
array.Emit (ec);
IntLiteral.EmitInt (ig, 0);
ig.Emit (OpCodes.Ldelema, array.Type.GetElementType ());
}
public override Expression DoResolve (EmitContext ec)
{
//
// We are born fully resolved
//
return this;
}
}
//
// Used by the fixed statement
//
public class StringPtr : Expression {
LocalBuilder b;
public StringPtr (LocalBuilder b, Location l)
{
this.b = b;
eclass = ExprClass.Value;
type = TypeManager.char_ptr_type;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
// This should never be invoked, we are born in fully
// initialized state.
return this;
}
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
ig.Emit (OpCodes.Ldloc, b);
ig.Emit (OpCodes.Conv_I);
ig.Emit (OpCodes.Call, TypeManager.int_get_offset_to_string_data);
ig.Emit (OpCodes.Add);
}
}
//
// Implements the 'stackalloc' keyword
//
public class StackAlloc : Expression {
Type otype;
Expression t;
Expression count;
public StackAlloc (Expression type, Expression count, Location l)
{
t = type;
this.count = count;
loc = l;
}
public override Expression DoResolve (EmitContext ec)
{
count = count.Resolve (ec);
if (count == null)
return null;
if (count.Type != TypeManager.int32_type){
count = ConvertImplicitRequired (ec, count, TypeManager.int32_type, loc);
if (count == null)
return null;
}
if (ec.InCatch || ec.InFinally){
Error (255,
"stackalloc can not be used in a catch or finally block");
return null;
}
otype = ec.DeclSpace.ResolveType (t, false, loc);
if (otype == null)
return null;
if (!TypeManager.VerifyUnManaged (otype, loc))
return null;
string ptr_name = otype.FullName + "*";
type = Type.GetType (ptr_name);
if (type == null){
ModuleBuilder mb = CodeGen.ModuleBuilder;
type = mb.GetType (ptr_name);
}
eclass = ExprClass.Value;
return this;
}
public override void Emit (EmitContext ec)
{
int size = GetTypeSize (otype);
ILGenerator ig = ec.ig;
if (size == 0)
ig.Emit (OpCodes.Sizeof, otype);
else
IntConstant.EmitInt (ig, size);
count.Emit (ec);
ig.Emit (OpCodes.Mul);
ig.Emit (OpCodes.Localloc);
}
}
}