// end of the code generated for EmitAssign
//
void Emit (EmitContext ec, bool leave_copy);
-
+
//
// This method does the assignment
// `source' will be stored into the location specified by `this'
// for expressions like a [f ()] ++, where you can't call `f ()' twice.
//
void EmitAssign (EmitContext ec, Expression source, bool leave_copy, bool prepare_for_load);
-
+
/*
For simple assignments, this interface is very simple, EmitAssign is called with source
as the source expression and leave_copy and prepare_for_load false.
-
+
For compound assignments it gets complicated.
-
+
EmitAssign will be called as before, however, prepare_for_load will be
true. The @source expression will contain an expression
which calls Emit. So, the calls look like:
-
+
this.EmitAssign (ec, source, false, true) ->
source.Emit (ec); ->
[...] ->
end [...]
end source.Emit (ec);
end this.EmitAssign (ec, source, false, true)
-
-
+
+
When prepare_for_load is true, EmitAssign emits a `token' on the stack that
Emit will use for its state.
-
+
Let's take FieldExpr as an example. assume we are emitting f ().y += 1;
-
+
Here is the call tree again. This time, each call is annotated with the IL
it produces:
-
+
this.EmitAssign (ec, source, false, true)
call f
dup
-
+
Binary.Emit ()
this.Emit (ec, false);
ldfld y
end this.Emit (ec, false);
-
+
IntConstant.Emit ()
ldc.i4.1
end IntConstant.Emit
-
+
add
end Binary.Emit ()
-
+
stfld
end this.EmitAssign (ec, source, false, true)
-
+
Observe two things:
1) EmitAssign left a token on the stack. It was the result of f ().
2) This token was used by Emit
-
+
leave_copy (in both EmitAssign and Emit) tells the compiler to leave a copy
of the expression at that point in evaluation. This is used for pre/post inc/dec
and for a = x += y. Let's do the above example with leave_copy true in EmitAssign
-
+
this.EmitAssign (ec, source, true, true)
call f
dup
-
+
Binary.Emit ()
this.Emit (ec, false);
ldfld y
end this.Emit (ec, false);
-
+
IntConstant.Emit ()
ldc.i4.1
end IntConstant.Emit
-
+
add
end Binary.Emit ()
-
+
dup
stloc temp
stfld
ldloc temp
end this.EmitAssign (ec, source, true, true)
-
+
And with it true in Emit
-
+
this.EmitAssign (ec, source, false, true)
call f
dup
-
+
Binary.Emit ()
this.Emit (ec, true);
ldfld y
dup
stloc temp
end this.Emit (ec, true);
-
+
IntConstant.Emit ()
ldc.i4.1
end IntConstant.Emit
-
+
add
end Binary.Emit ()
-
+
stfld
ldloc temp
end this.EmitAssign (ec, source, false, true)
-
+
Note that these two examples are what happens for ++x and x++, respectively.
*/
}
/// code to access this value, return its address or save its value.
///
/// If `is_address' is true, then the value that we store is the address to the
- /// real value, and not the value itself.
+ /// real value, and not the value itself.
///
/// This is needed for a value type, because otherwise you just end up making a
/// copy of the value on the stack and modifying it. You really need a pointer
public class LocalTemporary : Expression, IMemoryLocation {
LocalBuilder builder;
bool is_address;
-
- public LocalTemporary (EmitContext ec, Type t) : this (ec, t, false) {}
-
- public LocalTemporary (EmitContext ec, Type t, bool is_address)
+
+ public LocalTemporary (Type t) : this (t, false) {}
+
+ public LocalTemporary (Type t, bool is_address)
{
type = t;
eclass = ExprClass.Value;
- loc = Location.Null;
- builder = ec.GetTemporaryLocal (is_address ? TypeManager.GetReferenceType (t): t);
this.is_address = is_address;
}
ec.FreeTemporaryLocal (builder, type);
builder = null;
}
-
+
public override Expression DoResolve (EmitContext ec)
{
return this;
public override void Emit (EmitContext ec)
{
ILGenerator ig = ec.ig;
-
+
+ if (builder == null)
+ throw new InternalErrorException ("Emit without Store, or after Release");
+
ig.Emit (OpCodes.Ldloc, builder);
// we need to copy from the pointer
if (is_address)
public void Store (EmitContext ec)
{
ILGenerator ig = ec.ig;
+ if (builder == null)
+ builder = ec.GetTemporaryLocal (is_address ? TypeManager.GetReferenceType (type): type);
+
ig.Emit (OpCodes.Stloc, builder);
}
public void AddressOf (EmitContext ec, AddressOp mode)
{
+ if (builder == null)
+ builder = ec.GetTemporaryLocal (is_address ? TypeManager.GetReferenceType (type): type);
+
// if is_address, than this is just the address anyways,
// so we just return this.
ILGenerator ig = ec.ig;
-
+
if (is_address)
ig.Emit (OpCodes.Ldloc, builder);
else
/// <summary>
/// The Assign node takes care of assigning the value of source into
- /// the expression represented by target.
+ /// the expression represented by target.
/// </summary>
public class Assign : ExpressionStatement {
protected Expression target, source, real_source;
{
this.is_embedded = true;
}
+
+ public override Expression CreateExpressionTree (EmitContext ec)
+ {
+ Report.Error (832, loc, "An expression tree cannot contain an assignment operator");
+ return null;
+ }
protected virtual Assign GetEmbeddedAssign (Location loc)
{
source = embedded = ((Assign) source).GetEmbeddedAssign (loc);
real_source = source = source.Resolve (ec);
+
if (source == null) {
// Ensure that we don't propagate the error as spurious "uninitialized variable" errors.
target = target.ResolveLValue (ec, EmptyExpression.Null, Location);
if (embedded == null) {
if (this is CompoundAssign)
- real_temp = temp = new LocalTemporary (ec, target.Type);
+ real_temp = temp = new LocalTemporary (target.Type);
else
- real_temp = temp = new LocalTemporary (ec, source.Type);
+ real_temp = temp = new LocalTemporary (source.Type);
} else
temp = embedded.temp;
// local variable as source.
if (embedded != null)
source = (embedded.temp != null) ? embedded.temp : embedded.source;
-
+
target = target.ResolveLValue (ec, source, Location);
if (target == null)
return null;
-
- if (source.Equals (target)) {
+
+ bool same_assignment = (embedded != null) ? embedded.Target.Equals(target) : source.Equals (target);
+ if (same_assignment) {
Report.Warning (1717, 3, loc, "Assignment made to same variable; did you mean to assign something else?");
}
type = target_type;
eclass = ExprClass.Value;
-
if (target is EventExpr) {
EventInfo ei = ((EventExpr) target).EventInfo;
Expression ml = MemberLookup (
- ec, ec.ContainerType, ei.Name,
+ ec.ContainerType, ec.ContainerType, ei.Name,
MemberTypes.Event, AllBindingFlags | BindingFlags.DeclaredOnly, loc);
if (ml == null) {
- //
- // If this is the case, then the Event does not belong
+ //
+ // If this is the case, then the Event does not belong
// to this Type and so, according to the spec
// is allowed to only appear on the left hand of
// the += and -= operators
// in the case it is being referenced within the same type container;
// it will appear as a FieldExpr in that case.
//
-
+
if (!(source is BinaryDelegate)) {
error70 (ei, loc);
return null;
- }
- }
- }
-
- FieldExpr field_exp = target as FieldExpr;
- if (field_exp != null && field_exp.DeclaringType.IsValueType && !ec.IsConstructor && !ec.IsFieldInitializer) {
- field_exp = field_exp.InstanceExpression as FieldExpr;
- if (field_exp != null && field_exp.FieldInfo.IsInitOnly) {
- if (field_exp.IsStatic) {
- Report.Error (1650, loc, "Fields of static readonly field `{0}' cannot be assigned to (except in a static constructor or a variable initializer)",
- field_exp.GetSignatureForError ());
- } else {
- Report.Error (1648, loc, "Members of readonly field `{0}' cannot be modified (except in a constructor or a variable initializer)",
- field_exp.GetSignatureForError ());
}
- return null;
}
}
if (!(target is IAssignMethod) && (target.eclass != ExprClass.EventAccess)) {
- Report.Error (131, loc,
- "Left hand of an assignment must be a variable, " +
- "a property or an indexer");
+ Error_ValueAssignment (loc);
return null;
}
if ((source.eclass == ExprClass.Type) && (source is TypeExpr)) {
- source.Error_UnexpectedKind (ec, "variable or value", loc);
+ source.Error_UnexpectedKind (ec.DeclContainer, "variable or value", loc);
return null;
} else if ((RootContext.Version == LanguageVersion.ISO_1) &&
(source is MethodGroupExpr)){
}
- if (target_type == source_type){
- if (source is New && target_type.IsValueType &&
- (target.eclass != ExprClass.IndexerAccess) && (target.eclass != ExprClass.PropertyAccess)){
- New n = (New) source;
-
- if (n.SetValueTypeVariable (target))
+ if (target_type == source_type) {
+ if (target.eclass == ExprClass.Variable) {
+ New n = source as New;
+ if (n == null)
+ return this;
+
+ if (n.HasInitializer) {
+ n.SetTargetVariable (target);
+ } else if (target_type.IsValueType) {
+ n.SetTargetVariable (target);
return n;
- else
- return null;
+ }
}
-
+
return this;
}
-
+
//
// If this assignment/operator was part of a compound binary
// operator, then we allow an explicit conversion, as detailed
- // in the spec.
+ // in the spec.
//
if (this is CompoundAssign){
CompoundAssign a = (CompoundAssign) this;
-
+
Binary b = source as Binary;
if (b != null){
//
// 1. if the source is explicitly convertible to the
// target_type
//
-
+
source = Convert.ExplicitConversion (ec, source, target_type, loc);
if (source == null){
- a.original_source.Error_ValueCannotBeConverted (loc, target_type, true);
+ a.original_source.Error_ValueCannotBeConverted (ec, loc, target_type, true);
return null;
}
-
+
//
// 2. and the original right side is implicitly convertible to
// the type of target
//
- if (Convert.ImplicitStandardConversionExists (ec, a.original_source, target_type))
+ if (Convert.ImplicitConversionExists (ec, a.original_source, target_type))
return this;
//
(b.Oper == Binary.Operator.LeftShift || b.Oper == Binary.Operator.RightShift))
return this;
- a.original_source.Error_ValueCannotBeConverted (loc, target_type, false);
+ a.original_source.Error_ValueCannotBeConverted (ec, loc, target_type, false);
return null;
}
}
}
source = Convert.ImplicitConversionRequired (ec, source, target_type, loc);
-
if (source == null)
return null;
// type and store it in a new temporary local.
if (is_embedded || embedded != null) {
type = target_type;
- temp = new LocalTemporary (ec, type);
+ temp = new LocalTemporary (type);
must_free_temp = true;
}
-
+
return this;
}
((EventExpr) target).EmitAddOrRemove (ec, source);
return;
}
-
+
IAssignMethod am = (IAssignMethod) target;
Expression temp_source;
temp_source = source;
am.EmitAssign (ec, temp_source, !is_statement, this is CompoundAssign);
-
+
if (embedded != null) {
if (temp != null)
temp.Release (ec);
embedded.ReleaseEmbedded (ec);
}
}
-
+
public override void Emit (EmitContext ec)
{
Emit (ec, false);
{
Emit (ec, true);
}
+
+ protected override void CloneTo (CloneContext clonectx, Expression t)
+ {
+ Assign _target = (Assign) t;
+
+ _target.target = target.Clone (clonectx);
+ _target.source = source.Clone (clonectx);
+ }
}
-
+
+ // This class implements fields and events class initializers
+ public class FieldInitializer : Assign
+ {
+ //
+ // Keep resolved value because field initializers have their own rules
+ //
+ ExpressionStatement resolved;
+
+ public FieldInitializer (FieldBuilder field, Expression expression)
+ : base (new FieldExpr (field, expression.Location, true), expression)
+ {
+ if (!field.IsStatic)
+ ((FieldExpr)target).InstanceExpression = CompilerGeneratedThis.Instance;
+ }
+
+ public override Expression DoResolve (EmitContext ec)
+ {
+ // Field initializer can be resolved (fail) many times
+ if (Source == null)
+ return null;
+
+ if (resolved == null)
+ resolved = base.DoResolve (ec) as ExpressionStatement;
+
+ return resolved;
+ }
+
+ public override void EmitStatement (EmitContext ec)
+ {
+ if (resolved == null)
+ return;
+
+ if (resolved != this)
+ resolved.EmitStatement (ec);
+ else
+ base.EmitStatement (ec);
+ }
+
+ public bool IsComplexInitializer {
+ get {
+ if (embedded != null)
+ return true;
+
+ return !(source is Constant);
+ }
+ }
+
+ public bool IsDefaultInitializer {
+ get {
+ Constant c = source as Constant;
+ if (c == null)
+ return false;
+
+ FieldExpr fe = (FieldExpr)target;
+ return c.IsDefaultInitializer (fe.Type);
+ }
+ }
+ }
+
+
//
- // This class is used for compound assignments.
+ // This class is used for compound assignments.
//
class CompoundAssign : Assign {
Binary.Operator op;
public Expression original_source;
-
+
public CompoundAssign (Binary.Operator op, Expression target, Expression source)
: base (target, source, target.Location)
{
return new CompoundAssign (this, loc);
}
- public Expression ResolveSource (EmitContext ec)
- {
- return original_source.Resolve (ec);
- }
-
public override Expression DoResolve (EmitContext ec)
{
original_source = original_source.Resolve (ec);
if (original_source == null)
return null;
- target = target.Resolve (ec);
+ using (ec.Set (EmitContext.Flags.InCompoundAssignment)) {
+ target = target.Resolve (ec);
+ }
+
if (target == null)
return null;
-
+
+ if (target is MethodGroupExpr){
+ Error_CannotAssign (((MethodGroupExpr)target).Name, target.ExprClassName);
+ return null;
+ }
//
// Only now we can decouple the original source/target
// into a tree, to guarantee that we do not have side
// effects.
//
- source = new Binary (op, target, original_source);
+ source = new Binary (op, target, original_source, true);
return base.DoResolve (ec);
}
- }
-}
-
-
+ protected override void CloneTo (CloneContext clonectx, Expression t)
+ {
+ CompoundAssign target = (CompoundAssign) t;
+ target.original_source = original_source.Clone (clonectx);
+ }
+ }
+}