|
static private IsPrimitiveUnsignedIntegerType ( |
||
| t | ||
| return | bool | |
private void TranslateToILForNoOverloadCase(ILGenerator il, Type rtype)
{
Type lhtype = Convert.ToType(this.operand1.InferType(null));
Type rhtype = Convert.ToType(this.operand2.InferType(null));
Type rt = Typeob.Object;
if (lhtype == Typeob.String || rhtype == Typeob.String)
{
rt = Typeob.String;
}
else if (rtype == Typeob.Void || rtype == lhtype || Convert.IsPrimitiveNumericType(lhtype) &&
(Convert.IsPromotableTo(rhtype, lhtype) || ((this.operand2 is ConstantWrapper) && ((ConstantWrapper)this.operand2).IsAssignableTo(lhtype))))
{
rt = lhtype;
}
if (rt == Typeob.SByte || rt == Typeob.Int16)
{
rt = Typeob.Int32;
}
else if (rt == Typeob.Byte || rt == Typeob.UInt16)
{
rt = Typeob.UInt32;
}
// If we have "unsigned += signed" or "signed += unsigned" then generating the
// correct code gets quite complicated. Just go late-bound for this edge case.
if (this.operand2 is ConstantWrapper)
{
if (!((ConstantWrapper)this.operand2).IsAssignableTo(rt))
{
// eg: "var u : byte = 123; u += -100;" should go late bound because
// of signed/unsigned mismatch but "u += 1" should not.
rt = Typeob.Object;
}
}
else
{
if ((Convert.IsPrimitiveSignedNumericType(rhtype) && Convert.IsPrimitiveUnsignedIntegerType(lhtype)) ||
(Convert.IsPrimitiveUnsignedIntegerType(rhtype) && Convert.IsPrimitiveSignedIntegerType(lhtype)))
{
rt = Typeob.Object;
}
}
this.operand1.TranslateToILPreSetPlusGet(il);
Convert.Emit(this, il, lhtype, rt);
this.operand2.TranslateToIL(il, rt);
if (rt == Typeob.Object || rt == Typeob.String)
{
il.Emit(OpCodes.Call, CompilerGlobals.plusDoOpMethod);
rt = Typeob.Object;
}
else if (rt == Typeob.Double || rt == Typeob.Single)
{
il.Emit(OpCodes.Add);
}
else if (rt == Typeob.Int32 || rt == Typeob.Int64 || rt == Typeob.Int16 || rt == Typeob.SByte)
{
il.Emit(OpCodes.Add_Ovf);
}
else
{
il.Emit(OpCodes.Add_Ovf_Un);
}
if (rtype != Typeob.Void)
{
LocalBuilder result = il.DeclareLocal(rt);
il.Emit(OpCodes.Dup);
il.Emit(OpCodes.Stloc, result);
Convert.Emit(this, il, rt, lhtype);
this.operand1.TranslateToILSet(il);
il.Emit(OpCodes.Ldloc, result);
Convert.Emit(this, il, rt, rtype);
}
else
{
Convert.Emit(this, il, rt, lhtype);
this.operand1.TranslateToILSet(il);
}
}
private void TranslateToILForNoOverloadCase(ILGenerator il, Type rtype)
{
Type lhtype = Convert.ToType(this.operand1.InferType(null));
Type rhtype = Convert.ToType(this.operand2.InferType(null));
Type rt = Typeob.Double;
if (this.operatorTok != JSToken.Divide && (rtype == Typeob.Void || rtype == lhtype || Convert.IsPrimitiveNumericType(lhtype)) &&
(Convert.IsPromotableTo(rhtype, lhtype) || ((this.operand2 is ConstantWrapper) && ((ConstantWrapper)this.operand2).IsAssignableTo(lhtype))))
{
rt = lhtype;
}
if (rt == Typeob.SByte || rt == Typeob.Int16)
{
rt = Typeob.Int32;
}
else if (rt == Typeob.Byte || rt == Typeob.UInt16 || rt == Typeob.Char)
{
rt = Typeob.UInt32;
}
// If we have "unsigned -= signed" or "signed -= unsigned" then generating the
// correct code gets quite complicated. Just go late-bound for this edge case.
if (this.operand2 is ConstantWrapper)
{
if (!((ConstantWrapper)this.operand2).IsAssignableTo(rt))
{
// eg: "var u : byte = 123; u -= -100;" should go late bound because
// of signed/unsigned mismatch but "u -= 1" should not.
rt = Typeob.Object;
}
}
else
{
if ((Convert.IsPrimitiveSignedNumericType(rhtype) && Convert.IsPrimitiveUnsignedIntegerType(lhtype)) ||
(Convert.IsPrimitiveUnsignedIntegerType(rhtype) && Convert.IsPrimitiveSignedIntegerType(lhtype)))
{
rt = Typeob.Object;
}
}
this.operand1.TranslateToILPreSetPlusGet(il);
Convert.Emit(this, il, lhtype, rt);
this.operand2.TranslateToIL(il, rt);
if (rt == Typeob.Object)
{
il.Emit(OpCodes.Ldc_I4, (int)this.operatorTok);
il.Emit(OpCodes.Call, CompilerGlobals.numericbinaryDoOpMethod);
}
else if (rt == Typeob.Double || rt == Typeob.Single)
{
switch (this.operatorTok)
{
case JSToken.Divide:
il.Emit(OpCodes.Div); break;
case JSToken.Minus:
il.Emit(OpCodes.Sub); break;
case JSToken.Modulo:
il.Emit(OpCodes.Rem); break;
case JSToken.Multiply:
il.Emit(OpCodes.Mul); break;
default:
throw new JScriptException(JSError.InternalError, this.context);
}
}
else if (rt == Typeob.Int32 || rt == Typeob.Int64 || rt == Typeob.Int16 || rt == Typeob.SByte)
{
switch (this.operatorTok)
{
case JSToken.Divide:
il.Emit(OpCodes.Div); break;
case JSToken.Minus:
il.Emit(OpCodes.Sub_Ovf); break;
case JSToken.Modulo:
il.Emit(OpCodes.Rem); break;
case JSToken.Multiply:
il.Emit(OpCodes.Mul_Ovf); break;
default:
throw new JScriptException(JSError.InternalError, this.context);
}
}
else
{
switch (this.operatorTok)
{
case JSToken.Divide:
il.Emit(OpCodes.Div); break;
case JSToken.Minus:
il.Emit(OpCodes.Sub_Ovf_Un); break;
case JSToken.Modulo:
il.Emit(OpCodes.Rem); break;
case JSToken.Multiply:
il.Emit(OpCodes.Mul_Ovf_Un); break;
default:
throw new JScriptException(JSError.InternalError, this.context);
}
}
if (rtype != Typeob.Void)
{
LocalBuilder result = il.DeclareLocal(rt);
il.Emit(OpCodes.Dup);
il.Emit(OpCodes.Stloc, result);
Convert.Emit(this, il, rt, lhtype);
this.operand1.TranslateToILSet(il);
il.Emit(OpCodes.Ldloc, result);
Convert.Emit(this, il, rt, rtype);
}
else
{
Convert.Emit(this, il, rt, lhtype);
this.operand1.TranslateToILSet(il);
}
}
