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Rewrote type conversions

git-svn-id: svn://svn.cc65.org/cc65/trunk@2262 b7a2c559-68d2-44c3-8de9-860c34a00d81
This commit is contained in:
cuz 2003-08-11 20:18:30 +00:00
parent b4bfbfa8ce
commit 81f94afd5c
16 changed files with 478 additions and 459 deletions

View File

@ -85,7 +85,7 @@ void WriteOutput (FILE* F)
SymEntry* Entry;
/* Output the global data segment */
CHECK (CS_GetEntryCount (CS->Code) == 0);
CHECK (!HaveGlobalCode ());
OutputSegments (CS, F);
/* Output all global or referenced functions */

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@ -6,9 +6,9 @@
/* */
/* */
/* */
/* (C) 2002 Ullrich von Bassewitz */
/* Wacholderweg 14 */
/* D-70597 Stuttgart */
/* (C) 2002-2003 Ullrich von Bassewitz */
/* Römerstrasse 52 */
/* D-70794 Filderstadt */
/* EMail: uz@cc65.org */
/* */
/* */
@ -39,6 +39,7 @@
#include "error.h"
#include "expr.h"
#include "typecmp.h"
#include "typeconv.h"
#include "assignment.h"
@ -49,7 +50,7 @@
void Assignment (ExprDesc* lval)
int Assignment (ExprDesc* lval)
/* Parse an assignment */
{
int k;
@ -86,7 +87,7 @@ void Assignment (ExprDesc* lval)
if (UseReg) {
PushAddr (lval);
} else {
exprhs (0, 0, lval);
exprhs (0, 0, lval);
g_push (CF_PTR | CF_UNSIGNED, 0);
}
@ -147,27 +148,26 @@ void Assignment (ExprDesc* lval)
} else {
/* Get the address on stack if needed */
PushAddr (lval);
/* Get the address on stack if needed */
PushAddr (lval);
/* Get the expression on the right of the '=' into the primary */
if (evalexpr (CF_NONE, hie1, &lval2) == 0) {
/* Constant expression. Adjust the types */
assignadjust (ltype, &lval2);
/* Put the value into the primary register */
exprhs (CF_NONE, 0, &lval2);
} else {
/* Expression is not constant and already in the primary */
assignadjust (ltype, &lval2);
}
/* Read the expression on the right side of the '=' */
k = hie1 (&lval2);
/* Do type conversion if necessary */
k = TypeConversion (&lval2, k, ltype);
/* If necessary, load the value into the primary register */
exprhs (CF_NONE, k, &lval2);
/* Generate a store instruction */
Store (lval, 0);
}
/* Value is still in primary */
/* Value is still in primary and not an lvalue */
lval->Flags = E_MEXPR;
return 0;
}

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@ -6,9 +6,9 @@
/* */
/* */
/* */
/* (C) 2002 Ullrich von Bassewitz */
/* Wacholderweg 14 */
/* D-70597 Stuttgart */
/* (C) 2002-2003 Ullrich von Bassewitz */
/* Römerstrasse 52 */
/* D-70794 Filderstadt */
/* EMail: uz@cc65.org */
/* */
/* */
@ -49,7 +49,7 @@
void Assignment (ExprDesc* lval);
int Assignment (ExprDesc* lval);
/* Parse an assignment */

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@ -44,6 +44,7 @@
#include "anonname.h"
#include "codegen.h"
#include "datatype.h"
#include "declare.h"
#include "declattr.h"
#include "error.h"
#include "expr.h"
@ -54,7 +55,7 @@
#include "pragma.h"
#include "scanner.h"
#include "symtab.h"
#include "declare.h"
#include "typeconv.h"
@ -1076,18 +1077,10 @@ static void ClosingCurlyBraces (unsigned BracesExpected)
static unsigned ParseScalarInit (type* T)
/* Parse initializaton for scalar data types. Return the number of data bytes. */
{
static const unsigned long Masks[] = {
0x000000FFUL, 0x0000FFFFUL, 0x00FFFFFFUL, 0xFFFFFFFFUL
};
unsigned BraceCount;
ExprDesc ED;
/* Get the size of the expected type */
unsigned Size = SizeOf (T);
CHECK (Size > 0 && Size <= sizeof(Masks)/sizeof(Masks[0]));
/* Optional opening brace */
BraceCount = OpeningCurlyBraces (0);
unsigned BraceCount = OpeningCurlyBraces (0);
/* We warn if an initializer for a scalar contains braces, because this is
* quite unusual and often a sign for some problem in the input.
@ -1096,13 +1089,9 @@ static unsigned ParseScalarInit (type* T)
Warning ("Braces around scalar initializer");
}
/* Expression */
/* Get the expression and convert it to the target type */
ConstExpr (&ED);
if ((ED.Flags & E_MCTYPE) == E_TCONST) {
/* Make the const value the correct size */
ED.ConstVal &= Masks[Size-1];
}
assignadjust (T, &ED);
TypeConversion (&ED, 0, T);
/* Output the data */
DefineData (&ED);
@ -1111,7 +1100,7 @@ static unsigned ParseScalarInit (type* T)
ClosingCurlyBraces (BraceCount);
/* Done */
return Size;
return SizeOf (T);
}
@ -1129,7 +1118,7 @@ static unsigned ParsePointerInit (type* T)
/* Make the const value the correct size */
ED.ConstVal &= 0xFFFF;
}
assignadjust (T, &ED);
TypeConversion (&ED, 0, T);
/* Output the data */
DefineData (&ED);
@ -1406,7 +1395,19 @@ static unsigned ParseInitInternal (type* T, int AllowFlexibleMembers)
unsigned ParseInit (type* T)
/* Parse initialization of variables. Return the number of data bytes. */
{
return ParseInitInternal (T, !ANSI);
/* Parse the initialization */
unsigned Size = ParseInitInternal (T, !ANSI);
/* The initialization may not generate code on global level, because code
* outside function scope will never get executed.
*/
if (HaveGlobalCode ()) {
Error ("Non constant initializers");
RemoveGlobalCode ();
}
/* Return the size needed for the initialization */
return Size;
}

View File

@ -31,8 +31,8 @@
#include "scanner.h"
#include "stdfunc.h"
#include "symtab.h"
#include "typecast.h"
#include "typecmp.h"
#include "typeconv.h"
#include "expr.h"
@ -87,7 +87,7 @@ static GenDesc GenOASGN = { TOK_OR_ASSIGN, GEN_NOPUSH, g_or };
static int hie0 (ExprDesc *lval);
int hie0 (ExprDesc *lval);
/* Parse comma operator. */
static int expr (int (*func) (ExprDesc*), ExprDesc *lval);
@ -195,94 +195,6 @@ static unsigned typeadjust (ExprDesc* lhs, ExprDesc* rhs, int NoPush)
unsigned assignadjust (type* lhst, ExprDesc* rhs)
/* Adjust the type of the right hand expression so that it can be assigned to
* the type on the left hand side. This function is used for assignment and
* for converting parameters in a function call. It returns the code generator
* flags for the operation. The type string of the right hand side will be
* set to the type of the left hand side.
*/
{
/* Get the type of the right hand side. Treat function types as
* pointer-to-function
*/
type* rhst = rhs->Type;
if (IsTypeFunc (rhst)) {
rhst = PointerTo (rhst);
}
/* After calling this function, rhs will have the type of the lhs */
rhs->Type = lhst;
/* First, do some type checking */
if (IsTypeVoid (lhst) || IsTypeVoid (rhst)) {
/* If one of the sides are of type void, output a more apropriate
* error message.
*/
Error ("Illegal type");
} else if (IsClassInt (lhst)) {
if (IsClassPtr (rhst)) {
/* Pointer -> int conversion */
Warning ("Converting pointer to integer without a cast");
} else if (IsClassInt (rhst)) {
/* Convert the rhs to the type of the lhs. */
unsigned flags = TypeOf (rhst);
if (rhs->Flags == E_MCONST) {
flags |= CF_CONST;
}
return g_typecast (TypeOf (lhst), flags);
} else {
Error ("Incompatible types");
}
} else if (IsClassPtr (lhst)) {
if (IsClassPtr (rhst)) {
/* Pointer to pointer assignment is valid, if:
* - both point to the same types, or
* - the rhs pointer is a void pointer, or
* - the lhs pointer is a void pointer.
*/
if (!IsTypeVoid (Indirect (lhst)) && !IsTypeVoid (Indirect (rhst))) {
/* Compare the types */
switch (TypeCmp (lhst, rhst)) {
case TC_INCOMPATIBLE:
Error ("Incompatible pointer types");
break;
case TC_QUAL_DIFF:
Error ("Pointer types differ in type qualifiers");
break;
default:
/* Ok */
break;
}
}
} else if (IsClassInt (rhst)) {
/* Int to pointer assignment is valid only for constant zero */
if (rhs->Flags != E_MCONST || rhs->ConstVal != 0) {
Warning ("Converting integer to pointer without a cast");
}
} else if (IsTypeFuncPtr (lhst) && IsTypeFunc(rhst)) {
/* Assignment of function to function pointer is allowed, provided
* that both functions have the same parameter list.
*/
if (TypeCmp (Indirect (lhst), rhst) < TC_EQUAL) {
Error ("Incompatible types");
}
} else {
Error ("Incompatible types");
}
} else {
Error ("Incompatible types");
}
/* Return an int value in all cases where the operands are not both ints */
return CF_INT;
}
void DefineData (ExprDesc* Expr)
/* Output a data definition for the given expression */
{
@ -655,8 +567,8 @@ static unsigned FunctionParamList (FuncDesc* Func)
* convert the actual argument to the type needed.
*/
if (!Ellipsis) {
/* Promote the argument if needed */
assignadjust (Param->Type, &lval);
/* Convert the argument to the parameter type if needed */
TypeConversion (&lval, 0, Param->Type);
/* If we have a prototype, chars may be pushed as chars */
Flags |= CF_FORCECHAR;
@ -3022,12 +2934,10 @@ int hie1 (ExprDesc* lval)
static int hie0 (ExprDesc *lval)
int hie0 (ExprDesc *lval)
/* Parse comma operator. */
{
int k;
k = hie1 (lval);
int k = hie1 (lval);
while (CurTok.Tok == TOK_COMMA) {
NextToken ();
k = hie1 (lval);

View File

@ -42,13 +42,6 @@ void CheckBoolExpr (ExprDesc* lval);
* if not.
*/
unsigned assignadjust (type* lhst, ExprDesc* rhs);
/* Adjust the type of the right hand expression so that it can be assigned to
* the type on the left hand side. This function is used for assignment and
* for converting parameters in a function call. It returns the code generator
* flags for the operation.
*/
void exprhs (unsigned flags, int k, ExprDesc *lval);
/* Put the result of an expression into the primary register */
@ -58,13 +51,8 @@ void Store (ExprDesc* lval, const type* StoreType);
* is NULL, use lval->Type instead.
*/
void expression1 (ExprDesc* lval);
/* Evaluate an expression on level 1 (no comma operator) and put it into
* the primary register
*/
void expression (ExprDesc* lval);
/* Evaluate an expression and put it into the primary register */
int hie0 (ExprDesc *lval);
/* Parse comma operator. */
int evalexpr (unsigned flags, int (*f) (ExprDesc*), ExprDesc* lval);
/* Will evaluate an expression via the given function. If the result is a
@ -73,6 +61,14 @@ int evalexpr (unsigned flags, int (*f) (ExprDesc*), ExprDesc* lval);
* primary register and 1 is returned.
*/
void expression1 (ExprDesc* lval);
/* Evaluate an expression on level 1 (no comma operator) and put it into
* the primary register
*/
void expression (ExprDesc* lval);
/* Evaluate an expression and put it into the primary register */
void ConstExpr (ExprDesc* lval);
/* Get a constant value */

View File

@ -46,8 +46,9 @@
#include "expr.h"
#include "function.h"
#include "global.h"
#include "symtab.h"
#include "locals.h"
#include "symtab.h"
#include "typeconv.h"
@ -62,7 +63,6 @@ static unsigned ParseRegisterDecl (Declaration* Decl, unsigned* SC, int Reg)
* symbol data, which is the offset of the variable in the register bank.
*/
{
unsigned Flags;
unsigned InitLabel;
/* Determine if this is a compound variable */
@ -95,8 +95,8 @@ static unsigned ParseRegisterDecl (Declaration* Decl, unsigned* SC, int Reg)
/* Parse the initialization generating a memory image of the
* data in the RODATA segment. The function does return the size
* of the initialization data, which may be greater than the
* actual size of the type, if the type is a structure with a
* of the initialization data, which may be greater than the
* actual size of the type, if the type is a structure with a
* flexible array member that has been initialized. Since we must
* know the size of the data in advance for register variables,
* we cannot allow that here.
@ -110,27 +110,17 @@ static unsigned ParseRegisterDecl (Declaration* Decl, unsigned* SC, int Reg)
} else {
/* Setup the type flags for the assignment */
Flags = CF_NONE;
if (Size == SIZEOF_CHAR) {
Flags |= CF_FORCECHAR;
}
/* Parse the expression */
int k = hie1 (InitExprDesc (&lval));
/* Get the expression into the primary */
if (evalexpr (Flags, hie1, &lval) == 0) {
/* Constant expression. Adjust the types */
assignadjust (Decl->Type, &lval);
Flags |= CF_CONST;
/* Load it into the primary */
exprhs (Flags, 0, &lval);
} else {
/* Expression is not constant and in the primary */
assignadjust (Decl->Type, &lval);
}
/* Convert it to the target type */
k = TypeConversion (&lval, k, Decl->Type);
/* Load the value into the primary */
exprhs (CF_NONE, k, &lval);
/* Store the value into the variable */
Flags |= CF_REGVAR;
g_putstatic (Flags | TypeOf (Decl->Type), Reg, 0);
g_putstatic (CF_REGVAR | TypeOf (Decl->Type), Reg, 0);
}
@ -210,20 +200,28 @@ static unsigned ParseAutoDecl (Declaration* Decl, unsigned* SC)
} else {
int k;
/* Allocate previously reserved local space */
F_AllocLocalSpace (CurrentFunc);
/* Setup the type flags for the assignment */
Flags = (Size == SIZEOF_CHAR)? CF_FORCECHAR : CF_NONE;
/* Get the expression into the primary */
if (evalexpr (Flags, hie1, &lval) == 0) {
/* Constant expression. Adjust the types */
assignadjust (Decl->Type, &lval);
Flags |= CF_CONST;
/* Parse the expression */
k = hie1 (InitExprDesc (&lval));
/* Convert it to the target type */
k = TypeConversion (&lval, k, Decl->Type);
/* If the value is not const, load it into the primary.
* Otherwise pass the information to the code generator.
*/
if (k != 0 || lval.Flags != E_MCONST) {
exprhs (CF_NONE, k, &lval);
k = 0;
} else {
/* Expression is not constant and in the primary */
assignadjust (Decl->Type, &lval);
Flags |= CF_CONST;
}
/* Push the value */
@ -286,24 +284,17 @@ static unsigned ParseAutoDecl (Declaration* Decl, unsigned* SC)
} else {
/* Setup the type flags for the assignment */
Flags = (Size == SIZEOF_CHAR)? CF_FORCECHAR : CF_NONE;
/* Parse the expression */
int k = hie1 (InitExprDesc (&lval));
/* Get the expression into the primary */
if (evalexpr (Flags, hie1, &lval) == 0) {
/* Constant expression. Adjust the types */
assignadjust (Decl->Type, &lval);
Flags |= CF_CONST;
/* Load it into the primary */
exprhs (Flags, 0, &lval);
} else {
/* Expression is not constant and in the primary */
assignadjust (Decl->Type, &lval);
}
/* Convert it to the target type */
k = TypeConversion (&lval, k, Decl->Type);
/* Load the value into the primary */
exprhs (CF_NONE, k, &lval);
/* Store the value into the variable */
g_putstatic (Flags | TypeOf (Decl->Type), SymData, 0);
g_putstatic (TypeOf (Decl->Type), SymData, 0);
}
/* Mark the variable as referenced */

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@ -82,8 +82,8 @@ OBJS = anonname.o \
symentry.o \
symtab.o \
textseg.o \
typecast.o \
typecmp.o \
typeconv.o \
util.o
LIBS = $(COMMON)/common.a

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@ -103,8 +103,8 @@ OBJS = anonname.obj \
symentry.obj \
symtab.obj \
textseg.obj \
typecast.obj \
typecmp.obj \
typeconv.obj \
util.obj
LIBS = ..\common\common.lib

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@ -224,6 +224,22 @@ void AddDataLine (const char* Format, ...)
int HaveGlobalCode (void)
/* Return true if the global code segment contains entries (which is an error) */
{
return (CS_GetEntryCount (GS->Code) > 0);
}
void RemoveGlobalCode (void)
/* Remove all code from the global code segment. Used for error recovery. */
{
CS_DelEntries (GS->Code, 0, CS_GetEntryCount (GS->Code));
}
void OutputSegments (const Segments* S, FILE* F)
/* Output the given segments to the file */
{

View File

@ -132,6 +132,12 @@ void AddCode (opc_t OPC, am_t AM, const char* Arg, struct CodeLabel* JumpTo);
void AddDataLine (const char* Format, ...) attribute ((format (printf, 1, 2)));
/* Add a line of data to the current data segment */
int HaveGlobalCode (void);
/* Return true if the global code segment contains entries (which is an error) */
void RemoveGlobalCode (void);
/* Remove all code from the global code segment. Used for error recovery. */
void OutputSegments (const Segments* S, FILE* F);
/* Output the given segments to the file */

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@ -48,6 +48,7 @@
#include "litpool.h"
#include "scanner.h"
#include "stdfunc.h"
#include "typeconv.h"
@ -106,35 +107,36 @@ static struct StdFuncDesc* FindFunc (const char* Name)
static unsigned ParseArg (type* Type, ExprDesc* pval)
static unsigned ParseArg (type* Type, ExprDesc* Arg)
/* Parse one argument but do not push it onto the stack. Return the code
* generator flags needed to do the actual push.
*/
{
unsigned CFlags;
unsigned Flags;
/* Do some optimization: If we have a constant value to push,
* use a special function that may optimize.
*/
CFlags = CF_NONE;
if (CheckedSizeOf (Type) == 1) {
CFlags = CF_FORCECHAR;
}
Flags = CF_NONE;
if (evalexpr (CFlags, hie1, pval) == 0) {
/* A constant value */
Flags |= CF_CONST;
}
/* Promote the argument if needed */
assignadjust (Type, pval);
/* We have a prototype, so chars may be pushed as chars */
Flags |= CF_FORCECHAR;
unsigned Flags = CF_FORCECHAR;
/* Read the expression we're going to pass to the function */
int k = hie1 (InitExprDesc (Arg));
/* Convert this expression to the expected type */
k = TypeConversion (Arg, k, Type);
/* If the value is not a constant, load it into the primary */
if (k != 0 || Arg->Flags != E_MCONST) {
/* Load into the primary */
exprhs (CF_NONE, k, Arg);
k = 0;
} else {
/* Remember that we have a constant value */
Flags |= CF_CONST;
}
/* Use the type of the argument for the push */
return (Flags | TypeOf (pval->Type));
return (Flags | TypeOf (Arg->Type));
}
@ -208,20 +210,17 @@ static void StdFunc_strlen (FuncDesc* F attribute ((unused)),
ExprDesc* lval attribute ((unused)))
/* Handle the strlen function */
{
static type ParamType[] = { T_PTR, T_SCHAR, T_END };
ExprDesc Param;
unsigned CodeFlags;
static type ParamType[] = { T_PTR, T_SCHAR, T_END };
int k;
ExprDesc Param;
unsigned CodeFlags;
unsigned long ParamName;
/* Fetch the parameter */
int k = hie1 (InitExprDesc (&Param));
/* Setup the argument type string */
ParamType[1] = GetDefaultChar () | T_QUAL_CONST;
/* Convert the parameter type to the type needed, check for mismatches */
assignadjust (ParamType, &Param);
/* Fetch the parameter and convert it to the type needed */
k = TypeConversion (&Param, hie1 (InitExprDesc (&Param)), ParamType);
/* Check if the parameter is a constant array of some type, or a numeric
* address cast to a pointer.

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@ -58,6 +58,7 @@
#include "swstmt.h"
#include "symtab.h"
#include "stmt.h"
#include "typeconv.h"
@ -89,13 +90,13 @@ static void CheckSemi (int* PendingToken)
* error message if not found (plus some error recovery). If PendingToken is
* NULL, it will the skip the token, otherwise it will store one to
* PendingToken.
* This function is a special version of CheckTok with the addition of the
* This function is a special version of CheckTok with the addition of the
* error recovery.
*/
{
int HaveToken = (CurTok.Tok == TOK_SEMI);
if (!HaveToken) {
Error ("`;' expected");
Error ("`;' expected");
/* Try to be smart about errors */
if (CurTok.Tok == TOK_COLON || CurTok.Tok == TOK_COMMA) {
HaveToken = 1;
@ -256,7 +257,8 @@ static void WhileStatement (void)
static void ReturnStatement (void)
/* Handle the 'return' statement */
{
ExprDesc lval;
ExprDesc Expr;
int k;
NextToken ();
if (CurTok.Tok != TOK_SEMI) {
@ -266,12 +268,17 @@ static void ReturnStatement (void)
Error ("Returning a value in function with return type void");
}
/* Evaluate the return expression. Result will be in primary */
expression (&lval);
/* Evaluate the return expression */
k = hie0 (InitExprDesc (&Expr));
/* Convert the return value to the type of the function result */
/* Ignore the return expression if the function returns void */
if (!F_HasVoidReturn (CurrentFunc)) {
assignadjust (F_GetReturnType (CurrentFunc), &lval);
/* Convert the return value to the type of the function result */
TypeConversion (&Expr, k, F_GetReturnType (CurrentFunc));
/* Load the value into the primary */
exprhs (CF_NONE, k, &Expr);
}
} else if (!F_HasVoidReturn (CurrentFunc) && !F_HasOldStyleIntRet (CurrentFunc)) {

View File

@ -1,213 +0,0 @@
/*****************************************************************************/
/* */
/* typecast.c */
/* */
/* Handle type casts */
/* */
/* */
/* */
/* (C) 2002 Ullrich von Bassewitz */
/* Römerstrasse 52 */
/* D-70794 Filderstadt */
/* EMail: uz@cc65.org */
/* */
/* */
/* This software is provided 'as-is', without any expressed or implied */
/* warranty. In no event will the authors be held liable for any damages */
/* arising from the use of this software. */
/* */
/* Permission is granted to anyone to use this software for any purpose, */
/* including commercial applications, and to alter it and redistribute it */
/* freely, subject to the following restrictions: */
/* */
/* 1. The origin of this software must not be misrepresented; you must not */
/* claim that you wrote the original software. If you use this software */
/* in a product, an acknowledgment in the product documentation would be */
/* appreciated but is not required. */
/* 2. Altered source versions must be plainly marked as such, and must not */
/* be misrepresented as being the original software. */
/* 3. This notice may not be removed or altered from any source */
/* distribution. */
/* */
/*****************************************************************************/
/* cc65 */
#include "codegen.h"
#include "datatype.h"
#include "declare.h"
#include "error.h"
#include "expr.h"
#include "scanner.h"
#include "typecast.h"
/*****************************************************************************/
/* Code */
/*****************************************************************************/
int TypeCast (ExprDesc* lval)
/* Handle an explicit cast. The function returns true if the resulting
* expression is an lvalue and false if not.
*/
{
int k;
type* OldType;
type NewType[MAXTYPELEN];
unsigned OldSize;
unsigned NewSize;
/* Skip the left paren */
NextToken ();
/* Read the type */
ParseType (NewType);
/* Closing paren */
ConsumeRParen ();
/* Read the expression we have to cast */
k = hie10 (lval);
/* If the expression is a function, treat it as pointer to function.
* If the expression is an array, treat it as pointer to first element.
*/
if (IsTypeFunc (lval->Type)) {
lval->Type = PointerTo (lval->Type);
} else if (IsTypeArray (lval->Type)) {
lval->Type = ArrayToPtr (lval->Type);
}
/* Remember the old type */
OldType = lval->Type;
/* If we're casting to void, we're done. Note: This does also cover a cast
* void -> void.
*/
if (IsTypeVoid (NewType)) {
k = 0; /* Never an lvalue */
goto ExitPoint;
}
/* Don't allow casts from void to something else. */
if (IsTypeVoid (OldType)) {
Error ("Cannot cast from `void' to something else");
goto ExitPoint;
}
/* Get the sizes of the types. Since we've excluded void types, checking
* for known sizes makes sense here.
*/
OldSize = CheckedSizeOf (OldType);
NewSize = CheckedSizeOf (NewType);
/* Is this a cast of something into an integer? */
if (IsClassInt (NewType)) {
/* lvalue? */
if (k != 0) {
/* We have an lvalue. If the new size is smaller than the new one,
* we don't need to do anything. The compiler will generate code
* to load only the portion of the value that is actually needed.
* This works only on a little endian architecture, but that's
* what we support.
* If both sizes are equal, do also leave the value alone.
* If the new size is larger, we must convert the value.
*/
if (NewSize > OldSize) {
/* Load the value into the primary */
exprhs (CF_NONE, k, lval);
/* Emit typecast code */
g_typecast (TypeOf (OldType), TypeOf (NewType));
/* Value is now in primary */
lval->Flags = E_MEXPR;
k = 0;
}
} else {
/* We have an rvalue. Check for a constant. */
if (lval->Flags == E_MCONST) {
/* A cast of a constant to an integer. Be sure to handle sign
* extension correctly.
*/
/* Get the current and new size of the value */
unsigned OldBits = OldSize * 8;
unsigned NewBits = NewSize * 8;
/* Check if the new datatype will have a smaller range. If it
* has a larger range, things are ok, since the value is
* internally already represented by a long.
*/
if (NewBits <= OldBits) {
/* Cut the value to the new size */
lval->ConstVal &= (0xFFFFFFFFUL >> (32 - NewBits));
/* If the new type is signed, sign extend the value */
if (!IsSignUnsigned (NewType)) {
if (lval->ConstVal & (0x01UL << (NewBits-1))) {
lval->ConstVal |= ((~0L) << NewBits);
}
}
}
} else {
/* The value is not a constant. If the sizes of the types are
* not equal, add conversion code. Be sure to convert chars
* correctly.
*/
if (OldSize != NewSize) {
/* Load the value into the primary */
exprhs (CF_NONE, k, lval);
/* Emit typecast code. */
g_typecast (TypeOf (OldType), TypeOf (NewType) | CF_FORCECHAR);
/* Value is now in primary */
lval->Flags = E_MEXPR;
k = 0;
}
}
}
} else {
/* All other stuff is handled equally */
if (NewSize != OldSize) {
/* Load the value into the primary */
exprhs (CF_NONE, k, lval);
/* Emit typecast code */
g_typecast (TypeOf (OldType), TypeOf (NewType) | CF_FORCECHAR);
/* Value is now in primary */
lval->Flags = E_MEXPR;
k = 0;
}
}
ExitPoint:
/* The expression has always the new type */
ReplaceType (lval, NewType);
/* Done */
return k;
}

300
src/cc65/typeconv.c Normal file
View File

@ -0,0 +1,300 @@
/*****************************************************************************/
/* */
/* typeconv.c */
/* */
/* Handle type conversions */
/* */
/* */
/* */
/* (C) 2002-2003 Ullrich von Bassewitz */
/* Römerstrasse 52 */
/* D-70794 Filderstadt */
/* EMail: uz@cc65.org */
/* */
/* */
/* This software is provided 'as-is', without any expressed or implied */
/* warranty. In no event will the authors be held liable for any damages */
/* arising from the use of this software. */
/* */
/* Permission is granted to anyone to use this software for any purpose, */
/* including commercial applications, and to alter it and redistribute it */
/* freely, subject to the following restrictions: */
/* */
/* 1. The origin of this software must not be misrepresented; you must not */
/* claim that you wrote the original software. If you use this software */
/* in a product, an acknowledgment in the product documentation would be */
/* appreciated but is not required. */
/* 2. Altered source versions must be plainly marked as such, and must not */
/* be misrepresented as being the original software. */
/* 3. This notice may not be removed or altered from any source */
/* distribution. */
/* */
/*****************************************************************************/
/* cc65 */
#include "codegen.h"
#include "datatype.h"
#include "declare.h"
#include "error.h"
#include "expr.h"
#include "scanner.h"
#include "typecmp.h"
#include "typeconv.h"
/*****************************************************************************/
/* Code */
/*****************************************************************************/
static void DoPtrConversions (ExprDesc* Expr)
/* If the expression is a function, convert it to pointer to function.
* If the expression is an array, convert it to pointer to first element.
*/
{
if (IsTypeFunc (Expr->Type)) {
Expr->Type = PointerTo (Expr->Type);
} else if (IsTypeArray (Expr->Type)) {
Expr->Type = ArrayToPtr (Expr->Type);
}
}
static int DoConversion (ExprDesc* Expr, int k, type* NewType)
/* Emit code to convert the given expression to a new type. */
{
type* OldType;
unsigned OldSize;
unsigned NewSize;
/* Remember the old type */
OldType = Expr->Type;
/* If we're converting to void, we're done. Note: This does also cover a
* conversion void -> void.
*/
if (IsTypeVoid (NewType)) {
k = 0; /* Never an lvalue */
goto ExitPoint;
}
/* Don't allow casts from void to something else. */
if (IsTypeVoid (OldType)) {
Error ("Cannot convert from `void' to something else");
goto ExitPoint;
}
/* Get the sizes of the types. Since we've excluded void types, checking
* for known sizes makes sense here.
*/
OldSize = CheckedSizeOf (OldType);
NewSize = CheckedSizeOf (NewType);
/* lvalue? */
if (k != 0) {
/* We have an lvalue. If the new size is smaller than the new one,
* we don't need to do anything. The compiler will generate code
* to load only the portion of the value that is actually needed.
* This works only on a little endian architecture, but that's
* what we support.
* If both sizes are equal, do also leave the value alone.
* If the new size is larger, we must convert the value.
*/
if (NewSize > OldSize) {
/* Load the value into the primary */
exprhs (CF_NONE, k, Expr);
/* Emit typecast code */
g_typecast (TypeOf (OldType), TypeOf (NewType));
/* Value is now in primary */
Expr->Flags = E_MEXPR;
k = 0;
}
} else {
/* We have an rvalue. Check for a constant. */
if (Expr->Flags == E_MCONST) {
/* A cast of a constant to an integer. Be sure to handle sign
* extension correctly.
*/
/* Get the current and new size of the value */
unsigned OldBits = OldSize * 8;
unsigned NewBits = NewSize * 8;
/* Check if the new datatype will have a smaller range. If it
* has a larger range, things are ok, since the value is
* internally already represented by a long.
*/
if (NewBits <= OldBits) {
/* Cut the value to the new size */
Expr->ConstVal &= (0xFFFFFFFFUL >> (32 - NewBits));
/* If the new type is signed, sign extend the value */
if (!IsSignUnsigned (NewType)) {
if (Expr->ConstVal & (0x01UL << (NewBits-1))) {
Expr->ConstVal |= ((~0L) << NewBits);
}
}
}
} else {
/* The value is not a constant. If the sizes of the types are
* not equal, add conversion code. Be sure to convert chars
* correctly.
*/
if (OldSize != NewSize) {
/* Load the value into the primary */
exprhs (CF_NONE, k, Expr);
/* Emit typecast code. */
g_typecast (TypeOf (OldType), TypeOf (NewType) | CF_FORCECHAR);
/* Value is now in primary */
Expr->Flags = E_MEXPR;
k = 0;
}
}
}
ExitPoint:
/* The expression has always the new type */
ReplaceType (Expr, NewType);
/* Done */
return k;
}
int TypeConversion (ExprDesc* Expr, int k, type* NewType)
/* Do an automatic conversion of the given expression to the new type. Output
* warnings or errors where this automatic conversion is suspicious or
* impossible.
*/
{
/* Get the type of the right hand side. Treat function types as
* pointer-to-function
*/
DoPtrConversions (Expr);
/* First, do some type checking */
if (IsTypeVoid (NewType) || IsTypeVoid (Expr->Type)) {
/* If one of the sides are of type void, output a more apropriate
* error message.
*/
Error ("Illegal type");
return k;
}
/* Handle conversions to int type */
if (IsClassInt (NewType)) {
if (IsClassPtr (Expr->Type)) {
/* Pointer -> int conversion */
Warning ("Converting pointer to integer without a cast");
} else if (!IsClassInt (Expr->Type)) {
Error ("Incompatible types");
} else {
/* Convert the rhs to the type of the lhs. */
k = DoConversion (Expr, k, NewType);
}
return k;
}
/* Handle conversions to pointer type */
if (IsClassPtr (NewType)) {
if (IsClassPtr (Expr->Type)) {
/* Pointer to pointer assignment is valid, if:
* - both point to the same types, or
* - the rhs pointer is a void pointer, or
* - the lhs pointer is a void pointer.
*/
if (!IsTypeVoid (Indirect (NewType)) && !IsTypeVoid (Indirect (Expr->Type))) {
/* Compare the types */
switch (TypeCmp (NewType, Expr->Type)) {
case TC_INCOMPATIBLE:
Error ("Incompatible pointer types");
return k;
case TC_QUAL_DIFF:
Error ("Pointer types differ in type qualifiers");
return k;
default:
/* Ok */
break;
}
}
} else if (IsClassInt (Expr->Type)) {
/* Int to pointer assignment is valid only for constant zero */
if (Expr->Flags != E_MCONST || Expr->ConstVal != 0) {
Warning ("Converting integer to pointer without a cast");
}
} else if (IsTypeFuncPtr (NewType) && IsTypeFunc(Expr->Type)) {
/* Assignment of function to function pointer is allowed, provided
* that both functions have the same parameter list.
*/
if (TypeCmp (Indirect (NewType), Expr->Type) < TC_EQUAL) {
Error ("Incompatible types");
return k;
}
} else {
Error ("Incompatible types");
return k;
}
/* If we come here, the conversion is ok, convert and return the result */
return DoConversion (Expr, k, NewType);
}
/* Invalid automatic conversion */
Error ("Incompatible types");
return k;
}
int TypeCast (ExprDesc* Expr)
/* Handle an explicit cast. The function returns true if the resulting
* expression is an lvalue and false if not.
*/
{
int k;
type NewType[MAXTYPELEN];
/* Skip the left paren */
NextToken ();
/* Read the type */
ParseType (NewType);
/* Closing paren */
ConsumeRParen ();
/* Read the expression we have to cast */
k = hie10 (Expr);
/* Convert functions and arrays to "pointer to" object */
DoPtrConversions (Expr);
/* Convert the value and return the result. */
return DoConversion (Expr, k, NewType);
}

View File

@ -1,14 +1,14 @@
/*****************************************************************************/
/* */
/* typecast.h */
/* typeconv.h */
/* */
/* Handle type casts */
/* Handle type conversions */
/* */
/* */
/* */
/* (C) 2002 Ullrich von Bassewitz */
/* Wacholderweg 14 */
/* D-70597 Stuttgart */
/* (C) 2002-2003 Ullrich von Bassewitz */
/* Römerstrasse 52 */
/* D-70794 Filderstadt */
/* EMail: uz@cc65.org */
/* */
/* */
@ -33,11 +33,11 @@
#ifndef TYPECAST_H
#define TYPECAST_H
#ifndef TYPECONV_H
#define TYPECONV_H
/* cc65 */
#include "exprdesc.h"
@ -49,14 +49,20 @@
int TypeCast (ExprDesc* lval);
int TypeConversion (ExprDesc* Expr, int k, type* NewType);
/* Do an automatic conversion of the given expression to the new type. Output
* warnings or errors where this automatic conversion is suspicious or
* impossible.
*/
int TypeCast (ExprDesc* Expr);
/* Handle an explicit cast. The function returns true if the resulting
* expression is an lvalue and false if not.
*/
/* End of typecast.h */
/* End of typeconv.h */
#endif