#include "interpreter.h" /* whether evaluation is left to right for a given precedence level */ #define IS_LEFT_TO_RIGHT(p) ((p) != 2 && (p) != 14) #define BRACKET_PRECEDENCE 20 #define IS_TYPE_TOKEN(t) ((t) >= TokenIntType && (t) <= TokenUnsignedType) #define DEEP_PRECEDENCE (BRACKET_PRECEDENCE*1000) #ifdef DEBUG_EXPRESSIONS #define debugf printf #else void debugf(char *Format, ...) { } #endif /* local prototypes */ enum OperatorOrder { OrderNone, OrderPrefix, OrderInfix, OrderPostfix }; /* a stack of expressions we use in evaluation */ struct ExpressionStack { struct ExpressionStack *Next; /* the next lower item on the stack */ struct Value *Val; /* the value for this stack node */ enum LexToken Op; /* the operator */ short unsigned int Precedence; /* the operator precedence of this node */ unsigned char Order; /* the evaluation order of this operator */ }; /* operator precedence definitions */ struct OpPrecedence { unsigned int PrefixPrecedence:4; unsigned int PostfixPrecedence:4; unsigned int InfixPrecedence:4; char *Name; }; /* NOTE: the order of this array must correspond exactly to the order of these tokens in enum LexToken */ static struct OpPrecedence OperatorPrecedence[] = { /* TokenNone, */ { 0, 0, 0, "none" }, /* TokenComma, */ { 0, 0, 0, "," }, /* TokenAssign, */ { 0, 0, 2, "=" }, /* TokenAddAssign, */ { 0, 0, 2, "+=" }, /* TokenSubtractAssign, */ { 0, 0, 2, "-=" }, /* TokenMultiplyAssign, */ { 0, 0, 2, "*=" }, /* TokenDivideAssign, */ { 0, 0, 2, "/=" }, /* TokenModulusAssign, */ { 0, 0, 2, "%=" }, /* TokenShiftLeftAssign, */ { 0, 0, 2, "<<=" }, /* TokenShiftRightAssign, */ { 0, 0, 2, ">>=" }, /* TokenArithmeticAndAssign, */ { 0, 0, 2, "&=" }, /* TokenArithmeticOrAssign, */ { 0, 0, 2, "|=" }, /* TokenArithmeticExorAssign, */ { 0, 0, 2, "^=" }, /* TokenQuestionMark, */ { 0, 0, 3, "?" }, /* TokenColon, */ { 0, 0, 3, ":" }, /* TokenLogicalOr, */ { 0, 0, 4, "||" }, /* TokenLogicalAnd, */ { 0, 0, 5, "&&" }, /* TokenArithmeticOr, */ { 0, 0, 6, "|" }, /* TokenArithmeticExor, */ { 0, 0, 7, "^" }, /* TokenAmpersand, */ { 14, 0, 8, "&" }, /* TokenEqual, */ { 0, 0, 9, "==" }, /* TokenNotEqual, */ { 0, 0, 9, "!=" }, /* TokenLessThan, */ { 0, 0, 10, "<" }, /* TokenGreaterThan, */ { 0, 0, 10, ">" }, /* TokenLessEqual, */ { 0, 0, 10, "<=" }, /* TokenGreaterEqual, */ { 0, 0, 10, ">=" }, /* TokenShiftLeft, */ { 0, 0, 11, "<<" }, /* TokenShiftRight, */ { 0, 0, 11, ">>" }, /* TokenPlus, */ { 14, 0, 12, "+" }, /* TokenMinus, */ { 14, 0, 12, "-" }, /* TokenAsterisk, */ { 14, 0, 13, "*" }, /* TokenSlash, */ { 0, 0, 13, "/" }, /* TokenModulus, */ { 0, 0, 13, "%" }, /* TokenIncrement, */ { 14, 15, 0, "++" }, /* TokenDecrement, */ { 14, 15, 0, "--" }, /* TokenUnaryNot, */ { 14, 0, 0, "!" }, /* TokenUnaryExor, */ { 14, 0, 0, "~" }, /* TokenSizeof, */ { 14, 0, 0, "sizeof" }, /* TokenCast, */ { 14, 0, 0, "cast" }, /* TokenLeftSquareBracket, */ { 0, 0, 15, "[" }, /* TokenRightSquareBracket, */ { 0, 15, 0, "]" }, /* TokenDot, */ { 0, 0, 15, "." }, /* TokenArrow, */ { 0, 0, 15, "->" }, /* TokenOpenBracket, */ { 15, 0, 0, "(" }, /* TokenCloseBracket, */ { 0, 15, 0, ")" } }; void ExpressionParseFunctionCall(struct ParseState *Parser, struct ExpressionStack **StackTop, const char *FuncName, int RunIt); #ifdef DEBUG_EXPRESSIONS /* show the contents of the expression stack */ void ExpressionStackShow(struct ExpressionStack *StackTop) { printf("Expression stack [0x%lx,0x%lx]: ", (long)HeapStackTop, (long)StackTop); while (StackTop != NULL) { if (StackTop->Order == OrderNone) { /* it's a value */ if (StackTop->Val->IsLValue) printf("lvalue="); else printf("value="); switch (StackTop->Val->Typ->Base) { case TypeVoid: printf("void"); break; case TypeInt: printf("%d:int", StackTop->Val->Val->Integer); break; case TypeShort: printf("%d:short", StackTop->Val->Val->ShortInteger); break; case TypeChar: printf("%d:char", StackTop->Val->Val->Character); break; case TypeLong: printf("%d:long", StackTop->Val->Val->LongInteger); break; case TypeUnsignedShort: printf("%d:unsigned short", StackTop->Val->Val->UnsignedShortInteger); break; case TypeUnsignedInt: printf("%d:unsigned int", StackTop->Val->Val->UnsignedInteger); break; case TypeUnsignedLong: printf("%d:unsigned long", StackTop->Val->Val->UnsignedLongInteger); break; case TypeFP: printf("%f:fp", StackTop->Val->Val->FP); break; case TypeFunction: printf("%s:function", StackTop->Val->Val->Identifier); break; case TypeMacro: printf("%s:macro", StackTop->Val->Val->Identifier); break; case TypePointer: if (StackTop->Val->Val->Pointer == NULL) printf("ptr(NULL)"); else if (StackTop->Val->Typ->FromType->Base == TypeChar) printf("\"%s\":string", (char *)StackTop->Val->Val->Pointer); else printf("ptr(0x%lx)", (long)StackTop->Val->Val->Pointer); break; case TypeArray: printf("array"); break; case TypeStruct: printf("%s:struct", StackTop->Val->Val->Identifier); break; case TypeUnion: printf("%s:union", StackTop->Val->Val->Identifier); break; case TypeEnum: printf("%s:enum", StackTop->Val->Val->Identifier); break; case Type_Type: PrintType(StackTop->Val->Val->Typ, CStdOut); printf(":type"); break; default: printf("unknown"); break; } printf("[0x%lx,0x%lx]", (long)StackTop, (long)StackTop->Val); } else { /* it's an operator */ printf("op='%s' %s %d", OperatorPrecedence[(int)StackTop->Op].Name, (StackTop->Order == OrderPrefix) ? "prefix" : ((StackTop->Order == OrderPostfix) ? "postfix" : "infix"), StackTop->Precedence); printf("[0x%lx]", (long)StackTop); } StackTop = StackTop->Next; if (StackTop != NULL) printf(", "); } printf("\n"); } #endif long ExpressionCoerceInteger(struct Value *Val) { switch (Val->Typ->Base) { case TypeInt: return (long)Val->Val->Integer; case TypeChar: return (long)Val->Val->Character; case TypeShort: return (long)Val->Val->ShortInteger; case TypeLong: return (long)Val->Val->LongInteger; case TypeUnsignedInt: return (long)Val->Val->UnsignedInteger; case TypeUnsignedShort: return (long)Val->Val->UnsignedShortInteger; case TypeUnsignedLong: return (long)Val->Val->UnsignedLongInteger; case TypePointer: return (long)Val->Val->Pointer; #ifndef NO_FP case TypeFP: return (long)Val->Val->FP; #endif default: return 0; } } unsigned long ExpressionCoerceUnsignedInteger(struct Value *Val) { switch (Val->Typ->Base) { case TypeInt: return (unsigned long)Val->Val->Integer; case TypeChar: return (unsigned long)Val->Val->Character; case TypeShort: return (unsigned long)Val->Val->ShortInteger; case TypeLong: return (unsigned long)Val->Val->LongInteger; case TypeUnsignedInt: return (unsigned long)Val->Val->UnsignedInteger; case TypeUnsignedShort: return (unsigned long)Val->Val->UnsignedShortInteger; case TypeUnsignedLong: return (unsigned long)Val->Val->UnsignedLongInteger; case TypePointer: return (unsigned long)Val->Val->Pointer; #ifndef NO_FP case TypeFP: return (unsigned long)Val->Val->FP; #endif default: return 0; } } #ifndef NO_FP double ExpressionCoerceFP(struct Value *Val) { #ifndef BROKEN_FLOAT_CASTS int IntVal; unsigned UnsignedVal; switch (Val->Typ->Base) { case TypeInt: IntVal = Val->Val->Integer; return (double)IntVal; case TypeChar: IntVal = Val->Val->Character; return (double)IntVal; case TypeShort: IntVal = Val->Val->ShortInteger; return (double)IntVal; case TypeLong: IntVal = Val->Val->LongInteger; return (double)IntVal; case TypeUnsignedInt: UnsignedVal = Val->Val->UnsignedInteger; return (double)UnsignedVal; case TypeUnsignedShort: UnsignedVal = Val->Val->UnsignedShortInteger; return (double)UnsignedVal; case TypeUnsignedLong: UnsignedVal = Val->Val->UnsignedLongInteger; return (double)UnsignedVal; case TypeFP: return Val->Val->FP; default: return 0.0; } #else switch (Val->Typ->Base) { case TypeInt: return (double)Val->Val->Integer; case TypeChar: return (double)Val->Val->Character; case TypeShort: return (double)Val->Val->ShortInteger; case TypeLong: return (double)Val->Val->LongInteger; case TypeUnsignedInt: return (double)Val->Val->UnsignedInteger; case TypeUnsignedShort: return (double)Val->Val->UnsignedShortInteger; case TypeUnsignedLong: return (double)Val->Val->UnsignedLongInteger; case TypeFP: return (double)Val->Val->FP; default: return 0.0; } #endif } #endif /* assign an integer value */ long ExpressionAssignInt(struct ParseState *Parser, struct Value *DestValue, long FromInt, int After) { long Result; if (!DestValue->IsLValue) ProgramFail(Parser, "can't assign to this"); if (After) Result = ExpressionCoerceInteger(DestValue); else Result = FromInt; switch (DestValue->Typ->Base) { case TypeInt: DestValue->Val->Integer = FromInt; break; case TypeShort: DestValue->Val->ShortInteger = (short)FromInt; break; case TypeChar: DestValue->Val->Character = (unsigned char)FromInt; break; case TypeLong: DestValue->Val->LongInteger = (long)FromInt; break; case TypeUnsignedInt: DestValue->Val->UnsignedInteger = (unsigned int)FromInt; break; case TypeUnsignedShort: DestValue->Val->UnsignedShortInteger = (unsigned short)FromInt; break; case TypeUnsignedLong: DestValue->Val->UnsignedLongInteger = (unsigned long)FromInt; break; default: break; } return Result; } #ifndef NO_FP /* assign a floating point value */ double ExpressionAssignFP(struct ParseState *Parser, struct Value *DestValue, double FromFP) { if (!DestValue->IsLValue) ProgramFail(Parser, "can't assign to this"); DestValue->Val->FP = FromFP; return FromFP; } #endif /* push a node on to the expression stack */ void ExpressionStackPushValueNode(struct ParseState *Parser, struct ExpressionStack **StackTop, struct Value *ValueLoc) { struct ExpressionStack *StackNode = VariableAlloc(Parser, sizeof(struct ExpressionStack), FALSE); StackNode->Next = *StackTop; StackNode->Val = ValueLoc; *StackTop = StackNode; #ifdef FANCY_ERROR_MESSAGES StackNode->Line = Parser->Line; StackNode->CharacterPos = Parser->CharacterPos; #endif #ifdef DEBUG_EXPRESSIONS ExpressionStackShow(*StackTop); #endif } /* push a blank value on to the expression stack by type */ struct Value *ExpressionStackPushValueByType(struct ParseState *Parser, struct ExpressionStack **StackTop, struct ValueType *PushType) { struct Value *ValueLoc = VariableAllocValueFromType(Parser, PushType, FALSE, NULL, FALSE); ExpressionStackPushValueNode(Parser, StackTop, ValueLoc); return ValueLoc; } /* push a value on to the expression stack */ void ExpressionStackPushValue(struct ParseState *Parser, struct ExpressionStack **StackTop, struct Value *PushValue) { struct Value *ValueLoc = VariableAllocValueAndCopy(Parser, PushValue, FALSE); ExpressionStackPushValueNode(Parser, StackTop, ValueLoc); } void ExpressionStackPushLValue(struct ParseState *Parser, struct ExpressionStack **StackTop, struct Value *PushValue, int Offset) { struct Value *ValueLoc = VariableAllocValueShared(Parser, PushValue); ValueLoc->Val = (void *)((char *)ValueLoc->Val + Offset); ExpressionStackPushValueNode(Parser, StackTop, ValueLoc); } void ExpressionStackPushDereference(struct ParseState *Parser, struct ExpressionStack **StackTop, struct Value *DereferenceValue) { struct Value *DerefVal; struct Value *ValueLoc; int Offset; struct ValueType *DerefType; int DerefIsLValue; void *DerefDataLoc = VariableDereferencePointer(Parser, DereferenceValue, &DerefVal, &Offset, &DerefType, &DerefIsLValue); if (DerefDataLoc == NULL) ProgramFail(Parser, "NULL pointer dereference"); ValueLoc = VariableAllocValueFromExistingData(Parser, DerefType, (union AnyValue *)DerefDataLoc, DerefIsLValue, DerefVal); ExpressionStackPushValueNode(Parser, StackTop, ValueLoc); } void ExpressionPushInt(struct ParseState *Parser, struct ExpressionStack **StackTop, long IntValue) { struct Value *ValueLoc = VariableAllocValueFromType(Parser, &IntType, FALSE, NULL, FALSE); ValueLoc->Val->Integer = IntValue; ExpressionStackPushValueNode(Parser, StackTop, ValueLoc); } #ifndef NO_FP void ExpressionPushFP(struct ParseState *Parser, struct ExpressionStack **StackTop, double FPValue) { struct Value *ValueLoc = VariableAllocValueFromType(Parser, &FPType, FALSE, NULL, FALSE); ValueLoc->Val->FP = FPValue; ExpressionStackPushValueNode(Parser, StackTop, ValueLoc); } #endif /* assign to a pointer */ void ExpressionAssignToPointer(struct ParseState *Parser, struct Value *ToValue, struct Value *FromValue, const char *FuncName, int ParamNo, int AllowPointerCoercion) { struct ValueType *PointedToType = ToValue->Typ->FromType; if (FromValue->Typ == ToValue->Typ || FromValue->Typ == VoidPtrType || (ToValue->Typ == VoidPtrType && FromValue->Typ->Base == TypePointer)) ToValue->Val->Pointer = FromValue->Val->Pointer; /* plain old pointer assignment */ else if (FromValue->Typ->Base == TypeArray && (PointedToType == FromValue->Typ->FromType || ToValue->Typ == VoidPtrType)) { /* the form is: blah *x = array of blah */ ToValue->Val->Pointer = (void *)&FromValue->Val->ArrayMem[0]; } else if (FromValue->Typ->Base == TypePointer && FromValue->Typ->FromType->Base == TypeArray && (PointedToType == FromValue->Typ->FromType->FromType || ToValue->Typ == VoidPtrType) ) { /* the form is: blah *x = pointer to array of blah */ ToValue->Val->Pointer = VariableDereferencePointer(Parser, FromValue, NULL, NULL, NULL, NULL); } else if (IS_NUMERIC_COERCIBLE(FromValue) && ExpressionCoerceInteger(FromValue) == 0) { /* null pointer assignment */ ToValue->Val->Pointer = NULL; } else if (AllowPointerCoercion && IS_NUMERIC_COERCIBLE(FromValue)) { /* assign integer to native pointer */ ToValue->Val->Pointer = (void *)(unsigned long)ExpressionCoerceUnsignedInteger(FromValue); } else AssignFail(Parser, "%t from %t", ToValue->Typ, FromValue->Typ, 0, 0, FuncName, ParamNo); } /* assign any kind of value */ void ExpressionAssign(struct ParseState *Parser, struct Value *DestValue, struct Value *SourceValue, int Force, const char *FuncName, int ParamNo, int AllowPointerCoercion) { if (!DestValue->IsLValue && !Force) AssignFail(Parser, "not an lvalue", NULL, NULL, 0, 0, FuncName, ParamNo); if (IS_NUMERIC_COERCIBLE(DestValue) && !IS_NUMERIC_COERCIBLE_PLUS_POINTERS(SourceValue, AllowPointerCoercion)) AssignFail(Parser, "%t from %t", DestValue->Typ, SourceValue->Typ, 0, 0, FuncName, ParamNo); switch (DestValue->Typ->Base) { case TypeInt: DestValue->Val->Integer = ExpressionCoerceInteger(SourceValue); break; case TypeShort: DestValue->Val->ShortInteger = ExpressionCoerceInteger(SourceValue); break; case TypeChar: DestValue->Val->Character = ExpressionCoerceUnsignedInteger(SourceValue); break; case TypeLong: DestValue->Val->LongInteger = ExpressionCoerceInteger(SourceValue); break; case TypeUnsignedInt: DestValue->Val->UnsignedInteger = ExpressionCoerceUnsignedInteger(SourceValue); break; case TypeUnsignedShort: DestValue->Val->UnsignedShortInteger = ExpressionCoerceUnsignedInteger(SourceValue); break; case TypeUnsignedLong: DestValue->Val->UnsignedLongInteger = ExpressionCoerceUnsignedInteger(SourceValue); break; #ifndef NO_FP case TypeFP: if (!IS_NUMERIC_COERCIBLE_PLUS_POINTERS(SourceValue, AllowPointerCoercion)) AssignFail(Parser, "%t from %t", DestValue->Typ, SourceValue->Typ, 0, 0, FuncName, ParamNo); DestValue->Val->FP = ExpressionCoerceFP(SourceValue); break; #endif case TypePointer: ExpressionAssignToPointer(Parser, DestValue, SourceValue, FuncName, ParamNo, AllowPointerCoercion); break; case TypeArray: if (DestValue->Typ != SourceValue->Typ) AssignFail(Parser, "%t from %t", DestValue->Typ, SourceValue->Typ, 0, 0, FuncName, ParamNo); if (DestValue->Typ->ArraySize != SourceValue->Typ->ArraySize) AssignFail(Parser, "from an array of size %d to one of size %d", NULL, NULL, DestValue->Typ->ArraySize, SourceValue->Typ->ArraySize, FuncName, ParamNo); memcpy((void *)DestValue->Val, (void *)SourceValue->Val, TypeSizeValue(DestValue, FALSE)); break; case TypeStruct: case TypeUnion: if (DestValue->Typ != SourceValue->Typ) AssignFail(Parser, "%t from %t", DestValue->Typ, SourceValue->Typ, 0, 0, FuncName, ParamNo); memcpy((void *)DestValue->Val, (void *)SourceValue->Val, TypeSizeValue(SourceValue, FALSE)); break; default: AssignFail(Parser, "%t", DestValue->Typ, NULL, 0, 0, FuncName, ParamNo); break; } } /* evaluate the first half of a ternary operator x ? y : z */ void ExpressionQuestionMarkOperator(struct ParseState *Parser, struct ExpressionStack **StackTop, struct Value *BottomValue, struct Value *TopValue) { if (!IS_NUMERIC_COERCIBLE(TopValue)) ProgramFail(Parser, "first argument to '?' should be a number"); if (ExpressionCoerceInteger(TopValue)) { /* the condition's true, return the BottomValue */ ExpressionStackPushValue(Parser, StackTop, BottomValue); } else { /* the condition's false, return void */ ExpressionStackPushValueByType(Parser, StackTop, &VoidType); } } /* evaluate the second half of a ternary operator x ? y : z */ void ExpressionColonOperator(struct ParseState *Parser, struct ExpressionStack **StackTop, struct Value *BottomValue, struct Value *TopValue) { if (TopValue->Typ->Base == TypeVoid) { /* invoke the "else" part - return the BottomValue */ ExpressionStackPushValue(Parser, StackTop, BottomValue); } else { /* it was a "then" - return the TopValue */ ExpressionStackPushValue(Parser, StackTop, TopValue); } } /* evaluate a prefix operator */ void ExpressionPrefixOperator(struct ParseState *Parser, struct ExpressionStack **StackTop, enum LexToken Op, struct Value *TopValue) { struct Value *Result; union AnyValue *ValPtr; debugf("ExpressionPrefixOperator()\n"); switch (Op) { case TokenAmpersand: if (!TopValue->IsLValue) ProgramFail(Parser, "can't get the address of this"); ValPtr = TopValue->Val; Result = VariableAllocValueFromType(Parser, TypeGetMatching(Parser, TopValue->Typ, TypePointer, 0, StrEmpty, TRUE), FALSE, NULL, FALSE); Result->Val->Pointer = (void *)ValPtr; ExpressionStackPushValueNode(Parser, StackTop, Result); break; case TokenAsterisk: ExpressionStackPushDereference(Parser, StackTop, TopValue); break; case TokenSizeof: /* return the size of the argument */ if (TopValue->Typ == &TypeType) ExpressionPushInt(Parser, StackTop, TypeSize(TopValue->Val->Typ, TopValue->Val->Typ->ArraySize, TRUE)); else ExpressionPushInt(Parser, StackTop, TypeSize(TopValue->Typ, TopValue->Typ->ArraySize, TRUE)); break; default: /* an arithmetic operator */ #ifndef NO_FP if (TopValue->Typ == &FPType) { /* floating point prefix arithmetic */ double ResultFP = 0.0; switch (Op) { case TokenPlus: ResultFP = TopValue->Val->FP; break; case TokenMinus: ResultFP = -TopValue->Val->FP; break; default: ProgramFail(Parser, "invalid operation"); break; } ExpressionPushFP(Parser, StackTop, ResultFP); } else #endif if (IS_NUMERIC_COERCIBLE(TopValue)) { /* integer prefix arithmetic */ long ResultInt = 0; long TopInt = ExpressionCoerceInteger(TopValue); switch (Op) { case TokenPlus: ResultInt = TopInt; break; case TokenMinus: ResultInt = -TopInt; break; case TokenIncrement: ResultInt = ExpressionAssignInt(Parser, TopValue, TopInt+1, FALSE); break; case TokenDecrement: ResultInt = ExpressionAssignInt(Parser, TopValue, TopInt-1, FALSE); break; case TokenUnaryNot: ResultInt = !TopInt; break; case TokenUnaryExor: ResultInt = ~TopInt; break; default: ProgramFail(Parser, "invalid operation"); break; } ExpressionPushInt(Parser, StackTop, ResultInt); } else if (TopValue->Typ->Base == TypePointer) { /* pointer prefix arithmetic */ int Size = TypeSize(TopValue->Typ->FromType, 0, TRUE); struct Value *StackValue; void *ResultPtr; if (TopValue->Val->Pointer == NULL) ProgramFail(Parser, "invalid use of a NULL pointer"); if (!TopValue->IsLValue) ProgramFail(Parser, "can't assign to this"); switch (Op) { case TokenIncrement: TopValue->Val->Pointer = (void *)((char *)TopValue->Val->Pointer + Size); break; case TokenDecrement: TopValue->Val->Pointer = (void *)((char *)TopValue->Val->Pointer - Size); break; default: ProgramFail(Parser, "invalid operation"); break; } ResultPtr = TopValue->Val->Pointer; StackValue = ExpressionStackPushValueByType(Parser, StackTop, TopValue->Typ); StackValue->Val->Pointer = ResultPtr; } else ProgramFail(Parser, "invalid operation"); break; } } /* evaluate a postfix operator */ void ExpressionPostfixOperator(struct ParseState *Parser, struct ExpressionStack **StackTop, enum LexToken Op, struct Value *TopValue) { debugf("ExpressionPostfixOperator()\n"); if (IS_NUMERIC_COERCIBLE(TopValue)) { long ResultInt = 0; long TopInt = ExpressionCoerceInteger(TopValue); switch (Op) { case TokenIncrement: ResultInt = ExpressionAssignInt(Parser, TopValue, TopInt+1, TRUE); break; case TokenDecrement: ResultInt = ExpressionAssignInt(Parser, TopValue, TopInt-1, TRUE); break; case TokenRightSquareBracket: ProgramFail(Parser, "not supported"); break; /* XXX */ case TokenCloseBracket: ProgramFail(Parser, "not supported"); break; /* XXX */ default: ProgramFail(Parser, "invalid operation"); break; } ExpressionPushInt(Parser, StackTop, ResultInt); } else if (TopValue->Typ->Base == TypePointer) { /* pointer postfix arithmetic */ int Size = TypeSize(TopValue->Typ->FromType, 0, TRUE); struct Value *StackValue; void *OrigPointer = TopValue->Val->Pointer; if (TopValue->Val->Pointer == NULL) ProgramFail(Parser, "invalid use of a NULL pointer"); if (!TopValue->IsLValue) ProgramFail(Parser, "can't assign to this"); switch (Op) { case TokenIncrement: TopValue->Val->Pointer = (void *)((char *)TopValue->Val->Pointer + Size); break; case TokenDecrement: TopValue->Val->Pointer = (void *)((char *)TopValue->Val->Pointer - Size); break; default: ProgramFail(Parser, "invalid operation"); break; } StackValue = ExpressionStackPushValueByType(Parser, StackTop, TopValue->Typ); StackValue->Val->Pointer = OrigPointer; } else ProgramFail(Parser, "invalid operation"); } /* evaluate an infix operator */ void ExpressionInfixOperator(struct ParseState *Parser, struct ExpressionStack **StackTop, enum LexToken Op, struct Value *BottomValue, struct Value *TopValue) { long ResultInt = 0; struct Value *StackValue; void *Pointer; debugf("ExpressionInfixOperator()\n"); if (BottomValue == NULL || TopValue == NULL) ProgramFail(Parser, "invalid expression"); if (Op == TokenLeftSquareBracket) { /* array index */ int ArrayIndex; struct Value *Result = NULL; if (!IS_NUMERIC_COERCIBLE(TopValue)) ProgramFail(Parser, "array index must be an integer"); ArrayIndex = ExpressionCoerceInteger(TopValue); /* make the array element result */ switch (BottomValue->Typ->Base) { case TypeArray: Result = VariableAllocValueFromExistingData(Parser, BottomValue->Typ->FromType, (union AnyValue *)(&BottomValue->Val->ArrayMem[0] + TypeSize(BottomValue->Typ, ArrayIndex, TRUE)), BottomValue->IsLValue, BottomValue->LValueFrom); break; case TypePointer: Result = VariableAllocValueFromExistingData(Parser, BottomValue->Typ->FromType, (union AnyValue *)((char *)BottomValue->Val->Pointer + TypeSize(BottomValue->Typ->FromType, 0, TRUE) * ArrayIndex), BottomValue->IsLValue, BottomValue->LValueFrom); break; default: ProgramFail(Parser, "this %t is not an array", BottomValue->Typ); } ExpressionStackPushValueNode(Parser, StackTop, Result); } else if (Op == TokenQuestionMark) ExpressionQuestionMarkOperator(Parser, StackTop, TopValue, BottomValue); else if (Op == TokenColon) ExpressionColonOperator(Parser, StackTop, TopValue, BottomValue); #ifndef NO_FP else if ( (TopValue->Typ == &FPType && BottomValue->Typ == &FPType) || (TopValue->Typ == &FPType && IS_NUMERIC_COERCIBLE(BottomValue)) || (IS_NUMERIC_COERCIBLE(TopValue) && BottomValue->Typ == &FPType) ) { /* floating point infix arithmetic */ int ResultIsInt = FALSE; double ResultFP = 0.0; double TopFP = (TopValue->Typ == &FPType) ? TopValue->Val->FP : (double)ExpressionCoerceInteger(TopValue); double BottomFP = (BottomValue->Typ == &FPType) ? BottomValue->Val->FP : (double)ExpressionCoerceInteger(BottomValue); switch (Op) { case TokenAssign: ResultFP = ExpressionAssignFP(Parser, BottomValue, TopFP); break; case TokenAddAssign: ResultFP = ExpressionAssignFP(Parser, BottomValue, BottomFP + TopFP); break; case TokenSubtractAssign: ResultFP = ExpressionAssignFP(Parser, BottomValue, BottomFP - TopFP); break; case TokenMultiplyAssign: ResultFP = ExpressionAssignFP(Parser, BottomValue, BottomFP * TopFP); break; case TokenDivideAssign: ResultFP = ExpressionAssignFP(Parser, BottomValue, BottomFP / TopFP); break; case TokenEqual: ResultInt = BottomFP == TopFP; ResultIsInt = TRUE; break; case TokenNotEqual: ResultInt = BottomFP != TopFP; ResultIsInt = TRUE; break; case TokenLessThan: ResultInt = BottomFP < TopFP; ResultIsInt = TRUE; break; case TokenGreaterThan: ResultInt = BottomFP > TopFP; ResultIsInt = TRUE; break; case TokenLessEqual: ResultInt = BottomFP <= TopFP; ResultIsInt = TRUE; break; case TokenGreaterEqual: ResultInt = BottomFP >= TopFP; ResultIsInt = TRUE; break; case TokenPlus: ResultFP = BottomFP + TopFP; break; case TokenMinus: ResultFP = BottomFP - TopFP; break; case TokenAsterisk: ResultFP = BottomFP * TopFP; break; case TokenSlash: ResultFP = BottomFP / TopFP; break; default: ProgramFail(Parser, "invalid operation"); break; } if (ResultIsInt) ExpressionPushInt(Parser, StackTop, ResultInt); else ExpressionPushFP(Parser, StackTop, ResultFP); } #endif else if (IS_NUMERIC_COERCIBLE(TopValue) && IS_NUMERIC_COERCIBLE(BottomValue)) { /* integer operation */ long TopInt = ExpressionCoerceInteger(TopValue); long BottomInt = ExpressionCoerceInteger(BottomValue); switch (Op) { case TokenAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, TopInt, FALSE); break; case TokenAddAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt + TopInt, FALSE); break; case TokenSubtractAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt - TopInt, FALSE); break; case TokenMultiplyAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt * TopInt, FALSE); break; case TokenDivideAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt / TopInt, FALSE); break; #ifndef NO_MODULUS case TokenModulusAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt % TopInt, FALSE); break; #endif case TokenShiftLeftAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt << TopInt, FALSE); break; case TokenShiftRightAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt >> TopInt, FALSE); break; case TokenArithmeticAndAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt & TopInt, FALSE); break; case TokenArithmeticOrAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt | TopInt, FALSE); break; case TokenArithmeticExorAssign: ResultInt = ExpressionAssignInt(Parser, BottomValue, BottomInt ^ TopInt, FALSE); break; case TokenLogicalOr: ResultInt = BottomInt || TopInt; break; case TokenLogicalAnd: ResultInt = BottomInt && TopInt; break; case TokenArithmeticOr: ResultInt = BottomInt | TopInt; break; case TokenArithmeticExor: ResultInt = BottomInt ^ TopInt; break; case TokenAmpersand: ResultInt = BottomInt & TopInt; break; case TokenEqual: ResultInt = BottomInt == TopInt; break; case TokenNotEqual: ResultInt = BottomInt != TopInt; break; case TokenLessThan: ResultInt = BottomInt < TopInt; break; case TokenGreaterThan: ResultInt = BottomInt > TopInt; break; case TokenLessEqual: ResultInt = BottomInt <= TopInt; break; case TokenGreaterEqual: ResultInt = BottomInt >= TopInt; break; case TokenShiftLeft: ResultInt = BottomInt << TopInt; break; case TokenShiftRight: ResultInt = BottomInt >> TopInt; break; case TokenPlus: ResultInt = BottomInt + TopInt; break; case TokenMinus: ResultInt = BottomInt - TopInt; break; case TokenAsterisk: ResultInt = BottomInt * TopInt; break; case TokenSlash: ResultInt = BottomInt / TopInt; break; #ifndef NO_MODULUS case TokenModulus: ResultInt = BottomInt % TopInt; break; #endif default: ProgramFail(Parser, "invalid operation"); break; } ExpressionPushInt(Parser, StackTop, ResultInt); } else if (BottomValue->Typ->Base == TypePointer && IS_NUMERIC_COERCIBLE(TopValue)) { /* pointer/integer infix arithmetic */ long TopInt = ExpressionCoerceInteger(TopValue); if (Op == TokenEqual || Op == TokenNotEqual) { /* comparison to a NULL pointer */ if (TopInt != 0) ProgramFail(Parser, "invalid operation"); if (Op == TokenEqual) ExpressionPushInt(Parser, StackTop, BottomValue->Val->Pointer == NULL); else ExpressionPushInt(Parser, StackTop, BottomValue->Val->Pointer != NULL); } else if (Op == TokenPlus || Op == TokenMinus) { /* pointer arithmetic */ int Size = TypeSize(BottomValue->Typ->FromType, 0, TRUE); Pointer = BottomValue->Val->Pointer; if (Pointer == NULL) ProgramFail(Parser, "invalid use of a NULL pointer"); if (Op == TokenPlus) Pointer = (void *)((char *)Pointer + TopInt * Size); else Pointer = (void *)((char *)Pointer - TopInt * Size); StackValue = ExpressionStackPushValueByType(Parser, StackTop, BottomValue->Typ); StackValue->Val->Pointer = Pointer; } else if (Op == TokenAssign && TopInt == 0) { /* assign a NULL pointer */ HeapUnpopStack(sizeof(struct Value)); ExpressionAssign(Parser, BottomValue, TopValue, FALSE, NULL, 0, FALSE); ExpressionStackPushValueNode(Parser, StackTop, BottomValue); } else if (Op == TokenAddAssign || Op == TokenSubtractAssign) { /* pointer arithmetic */ int Size = TypeSize(BottomValue->Typ->FromType, 0, TRUE); Pointer = BottomValue->Val->Pointer; if (Pointer == NULL) ProgramFail(Parser, "invalid use of a NULL pointer"); if (Op == TokenAddAssign) Pointer = (void *)((char *)Pointer + TopInt * Size); else Pointer = (void *)((char *)Pointer - TopInt * Size); HeapUnpopStack(sizeof(struct Value)); BottomValue->Val->Pointer = Pointer; ExpressionStackPushValueNode(Parser, StackTop, BottomValue); } else ProgramFail(Parser, "invalid operation"); } else if (BottomValue->Typ->Base == TypePointer && TopValue->Typ->Base == TypePointer && Op != TokenAssign) { /* pointer/pointer operations */ char *TopLoc = (char *)TopValue->Val->Pointer; char *BottomLoc = (char *)BottomValue->Val->Pointer; switch (Op) { case TokenEqual: ExpressionPushInt(Parser, StackTop, BottomLoc == TopLoc); break; case TokenNotEqual: ExpressionPushInt(Parser, StackTop, BottomLoc != TopLoc); break; case TokenMinus: ExpressionPushInt(Parser, StackTop, BottomLoc - TopLoc); break; default: ProgramFail(Parser, "invalid operation"); break; } } else if (Op == TokenAssign) { /* assign a non-numeric type */ HeapUnpopStack(sizeof(struct Value)); /* XXX - possible bug if lvalue is a temp value and takes more than sizeof(struct Value) */ ExpressionAssign(Parser, BottomValue, TopValue, FALSE, NULL, 0, FALSE); ExpressionStackPushValueNode(Parser, StackTop, BottomValue); } else if (Op == TokenCast) { /* cast a value to a different type */ /* XXX - possible bug if the destination type takes more than sizeof(struct Value) + sizeof(struct ValueType *) */ struct Value *ValueLoc = ExpressionStackPushValueByType(Parser, StackTop, BottomValue->Val->Typ); ExpressionAssign(Parser, ValueLoc, TopValue, TRUE, NULL, 0, TRUE); } else ProgramFail(Parser, "invalid operation"); } /* take the contents of the expression stack and compute the top until there's nothing greater than the given precedence */ void ExpressionStackCollapse(struct ParseState *Parser, struct ExpressionStack **StackTop, int Precedence, int *IgnorePrecedence) { int FoundPrecedence = Precedence; struct Value *TopValue; struct Value *BottomValue; struct ExpressionStack *TopStackNode = *StackTop; struct ExpressionStack *TopOperatorNode; debugf("ExpressionStackCollapse(%d):\n", Precedence); #ifdef DEBUG_EXPRESSIONS ExpressionStackShow(*StackTop); #endif while (TopStackNode != NULL && TopStackNode->Next != NULL && FoundPrecedence >= Precedence) { /* find the top operator on the stack */ if (TopStackNode->Order == OrderNone) TopOperatorNode = TopStackNode->Next; else TopOperatorNode = TopStackNode; FoundPrecedence = TopOperatorNode->Precedence; /* does it have a high enough precedence? */ if (FoundPrecedence >= Precedence && TopOperatorNode != NULL) { /* execute this operator */ switch (TopOperatorNode->Order) { case OrderPrefix: /* prefix evaluation */ debugf("prefix evaluation\n"); TopValue = TopStackNode->Val; /* pop the value and then the prefix operator - assume they'll still be there until we're done */ HeapPopStack(NULL, sizeof(struct ExpressionStack) + sizeof(struct Value) + TypeStackSizeValue(TopValue)); HeapPopStack(TopOperatorNode, sizeof(struct ExpressionStack)); *StackTop = TopOperatorNode->Next; /* do the prefix operation */ if (Parser->Mode == RunModeRun && FoundPrecedence < *IgnorePrecedence) { /* run the operator */ ExpressionPrefixOperator(Parser, StackTop, TopOperatorNode->Op, TopValue); } else { /* we're not running it so just return 0 */ ExpressionPushInt(Parser, StackTop, 0); } break; case OrderPostfix: /* postfix evaluation */ debugf("postfix evaluation\n"); TopValue = TopStackNode->Next->Val; /* pop the postfix operator and then the value - assume they'll still be there until we're done */ HeapPopStack(NULL, sizeof(struct ExpressionStack)); HeapPopStack(TopValue, sizeof(struct ExpressionStack) + sizeof(struct Value) + TypeStackSizeValue(TopValue)); *StackTop = TopStackNode->Next->Next; /* do the postfix operation */ if (Parser->Mode == RunModeRun && FoundPrecedence < *IgnorePrecedence) { /* run the operator */ ExpressionPostfixOperator(Parser, StackTop, TopOperatorNode->Op, TopValue); } else { /* we're not running it so just return 0 */ ExpressionPushInt(Parser, StackTop, 0); } break; case OrderInfix: /* infix evaluation */ debugf("infix evaluation\n"); TopValue = TopStackNode->Val; if (TopValue != NULL) { BottomValue = TopOperatorNode->Next->Val; /* pop a value, the operator and another value - assume they'll still be there until we're done */ HeapPopStack(NULL, sizeof(struct ExpressionStack) + sizeof(struct Value) + TypeStackSizeValue(TopValue)); HeapPopStack(NULL, sizeof(struct ExpressionStack)); HeapPopStack(BottomValue, sizeof(struct ExpressionStack) + sizeof(struct Value) + TypeStackSizeValue(BottomValue)); *StackTop = TopOperatorNode->Next->Next; /* do the infix operation */ if (Parser->Mode == RunModeRun && FoundPrecedence <= *IgnorePrecedence) { /* run the operator */ ExpressionInfixOperator(Parser, StackTop, TopOperatorNode->Op, BottomValue, TopValue); } else { /* we're not running it so just return 0 */ ExpressionPushInt(Parser, StackTop, 0); } } else FoundPrecedence = -1; break; case OrderNone: /* this should never happen */ assert(TopOperatorNode->Order != OrderNone); break; } /* if we've returned above the ignored precedence level turn ignoring off */ if (FoundPrecedence <= *IgnorePrecedence) *IgnorePrecedence = DEEP_PRECEDENCE; } #ifdef DEBUG_EXPRESSIONS ExpressionStackShow(*StackTop); #endif TopStackNode = *StackTop; } debugf("ExpressionStackCollapse() finished\n"); #ifdef DEBUG_EXPRESSIONS ExpressionStackShow(*StackTop); #endif } /* push an operator on to the expression stack */ void ExpressionStackPushOperator(struct ParseState *Parser, struct ExpressionStack **StackTop, enum OperatorOrder Order, enum LexToken Token, int Precedence) { struct ExpressionStack *StackNode = VariableAlloc(Parser, sizeof(struct ExpressionStack), FALSE); StackNode->Next = *StackTop; StackNode->Order = Order; StackNode->Op = Token; StackNode->Precedence = Precedence; *StackTop = StackNode; debugf("ExpressionStackPushOperator()\n"); #ifdef FANCY_ERROR_MESSAGES StackNode->Line = Parser->Line; StackNode->CharacterPos = Parser->CharacterPos; #endif #ifdef DEBUG_EXPRESSIONS ExpressionStackShow(*StackTop); #endif } /* do the '.' and '->' operators */ void ExpressionGetStructElement(struct ParseState *Parser, struct ExpressionStack **StackTop, enum LexToken Token) { struct Value *Ident; /* get the identifier following the '.' or '->' */ if (LexGetToken(Parser, &Ident, TRUE) != TokenIdentifier) ProgramFail(Parser, "need an structure or union member after '%s'", (Token == TokenDot) ? "." : "->"); if (Parser->Mode == RunModeRun) { /* look up the struct element */ struct Value *ParamVal = (*StackTop)->Val; struct Value *StructVal = ParamVal; struct ValueType *StructType = ParamVal->Typ; char *DerefDataLoc = (char *)ParamVal->Val; struct Value *MemberValue; struct Value *Result; /* if we're doing '->' dereference the struct pointer first */ if (Token == TokenArrow) DerefDataLoc = VariableDereferencePointer(Parser, ParamVal, &StructVal, NULL, &StructType, NULL); if (StructType->Base != TypeStruct && StructType->Base != TypeUnion) ProgramFail(Parser, "can't use '%s' on something that's not a struct or union %s : it's a %t", (Token == TokenDot) ? "." : "->", (Token == TokenArrow) ? "pointer" : "", ParamVal->Typ); if (!TableGet(StructType->Members, Ident->Val->Identifier, &MemberValue, NULL, NULL, NULL)) ProgramFail(Parser, "doesn't have a member called '%s'", Ident->Val->Identifier); /* pop the value - assume it'll still be there until we're done */ HeapPopStack(ParamVal, sizeof(struct ExpressionStack) + sizeof(struct Value) + TypeStackSizeValue(StructVal)); *StackTop = (*StackTop)->Next; /* make the result value for this member only */ Result = VariableAllocValueFromExistingData(Parser, MemberValue->Typ, (void *)(DerefDataLoc + MemberValue->Val->Integer), TRUE, (StructVal != NULL) ? StructVal->LValueFrom : NULL); ExpressionStackPushValueNode(Parser, StackTop, Result); } } /* parse an expression with operator precedence */ int ExpressionParse(struct ParseState *Parser, struct Value **Result) { struct Value *LexValue; int PrefixState = TRUE; int Done = FALSE; int BracketPrecedence = 0; int LocalPrecedence; int Precedence = 0; int IgnorePrecedence = DEEP_PRECEDENCE; struct ExpressionStack *StackTop = NULL; int TernaryDepth = 0; debugf("ExpressionParse():\n"); do { struct ParseState PreState; enum LexToken Token; ParserCopy(&PreState, Parser); Token = LexGetToken(Parser, &LexValue, TRUE); if ( ( ( (int)Token > TokenComma && (int)Token <= (int)TokenOpenBracket) || (Token == TokenCloseBracket && BracketPrecedence != 0)) && (Token != TokenColon || TernaryDepth > 0) ) { /* it's an operator with precedence */ if (PrefixState) { /* expect a prefix operator */ if (OperatorPrecedence[(int)Token].PrefixPrecedence == 0) ProgramFail(Parser, "operator not expected here"); LocalPrecedence = OperatorPrecedence[(int)Token].PrefixPrecedence; Precedence = BracketPrecedence + LocalPrecedence; if (Token == TokenOpenBracket) { /* it's either a new bracket level or a cast */ enum LexToken BracketToken = LexGetToken(Parser, &LexValue, FALSE); if (IS_TYPE_TOKEN(BracketToken) && (StackTop == NULL || StackTop->Op != TokenSizeof) ) { /* it's a cast - get the new type */ struct ValueType *CastType; char *CastIdentifier; struct Value *CastTypeValue; TypeParse(Parser, &CastType, &CastIdentifier, NULL); if (LexGetToken(Parser, &LexValue, TRUE) != TokenCloseBracket) ProgramFail(Parser, "brackets not closed"); /* scan and collapse the stack to the precedence of this infix cast operator, then push */ Precedence = BracketPrecedence + OperatorPrecedence[(int)TokenCast].PrefixPrecedence; ExpressionStackCollapse(Parser, &StackTop, Precedence+1, &IgnorePrecedence); CastTypeValue = VariableAllocValueFromType(Parser, &TypeType, FALSE, NULL, FALSE); CastTypeValue->Val->Typ = CastType; ExpressionStackPushValueNode(Parser, &StackTop, CastTypeValue); ExpressionStackPushOperator(Parser, &StackTop, OrderInfix, TokenCast, Precedence); } else { /* boost the bracket operator precedence */ BracketPrecedence += BRACKET_PRECEDENCE; } } else { /* scan and collapse the stack to the precedence of this operator, then push */ ExpressionStackCollapse(Parser, &StackTop, Precedence, &IgnorePrecedence); ExpressionStackPushOperator(Parser, &StackTop, OrderPrefix, Token, Precedence); } } else { /* expect an infix or postfix operator */ if (OperatorPrecedence[(int)Token].PostfixPrecedence != 0) { switch (Token) { case TokenCloseBracket: case TokenRightSquareBracket: if (BracketPrecedence == 0) { /* assume this bracket is after the end of the expression */ ParserCopy(Parser, &PreState); Done = TRUE; } else { /* collapse to the bracket precedence */ ExpressionStackCollapse(Parser, &StackTop, BracketPrecedence, &IgnorePrecedence); BracketPrecedence -= BRACKET_PRECEDENCE; } break; default: /* scan and collapse the stack to the precedence of this operator, then push */ Precedence = BracketPrecedence + OperatorPrecedence[(int)Token].PostfixPrecedence; ExpressionStackCollapse(Parser, &StackTop, Precedence, &IgnorePrecedence); ExpressionStackPushOperator(Parser, &StackTop, OrderPostfix, Token, Precedence); break; } } else if (OperatorPrecedence[(int)Token].InfixPrecedence != 0) { /* scan and collapse the stack, then push */ Precedence = BracketPrecedence + OperatorPrecedence[(int)Token].InfixPrecedence; /* for right to left order, only go down to the next higher precedence so we evaluate it in reverse order */ /* for left to right order, collapse down to this precedence so we evaluate it in forward order */ if (IS_LEFT_TO_RIGHT(OperatorPrecedence[(int)Token].InfixPrecedence)) ExpressionStackCollapse(Parser, &StackTop, Precedence, &IgnorePrecedence); else ExpressionStackCollapse(Parser, &StackTop, Precedence+1, &IgnorePrecedence); if (Token == TokenDot || Token == TokenArrow) { ExpressionGetStructElement(Parser, &StackTop, Token); /* this operator is followed by a struct element so handle it as a special case */ } else { /* if it's a && or || operator we may not need to evaluate the right hand side of the expression */ if ( (Token == TokenLogicalOr || Token == TokenLogicalAnd) && IS_NUMERIC_COERCIBLE(StackTop->Val)) { long LHSInt = ExpressionCoerceInteger(StackTop->Val); if ( ( (Token == TokenLogicalOr && LHSInt) || (Token == TokenLogicalAnd && !LHSInt) ) && (IgnorePrecedence > Precedence) ) IgnorePrecedence = Precedence; } /* push the operator on the stack */ ExpressionStackPushOperator(Parser, &StackTop, OrderInfix, Token, Precedence); PrefixState = TRUE; switch (Token) { case TokenQuestionMark: TernaryDepth++; break; case TokenColon: TernaryDepth--; break; default: break; } } /* treat an open square bracket as an infix array index operator followed by an open bracket */ if (Token == TokenLeftSquareBracket) { /* boost the bracket operator precedence, then push */ BracketPrecedence += BRACKET_PRECEDENCE; } } else ProgramFail(Parser, "operator not expected here"); } } else if (Token == TokenIdentifier) { /* it's a variable, function or a macro */ if (!PrefixState) ProgramFail(Parser, "identifier not expected here"); if (LexGetToken(Parser, NULL, FALSE) == TokenOpenBracket) { ExpressionParseFunctionCall(Parser, &StackTop, LexValue->Val->Identifier, Parser->Mode == RunModeRun && Precedence < IgnorePrecedence); } else { if (Parser->Mode == RunModeRun && Precedence < IgnorePrecedence) { struct Value *VariableValue = NULL; VariableGet(Parser, LexValue->Val->Identifier, &VariableValue); if (VariableValue->Typ->Base == TypeMacro) { /* evaluate a macro as a kind of simple subroutine */ struct ParseState MacroParser; struct Value *MacroResult; ParserCopy(&MacroParser, &VariableValue->Val->MacroDef.Body); if (VariableValue->Val->MacroDef.NumParams != 0) ProgramFail(&MacroParser, "macro arguments missing"); if (!ExpressionParse(&MacroParser, &MacroResult) || LexGetToken(&MacroParser, NULL, FALSE) != TokenEndOfFunction) ProgramFail(&MacroParser, "expression expected"); ExpressionStackPushValueNode(Parser, &StackTop, MacroResult); } else if (VariableValue->Typ == TypeVoid) ProgramFail(Parser, "a void value isn't much use here"); else ExpressionStackPushLValue(Parser, &StackTop, VariableValue, 0); /* it's a value variable */ } else /* push a dummy value */ ExpressionPushInt(Parser, &StackTop, 0); } /* if we've successfully ignored the RHS turn ignoring off */ if (Precedence <= IgnorePrecedence) IgnorePrecedence = DEEP_PRECEDENCE; PrefixState = FALSE; } else if ((int)Token > TokenCloseBracket && (int)Token <= TokenCharacterConstant) { /* it's a value of some sort, push it */ if (!PrefixState) ProgramFail(Parser, "value not expected here"); PrefixState = FALSE; ExpressionStackPushValue(Parser, &StackTop, LexValue); } else if (IS_TYPE_TOKEN(Token)) { /* it's a type. push it on the stack like a value. this is used in sizeof() */ struct ValueType *Typ; char *Identifier; struct Value *TypeValue; if (!PrefixState) ProgramFail(Parser, "type not expected here"); PrefixState = FALSE; ParserCopy(Parser, &PreState); TypeParse(Parser, &Typ, &Identifier, NULL); TypeValue = VariableAllocValueFromType(Parser, &TypeType, FALSE, NULL, FALSE); TypeValue->Val->Typ = Typ; ExpressionStackPushValueNode(Parser, &StackTop, TypeValue); } else { /* it isn't a token from an expression */ ParserCopy(Parser, &PreState); Done = TRUE; } } while (!Done); /* check that brackets have been closed */ if (BracketPrecedence > 0) ProgramFail(Parser, "brackets not closed"); /* scan and collapse the stack to precedence 0 */ ExpressionStackCollapse(Parser, &StackTop, 0, &IgnorePrecedence); /* fix up the stack and return the result if we're in run mode */ if (StackTop != NULL) { /* all that should be left is a single value on the stack */ if (Parser->Mode == RunModeRun) { if (StackTop->Order != OrderNone || StackTop->Next != NULL) ProgramFail(Parser, "invalid expression"); *Result = StackTop->Val; HeapPopStack(StackTop, sizeof(struct ExpressionStack)); } else HeapPopStack(StackTop->Val, sizeof(struct ExpressionStack) + sizeof(struct Value) + TypeStackSizeValue(StackTop->Val)); } debugf("ExpressionParse() done\n\n"); #ifdef DEBUG_EXPRESSIONS ExpressionStackShow(StackTop); #endif return StackTop != NULL; } /* do a parameterised macro call */ void ExpressionParseMacroCall(struct ParseState *Parser, struct ExpressionStack **StackTop, const char *MacroName, struct MacroDef *MDef) { struct Value *ReturnValue = NULL; struct Value *Param; struct Value **ParamArray = NULL; int ArgCount; enum LexToken Token; if (Parser->Mode == RunModeRun) { /* create a stack frame for this macro */ #ifndef NO_FP ExpressionStackPushValueByType(Parser, StackTop, &FPType); /* largest return type there is */ #else ExpressionStackPushValueByType(Parser, StackTop, &IntType); /* largest return type there is */ #endif ReturnValue = (*StackTop)->Val; HeapPushStackFrame(); ParamArray = HeapAllocStack(sizeof(struct Value *) * MDef->NumParams); if (ParamArray == NULL) ProgramFail(Parser, "out of memory"); } else ExpressionPushInt(Parser, StackTop, 0); /* parse arguments */ ArgCount = 0; do { if (ExpressionParse(Parser, &Param)) { if (Parser->Mode == RunModeRun) { if (ArgCount < MDef->NumParams) ParamArray[ArgCount] = Param; else ProgramFail(Parser, "too many arguments to %s()", MacroName); } ArgCount++; Token = LexGetToken(Parser, NULL, TRUE); if (Token != TokenComma && Token != TokenCloseBracket) ProgramFail(Parser, "comma expected"); } else { /* end of argument list? */ Token = LexGetToken(Parser, NULL, TRUE); if (!TokenCloseBracket) ProgramFail(Parser, "bad argument"); } } while (Token != TokenCloseBracket); if (Parser->Mode == RunModeRun) { /* evaluate the macro */ struct ParseState MacroParser; int Count; struct Value *EvalValue; if (ArgCount < MDef->NumParams) ProgramFail(Parser, "not enough arguments to '%s'", MacroName); if (MDef->Body.Pos == NULL) ProgramFail(Parser, "'%s' is undefined", MacroName); ParserCopy(&MacroParser, &MDef->Body); VariableStackFrameAdd(Parser, MacroName, 0); TopStackFrame->NumParams = ArgCount; TopStackFrame->ReturnValue = ReturnValue; for (Count = 0; Count < MDef->NumParams; Count++) VariableDefine(Parser, MDef->ParamName[Count], ParamArray[Count], NULL, TRUE); ExpressionParse(&MacroParser, &EvalValue); ExpressionAssign(Parser, ReturnValue, EvalValue, TRUE, MacroName, 0, FALSE); VariableStackFramePop(Parser); HeapPopStackFrame(); } } /* do a function call */ void ExpressionParseFunctionCall(struct ParseState *Parser, struct ExpressionStack **StackTop, const char *FuncName, int RunIt) { struct Value *ReturnValue = NULL; struct Value *FuncValue; struct Value *Param; struct Value **ParamArray = NULL; int ArgCount; enum LexToken Token = LexGetToken(Parser, NULL, TRUE); /* open bracket */ enum RunMode OldMode = Parser->Mode; if (RunIt) { /* get the function definition */ VariableGet(Parser, FuncName, &FuncValue); if (FuncValue->Typ->Base == TypeMacro) { /* this is actually a macro, not a function */ ExpressionParseMacroCall(Parser, StackTop, FuncName, &FuncValue->Val->MacroDef); return; } if (FuncValue->Typ->Base != TypeFunction) ProgramFail(Parser, "%t is not a function - can't call", FuncValue->Typ); ExpressionStackPushValueByType(Parser, StackTop, FuncValue->Val->FuncDef.ReturnType); ReturnValue = (*StackTop)->Val; HeapPushStackFrame(); ParamArray = HeapAllocStack(sizeof(struct Value *) * FuncValue->Val->FuncDef.NumParams); if (ParamArray == NULL) ProgramFail(Parser, "out of memory"); } else { ExpressionPushInt(Parser, StackTop, 0); Parser->Mode = RunModeSkip; } /* parse arguments */ ArgCount = 0; do { if (RunIt && ArgCount < FuncValue->Val->FuncDef.NumParams) ParamArray[ArgCount] = VariableAllocValueFromType(Parser, FuncValue->Val->FuncDef.ParamType[ArgCount], FALSE, NULL, FALSE); if (ExpressionParse(Parser, &Param)) { if (RunIt) { if (ArgCount < FuncValue->Val->FuncDef.NumParams) { ExpressionAssign(Parser, ParamArray[ArgCount], Param, TRUE, FuncName, ArgCount+1, FALSE); VariableStackPop(Parser, Param); } else { if (!FuncValue->Val->FuncDef.VarArgs) ProgramFail(Parser, "too many arguments to %s()", FuncName); } } ArgCount++; Token = LexGetToken(Parser, NULL, TRUE); if (Token != TokenComma && Token != TokenCloseBracket) ProgramFail(Parser, "comma expected"); } else { /* end of argument list? */ Token = LexGetToken(Parser, NULL, TRUE); if (!TokenCloseBracket) ProgramFail(Parser, "bad argument"); } } while (Token != TokenCloseBracket); if (RunIt) { /* run the function */ if (ArgCount < FuncValue->Val->FuncDef.NumParams) ProgramFail(Parser, "not enough arguments to '%s'", FuncName); if (FuncValue->Val->FuncDef.Intrinsic == NULL) { /* run a user-defined function */ struct ParseState FuncParser; int Count; if (FuncValue->Val->FuncDef.Body.Pos == NULL) ProgramFail(Parser, "'%s' is undefined", FuncName); ParserCopy(&FuncParser, &FuncValue->Val->FuncDef.Body); VariableStackFrameAdd(Parser, FuncName, FuncValue->Val->FuncDef.Intrinsic ? FuncValue->Val->FuncDef.NumParams : 0); TopStackFrame->NumParams = ArgCount; TopStackFrame->ReturnValue = ReturnValue; for (Count = 0; Count < FuncValue->Val->FuncDef.NumParams; Count++) VariableDefine(Parser, FuncValue->Val->FuncDef.ParamName[Count], ParamArray[Count], NULL, TRUE); if (ParseStatement(&FuncParser, TRUE) != ParseResultOk) ProgramFail(&FuncParser, "function body expected"); if (FuncValue->Val->FuncDef.ReturnType != &VoidType && FuncParser.Mode == RunIt) ProgramFail(&FuncParser, "no value returned from a function returning %t", FuncValue->Val->FuncDef.ReturnType); VariableStackFramePop(Parser); } else FuncValue->Val->FuncDef.Intrinsic(Parser, ReturnValue, ParamArray, ArgCount); HeapPopStackFrame(); } Parser->Mode = OldMode; } /* parse an expression */ long ExpressionParseInt(struct ParseState *Parser) { struct Value *Val; long Result = 0; if (!ExpressionParse(Parser, &Val)) ProgramFail(Parser, "expression expected"); if (Parser->Mode == RunModeRun) { if (!IS_NUMERIC_COERCIBLE(Val)) ProgramFail(Parser, "integer value expected instead of %t", Val->Typ); Result = ExpressionCoerceInteger(Val); VariableStackPop(Parser, Val); } return Result; }