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windows-xp/Source/XPSP1/NT/sdktools/asn1/asn1c/defs.c

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/* Copyright (C) Boris Nikolaus, Germany, 1996-1997. All rights reserved. */
/* Copyright (C) Microsoft Corporation, 1997-1998. All rights reserved. */
#include "precomp.h"
#include "error.h"
/* allocate a new value of type _T, copy *_src and return this duplicate */
#define RETDUP(_T, _src) _T *ret; ret = (_T *)malloc(sizeof(_T)); *ret = *(_src); return ret
/* constructor of Assignment_t */
Assignment_t *
NewAssignment(Assignment_e type)
{
Assignment_t *ret;
ret = (Assignment_t *)malloc(sizeof(Assignment_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Assignment_t));
// ret->Next = NULL;
// ret->Identifier = NULL;
// ret->Module = NULL;
// ret->Flags = 0;
// ret->fImportedLocalDuplicate = 0;
// ret->fGhost = 0;
ret->eDefTagType = eTagType_Unknown;
ret->Type = type;
switch (type) {
case eAssignment_Undefined:
break;
case eAssignment_ModuleIdentifier:
break;
case eAssignment_Type:
// ret->U.Type.Type = NULL;
break;
case eAssignment_Value:
// ret->U.Value.Value = NULL;
break;
case eAssignment_ObjectClass:
// ret->U.ObjectClass.ObjectClass = NULL;
break;
case eAssignment_Object:
// ret->U.Object.Object = NULL;
break;
case eAssignment_ObjectSet:
// ret->U.ObjectSet.ObjectSet = NULL;
break;
case eAssignment_Reference:
// ret->U.Reference.Identifier = NULL;
// ret->U.Reference.Module = NULL;
break;
}
return ret;
}
/* copy constructor of Assignment_t */
Assignment_t *
DupAssignment(Assignment_t *src)
{
RETDUP(Assignment_t, src);
}
/* find an assignment by name+moduleidentifier in an assignment list */
Assignment_t *
FindAssignment(AssignmentList_t ass, Assignment_e type, char *identifier, ModuleIdentifier_t *module)
{
Assignment_t *a;
Assignment_e at;
for (a = ass; a; a = a->Next) {
if (a->Type == eAssignment_NextPass)
continue;
if (type == eAssignment_Undefined) {
at = eAssignment_Undefined;
} else {
at = GetAssignmentType(ass, a);
}
if (at == type &&
!strcmp(a->Identifier, identifier) &&
!CmpModuleIdentifier(ass, a->Module, module))
return a;
}
return NULL;
}
/* find an exported assignment by name+moduleidentifier in an assignment list */
Assignment_t *
FindExportedAssignment(AssignmentList_t ass, Assignment_e type, char *identifier, ModuleIdentifier_t *module)
{
Assignment_t *a;
Assignment_e at;
for (a = ass; a; a = a->Next) {
if (a->Type == eAssignment_NextPass ||
!(a->Flags & eAssignmentFlags_Exported))
continue;
if (type == eAssignment_Undefined) {
at = eAssignment_Undefined;
} else {
at = GetAssignmentType(ass, a);
}
if (at == type &&
!strcmp(a->Identifier, identifier) &&
!CmpModuleIdentifier(ass, a->Module, module))
return a;
}
return NULL;
}
/* find an assignment by name+moduleidentifier in an assignment list */
/* do not use assignments of previous parsing passes */
Assignment_t *
FindAssignmentInCurrentPass(AssignmentList_t ass, char *identifier, ModuleIdentifier_t *module)
{
for (; ass; ass = ass->Next) {
if (ass->Type == eAssignment_NextPass)
return NULL;
if (!strcmp(ass->Identifier, identifier) &&
!CmpModuleIdentifier(ass, ass->Module, module))
return ass;
}
return NULL;
}
/* resolve assignment references */
Assignment_t *
GetAssignment(AssignmentList_t ass, Assignment_t *a)
{
while (a && a->Type == eAssignment_Reference) {
a = FindAssignment(ass, eAssignment_Undefined,
a->U.Reference.Identifier, a->U.Reference.Module);
}
return a;
}
/* get type of an assignment */
Assignment_e
GetAssignmentType(AssignmentList_t ass, Assignment_t *a)
{
a = GetAssignment(ass, a);
return a ? a->Type : eAssignment_Undefined;
}
/* assign a type */
/* lhs must be an type reference */
/* returns 0 if type is already defined in current parser pass */
int
AssignType(AssignmentList_t *ass, Type_t *lhs, Type_t *rhs)
{
Assignment_t *a;
if (lhs->Type != eType_Reference)
MyAbort();
for (a = *ass; a && a->Type != eAssignment_NextPass; a = a->Next) {
if (a->Type == eAssignment_Type &&
!strcmp(a->Identifier, lhs->U.Reference.Identifier) &&
!CmpModuleIdentifier(*ass, a->Module, lhs->U.Reference.Module))
return 0;
}
// propagate the directives from rhs to lhs
PropagatePrivateDirectives(lhs, &(rhs->PrivateDirectives));
// create new assignment
a = NewAssignment(eAssignment_Type);
a->Identifier = lhs->U.Reference.Identifier;
a->Module = lhs->U.Reference.Module;
a->U.Type.Type = rhs;
a->Next = *ass;
*ass = a;
return 1;
}
/* assign a value */
/* lhs must be an value reference */
/* returns 0 if value is already defined in current parser pass */
int
AssignValue(AssignmentList_t *ass, Value_t *lhs, Value_t *rhs)
{
Assignment_t *a;
if (lhs->Type)
MyAbort();
for (a = *ass; a && a->Type != eAssignment_NextPass; a = a->Next) {
if (a->Type == eAssignment_Value &&
!strcmp(a->Identifier, lhs->U.Reference.Identifier) &&
!CmpModuleIdentifier(*ass, a->Module, lhs->U.Reference.Module))
return 0;
}
a = NewAssignment(eAssignment_Value);
a->Identifier = lhs->U.Reference.Identifier;
a->Module = lhs->U.Reference.Module;
a->U.Value.Value = rhs;
ASSERT(rhs);
if (rhs->Type && rhs->Type->Type == eType_ObjectIdentifier)
{
AddDefinedOID(a->Identifier, rhs);
}
a->Next = *ass;
*ass = a;
return 1;
}
/* assign a object class */
/* lhs must be an object class reference */
/* returns 0 if object class is already defined in current parser pass */
int
AssignObjectClass(AssignmentList_t *ass, ObjectClass_t *lhs, ObjectClass_t *rhs)
{
Assignment_t *a;
if (lhs->Type != eObjectClass_Reference)
MyAbort();
for (a = *ass; a && a->Type != eAssignment_NextPass; a = a->Next) {
if (a->Type == eAssignment_ObjectClass &&
!strcmp(a->Identifier, lhs->U.Reference.Identifier) &&
!CmpModuleIdentifier(*ass, a->Module, lhs->U.Reference.Module))
return 0;
}
a = NewAssignment(eAssignment_ObjectClass);
a->Identifier = lhs->U.Reference.Identifier;
a->Module = lhs->U.Reference.Module;
a->U.ObjectClass.ObjectClass = rhs;
a->Next = *ass;
*ass = a;
return 1;
}
/* assign a object */
/* lhs must be an object reference */
/* returns 0 if object is already defined in current parser pass */
int
AssignObject(AssignmentList_t *ass, Object_t *lhs, Object_t *rhs)
{
Assignment_t *a;
if (lhs->Type != eObject_Reference)
MyAbort();
for (a = *ass; a && a->Type != eAssignment_NextPass; a = a->Next) {
if (a->Type == eAssignment_Object &&
!strcmp(a->Identifier, lhs->U.Reference.Identifier) &&
!CmpModuleIdentifier(*ass, a->Module, lhs->U.Reference.Module))
return 0;
}
a = NewAssignment(eAssignment_Object);
a->Identifier = lhs->U.Reference.Identifier;
a->Module = lhs->U.Reference.Module;
a->U.Object.Object = rhs;
a->Next = *ass;
*ass = a;
return 1;
}
/* assign a object set */
/* lhs must be an object set reference */
/* returns 0 if type is already defined in current parser pass */
int
AssignObjectSet(AssignmentList_t *ass, ObjectSet_t *lhs, ObjectSet_t *rhs)
{
Assignment_t *a;
if (lhs->Type != eObjectSet_Reference)
MyAbort();
for (a = *ass; a && a->Type != eAssignment_NextPass; a = a->Next) {
if (a->Type == eAssignment_ObjectSet &&
!strcmp(a->Identifier, lhs->U.Reference.Identifier) &&
!CmpModuleIdentifier(*ass, a->Module, lhs->U.Reference.Module))
return 0;
}
a = NewAssignment(eAssignment_ObjectSet);
a->Identifier = lhs->U.Reference.Identifier;
a->Module = lhs->U.Reference.Module;
a->U.ObjectSet.ObjectSet = rhs;
a->Next = *ass;
*ass = a;
return 1;
}
/* assign a macro */
/* lhs must be an macro reference */
/* returns 0 if macro is already defined in current parser pass */
int
AssignMacro(AssignmentList_t *ass, Macro_t *lhs, Macro_t *rhs)
{
Assignment_t *a;
if (lhs->Type != eMacro_Reference)
MyAbort();
for (a = *ass; a && a->Type != eAssignment_NextPass; a = a->Next) {
if (a->Type == eAssignment_Macro &&
!strcmp(a->Identifier, lhs->U.Reference.Identifier) &&
!CmpModuleIdentifier(*ass, a->Module, lhs->U.Reference.Module))
return 0;
}
a = NewAssignment(eAssignment_Macro);
a->Identifier = lhs->U.Reference.Identifier;
a->Module = lhs->U.Reference.Module;
a->U.Macro.Macro = rhs;
a->Next = *ass;
*ass = a;
return 1;
}
/* define a module identifier */
/* returns 0 if module identifier is already defined in current parser pass */
int
AssignModuleIdentifier(AssignmentList_t *ass, ModuleIdentifier_t *module)
{
Assignment_t *a;
for (a = *ass; a && a->Type != eAssignment_NextPass; a = a->Next) {
if (a->Type == eAssignment_ModuleIdentifier &&
!CmpModuleIdentifier(*ass, a->Module, module))
return 0;
}
a = NewAssignment(eAssignment_ModuleIdentifier);
a->Identifier = "<module>";
a->Module = module;
a->Next = *ass;
*ass = a;
return 1;
}
/* constructor of UndefinedSymbol_t */
UndefinedSymbol_t *
NewUndefinedSymbol(UndefinedSymbol_e type, Assignment_e reftype)
{
UndefinedSymbol_t *ret;
ret = (UndefinedSymbol_t *)malloc(sizeof(UndefinedSymbol_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(UndefinedSymbol_t));
ret->Type = type;
ret->U.Symbol.ReferenceType = reftype;
// ret->U.Symbol.Identifier = NULL;
// ret->U.Symbol.Module = NULL;
// ret->Next = NULL;
return ret;
}
/* constructor of UndefinedSymbol_t */
UndefinedSymbol_t *
NewUndefinedField(UndefinedSymbol_e type, ObjectClass_t *oc, Settings_e reffieldtype)
{
UndefinedSymbol_t *ret;
if (oc->Type != eObjectClass_Reference)
MyAbort();
ret = (UndefinedSymbol_t *)malloc(sizeof(UndefinedSymbol_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(UndefinedSymbol_t));
ret->Type = type;
ret->U.Field.ReferenceFieldType = reffieldtype;
// ret->U.Field.Identifier = NULL;
// ret->U.Field.Module = NULL;
ret->U.Field.ObjectClass = oc;
// ret->Next = NULL;
return ret;
}
/* find an undefined symbol by type/name/moduleidentifier in a list of */
/* undefined symbols */
UndefinedSymbol_t *
FindUndefinedSymbol(AssignmentList_t ass, UndefinedSymbolList_t u, Assignment_e type, char *ide, ModuleIdentifier_t *mod)
{
for (; u; u = u->Next) {
if (u->Type != eUndefinedSymbol_SymbolNotDefined &&
u->Type != eUndefinedSymbol_SymbolNotExported)
continue;
if ((type == eAssignment_Undefined ||
u->U.Symbol.ReferenceType == eAssignment_Undefined ||
u->U.Symbol.ReferenceType == type) &&
!strcmp(u->U.Symbol.Identifier, ide) &&
!CmpModuleIdentifier(ass, u->U.Field.Module, mod))
return u;
}
return NULL;
}
/* find an undefined field by type/objectclass/name/moduleidentifier in a */
/* list of undefined symbols */
UndefinedSymbol_t *
FindUndefinedField(AssignmentList_t ass, UndefinedSymbolList_t u, Settings_e fieldtype, ObjectClass_t *oc, char *ide, ModuleIdentifier_t *mod)
{
for (; u; u = u->Next) {
if (u->Type != eUndefinedSymbol_FieldNotDefined &&
u->Type != eUndefinedSymbol_FieldNotExported)
continue;
if ((fieldtype == eSetting_Undefined ||
u->U.Field.ReferenceFieldType == eSetting_Undefined ||
u->U.Field.ReferenceFieldType == fieldtype) &&
!strcmp(u->U.Field.Identifier, ide) &&
GetObjectClass(ass, oc) ==
GetObjectClass(ass, u->U.Field.ObjectClass) &&
!CmpModuleIdentifier(ass, u->U.Field.Module, mod))
return u;
}
return NULL;
}
/* constructor of Type_t */
Type_t *
NewType(Type_e type)
{
Type_t *ret;
ret = (Type_t *)malloc(sizeof(Type_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Type_t));
ret->Type = type;
// ret->Tags = NULL;
// ret->AllTags = NULL;
// ret->FirstTags = NULL;
// ret->Constraints = NULL;
// ret->Directives = NULL;
// ret->Flags = 0;
ret->Rules = eTypeRules_Normal;
ret->TagDefault = eTagType_Unknown;
ret->ExtensionDefault = eExtensionType_None;
ret->PERConstraints.Value.Type = eExtension_Unconstrained;
// ret->PERConstraints.Value.Root = NULL;
// ret->PERConstraints.Value.Additional = NULL;
ret->PERConstraints.Size.Type = eExtension_Unconstrained;
// ret->PERConstraints.Size.Root = NULL;
// ret->PERConstraints.Size.Additional = NULL;
ret->PERConstraints.PermittedAlphabet.Type = eExtension_Unconstrained;
// ret->PERConstraints.PermittedAlphabet.Root = NULL;
// ret->PERConstraints.PermittedAlphabet.Additional = NULL;
// ret->PrivateDirectives = { 0 };
switch (type) {
case eType_Boolean:
break;
case eType_Integer:
case eType_Enumerated:
case eType_BitString:
// ret->U.IEB.NamedNumbers = NULL;
break;
case eType_OctetString:
case eType_UTF8String:
break;
case eType_Null:
break;
case eType_Sequence:
case eType_Set:
case eType_Choice:
case eType_Real:
case eType_EmbeddedPdv:
case eType_External:
case eType_CharacterString:
case eType_InstanceOf:
// ret->U.SSC.Components = NULL;
// ret->U.SSC.Optionals = 0;
// ret->U.SSC.Alternatives = 0;
// ret->U.SSC.Extensions = 0;
// ret->U.SSC.Autotag[0] = 0;
// ret->U.SSC.Autotag[1] = 0;
break;
case eType_SequenceOf:
case eType_SetOf:
// ret->U.SS.Type = NULL;
// ret->U.SS.Directives = NULL;
break;
case eType_Selection:
// ret->U.Selection.Identifier = NULL;
// ret->U.Selection.Type = NULL;
break;
case eType_ObjectIdentifier:
break;
case eType_BMPString:
break;
case eType_GeneralString:
break;
case eType_GraphicString:
break;
case eType_IA5String:
break;
case eType_ISO646String:
break;
case eType_NumericString:
break;
case eType_PrintableString:
break;
case eType_TeletexString:
break;
case eType_T61String:
break;
case eType_UniversalString:
break;
case eType_VideotexString:
break;
case eType_VisibleString:
break;
case eType_GeneralizedTime:
break;
case eType_UTCTime:
break;
case eType_ObjectDescriptor:
break;
case eType_Undefined:
break;
case eType_RestrictedString:
break;
case eType_Reference:
// ret->U.Reference.Identifier = NULL;
// ret->U.Reference.Module = NULL;
break;
case eType_FieldReference:
// ret->U.FieldReference.ObjectClass = NULL;
// ret->U.FieldReference.Identifier = NULL;
break;
case eType_Macro:
// ret->U.Macro.Macro = NULL;
// ret->U.Macro.LocalAssignments = NULL;
break;
}
return ret;
}
/* copy constructor of Type_t */
Type_t *
DupType(Type_t *src)
{
RETDUP(Type_t, src);
}
/* resolve field reference */
FieldSpec_t *
GetReferencedFieldSpec(AssignmentList_t ass, Type_t *type, ObjectClass_t **objectclass)
{
FieldSpec_t *fs;
ObjectClass_t *oc;
if (type->Type != eType_FieldReference)
MyAbort();
oc = type->U.FieldReference.ObjectClass;
oc = GetObjectClass(ass, oc);
if (!oc)
return NULL;
fs = GetFieldSpec(ass, FindFieldSpec(oc->U.ObjectClass.FieldSpec,
type->U.FieldReference.Identifier));
if (!fs)
return NULL;
if (fs->Type == eFieldSpec_Object)
oc = fs->U.Object.ObjectClass;
else if (fs->Type == eFieldSpec_ObjectSet)
oc = fs->U.ObjectSet.ObjectClass;
else
return NULL;
if (objectclass)
*objectclass = oc;
return GetFieldSpec(ass, fs);
}
/* resolve type reference */
Type_t *
GetReferencedType(AssignmentList_t ass, Type_t *type)
{
Assignment_t *a;
FieldSpec_t *fs;
switch (type->Type) {
case eType_Reference:
a = FindAssignment(ass, eAssignment_Type, type->U.Reference.Identifier,
type->U.Reference.Module);
a = GetAssignment(ass, a);
if (!a)
return NULL;
return a->U.Type.Type;
case eType_FieldReference:
fs = GetReferencedFieldSpec(ass, type, NULL);
if (!fs)
return NULL;
switch (fs->Type) {
case eFieldSpec_FixedTypeValue:
return fs->U.FixedTypeValue.Type;
case eFieldSpec_FixedTypeValueSet:
return fs->U.FixedTypeValueSet.Type;
case eFieldSpec_Type:
case eFieldSpec_VariableTypeValue:
case eFieldSpec_VariableTypeValueSet:
return Builtin_Type_Open;
default:
return NULL;
}
/*NOTREACHED*/
default:
MyAbort();
/*NOTREACHED*/
}
return NULL;
}
/* constructor of Component_t */
Component_t *
NewComponent(Components_e type)
{
Component_t *ret;
ret = (Component_t *)malloc(sizeof(Component_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Component_t));
ret->Type = type;
// ret->Next = NULL;
switch (type) {
case eComponent_Normal:
// ret->U.Normal.NamedType = NULL;
break;
case eComponent_Optional:
// ret->U.Optional.NamedType = NULL;
break;
case eComponent_Default:
// ret->U.Default.NamedType = NULL;
// ret->U.Default.Value = NULL;
break;
case eComponent_ComponentsOf:
// ret->U.ComponentsOf.Type = NULL;
break;
case eComponent_ExtensionMarker:
/*ret->U.ExtensionMarker.ExceptionSpec = NULL;*/
break;
}
return ret;
}
/* copy constructor of Component_t */
Component_t *
DupComponent(Component_t *src)
{
RETDUP(Component_t, src);
}
/* find a component by name in a list of components */
Component_t *
FindComponent(AssignmentList_t ass, ComponentList_t components, char *identifier)
{
Component_t *c;
NamedType_t *namedType;
while (components) {
switch (components->Type) {
case eComponent_Normal:
case eComponent_Optional:
case eComponent_Default:
namedType = components->U.NOD.NamedType;
if (namedType && !strcmp(namedType->Identifier, identifier))
return components;
break;
case eComponent_ComponentsOf:
switch (GetTypeType(ass, components->U.ComponentsOf.Type)) {
case eType_Sequence:
case eType_Set:
case eType_Choice:
case eType_External:
case eType_EmbeddedPdv:
case eType_CharacterString:
case eType_Real:
case eType_InstanceOf:
c = FindComponent(ass,
GetType(ass, components->U.ComponentsOf.Type)->
U.SSC.Components, identifier);
if (c)
return c;
break;
default:
break;
}
break;
}
components = components->Next;
}
return NULL;
}
/* constructor of NamedType_t */
NamedType_t *
NewNamedType(char *identifier, Type_t *type)
{
NamedType_t *ret;
ret = (NamedType_t *)malloc(sizeof(NamedType_t));
if (! ret)
return NULL;
ret->Type = type;
ret->Identifier = identifier;
return ret;
}
/* constructor of NamedValue_t */
NamedValue_t *
NewNamedValue(char *identifier, Value_t *value)
{
NamedValue_t *ret;
ret = (NamedValue_t *)malloc(sizeof(NamedValue_t));
if (! ret)
return NULL;
ret->Next = NULL;
ret->Value = value;
ret->Identifier = identifier;
return ret;
}
/* copy constructor of NamedValue_t */
NamedValue_t *
DupNamedValue(NamedValue_t *src)
{
RETDUP(NamedValue_t, src);
}
/* find a named value by name in a list of named values */
NamedValue_t *
FindNamedValue(NamedValueList_t namedValues, char *identifier)
{
for (; namedValues; namedValues = namedValues->Next) {
if (!strcmp(namedValues->Identifier, identifier))
return namedValues;
}
return NULL;
}
/* constructor of NamedNumber_t */
NamedNumber_t *
NewNamedNumber(NamedNumbers_e type)
{
NamedNumber_t *ret;
ret = (NamedNumber_t *)malloc(sizeof(NamedNumber_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(NamedNumber_t));
// ret->Next = NULL;
ret->Type = type;
switch (type) {
case eNamedNumber_Normal:
// ret->U.Normal.Identifier = NULL;
// ret->U.Normal.Value = NULL;
break;
case eNamedNumber_ExtensionMarker:
/*XXX*/
break;
}
return ret;
}
/* copy constructor of NamedNumber_t */
NamedNumber_t *
DupNamedNumber(NamedNumber_t *src)
{
RETDUP(NamedNumber_t, src);
}
/* find a named number by name in a list of named numbers */
NamedNumber_t *
FindNamedNumber(NamedNumberList_t namedNumbers, char *identifier)
{
for (; namedNumbers; namedNumbers = namedNumbers->Next) {
switch (namedNumbers->Type) {
case eNamedNumber_Normal:
if (!strcmp(namedNumbers->U.Normal.Identifier, identifier))
return namedNumbers;
break;
case eNamedNumber_ExtensionMarker:
break;
}
}
return NULL;
}
/* constructor of Value_t */
Value_t *
NewValue(AssignmentList_t ass, Type_t *type)
{
Value_t *ret;
ret = (Value_t *)malloc(sizeof(Value_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Value_t));
// ret->Next = NULL;
ret->Type = type;
if (type) {
// ret->Flags = 0;
switch (GetTypeType(ass, type)) {
case eType_Boolean:
// ret->U.Boolean.Value = 0;
break;
case eType_Integer:
ret->U.Integer.Value.length = 1;
ret->U.Integer.Value.value = (octet_t *)malloc(1);
// ret->U.Integer.Value.value[0] = 0;
break;
case eType_Enumerated:
// ret->U.Enumerated.Value = 0;
break;
case eType_Real:
ret->U.Real.Value.type = eReal_Normal;
intx_setuint32(&ret->U.Real.Value.mantissa, 0);
intx_setuint32(&ret->U.Real.Value.exponent, 0);
ret->U.Real.Value.base = 2;
break;
case eType_BitString:
// ret->U.BitString.Value.length = 0;
// ret->U.BitString.Value.value = NULL;
break;
case eType_OctetString:
case eType_UTF8String:
// ret->U.OctetString.Value.length = 0;
// ret->U.OctetString.Value.value = NULL;
break;
case eType_Null:
break;
case eType_SequenceOf:
case eType_SetOf:
// ret->U.SS.Values = NULL;
break;
case eType_Sequence:
case eType_Set:
case eType_Choice:
case eType_EmbeddedPdv:
case eType_External:
case eType_CharacterString:
case eType_InstanceOf:
// ret->U.SSC.NamedValues = NULL;
break;
case eType_Selection:
break;
case eType_ObjectIdentifier:
break;
case eType_BMPString:
break;
case eType_GeneralString:
break;
case eType_GraphicString:
break;
case eType_IA5String:
break;
case eType_ISO646String:
break;
case eType_NumericString:
break;
case eType_PrintableString:
break;
case eType_TeletexString:
break;
case eType_T61String:
break;
case eType_UniversalString:
break;
case eType_VideotexString:
break;
case eType_VisibleString:
break;
case eType_GeneralizedTime:
break;
case eType_UTCTime:
break;
case eType_ObjectDescriptor:
break;
case eType_Undefined:
break;
}
} else {
// ret->U.Reference.Identifier = NULL;
// ret->U.Reference.Module = NULL;
}
return ret;
}
/* copy constructor of Value_t */
Value_t *
DupValue(Value_t *src)
{
RETDUP(Value_t, src);
}
/* constructor of ValueSet_t */
ValueSet_t *
NewValueSet()
{
ValueSet_t *ret;
ret = (ValueSet_t *)malloc(sizeof(ValueSet_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(ValueSet_t));
// ret->Elements = NULL;
return ret;
}
/* copy constructor of ValueSet_t */
ValueSet_t *
DupValueSet(ValueSet_t *src)
{
RETDUP(ValueSet_t, src);
}
/* constructor of Macro_t */
Macro_t *
NewMacro(Macro_e type)
{
Macro_t *ret;
ret = (Macro_t *)malloc(sizeof(Macro_t));
if (! ret)
return NULL;
ret->Type = type;
return ret;
}
/* copy constructor of Macro_t */
Macro_t *
DupMacro(Macro_t *src)
{
RETDUP(Macro_t, src);
}
/* constructor of MacroProduction_t */
MacroProduction_t *
NewMacroProduction(MacroProduction_e type)
{
MacroProduction_t *ret;
ret = (MacroProduction_t *)malloc(sizeof(MacroProduction_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(MacroProduction_t));
ret->Type = type;
switch (type) {
case eMacroProduction_Alternative:
// ret->U.Alternative.Production1 = NULL;
// ret->U.Alternative.Production2 = NULL;
break;
case eMacroProduction_Sequence:
// ret->U.Sequence.Production1 = NULL;
// ret->U.Sequence.Production2 = NULL;
break;
case eMacroProduction_AString:
// ret->U.AString.String = NULL;
break;
case eMacroProduction_ProductionReference:
// ret->U.ProductionReference.Reference = NULL;
break;
case eMacroProduction_String:
case eMacroProduction_Identifier:
case eMacroProduction_Number:
case eMacroProduction_Empty:
break;
case eMacroProduction_Type:
// ret->U.Type.LocalTypeReference = NULL;
break;
case eMacroProduction_Value:
// ret->U.Value.LocalTypeReference = NULL;
// ret->U.Value.LocalValueReference = NULL;
// ret->U.Value.Type = NULL;
break;
case eMacroProduction_LocalTypeAssignment:
// ret->U.LocalTypeAssignment.LocalTypeReference = NULL;
// ret->U.LocalTypeAssignment.Type = NULL;
break;
case eMacroProduction_LocalValueAssignment:
// ret->U.LocalValueAssignment.LocalValueReference = NULL;
// ret->U.LocalValueAssignment.Value = NULL;
break;
}
return ret;
}
/* copy constructor of MacroProduction_t */
MacroProduction_t *
DupMacroProduction(MacroProduction_t *src)
{
RETDUP(MacroProduction_t, src);
}
/* constructor of NamedMacroProduction_t */
NamedMacroProduction_t *
NewNamedMacroProduction()
{
NamedMacroProduction_t *ret;
ret = (NamedMacroProduction_t *)malloc(sizeof(NamedMacroProduction_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(NamedMacroProduction_t));
// ret->Next = NULL;
// ret->Identifier = NULL;
// ret->Production = NULL;
return ret;
}
/* copy constructor of NamedMacroProduction */
NamedMacroProduction_t *
DupNamedMacroProduction(NamedMacroProduction_t *src)
{
RETDUP(NamedMacroProduction_t, src);
}
/* constructor of MacroLocalAssignment_t */
MacroLocalAssignment_t *
NewMacroLocalAssignment(MacroLocalAssignment_e type)
{
MacroLocalAssignment_t *ret;
ret = (MacroLocalAssignment_t *)malloc(sizeof(MacroLocalAssignment_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(MacroLocalAssignment_t));
// ret->Next = NULL;
ret->Type = type;
// ret->Identifier = NULL;
switch (type) {
case eMacroLocalAssignment_Type:
// ret->U.Type = NULL;
break;
case eMacroLocalAssignment_Value:
// ret->U.Value = NULL;
break;
}
return ret;
}
/* copy constructor of MacroLocalAssignment_t */
MacroLocalAssignment_t *
DupMacroLocalAssignment(MacroLocalAssignment_t *src)
{
RETDUP(MacroLocalAssignment_t, src);
}
/* find a macrolocalassignment by name in a list of macrolocalassignments */
MacroLocalAssignment_t *
FindMacroLocalAssignment(MacroLocalAssignmentList_t la, char *ide)
{
for (; la; la = la->Next) {
if (!strcmp(la->Identifier, ide))
break;
}
return la;
}
/* constructor of EndPoint_t */
EndPoint_t *
NewEndPoint()
{
EndPoint_t *ret;
ret = (EndPoint_t *)malloc(sizeof(EndPoint_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(EndPoint_t));
// ret->Flags = 0;
// ret->Value = NULL;
return ret;
}
/* constructor of Constraint_t */
Constraint_t *
NewConstraint()
{
Constraint_t *ret;
ret = (Constraint_t *)malloc(sizeof(Constraint_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Constraint_t));
ret->Type = eExtension_Unextended;
// ret->Root = NULL;
// ret->Additional = NULL;
return ret;
}
/* copy constructor of Constraint_t */
Constraint_t *DupConstraint(Constraint_t *src)
{
RETDUP(Constraint_t, src);
}
/* constructor of ElementSetSpec_t */
ElementSetSpec_t *
NewElementSetSpec(ElementSetSpec_e type)
{
ElementSetSpec_t *ret;
ret = (ElementSetSpec_t *)malloc(sizeof(ElementSetSpec_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(ElementSetSpec_t));
ret->Type = type;
switch (type) {
case eElementSetSpec_AllExcept:
// ret->U.AllExcept.Elements = NULL;
break;
case eElementSetSpec_Union:
// ret->U.Union.Elements1 = NULL;
// ret->U.Union.Elements2 = NULL;
break;
case eElementSetSpec_Intersection:
// ret->U.Intersection.Elements1 = NULL;
// ret->U.Intersection.Elements2 = NULL;
break;
case eElementSetSpec_Exclusion:
// ret->U.Exclusion.Elements1 = NULL;
// ret->U.Exclusion.Elements2 = NULL;
break;
case eElementSetSpec_SubtypeElement:
// ret->U.SubtypeElement.SubtypeElement = NULL;
break;
case eElementSetSpec_ObjectSetElement:
// ret->U.ObjectSetElement.ObjectSetElement = NULL;
break;
default:
MyAbort();
}
return ret;
}
/* constructor of SubtypeElement_t */
SubtypeElement_t *
NewSubtypeElement(SubtypeElement_e type)
{
SubtypeElement_t *ret;
ret = (SubtypeElement_t *)malloc(sizeof(SubtypeElement_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(SubtypeElement_t));
ret->Type = type;
switch (type) {
case eSubtypeElement_ValueRange:
ret->U.ValueRange.Lower.Flags = eEndPoint_Min;
// ret->U.ValueRange.Lower.Value = NULL;
ret->U.ValueRange.Upper.Flags = eEndPoint_Max;
// ret->U.ValueRange.Upper.Value = NULL;
break;
case eSubtypeElement_Size:
// ret->U.Size.Constraints = NULL;
break;
case eSubtypeElement_SingleValue:
// ret->U.SingleValue.Value = NULL;
break;
case eSubtypeElement_PermittedAlphabet:
// ret->U.PermittedAlphabet.Constraints = NULL;
break;
case eSubtypeElement_ContainedSubtype:
// ret->U.ContainedSubtype.Type = NULL;
break;
case eSubtypeElement_Type:
// ret->U.Type.Type = NULL;
break;
case eSubtypeElement_SingleType:
// ret->U.SingleType.Constraints = NULL;
break;
case eSubtypeElement_FullSpecification:
// ret->U.FullSpecification.NamedConstraints = NULL;
break;
case eSubtypeElement_PartialSpecification:
// ret->U.PartialSpecification.NamedConstraints = NULL;
break;
case eSubtypeElement_ElementSetSpec:
// ret->U.ElementSetSpec.ElementSetSpec = NULL;
break;
}
return ret;
}
/* constructor of ObjectSetElement_t */
ObjectSetElement_t *NewObjectSetElement(ObjectSetElement_e type)
{
ObjectSetElement_t *ret;
ret = (ObjectSetElement_t *)malloc(sizeof(ObjectSetElement_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(ObjectSetElement_t));
ret->Type = type;
switch (type) {
case eObjectSetElement_Object:
// ret->U.Object.Object = NULL;
break;
case eObjectSetElement_ObjectSet:
// ret->U.ObjectSet.ObjectSet = NULL;
break;
case eObjectSetElement_ElementSetSpec:
// ret->U.ElementSetSpec.ElementSetSpec = NULL;
break;
}
return ret;
}
/* constructor of ValueConstraint_t */
ValueConstraint_t *
NewValueConstraint()
{
ValueConstraint_t *ret;
ret = (ValueConstraint_t *)malloc(sizeof(ValueConstraint_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(ValueConstraint_t));
// ret->Next = NULL;
// ret->Lower.Flags = ret->Upper.Flags = 0;
// ret->Lower.Value = ret->Upper.Value = NULL;
return ret;
}
/* constructor of NamedConstraint_t */
NamedConstraint_t *
NewNamedConstraint()
{
NamedConstraint_t *ret;
ret = (NamedConstraint_t *)malloc(sizeof(NamedConstraint_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(NamedConstraint_t));
// ret->Next = NULL;
// ret->Identifier = NULL;
// ret->Constraint = NULL;
ret->Presence = ePresence_Normal;
return ret;
}
/* constructor of Tag_t */
Tag_t *
NewTag(TagType_e type)
{
Tag_t *tag;
tag = (Tag_t *)malloc(sizeof(Tag_t));
if (! tag)
return NULL;
memset(tag, 0, sizeof(Tag_t));
tag->Type = type;
tag->Class = eTagClass_Unknown;
// tag->Tag = NULL;
// tag->Next = NULL;
return tag;
}
/* copy constructor of Tag_t */
Tag_t *
DupTag(Tag_t *src)
{
RETDUP(Tag_t, src);
}
/* constructor of Directive_t */
Directive_t *
NewDirective(Directives_e type)
{
Directive_t *ret;
ret = (Directive_t *)malloc(sizeof(Directive_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Directive_t));
ret->Type = type;
// ret->Next = NULL;
return ret;
}
/* copy constructor of Directive_t */
Directive_t *
DupDirective(Directive_t *src)
{
RETDUP(Directive_t, src);
}
/* constructor of ModuleIdentifier_t */
ModuleIdentifier_t *
NewModuleIdentifier()
{
ModuleIdentifier_t *ret;
ret = (ModuleIdentifier_t *)malloc(sizeof(ModuleIdentifier_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(ModuleIdentifier_t));
// ret->Identifier = NULL;
// ret->ObjectIdentifier = NULL;
return ret;
}
/* constructor of ObjectClass_t */
ObjectClass_t *
NewObjectClass(ObjectClass_e type)
{
ObjectClass_t *ret;
ret = (ObjectClass_t *)malloc(sizeof(ObjectClass_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(ObjectClass_t));
ret->Type = type;
switch (type) {
case eObjectClass_ObjectClass:
// ret->U.ObjectClass.FieldSpec = NULL;
// ret->U.ObjectClass.SyntaxSpec = NULL;
break;
case eObjectClass_Reference:
// ret->U.Reference.Identifier = NULL;
// ret->U.Reference.Module = NULL;
break;
}
return ret;
}
/* constructor of Object_t */
Object_t *
NewObject(Object_e type)
{
Object_t *ret;
ret = (Object_t *)malloc(sizeof(Object_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Object_t));
ret->Type = type;
switch (type) {
case eObject_Object:
// ret->U.Object.ObjectClass = NULL;
// ret->U.Object.Settings = NULL;
break;
case eObject_Reference:
// ret->U.Reference.Identifier = NULL;
// ret->U.Reference.Module = NULL;
break;
}
return ret;
}
/* constructor of ObjectSet_t */
ObjectSet_t *
NewObjectSet(ObjectSet_e type)
{
ObjectSet_t *ret;
ret = (ObjectSet_t *)malloc(sizeof(ObjectSet_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(ObjectSet_t));
ret->Type = type;
switch (type) {
case eObjectSet_ObjectSet:
// ret->U.ObjectSet.ObjectClass = NULL;
// ret->U.ObjectSet.Elements = NULL;
break;
case eObjectSet_Reference:
// ret->U.Reference.Identifier = NULL;
// ret->U.Reference.Module = NULL;
break;
case eObjectSet_ExtensionMarker:
// ret->U.ExtensionMarker.ObjectClass = NULL;
// ret->U.ExtensionMarker.Elements = NULL;
break;
}
return ret;
}
/* constructor of Setting_t */
Setting_t *
NewSetting(Settings_e type)
{
Setting_t *ret;
ret = (Setting_t *)malloc(sizeof(Setting_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Setting_t));
ret->Type = type;
// ret->Identifier = NULL;
// ret->Next = NULL;
switch (type) {
case eSetting_Type:
// ret->U.Type.Type = NULL;
break;
case eSetting_Value:
// ret->U.Value.Value = NULL;
break;
case eSetting_ValueSet:
// ret->U.ValueSet.ValueSet = NULL;
break;
case eSetting_Object:
// ret->U.Object.Object = NULL;
break;
case eSetting_ObjectSet:
// ret->U.ObjectSet.ObjectSet = NULL;
break;
}
return ret;
}
/* copy constructor of Setting_t */
Setting_t *
DupSetting(Setting_t *src)
{
RETDUP(Setting_t, src);
}
/* get the type of a setting */
Settings_e
GetSettingType(Setting_t *se)
{
return se ? se->Type : eSetting_Undefined;
}
/* find a setting by name in a list of settings */
Setting_t *
FindSetting(SettingList_t se, char *identifier)
{
for (; se; se = se->Next) {
if (!strcmp(se->Identifier, identifier))
return se;
}
return NULL;
}
/* constructor of FieldSpec_t */
FieldSpec_t *
NewFieldSpec(FieldSpecs_e type)
{
FieldSpec_t *ret;
ret = (FieldSpec_t *)malloc(sizeof(FieldSpec_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(FieldSpec_t));
ret->Type = type;
// ret->Identifier = NULL;
// ret->Next = NULL;
switch (type) {
case eFieldSpec_Type:
// ret->U.Type.Optionality = NULL;
break;
case eFieldSpec_FixedTypeValue:
// ret->U.FixedTypeValue.Type = NULL;
// ret->U.FixedTypeValue.Unique = 0;
// ret->U.FixedTypeValue.Optionality = NULL;
break;
case eFieldSpec_VariableTypeValue:
// ret->U.VariableTypeValue.Fields = NULL;
// ret->U.VariableTypeValue.Optionality = NULL;
break;
case eFieldSpec_FixedTypeValueSet:
// ret->U.FixedTypeValueSet.Type = NULL;
// ret->U.FixedTypeValueSet.Optionality = NULL;
break;
case eFieldSpec_VariableTypeValueSet:
// ret->U.VariableTypeValueSet.Fields = NULL;
// ret->U.VariableTypeValueSet.Optionality = NULL;
break;
case eFieldSpec_Object:
// ret->U.Object.ObjectClass = NULL;
// ret->U.Object.Optionality = NULL;
break;
case eFieldSpec_ObjectSet:
// ret->U.ObjectSet.ObjectClass = NULL;
// ret->U.ObjectSet.Optionality = NULL;
break;
default:
MyAbort();
}
return ret;
}
/* copy constructor of FieldSpec_t */
FieldSpec_t *
DupFieldSpec(FieldSpec_t *src)
{
RETDUP(FieldSpec_t, src);
}
/* find a fieldspec by name in a list of fieldspecs */
FieldSpec_t *
FindFieldSpec(FieldSpecList_t fs, char *identifier)
{
if (!identifier)
return NULL;
for (; fs; fs = fs->Next) {
if (!strcmp(fs->Identifier, identifier))
return fs;
}
return NULL;
}
/* constructor of Optionality_t */
Optionality_t *
NewOptionality(Optionality_e type)
{
Optionality_t *ret;
ret = (Optionality_t *)malloc(sizeof(Optionality_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(Optionality_t));
ret->Type = type;
switch (type) {
case eOptionality_Normal:
break;
case eOptionality_Optional:
break;
case eOptionality_Default_Type:
// ret->U.Type = NULL;
break;
case eOptionality_Default_Value:
// ret->U.Value = NULL;
break;
case eOptionality_Default_ValueSet:
// ret->U.ValueSet = NULL;
break;
case eOptionality_Default_Object:
// ret->U.Object = NULL;
break;
case eOptionality_Default_ObjectSet:
// ret->U.ObjectSet = NULL;
break;
}
return ret;
}
/* constructor of String_t */
String_t *
NewString()
{
String_t *ret;
ret = (String_t *)malloc(sizeof(String_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(String_t));
// ret->String = NULL;
// ret->Next = NULL;
return ret;
}
/* copy constructor of String_t */
String_t *
DupString(String_t *src)
{
RETDUP(String_t, src);
}
/* find a string by name in a string list */
String_t *
FindString(StringList_t list, char *string)
{
for (; list; list = list->Next) {
if (!strcmp(list->String, string))
return list;
}
return NULL;
}
/* constructor of StringModule_t */
StringModule_t *
NewStringModule()
{
StringModule_t *ret;
ret = (StringModule_t *)malloc(sizeof(StringModule_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(StringModule_t));
// ret->String = NULL;
// ret->Module = NULL;
// ret->Next = NULL;
return ret;
}
/* copy constructor of StringModule_t */
StringModule_t *
DupStringModule(StringModule_t *src)
{
RETDUP(StringModule_t, src);
}
/* find a stringmodule by name/module in a list of stringmodules */
StringModule_t *
FindStringModule(AssignmentList_t ass, StringModuleList_t list, char *string, ModuleIdentifier_t *module)
{
for (; list; list = list->Next) {
if (!strcmp(list->String, string) &&
!CmpModuleIdentifier(ass, list->Module, module))
return list;
}
return NULL;
}
/* constructor of SyntaxSpec_t */
SyntaxSpec_t *
NewSyntaxSpec(SyntaxSpecs_e type)
{
SyntaxSpec_t *ret;
ret = (SyntaxSpec_t *)malloc(sizeof(SyntaxSpec_t));
if (! ret)
return NULL;
memset(ret, 0, sizeof(SyntaxSpec_t));
// ret->Next = NULL;
ret->Type = type;
switch (type) {
case eSyntaxSpec_Literal:
// ret->U.Literal.Literal = NULL;
break;
case eSyntaxSpec_Field:
// ret->U.Field.Field = NULL;
break;
case eSyntaxSpec_Optional:
// ret->U.Optional.SyntaxSpec = NULL;
break;
}
return ret;
}
/* copy constructor of SyntaxSpec_t */
SyntaxSpec_t *
DupSyntaxSpec(SyntaxSpec_t *src)
{
RETDUP(SyntaxSpec_t, src);
}
/* check if a type depends on other types which would be declared later */
/* returns 1 if the type depends on a type of the unknown list and */
/* therefore has to be defined later */
/* returns 0 if the type can be defined now */
int
Depends(AssignmentList_t known, AssignmentList_t unknown, Type_t *type, Type_t *parent)
{
Type_t *reftype;
int isunknown = 0;
/* no dependency if no type is referenced */
if (type->Type != eType_Reference && type->Type != eType_FieldReference)
return 0;
/* get the directly referenced type */
reftype = GetReferencedType(known, type);
if (!reftype) {
reftype = GetReferencedType(unknown, type);
isunknown = 1;
}
if (!reftype)
MyAbort();
// fix intermediate pdu
if (IsStructuredType(reftype) || IsSequenceType(reftype) || IsReferenceType(reftype))
{
reftype->Flags |= eTypeFlags_MiddlePDU;
}
/* no dependency if a structured type is referenced by use of pointer */
/* because a 'struct XXX_s *' can be used */
if (IsStructuredType(reftype) && (type->Rules & eTypeRules_IndirectMask))
return 0;
/* no dependency if a structured type is referenced in an length-pointer */
/* type, because a 'struct XXX_s *values' can be used */
if (IsStructuredType(reftype) && (parent->Rules & eTypeRules_LengthPointer))
return 0;
// special case for pointer related components
if (! isunknown && IsStructuredType(reftype) &&
(parent->Rules & eTypeRules_LinkedListMask))
return 0;
// special case for SequenceOf and SetOf because they are using Pxxx.
if ((reftype->Type == eType_SequenceOf || reftype->Type == eType_SetOf) &&
(reftype->Rules & (eTypeRules_LinkedListMask | eTypeRules_PointerToElement)))
// && (type->Rules & eTypeRules_IndirectMask))
return 0;
/* return true if referenced type is unknown up to now */
return isunknown;
}
/* sort the assignments */
/* obtain an order usable by C type definitions */
void
SortAssignedTypes(AssignmentList_t *a)
{
Assignment_t *list, *curr, *next, **prev, **last;
int depends;
Component_t *components;
Type_t *type;
int flag;
int structured;
/* list will contain the unordered assignments */
list = *a;
/* *a is the ordered list of assignments */
*a = NULL;
/* last will be used for appending to the list of ordered assignments */
last = a;
/* at first try to dump all non-structured types */
structured = 0;
/* we have to move all elements of the unordered assignment list into */
/* the list of the ordered assignments */
while (list) {
/* flag if any assignment has been moved */
flag = 0;
/* examine every element in the unordered list */
for (prev = &list, curr = list; curr; ) {
/* flag if the current type depends on another type and */
/* therefore cannot be moved now */
depends = 0;
/* only types will need dependencies */
if (curr->Type == eAssignment_Type) {
/* examine the current type */
switch (curr->U.Type.Type->Type) {
case eType_Sequence:
case eType_Set:
case eType_Choice:
case eType_External:
case eType_EmbeddedPdv:
case eType_CharacterString:
case eType_Real:
case eType_InstanceOf:
/* structured types shall not be moved in the first pass */
if (!structured) {
depends = 1;
break;
}
/* examine all components of the current type */
for (components = curr->U.Type.Type->U.SSC.Components;
components && !depends; components = components->Next) {
switch (components->Type) {
case eComponent_Normal:
case eComponent_Optional:
case eComponent_Default:
/* check if the type of the component depends */
/* on an undefined type */
type = components->U.NOD.NamedType->Type;
depends |= Depends(*a, list, type,
curr->U.Type.Type);
break;
case eComponent_ComponentsOf:
/* components of should have been already */
/* resolved */
MyAbort();
/*NOTREACHED*/
case eComponent_ExtensionMarker:
break;
}
}
break;
case eType_SequenceOf:
case eType_SetOf:
/* structured types shall not be moved in the first pass */
if (!structured) {
depends = 1;
break;
}
/* check if the type of the elements depends on an */
/* undefined type */
type = curr->U.Type.Type->U.SS.Type;
depends |= Depends(*a, list, type, curr->U.Type.Type);
break;
case eType_Reference:
/* check if the referenced type depends on an */
/* undefined type */
type = curr->U.Type.Type;
depends |= Depends(*a, list, type, curr->U.Type.Type);
break;
}
}
/* move assignment into ordered assignment list if there's no */
/* unresolved dependency */
if (!depends) {
next = curr->Next;
*last = curr;
curr->Next = NULL;
last = &curr->Next;
curr = next;
*prev = curr;
flag = 1;
} else {
prev = &curr->Next;
curr = curr->Next;
}
}
/* if no types have been moved, allow examination of structured types */
/* if already allowed structured types, MyAbort because of cyclic */
/* type definitions */
if (!flag) {
if (!structured) {
structured = 1;
} else {
if (! curr || ! curr->Next)
{
error(E_recursive_type_definition, NULL);
}
}
}
}
}
// --- The following is added by Microsoft ---
static const char *c_aReservedWords[] =
{
// special for C language
"__asm",
"__based",
"__cdecl",
"__declspec",
"__except",
"__fastcall",
"__finally",
"__inline",
"__int16",
"__int32",
"__int64",
"__int8",
"__leave",
"__multiple_inheritance",
"__single_inheritance",
"__stdcall",
"__try",
"__uuidof",
"__virtual_inheritance",
"auto",
"bool",
"break",
"case",
"catch",
"char",
"class",
"const",
"const_cast",
"continue",
"default",
"delete",
"dllexport",
"dllimport",
"do",
"double",
"dynamic_cast",
"else",
"enum",
"explicit",
"extern",
"false",
"float",
"for",
"friend",
"goto",
"if",
"inline",
"int",
"long",
"main",
"mutable",
"naked",
"namespace",
"new",
"operator",
"private",
"protected",
"public",
"register",
"reinterpret_cast",
"return",
"short",
"signed",
"sizeof",
"static",
"static_cast",
"struct",
"switch",
"template",
"this",
"thread",
"throw",
"true",
"try",
"typedef",
"typeid",
"typename",
"union",
"unsigned",
"using",
"uuid",
"virtual",
"void",
"volatile",
"while",
"wmain",
"xalloc"
};
int IsReservedWord ( char *psz )
{
int cWords = sizeof(c_aReservedWords) / sizeof(c_aReservedWords[0]);
const char **ppszWord;
for (ppszWord = &c_aReservedWords[0]; cWords--; ppszWord++)
{
if (strcmp(psz, *ppszWord) == 0)
return 1;
}
return 0;
}
typedef struct ConflictNameList_s
{
struct ConflictNameList_s *next;
char *pszName;
unsigned int cInstances;
} ConflictNameList_t;
static ConflictNameList_t *g_pEnumNameList = NULL; // ENUMERATED
static ConflictNameList_t *g_pOptNameList = NULL; // OPTIONAL
static ConflictNameList_t *g_pChoiceNameList = NULL; // CHOICE
void KeepConflictNames ( ConflictNameList_t **ppListHead, char *pszName )
{
ConflictNameList_t *p;
char *psz;
char szName[256];
strcpy(&szName[0], pszName);
for (psz = &szName[0]; *psz; psz++)
{
if (*psz == '-')
*psz = '_';
}
for (p = *ppListHead; p; p = p->next)
{
if (strcmp(p->pszName, &szName[0]) == 0)
{
p->cInstances++;
return;
}
}
p = (ConflictNameList_t *) malloc(sizeof(ConflictNameList_t));
if (p)
{
memset(p, 0, sizeof(ConflictNameList_t));
p->next = *ppListHead;
*ppListHead = p;
p->cInstances = 1;
p->pszName = strdup(&szName[0]);
}
}
void KeepEnumNames ( char *pszEnumName )
{
KeepConflictNames(&g_pEnumNameList, pszEnumName);
}
void KeepOptNames ( char *pszOptName )
{
KeepConflictNames(&g_pOptNameList, pszOptName);
}
void KeepChoiceNames ( char *pszChoiceName )
{
KeepConflictNames(&g_pChoiceNameList, pszChoiceName);
}
unsigned int GetConflictNameInstanceCount ( ConflictNameList_t *pListHead, char *pszName )
{
ConflictNameList_t *p;
for (p = pListHead; p; p = p->next)
{
if (strcmp(p->pszName, pszName) == 0)
{
return p->cInstances;
}
}
return 0;
}
int DoesEnumNameConflict ( char *pszEnumName )
{
return (GetConflictNameInstanceCount(g_pEnumNameList, pszEnumName) > 2); // counted twice
}
int DoesOptNameConflict ( char *pszOptName )
{
return (GetConflictNameInstanceCount(g_pOptNameList, pszOptName) > 2); // counted twice
}
int DoesChoiceNameConflict ( char *pszChoiceName )
{
return (GetConflictNameInstanceCount(g_pChoiceNameList, pszChoiceName) > 2); // counted twice
}
int IsImportedLocalDuplicate(AssignmentList_t ass, ModuleIdentifier_t *pMainModule, Assignment_t *curr)
{
if (0 == CmpModuleIdentifier(ass, curr->Module, pMainModule))
{
Assignment_t *a;
for (a = ass; a; a = a->Next)
{
if (a->Flags & eAssignmentFlags_LongName)
{
if (0 == strcmp(a->Identifier, curr->Identifier))
{
if (0 != CmpModuleIdentifier(ass, a->Module, curr->Module))
{
return 1;
}
}
}
}
}
return 0;
}
DefinedObjectID_t *g_pDefinedObjectIDs = NULL;
Value_t *GetDefinedOIDValue ( char *pszName )
{
if (pszName)
{
DefinedObjectID_t *p;
for (p = g_pDefinedObjectIDs; p; p = p->next)
{
if (strcmp(pszName, p->pszName) == 0)
{
return p->pValue;
}
}
}
return NULL;
}
void AddDefinedOID ( char *pszName, Value_t *pValue )
{
// add it only when it does not exist
if (! GetDefinedOIDValue(pszName))
{
DefinedObjectID_t *p;
p = (DefinedObjectID_t *) malloc(sizeof(DefinedObjectID_t));
if (p)
{
p->next = g_pDefinedObjectIDs;
p->pszName = pszName;
p->pValue = pValue;
g_pDefinedObjectIDs = p;
}
}
}
void PropagatePrivateDirectives ( Type_t *pDst, PrivateDirectives_t *pSrc )
{
if (pSrc && pDst)
{
if (! pDst->PrivateDirectives.pszTypeName)
{
pDst->PrivateDirectives.pszTypeName = pSrc->pszTypeName;
}
if (! pDst->PrivateDirectives.pszFieldName)
{
pDst->PrivateDirectives.pszFieldName = pSrc->pszFieldName;
}
if (! pDst->PrivateDirectives.pszValueName)
{
pDst->PrivateDirectives.pszValueName = pSrc->pszValueName;
}
pDst->PrivateDirectives.fPublic |= pSrc->fPublic;
pDst->PrivateDirectives.fIntx |= pSrc->fIntx;
pDst->PrivateDirectives.fLenPtr |= pSrc->fLenPtr;
pDst->PrivateDirectives.fPointer |= pSrc->fPointer;
pDst->PrivateDirectives.fArray |= pSrc->fArray;
pDst->PrivateDirectives.fNoCode |= pSrc->fNoCode;
pDst->PrivateDirectives.fNoMemCopy |= pSrc->fNoMemCopy;
pDst->PrivateDirectives.fOidPacked |= pSrc->fOidPacked;
pDst->PrivateDirectives.fOidArray |= pSrc->fOidArray;
pDst->PrivateDirectives.fSLinked |= pSrc->fSLinked;
pDst->PrivateDirectives.fDLinked |= pSrc->fDLinked;
}
}
void PropagateReferenceTypePrivateDirectives ( Type_t *pDst, PrivateDirectives_t *pSrc )
{
if (pSrc && pDst)
{
pDst->PrivateDirectives.fPublic |= pSrc->fPublic;
pDst->PrivateDirectives.fIntx |= pSrc->fIntx;
pDst->PrivateDirectives.fLenPtr |= pSrc->fLenPtr;
pDst->PrivateDirectives.fPointer |= pSrc->fPointer;
pDst->PrivateDirectives.fArray |= pSrc->fArray;
pDst->PrivateDirectives.fNoCode |= pSrc->fNoCode;
pDst->PrivateDirectives.fNoMemCopy |= pSrc->fNoMemCopy;
pDst->PrivateDirectives.fOidPacked |= pSrc->fOidPacked;
pDst->PrivateDirectives.fOidArray |= pSrc->fOidArray;
pDst->PrivateDirectives.fSLinked |= pSrc->fSLinked;
pDst->PrivateDirectives.fDLinked |= pSrc->fDLinked;
}
}
char *GetPrivateValueName(PrivateDirectives_t *pPrivateDirectives, char *pszDefValueName)
{
return pPrivateDirectives->pszValueName ? pPrivateDirectives->pszValueName : pszDefValueName;
}