blob: 233830791bd7a3de208a5065d505cc72955cb7c8 [file] [log] [blame]
/* -----------------------------------------------------------------------------
* This file is part of SWIG, which is licensed as a whole under version 3
* (or any later version) of the GNU General Public License. Some additional
* terms also apply to certain portions of SWIG. The full details of the SWIG
* license and copyrights can be found in the LICENSE and COPYRIGHT files
* included with the SWIG source code as distributed by the SWIG developers
* and at https://www.swig.org/legal.html.
*
* allocate.cxx
*
* This module tries to figure out which classes and structures support
* default constructors and destructors in C++. There are several rules that
* define this behavior including pure abstract methods, private sections,
* and non-default constructors in base classes. See the ARM or
* Doc/Manual/SWIGPlus.html for details.
* ----------------------------------------------------------------------------- */
#include "swigmod.h"
#include "cparse.h"
static int virtual_elimination_mode = 0; /* set to 0 on default */
/* Set virtual_elimination_mode */
void Wrapper_virtual_elimination_mode_set(int flag) {
virtual_elimination_mode = flag;
}
/* Helper function to assist with abstract class checking.
This is a major hack. Sorry. */
extern "C" {
static String *search_decl = 0; /* Declarator being searched */
static int check_implemented(Node *n) {
String *decl;
if (!n)
return 0;
while (n) {
if (Strcmp(nodeType(n), "cdecl") == 0) {
decl = Getattr(n, "decl");
if (SwigType_isfunction(decl)) {
SwigType *decl1 = SwigType_typedef_resolve_all(decl);
SwigType *decl2 = SwigType_pop_function(decl1);
if (Strcmp(decl2, search_decl) == 0) {
if (!GetFlag(n, "abstract")) {
Delete(decl1);
Delete(decl2);
return 1;
}
}
Delete(decl1);
Delete(decl2);
}
}
n = Getattr(n, "csym:nextSibling");
}
return 0;
}
}
class Allocate:public Dispatcher {
Node *inclass;
int extendmode;
/* Checks if a function, n, is the same as any in the base class, ie if the method is polymorphic.
* Also checks for methods which will be hidden (ie a base has an identical non-virtual method).
* Both methods must have public access for a match to occur. */
int function_is_defined_in_bases(Node *n, Node *bases) {
if (!bases)
return 0;
String *this_decl = Getattr(n, "decl");
if (!this_decl)
return 0;
String *name = Getattr(n, "name");
String *this_type = Getattr(n, "type");
String *resolved_decl = SwigType_typedef_resolve_all(this_decl);
// Search all base classes for methods with same signature
for (int i = 0; i < Len(bases); i++) {
Node *b = Getitem(bases, i);
Node *base = firstChild(b);
while (base) {
if (Strcmp(nodeType(base), "extend") == 0) {
// Loop through all the %extend methods
Node *extend = firstChild(base);
while (extend) {
if (function_is_defined_in_bases_seek(n, b, extend, this_decl, name, this_type, resolved_decl)) {
Delete(resolved_decl);
return 1;
}
extend = nextSibling(extend);
}
} else if (Strcmp(nodeType(base), "using") == 0) {
// Loop through all the using declaration methods
Node *usingdecl = firstChild(base);
while (usingdecl) {
if (function_is_defined_in_bases_seek(n, b, usingdecl, this_decl, name, this_type, resolved_decl)) {
Delete(resolved_decl);
return 1;
}
usingdecl = nextSibling(usingdecl);
}
} else {
// normal methods
if (function_is_defined_in_bases_seek(n, b, base, this_decl, name, this_type, resolved_decl)) {
Delete(resolved_decl);
return 1;
}
}
base = nextSibling(base);
}
}
Delete(resolved_decl);
resolved_decl = 0;
for (int j = 0; j < Len(bases); j++) {
Node *b = Getitem(bases, j);
if (function_is_defined_in_bases(n, Getattr(b, "allbases")))
return 1;
}
return 0;
}
/* Helper function for function_is_defined_in_bases */
int function_is_defined_in_bases_seek(Node *n, Node *b, Node *base, String *this_decl, String *name, String *this_type, String *resolved_decl) {
String *base_decl = Getattr(base, "decl");
SwigType *base_type = Getattr(base, "type");
if (base_decl && base_type) {
if (checkAttribute(base, "name", name) && !GetFlag(b, "feature:ignore") /* whole class is ignored */ ) {
if (SwigType_isfunction(resolved_decl) && SwigType_isfunction(base_decl)) {
// We have found a method that has the same name as one in a base class
bool covariant_returntype = false;
bool returntype_match = Strcmp(base_type, this_type) == 0 ? true : false;
bool decl_match = Strcmp(base_decl, this_decl) == 0 ? true : false;
if (returntype_match && decl_match) {
// Exact match - we have found a method with identical signature
// No typedef resolution was done, but skipping it speeds things up slightly
} else {
// Either we have:
// 1) matching methods but are one of them uses a different typedef (return type or parameter) to the one in base class' method
// 2) matching polymorphic methods with covariant return type
// 3) a non-matching method (ie an overloaded method of some sort)
// 4) a matching method which is not polymorphic, ie it hides the base class' method
// Check if fully resolved return types match (including
// covariant return types)
if (!returntype_match) {
String *this_returntype = function_return_type(n);
String *base_returntype = function_return_type(base);
returntype_match = Strcmp(this_returntype, base_returntype) == 0 ? true : false;
if (!returntype_match) {
covariant_returntype = SwigType_issubtype(this_returntype, base_returntype) ? true : false;
returntype_match = covariant_returntype;
}
Delete(this_returntype);
Delete(base_returntype);
}
// The return types must match at this point, for the whole method to match
if (returntype_match && !decl_match) {
// Now need to check the parameter list
// First do an inexpensive parameter count
ParmList *this_parms = Getattr(n, "parms");
ParmList *base_parms = Getattr(base, "parms");
if (ParmList_len(this_parms) == ParmList_len(base_parms)) {
// Number of parameters are the same, now check that all the parameters match
SwigType *base_fn = NewString("");
SwigType *this_fn = NewString("");
SwigType_add_function(base_fn, base_parms);
SwigType_add_function(this_fn, this_parms);
base_fn = SwigType_typedef_resolve_all(base_fn);
this_fn = SwigType_typedef_resolve_all(this_fn);
if (Strcmp(base_fn, this_fn) == 0) {
// Finally check that the qualifiers match
int base_qualifier = SwigType_isqualifier(resolved_decl);
int this_qualifier = SwigType_isqualifier(base_decl);
if (base_qualifier == this_qualifier) {
decl_match = true;
}
}
Delete(base_fn);
Delete(this_fn);
}
}
}
//Printf(stderr,"look %s %s %d %d\n",base_decl, this_decl, returntype_match, decl_match);
if (decl_match && returntype_match) {
// Found an identical method in the base class
bool this_wrapping_protected_members = is_member_director(n) ? true : false; // This should really check for dirprot rather than just being a director method
bool base_wrapping_protected_members = is_member_director(base) ? true : false; // This should really check for dirprot rather than just being a director method
bool both_have_public_access = is_public(n) && is_public(base);
bool both_have_protected_access = (is_protected(n) && this_wrapping_protected_members) && (is_protected(base) && base_wrapping_protected_members);
bool both_have_private_access = is_private(n) && is_private(base);
if (checkAttribute(base, "storage", "virtual")) {
// Found a polymorphic method.
// Mark the polymorphic method, in case the virtual keyword was not used.
Setattr(n, "storage", "virtual");
if (!GetFlag(b, "feature:interface")) { // interface implementation neither hides nor overrides
if (both_have_public_access || both_have_protected_access) {
if (!is_non_public_base(inclass, b))
Setattr(n, "override", base); // Note C# definition of override, ie access must be the same
}
else if (!both_have_private_access) {
// Different access
if (this_wrapping_protected_members || base_wrapping_protected_members)
if (!is_non_public_base(inclass, b))
Setattr(n, "hides", base); // Note C# definition of hiding, ie hidden if access is different
}
}
// Try and find the most base's covariant return type
SwigType *most_base_covariant_type = Getattr(base, "covariant");
if (!most_base_covariant_type && covariant_returntype)
most_base_covariant_type = function_return_type(base, false);
if (!most_base_covariant_type) {
// Eliminate the derived virtual method.
if (virtual_elimination_mode && !is_member_director(n))
if (both_have_public_access)
if (!is_non_public_base(inclass, b))
if (!Swig_symbol_isoverloaded(n)) {
// Don't eliminate if an overloaded method as this hides the method
// in the scripting languages: the dispatch function will hide the base method if ignored.
SetFlag(n, "feature:ignore");
}
} else {
// Some languages need to know about covariant return types
Setattr(n, "covariant", most_base_covariant_type);
}
} else {
// Found an identical method in the base class, but it is not polymorphic.
if (both_have_public_access || both_have_protected_access)
if (!is_non_public_base(inclass, b))
Setattr(n, "hides", base);
}
if (both_have_public_access || both_have_protected_access)
return 1;
}
}
}
}
return 0;
}
/* Determines whether the base class, b, is in the list of private
* or protected base classes for class n. */
bool is_non_public_base(Node *n, Node *b) {
bool non_public_base = false;
Node *bases = Getattr(n, "privatebases");
if (bases) {
for (int i = 0; i < Len(bases); i++) {
Node *base = Getitem(bases, i);
if (base == b)
non_public_base = true;
}
}
bases = Getattr(n, "protectedbases");
if (bases) {
for (int i = 0; i < Len(bases); i++) {
Node *base = Getitem(bases, i);
if (base == b)
non_public_base = true;
}
}
return non_public_base;
}
/* Returns the return type for a function. The node n should be a function.
If resolve is true the fully returned type is fully resolved.
Caller is responsible for deleting returned string. */
String *function_return_type(Node *n, bool resolve = true) {
String *decl = Getattr(n, "decl");
SwigType *type = Getattr(n, "type");
String *ty = NewString(type);
SwigType_push(ty, decl);
if (SwigType_isqualifier(ty))
Delete(SwigType_pop(ty));
Delete(SwigType_pop_function(ty));
if (resolve) {
String *unresolved = ty;
ty = SwigType_typedef_resolve_all(unresolved);
Delete(unresolved);
}
return ty;
}
/* Checks if a class member is the same as inherited from the class bases */
int class_member_is_defined_in_bases(Node *member, Node *classnode) {
Node *bases; /* bases is the closest ancestors of classnode */
int defined = 0;
bases = Getattr(classnode, "allbases");
if (!bases)
return 0;
{
int old_mode = virtual_elimination_mode;
if (is_member_director(classnode, member))
virtual_elimination_mode = 0;
if (function_is_defined_in_bases(member, bases)) {
defined = 1;
}
virtual_elimination_mode = old_mode;
}
if (defined)
return 1;
else
return 0;
}
/* Checks to see if a class is abstract through inheritance,
and saves the first node that seems to be abstract.
*/
int is_abstract_inherit(Node *n, Node *base = 0, int first = 0) {
if (!first && (base == n))
return 0;
if (!base) {
/* Root node */
Symtab *stab = Getattr(n, "symtab"); /* Get symbol table for node */
Symtab *oldtab = Swig_symbol_setscope(stab);
int ret = is_abstract_inherit(n, n, 1);
Swig_symbol_setscope(oldtab);
return ret;
}
List *abstracts = Getattr(base, "abstracts");
if (abstracts) {
int dabstract = 0;
int len = Len(abstracts);
for (int i = 0; i < len; i++) {
Node *nn = Getitem(abstracts, i);
String *name = Getattr(nn, "name");
if (!name)
continue;
if (Strchr(name, '~'))
continue; /* Don't care about destructors */
String *base_decl = Getattr(nn, "decl");
if (base_decl)
base_decl = SwigType_typedef_resolve_all(base_decl);
if (SwigType_isfunction(base_decl))
search_decl = SwigType_pop_function(base_decl);
Node *dn = Swig_symbol_clookup_local_check(name, 0, check_implemented);
Delete(search_decl);
Delete(base_decl);
if (!dn) {
List *nabstracts = Getattr(n, "abstracts");
if (!nabstracts) {
nabstracts = NewList();
Setattr(n, "abstracts", nabstracts);
Delete(nabstracts);
}
Append(nabstracts, nn);
if (!Getattr(n, "abstracts:firstnode")) {
Setattr(n, "abstracts:firstnode", nn);
}
dabstract = base != n;
}
}
if (dabstract)
return 1;
}
List *bases = Getattr(base, "allbases");
if (!bases)
return 0;
for (int i = 0; i < Len(bases); i++) {
if (is_abstract_inherit(n, Getitem(bases, i))) {
return 1;
}
}
return 0;
}
/* Grab methods used by smart pointers */
List *smart_pointer_methods(Node *cls, List *methods, int isconst, String *classname = 0) {
if (!methods) {
methods = NewList();
}
Node *c = firstChild(cls);
while (c) {
if (Getattr(c, "error") || GetFlag(c, "feature:ignore")) {
c = nextSibling(c);
continue;
}
if (!isconst && (Strcmp(nodeType(c), "extend") == 0)) {
methods = smart_pointer_methods(c, methods, isconst, Getattr(cls, "name"));
} else if (Strcmp(nodeType(c), "cdecl") == 0) {
if (!GetFlag(c, "feature:ignore")) {
String *storage = Getattr(c, "storage");
if (!((Cmp(storage, "typedef") == 0))
&& !Strstr(storage, "friend")) {
String *name = Getattr(c, "name");
String *symname = Getattr(c, "sym:name");
Node *e = Swig_symbol_clookup_local(name, 0);
if (e && is_public(e) && !GetFlag(e, "feature:ignore") && (Cmp(symname, Getattr(e, "sym:name")) == 0)) {
Swig_warning(WARN_LANG_DEREF_SHADOW, Getfile(e), Getline(e), "Declaration of '%s' shadows declaration accessible via operator->(),\n", name);
Swig_warning(WARN_LANG_DEREF_SHADOW, Getfile(c), Getline(c), "previous declaration of '%s'.\n", name);
} else {
/* Make sure node with same name doesn't already exist */
int k;
int match = 0;
for (k = 0; k < Len(methods); k++) {
e = Getitem(methods, k);
if (Cmp(symname, Getattr(e, "sym:name")) == 0) {
match = 1;
break;
}
if (!Getattr(e, "sym:name") && (Cmp(name, Getattr(e, "name")) == 0)) {
match = 1;
break;
}
}
if (!match) {
Node *cc = c;
while (cc) {
Node *cp = cc;
if (classname) {
Setattr(cp, "extendsmartclassname", classname);
}
Setattr(cp, "allocate:smartpointeraccess", "1");
/* If constant, we have to be careful */
if (isconst) {
SwigType *decl = Getattr(cp, "decl");
if (decl) {
if (SwigType_isfunction(decl)) { /* If method, we only add if it's a const method */
if (SwigType_isconst(decl)) {
Append(methods, cp);
}
} else {
Append(methods, cp);
}
} else {
Append(methods, cp);
}
} else {
Append(methods, cp);
}
cc = Getattr(cc, "sym:nextSibling");
}
}
}
}
}
}
c = nextSibling(c);
}
/* Look for methods in base classes */
{
Node *bases = Getattr(cls, "bases");
int k;
for (k = 0; k < Len(bases); k++) {
smart_pointer_methods(Getitem(bases, k), methods, isconst);
}
}
/* Remove protected/private members */
{
for (int i = 0; i < Len(methods);) {
Node *n = Getitem(methods, i);
if (!is_public(n)) {
Delitem(methods, i);
continue;
}
i++;
}
}
return methods;
}
void mark_exception_classes(ParmList *p) {
while (p) {
SwigType *ty = Getattr(p, "type");
SwigType *t = SwigType_typedef_resolve_all(ty);
if (SwigType_isreference(t) || SwigType_ispointer(t) || SwigType_isarray(t)) {
Delete(SwigType_pop(t));
}
Node *c = Swig_symbol_clookup(t, 0);
if (c) {
if (!GetFlag(c, "feature:exceptionclass")) {
SetFlag(c, "feature:exceptionclass");
}
}
p = nextSibling(p);
Delete(t);
}
}
void process_exceptions(Node *n) {
ParmList *catchlist = 0;
/*
the "catchlist" attribute is used to emit the block
try {$action;}
catch <list of catches>;
in emit.cxx
and is either constructed from the "feature:catches" feature
or copied from the node "throws" list.
*/
String *scatchlist = Getattr(n, "feature:catches");
if (scatchlist) {
catchlist = Swig_cparse_parms(scatchlist, n);
if (catchlist) {
Setattr(n, "catchlist", catchlist);
mark_exception_classes(catchlist);
Delete(catchlist);
}
}
ParmList *throws = Getattr(n, "throws");
if (throws) {
/* if there is no explicit catchlist, we catch everything in the throws list */
if (!catchlist) {
Setattr(n, "catchlist", throws);
}
mark_exception_classes(throws);
}
}
public:
Allocate():
inclass(NULL), extendmode(0) {
}
virtual int top(Node *n) {
cplus_mode = PUBLIC;
inclass = 0;
extendmode = 0;
emit_children(n);
return SWIG_OK;
}
virtual int importDirective(Node *n) {
return emit_children(n);
}
virtual int includeDirective(Node *n) {
return emit_children(n);
}
virtual int externDeclaration(Node *n) {
return emit_children(n);
}
virtual int namespaceDeclaration(Node *n) {
return emit_children(n);
}
virtual int extendDirective(Node *n) {
extendmode = 1;
emit_children(n);
extendmode = 0;
return SWIG_OK;
}
virtual int classDeclaration(Node *n) {
Symtab *symtab = Swig_symbol_current();
Swig_symbol_setscope(Getattr(n, "symtab"));
save_value<Node*> oldInclass(inclass);
save_value<AccessMode> oldAcessMode(cplus_mode);
save_value<int> oldExtendMode(extendmode);
if (Getattr(n, "template"))
extendmode = 0;
if (!CPlusPlus) {
/* Always have default constructors/destructors in C */
Setattr(n, "allocate:default_constructor", "1");
Setattr(n, "allocate:default_destructor", "1");
}
if (Getattr(n, "allocate:visit"))
return SWIG_OK;
Setattr(n, "allocate:visit", "1");
/* Always visit base classes first */
{
List *bases = Getattr(n, "bases");
if (bases) {
for (int i = 0; i < Len(bases); i++) {
Node *b = Getitem(bases, i);
classDeclaration(b);
}
}
}
inclass = n;
String *kind = Getattr(n, "kind");
if (Strcmp(kind, "class") == 0) {
cplus_mode = PRIVATE;
} else {
cplus_mode = PUBLIC;
}
emit_children(n);
/* Check if the class is abstract via inheritance. This might occur if a class didn't have
any pure virtual methods of its own, but it didn't implement all of the pure methods in
a base class */
if (!Getattr(n, "abstracts") && is_abstract_inherit(n)) {
if (((Getattr(n, "allocate:public_constructor") || (!GetFlag(n, "feature:nodefault") && !Getattr(n, "allocate:has_constructor"))))) {
if (!GetFlag(n, "feature:notabstract")) {
Node *na = Getattr(n, "abstracts:firstnode");
if (na) {
Swig_warning(WARN_TYPE_ABSTRACT, Getfile(n), Getline(n),
"Class '%s' might be abstract, " "no constructors generated,\n", SwigType_namestr(Getattr(n, "name")));
Swig_warning(WARN_TYPE_ABSTRACT, Getfile(na), Getline(na), "Method %s might not be implemented.\n", Swig_name_decl(na));
if (!Getattr(n, "abstracts")) {
List *abstracts = NewList();
Append(abstracts, na);
Setattr(n, "abstracts", abstracts);
Delete(abstracts);
}
}
}
}
}
if (!Getattr(n, "allocate:has_constructor")) {
/* No constructor is defined. We need to check a few things */
/* If class is abstract. No default constructor. Sorry */
if (Getattr(n, "abstracts")) {
Delattr(n, "allocate:default_constructor");
}
if (!Getattr(n, "allocate:default_constructor")) {
/* Check base classes */
List *bases = Getattr(n, "allbases");
int allows_default = 1;
for (int i = 0; i < Len(bases); i++) {
Node *n = Getitem(bases, i);
/* If base class does not allow default constructor, we don't allow it either */
if (!Getattr(n, "allocate:default_constructor") && (!Getattr(n, "allocate:default_base_constructor"))) {
allows_default = 0;
}
}
if (allows_default) {
Setattr(n, "allocate:default_constructor", "1");
}
}
}
if (!Getattr(n, "allocate:has_copy_constructor")) {
if (Getattr(n, "abstracts")) {
Delattr(n, "allocate:copy_constructor");
}
if (!Getattr(n, "allocate:copy_constructor")) {
/* Check base classes */
List *bases = Getattr(n, "allbases");
int allows_copy = 1;
for (int i = 0; i < Len(bases); i++) {
Node *n = Getitem(bases, i);
/* If base class does not allow copy constructor, we don't allow it either */
if (!Getattr(n, "allocate:copy_constructor") && (!Getattr(n, "allocate:copy_base_constructor"))) {
allows_copy = 0;
}
}
if (allows_copy) {
Setattr(n, "allocate:copy_constructor", "1");
}
}
}
if (!Getattr(n, "allocate:has_destructor")) {
/* No destructor was defined */
List *bases = Getattr(n, "allbases");
int allows_destruct = 1;
for (int i = 0; i < Len(bases); i++) {
Node *n = Getitem(bases, i);
/* If base class does not allow default destructor, we don't allow it either */
if (!Getattr(n, "allocate:default_destructor") && (!Getattr(n, "allocate:default_base_destructor"))) {
allows_destruct = 0;
}
}
if (allows_destruct) {
Setattr(n, "allocate:default_destructor", "1");
}
}
if (!Getattr(n, "allocate:has_assign")) {
/* No assignment operator was defined */
List *bases = Getattr(n, "allbases");
int allows_assign = 1;
for (int i = 0; i < Len(bases); i++) {
Node *n = Getitem(bases, i);
/* If base class does not allow assignment, we don't allow it either */
if (Getattr(n, "allocate:has_assign")) {
allows_assign = !Getattr(n, "allocate:noassign");
}
}
if (!allows_assign) {
Setattr(n, "allocate:noassign", "1");
}
}
if (!Getattr(n, "allocate:has_new")) {
/* No new operator was defined */
List *bases = Getattr(n, "allbases");
int allows_new = 1;
for (int i = 0; i < Len(bases); i++) {
Node *n = Getitem(bases, i);
/* If base class does not allow new operator, we don't allow it either */
if (Getattr(n, "allocate:has_new")) {
allows_new = !Getattr(n, "allocate:nonew");
}
}
if (!allows_new) {
Setattr(n, "allocate:nonew", "1");
}
}
/* Check if base classes allow smart pointers, but might be hidden */
if (!Getattr(n, "allocate:smartpointer")) {
Node *sp = Swig_symbol_clookup("operator ->", 0);
if (sp) {
/* Look for parent */
Node *p = parentNode(sp);
if (Strcmp(nodeType(p), "extend") == 0) {
p = parentNode(p);
}
if (Strcmp(nodeType(p), "class") == 0) {
if (GetFlag(p, "feature:ignore")) {
Setattr(n, "allocate:smartpointer", Getattr(p, "allocate:smartpointer"));
}
}
}
}
Swig_interface_propagate_methods(n);
/* Only care about default behavior. Remove temporary values */
Setattr(n, "allocate:visit", "1");
Swig_symbol_setscope(symtab);
return SWIG_OK;
}
virtual int accessDeclaration(Node *n) {
String *kind = Getattr(n, "kind");
if (Cmp(kind, "public") == 0) {
cplus_mode = PUBLIC;
} else if (Cmp(kind, "private") == 0) {
cplus_mode = PRIVATE;
} else if (Cmp(kind, "protected") == 0) {
cplus_mode = PROTECTED;
}
return SWIG_OK;
}
virtual int usingDeclaration(Node *n) {
Node *c = 0;
for (c = firstChild(n); c; c = nextSibling(c)) {
if (Strcmp(nodeType(c), "cdecl") == 0) {
process_exceptions(c);
if (inclass)
class_member_is_defined_in_bases(c, inclass);
}
}
return SWIG_OK;
}
virtual int cDeclaration(Node *n) {
process_exceptions(n);
if (inclass) {
/* check whether the member node n is defined in class node in class's bases */
class_member_is_defined_in_bases(n, inclass);
/* Check to see if this is a static member or not. If so, we add an attribute
cplus:staticbase that saves the current class */
if (Swig_storage_isstatic(n)) {
Setattr(n, "cplus:staticbase", inclass);
} else if (Cmp(Getattr(n, "kind"), "variable") == 0) {
/* Check member variable to determine whether assignment is valid */
if (SwigType_isreference(Getattr(n, "type"))) {
/* Can't assign a class with reference member data */
Setattr(inclass, "allocate:noassign", "1");
}
}
String *name = Getattr(n, "name");
if (cplus_mode != PUBLIC) {
if (Strcmp(name, "operator =") == 0) {
/* Look for a private assignment operator */
if (!GetFlag(n, "deleted"))
Setattr(inclass, "allocate:has_assign", "1");
Setattr(inclass, "allocate:noassign", "1");
} else if (Strcmp(name, "operator new") == 0) {
/* Look for a private new operator */
if (!GetFlag(n, "deleted"))
Setattr(inclass, "allocate:has_new", "1");
Setattr(inclass, "allocate:nonew", "1");
}
} else {
if (Strcmp(name, "operator =") == 0) {
if (!GetFlag(n, "deleted"))
Setattr(inclass, "allocate:has_assign", "1");
else
Setattr(inclass, "allocate:noassign", "1");
} else if (Strcmp(name, "operator new") == 0) {
if (!GetFlag(n, "deleted"))
Setattr(inclass, "allocate:has_new", "1");
else
Setattr(inclass, "allocate:nonew", "1");
}
/* Look for smart pointer operator */
if ((Strcmp(name, "operator ->") == 0) && (!GetFlag(n, "feature:ignore"))) {
/* Look for version with no parameters */
Node *sn = n;
while (sn) {
if (!Getattr(sn, "parms")) {
SwigType *type = SwigType_typedef_resolve_all(Getattr(sn, "type"));
SwigType_push(type, Getattr(sn, "decl"));
Delete(SwigType_pop_function(type));
SwigType *base = SwigType_base(type);
Node *sc = Swig_symbol_clookup(base, 0);
if ((sc) && (Strcmp(nodeType(sc), "class") == 0)) {
if (SwigType_check_decl(type, "p.")) {
/* Need to check if type is a const pointer */
int isconst = 0;
Delete(SwigType_pop(type));
if (SwigType_isconst(type)) {
isconst = !Getattr(inclass, "allocate:smartpointermutable");
Setattr(inclass, "allocate:smartpointerconst", "1");
}
else {
Setattr(inclass, "allocate:smartpointermutable", "1");
}
List *methods = smart_pointer_methods(sc, 0, isconst);
Setattr(inclass, "allocate:smartpointer", methods);
Setattr(inclass, "allocate:smartpointerpointeeclassname", Getattr(sc, "name"));
} else {
/* Hmmm. The return value is not a pointer. If the type is a value
or reference. We're going to chase it to see if another operator->()
can be found */
if ((SwigType_check_decl(type, "")) || (SwigType_check_decl(type, "r."))) {
Node *nn = Swig_symbol_clookup("operator ->", Getattr(sc, "symtab"));
if (nn) {
Delete(base);
Delete(type);
sn = nn;
continue;
}
}
}
}
Delete(base);
Delete(type);
break;
}
}
}
}
}
return SWIG_OK;
}
virtual int constructorDeclaration(Node *n) {
if (!inclass)
return SWIG_OK;
Parm *parms = Getattr(n, "parms");
process_exceptions(n);
if (!extendmode) {
if (!ParmList_numrequired(parms)) {
/* Class does define a default constructor */
/* However, we had better see where it is defined */
if (cplus_mode == PUBLIC) {
Setattr(inclass, "allocate:default_constructor", "1");
} else if (cplus_mode == PROTECTED) {
Setattr(inclass, "allocate:default_base_constructor", "1");
}
}
/* Class defines some kind of constructor. May or may not be public */
Setattr(inclass, "allocate:has_constructor", "1");
if (cplus_mode == PUBLIC) {
Setattr(inclass, "allocate:public_constructor", "1");
}
} else {
Setattr(inclass, "allocate:has_constructor", "1");
Setattr(inclass, "allocate:public_constructor", "1");
}
/* See if this is a copy constructor */
if (parms && (ParmList_numrequired(parms) == 1)) {
/* Look for a few cases. X(const X &), X(X &), X(X *) */
int copy_constructor = 0;
SwigType *type = Getattr(inclass, "name");
String *tn = NewStringf("r.q(const).%s", type);
String *cc = SwigType_typedef_resolve_all(tn);
SwigType *rt = SwigType_typedef_resolve_all(Getattr(parms, "type"));
if (SwigType_istemplate(type)) {
String *tmp = Swig_symbol_template_deftype(cc, 0);
Delete(cc);
cc = tmp;
tmp = Swig_symbol_template_deftype(rt, 0);
Delete(rt);
rt = tmp;
}
if (Strcmp(cc, rt) == 0) {
copy_constructor = 1;
} else {
Delete(cc);
cc = NewStringf("r.%s", Getattr(inclass, "name"));
if (Strcmp(cc, Getattr(parms, "type")) == 0) {
copy_constructor = 1;
} else {
Delete(cc);
cc = NewStringf("p.%s", Getattr(inclass, "name"));
String *ty = SwigType_strip_qualifiers(Getattr(parms, "type"));
if (Strcmp(cc, ty) == 0) {
copy_constructor = 1;
}
Delete(ty);
}
}
Delete(cc);
Delete(rt);
Delete(tn);
if (copy_constructor) {
Setattr(n, "copy_constructor", "1");
Setattr(inclass, "allocate:has_copy_constructor", "1");
if (cplus_mode == PUBLIC) {
Setattr(inclass, "allocate:copy_constructor", "1");
} else if (cplus_mode == PROTECTED) {
Setattr(inclass, "allocate:copy_base_constructor", "1");
}
}
}
return SWIG_OK;
}
virtual int destructorDeclaration(Node *n) {
(void) n;
if (!inclass)
return SWIG_OK;
if (!extendmode) {
Setattr(inclass, "allocate:has_destructor", "1");
if (cplus_mode == PUBLIC) {
Setattr(inclass, "allocate:default_destructor", "1");
} else if (cplus_mode == PROTECTED) {
Setattr(inclass, "allocate:default_base_destructor", "1");
} else if (cplus_mode == PRIVATE) {
Setattr(inclass, "allocate:private_destructor", "1");
}
} else {
Setattr(inclass, "allocate:has_destructor", "1");
Setattr(inclass, "allocate:default_destructor", "1");
}
return SWIG_OK;
}
};
void Swig_default_allocators(Node *n) {
if (!n)
return;
Allocate *a = new Allocate;
a->top(n);
delete a;
}