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* del_op.cc, del_opnt.cc, del_opv.cc, del_opvnt.cc: New files. * exception.cc, new_handler.cc, new_op.cc, new_opnt.cc: New files. * new_opv.cc, new_opvnt.cc, tinfo.cc, tinfo2.cc, vec.cc: New files. * cxxabi.h, exception, new, new.h, typeinfo, pure.c: New files. * tinfo.hP: New file. * Makefile.in (OBJS, HEADERS): Add new files. * configure.in (XCXXINCLUDES): Add ../include and ../gcc. From-SVN: r36780
224 lines
9.0 KiB
C++
224 lines
9.0 KiB
C++
// RTTI support internals for -*- C++ -*-
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// Copyright (C) 1994, 1995, 1996, 1998, 1999, 2000 Free Software Foundation
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#include "typeinfo"
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// Class declarations shared between the typeinfo implementation files.
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#if !defined(__GXX_ABI_VERSION) || __GXX_ABI_VERSION < 100
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// original (old) abi
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// type_info for a class with no base classes (or an enum).
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struct __user_type_info : public std::type_info {
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__user_type_info (const char *n) : type_info (n) {}
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// If our type can be upcast to a public and unambiguous base, then return
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// non-zero and set RES to point to the base object. OBJ points to the throw
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// object and can be NULL, if there is no object to adjust.
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int upcast (const type_info &target, void *obj, void **res) const;
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// If our type can be dynamicly cast to the target type, then return
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// pointer to the target object. OBJ is the pointer to the most derived
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// type and cannot be NULL. SUBTYPE and SUBOBJ indicate the static type
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// base object from whence we came, it cannot be NULL. SUBTYPE cannot be
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// the same as TARGET. TARGET cannot be a base of SUBTYPE.
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// BOFF indicates how SUBTYPE is related to TARGET.
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// BOFF >= 0, there is only one public non-virtual SUBTYPE base at offset
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// BOFF, and there are no public virtual SUBTYPE bases.
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// Therefore check if SUBOBJ is at offset BOFF when we find a target
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// BOFF == -1, SUBTYPE occurs as multiple public virtual or non-virtual bases.
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// Lazily search all the bases of TARGET.
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// BOFF == -2, SUBTYPE is not a public base.
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// BOFF == -3, SUBTYPE occurs as multiple public non-virtual bases.
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// Lazily search the non-virtual bases of TARGET.
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// For backwards compatibility set BOFF to -1, that is the safe "unknown"
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// value. We do not care about SUBTYPES as private bases of TARGET, as they
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// can never succeed as downcasts, only as crosscasts -- and then only if
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// they are virtual. This is more complicated that it might seem.
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void *dyncast (int boff,
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const type_info &target, void *obj,
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const type_info &subtype, void *subobj) const;
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// non_virtual_base_type is used to indicate that a base class is via a
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// non-virtual access path.
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static const type_info *const nonvirtual_base_type
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= static_cast <const type_info *> (0) + 1;
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// sub_kind tells us about how a base object is contained within a derived
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// object. We often do this lazily, hence the UNKNOWN value. At other times
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// we may use NOT_CONTAINED to mean not publicly contained.
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enum sub_kind
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{
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unknown = 0, // we have no idea
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not_contained, // not contained within us (in some
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// circumstances this might mean not contained
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// publicly)
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contained_ambig, // contained ambiguously
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contained_mask = 4, // contained within us
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contained_virtual_mask = 1, // via a virtual path
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contained_public_mask = 2, // via a public path
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contained_private = contained_mask,
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contained_public = contained_mask | contained_public_mask
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};
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// some predicate functions for sub_kind
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static inline bool contained_p (sub_kind access_path)
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{
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return access_path >= contained_mask;
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}
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static inline bool contained_public_p (sub_kind access_path)
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{
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return access_path >= contained_public;
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}
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static inline bool contained_nonpublic_p (sub_kind access_path)
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{
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return (access_path & contained_public) == contained_mask;
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}
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static inline bool contained_nonvirtual_p (sub_kind access_path)
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{
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return (access_path & (contained_mask | contained_virtual_mask))
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== contained_mask;
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}
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static inline bool contained_virtual_p (sub_kind access_path)
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{
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return (access_path & (contained_mask | contained_virtual_mask))
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== (contained_mask | contained_virtual_mask);
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}
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struct upcast_result
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{
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void *target_obj; // pointer to target object or NULL (init NULL)
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sub_kind whole2target; // path from most derived object to target
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const type_info *base_type; // where we found the target, (init NULL)
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// if in vbase the __user_type_info of vbase)
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// if a non-virtual base then 1
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// else NULL
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public:
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upcast_result ()
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:target_obj (NULL), whole2target (unknown), base_type (NULL)
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{}
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};
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struct dyncast_result
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{
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void *target_obj; // pointer to target object or NULL (init NULL)
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sub_kind whole2target; // path from most derived object to target
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sub_kind whole2sub; // path from most derived object to sub object
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sub_kind target2sub; // path from target to sub object
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public:
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dyncast_result ()
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:target_obj (NULL), whole2target (unknown),
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whole2sub (unknown), target2sub (unknown)
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{}
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};
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public:
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// Helper for upcast. See if TARGET is us, or one of our bases. ACCESS_PATH
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// gives the access from the start object. Return TRUE if we know the catch
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// fails.
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virtual bool do_upcast (sub_kind access_path,
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const type_info &target, void *obj,
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upcast_result &__restrict result) const;
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// Helper for dyncast. BOFF indicates how the SUBTYPE is related to TARGET.
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// ACCESS_PATH indicates the access from the most derived object. It is
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// used to prune the DAG walk. All information about what we find is put
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// into RESULT. Return true, if the match we have found is ambiguous.
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virtual bool do_dyncast (int boff, sub_kind access_path,
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const type_info &target, void *obj,
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const type_info &subtype, void *subptr,
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dyncast_result &__restrict result) const;
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public:
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// Indicate whether SUBPTR of type SUBTYPE is contained publicly within
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// OBJPTR. OBJPTR points to this base object. BOFF indicates how SUBTYPE
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// objects might be contained within this type. If SUBPTR is one of our
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// SUBTYPE bases, indicate virtuality. Returns not_contained for non
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// containment or private containment.
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sub_kind find_public_subobj (int boff, const type_info &subtype,
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void *objptr, void *subptr) const
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{
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if (boff >= 0)
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return ((char *)subptr - (char *)objptr) == boff
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? contained_public : not_contained;
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if (boff == -2)
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return not_contained;
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return do_find_public_subobj (boff, subtype, objptr, subptr);
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}
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public:
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// Helper for find_subobj. BOFF indicates how SUBTYPE bases are inherited by
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// the type started from -- which is not necessarily the current type.
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// OBJPTR points to the current base.
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virtual sub_kind do_find_public_subobj (int boff, const type_info &subtype,
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void *objptr, void *subptr) const;
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};
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// type_info for a class with one public, nonvirtual base class.
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class __si_type_info : public __user_type_info {
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const __user_type_info &base;
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public:
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__si_type_info (const char *n, const __user_type_info &b)
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: __user_type_info (n), base (b) { }
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private:
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virtual bool do_upcast (sub_kind access_path,
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const type_info &target, void *obj,
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upcast_result &__restrict result) const;
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virtual bool do_dyncast (int boff, sub_kind access_path,
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const type_info &target, void *obj,
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const type_info &subtype, void *subptr,
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dyncast_result &__restrict result) const;
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virtual sub_kind do_find_public_subobj (int boff, const type_info &subtype,
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void *objptr, void *subptr) const;
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};
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// type_info for a general class.
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#include <limits.h>
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#if INT_MAX == 2147483647
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typedef int myint32;
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#elif SHRT_MAX == 2147483647
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typedef short myint32;
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#elif SCHAR_MAX == 2147483647
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typedef signed char myint32;
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#elif LONG_MAX == 2147483647
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typedef long myint32;
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#else
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# error "No 32-bit data type?"
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#endif
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struct __class_type_info : public __user_type_info {
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enum access { PUBLIC = 1, PROTECTED = 2, PRIVATE = 3 };
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struct base_info {
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const __user_type_info *base;
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myint32 offset: 29;
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bool is_virtual: 1;
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enum access access: 2;
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};
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const base_info *base_list;
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size_t n_bases;
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__class_type_info (const char *name, const base_info *bl, size_t bn)
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: __user_type_info (name), base_list (bl), n_bases (bn) {}
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public:
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virtual bool do_upcast (sub_kind access_path,
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const type_info &target, void *obj,
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upcast_result &__restrict result) const;
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virtual bool do_dyncast (int boff, sub_kind access_path,
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const type_info &target, void *obj,
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const type_info &subtype, void *subptr,
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dyncast_result &__restrict result) const;
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virtual sub_kind do_find_public_subobj (int boff, const type_info &subtype,
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void *objptr, void *subptr) const;
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};
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#else
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// new abi
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#include <cxxabi.h>
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#endif
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