4109fe8594
libjava: 2004-08-13 Bryce McKinlay <mckinlay@redhat.com> * configure.in (GCINCS): Don't use "boehm-cflags". Instead, -I boehm-gc's include dirs. * configure: Rebuilt. * include/boehm-gc.h: Include gc_config.h. boehm-gc: 2004-08-13 Bryce McKinlay <mckinlay@redhat.com> * configure.ac (gc_cflags): Add -Iinclude. (AC_CONFIG_HEADERS): New. Configure gc_config.h header. Don't write DEFS to boehm-cflags file. * configure: Rebuilt. * gcj_mlc.c: Check #ifdef GC_GCJ_SUPPORT after including headers. * specific.c: Check #ifdef GC_LINUX_THREADS after including headers. * include/gc_config_macros.h: Remove backward-compatibility redefinitions of GC_ names. * include/gc.h: Include <gc_config.h>. 2004-08-13 Bryce McKinlay <mckinlay@redhat.com> Import Boehm GC version 6.3. From-SVN: r85972
368 lines
12 KiB
C++
368 lines
12 KiB
C++
#ifndef GC_CPP_H
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#define GC_CPP_H
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/****************************************************************************
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Copyright (c) 1994 by Xerox Corporation. All rights reserved.
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THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY EXPRESSED
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OR IMPLIED. ANY USE IS AT YOUR OWN RISK.
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Permission is hereby granted to use or copy this program for any
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purpose, provided the above notices are retained on all copies.
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Permission to modify the code and to distribute modified code is
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granted, provided the above notices are retained, and a notice that
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the code was modified is included with the above copyright notice.
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****************************************************************************
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C++ Interface to the Boehm Collector
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John R. Ellis and Jesse Hull
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This interface provides access to the Boehm collector. It provides
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basic facilities similar to those described in "Safe, Efficient
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Garbage Collection for C++", by John R. Elis and David L. Detlefs
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(ftp://ftp.parc.xerox.com/pub/ellis/gc).
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All heap-allocated objects are either "collectable" or
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"uncollectable". Programs must explicitly delete uncollectable
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objects, whereas the garbage collector will automatically delete
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collectable objects when it discovers them to be inaccessible.
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Collectable objects may freely point at uncollectable objects and vice
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versa.
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Objects allocated with the built-in "::operator new" are uncollectable.
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Objects derived from class "gc" are collectable. For example:
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class A: public gc {...};
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A* a = new A; // a is collectable.
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Collectable instances of non-class types can be allocated using the GC
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(or UseGC) placement:
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typedef int A[ 10 ];
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A* a = new (GC) A;
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Uncollectable instances of classes derived from "gc" can be allocated
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using the NoGC placement:
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class A: public gc {...};
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A* a = new (NoGC) A; // a is uncollectable.
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Both uncollectable and collectable objects can be explicitly deleted
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with "delete", which invokes an object's destructors and frees its
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storage immediately.
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A collectable object may have a clean-up function, which will be
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invoked when the collector discovers the object to be inaccessible.
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An object derived from "gc_cleanup" or containing a member derived
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from "gc_cleanup" has a default clean-up function that invokes the
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object's destructors. Explicit clean-up functions may be specified as
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an additional placement argument:
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A* a = ::new (GC, MyCleanup) A;
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An object is considered "accessible" by the collector if it can be
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reached by a path of pointers from static variables, automatic
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variables of active functions, or from some object with clean-up
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enabled; pointers from an object to itself are ignored.
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Thus, if objects A and B both have clean-up functions, and A points at
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B, B is considered accessible. After A's clean-up is invoked and its
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storage released, B will then become inaccessible and will have its
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clean-up invoked. If A points at B and B points to A, forming a
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cycle, then that's considered a storage leak, and neither will be
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collectable. See the interface gc.h for low-level facilities for
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handling such cycles of objects with clean-up.
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The collector cannot guarrantee that it will find all inaccessible
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objects. In practice, it finds almost all of them.
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Cautions:
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1. Be sure the collector has been augmented with "make c++".
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2. If your compiler supports the new "operator new[]" syntax, then
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add -DGC_OPERATOR_NEW_ARRAY to the Makefile.
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If your compiler doesn't support "operator new[]", beware that an
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array of type T, where T is derived from "gc", may or may not be
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allocated as a collectable object (it depends on the compiler). Use
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the explicit GC placement to make the array collectable. For example:
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class A: public gc {...};
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A* a1 = new A[ 10 ]; // collectable or uncollectable?
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A* a2 = new (GC) A[ 10 ]; // collectable
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3. The destructors of collectable arrays of objects derived from
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"gc_cleanup" will not be invoked properly. For example:
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class A: public gc_cleanup {...};
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A* a = new (GC) A[ 10 ]; // destructors not invoked correctly
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Typically, only the destructor for the first element of the array will
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be invoked when the array is garbage-collected. To get all the
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destructors of any array executed, you must supply an explicit
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clean-up function:
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A* a = new (GC, MyCleanUp) A[ 10 ];
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(Implementing clean-up of arrays correctly, portably, and in a way
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that preserves the correct exception semantics requires a language
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extension, e.g. the "gc" keyword.)
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4. Compiler bugs:
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* Solaris 2's CC (SC3.0) doesn't implement t->~T() correctly, so the
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destructors of classes derived from gc_cleanup won't be invoked.
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You'll have to explicitly register a clean-up function with
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new-placement syntax.
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* Evidently cfront 3.0 does not allow destructors to be explicitly
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invoked using the ANSI-conforming syntax t->~T(). If you're using
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cfront 3.0, you'll have to comment out the class gc_cleanup, which
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uses explicit invocation.
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5. GC name conflicts:
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Many other systems seem to use the identifier "GC" as an abbreviation
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for "Graphics Context". Since version 5.0, GC placement has been replaced
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by UseGC. GC is an alias for UseGC, unless GC_NAME_CONFLICT is defined.
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****************************************************************************/
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#include "gc.h"
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#ifndef THINK_CPLUS
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# define GC_cdecl
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#else
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# define GC_cdecl _cdecl
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#endif
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#if ! defined( GC_NO_OPERATOR_NEW_ARRAY ) \
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&& !defined(_ENABLE_ARRAYNEW) /* Digimars */ \
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&& (defined(__BORLANDC__) && (__BORLANDC__ < 0x450) \
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|| (defined(__GNUC__) && \
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(__GNUC__ < 2 || __GNUC__ == 2 && __GNUC_MINOR__ < 6)) \
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|| (defined(__WATCOMC__) && __WATCOMC__ < 1050))
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# define GC_NO_OPERATOR_NEW_ARRAY
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#endif
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#if !defined(GC_NO_OPERATOR_NEW_ARRAY) && !defined(GC_OPERATOR_NEW_ARRAY)
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# define GC_OPERATOR_NEW_ARRAY
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#endif
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#if ! defined ( __BORLANDC__ ) /* Confuses the Borland compiler. */ \
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&& ! defined ( __sgi )
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# define GC_PLACEMENT_DELETE
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#endif
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enum GCPlacement {UseGC,
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#ifndef GC_NAME_CONFLICT
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GC=UseGC,
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#endif
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NoGC, PointerFreeGC};
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class gc {public:
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inline void* operator new( size_t size );
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inline void* operator new( size_t size, GCPlacement gcp );
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inline void* operator new( size_t size, void *p );
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/* Must be redefined here, since the other overloadings */
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/* hide the global definition. */
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inline void operator delete( void* obj );
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# ifdef GC_PLACEMENT_DELETE
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inline void operator delete( void*, void* );
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# endif
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#ifdef GC_OPERATOR_NEW_ARRAY
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inline void* operator new[]( size_t size );
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inline void* operator new[]( size_t size, GCPlacement gcp );
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inline void* operator new[]( size_t size, void *p );
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inline void operator delete[]( void* obj );
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# ifdef GC_PLACEMENT_DELETE
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inline void gc::operator delete[]( void*, void* );
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# endif
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#endif /* GC_OPERATOR_NEW_ARRAY */
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};
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/*
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Instances of classes derived from "gc" will be allocated in the
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collected heap by default, unless an explicit NoGC placement is
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specified. */
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class gc_cleanup: virtual public gc {public:
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inline gc_cleanup();
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inline virtual ~gc_cleanup();
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private:
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inline static void GC_cdecl cleanup( void* obj, void* clientData );};
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/*
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Instances of classes derived from "gc_cleanup" will be allocated
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in the collected heap by default. When the collector discovers an
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inaccessible object derived from "gc_cleanup" or containing a
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member derived from "gc_cleanup", its destructors will be
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invoked. */
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extern "C" {typedef void (*GCCleanUpFunc)( void* obj, void* clientData );}
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#ifdef _MSC_VER
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// Disable warning that "no matching operator delete found; memory will
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// not be freed if initialization throws an exception"
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# pragma warning(disable:4291)
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#endif
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inline void* operator new(
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size_t size,
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GCPlacement gcp,
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GCCleanUpFunc cleanup = 0,
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void* clientData = 0 );
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/*
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Allocates a collectable or uncollected object, according to the
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value of "gcp".
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For collectable objects, if "cleanup" is non-null, then when the
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allocated object "obj" becomes inaccessible, the collector will
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invoke the function "cleanup( obj, clientData )" but will not
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invoke the object's destructors. It is an error to explicitly
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delete an object allocated with a non-null "cleanup".
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It is an error to specify a non-null "cleanup" with NoGC or for
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classes derived from "gc_cleanup" or containing members derived
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from "gc_cleanup". */
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#ifdef _MSC_VER
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/** This ensures that the system default operator new[] doesn't get
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* undefined, which is what seems to happen on VC++ 6 for some reason
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* if we define a multi-argument operator new[].
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* There seems to be really redirect new in this environment without
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* including this everywhere.
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*/
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void *operator new[]( size_t size );
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void operator delete[](void* obj);
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void* operator new( size_t size);
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void operator delete(void* obj);
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// This new operator is used by VC++ in case of Debug builds !
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void* operator new( size_t size,
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int ,//nBlockUse,
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const char * szFileName,
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int nLine );
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#endif /* _MSC_VER */
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#ifdef GC_OPERATOR_NEW_ARRAY
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inline void* operator new[](
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size_t size,
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GCPlacement gcp,
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GCCleanUpFunc cleanup = 0,
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void* clientData = 0 );
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/*
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The operator new for arrays, identical to the above. */
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#endif /* GC_OPERATOR_NEW_ARRAY */
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/****************************************************************************
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Inline implementation
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****************************************************************************/
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inline void* gc::operator new( size_t size ) {
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return GC_MALLOC( size );}
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inline void* gc::operator new( size_t size, GCPlacement gcp ) {
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if (gcp == UseGC)
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return GC_MALLOC( size );
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else if (gcp == PointerFreeGC)
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return GC_MALLOC_ATOMIC( size );
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else
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return GC_MALLOC_UNCOLLECTABLE( size );}
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inline void* gc::operator new( size_t size, void *p ) {
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return p;}
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inline void gc::operator delete( void* obj ) {
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GC_FREE( obj );}
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#ifdef GC_PLACEMENT_DELETE
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inline void gc::operator delete( void*, void* ) {}
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#endif
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#ifdef GC_OPERATOR_NEW_ARRAY
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inline void* gc::operator new[]( size_t size ) {
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return gc::operator new( size );}
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inline void* gc::operator new[]( size_t size, GCPlacement gcp ) {
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return gc::operator new( size, gcp );}
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inline void* gc::operator new[]( size_t size, void *p ) {
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return p;}
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inline void gc::operator delete[]( void* obj ) {
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gc::operator delete( obj );}
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#ifdef GC_PLACEMENT_DELETE
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inline void gc::operator delete[]( void*, void* ) {}
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#endif
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#endif /* GC_OPERATOR_NEW_ARRAY */
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inline gc_cleanup::~gc_cleanup() {
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GC_register_finalizer_ignore_self( GC_base(this), 0, 0, 0, 0 );}
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inline void gc_cleanup::cleanup( void* obj, void* displ ) {
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((gc_cleanup*) ((char*) obj + (ptrdiff_t) displ))->~gc_cleanup();}
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inline gc_cleanup::gc_cleanup() {
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GC_finalization_proc oldProc;
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void* oldData;
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void* base = GC_base( (void *) this );
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if (0 != base) {
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// Don't call the debug version, since this is a real base address.
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GC_register_finalizer_ignore_self(
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base, (GC_finalization_proc)cleanup, (void*) ((char*) this - (char*) base),
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&oldProc, &oldData );
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if (0 != oldProc) {
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GC_register_finalizer_ignore_self( base, oldProc, oldData, 0, 0 );}}}
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inline void* operator new(
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size_t size,
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GCPlacement gcp,
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GCCleanUpFunc cleanup,
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void* clientData )
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{
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void* obj;
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if (gcp == UseGC) {
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obj = GC_MALLOC( size );
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if (cleanup != 0)
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GC_REGISTER_FINALIZER_IGNORE_SELF(
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obj, cleanup, clientData, 0, 0 );}
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else if (gcp == PointerFreeGC) {
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obj = GC_MALLOC_ATOMIC( size );}
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else {
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obj = GC_MALLOC_UNCOLLECTABLE( size );};
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return obj;}
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#ifdef GC_OPERATOR_NEW_ARRAY
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inline void* operator new[](
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size_t size,
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GCPlacement gcp,
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GCCleanUpFunc cleanup,
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void* clientData )
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{
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return ::operator new( size, gcp, cleanup, clientData );}
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#endif /* GC_OPERATOR_NEW_ARRAY */
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#endif /* GC_CPP_H */
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