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7125beea7a
2002-12-22 Anthony Green <green@redhat.com> * boehm.cc (_Jv_MarkObj): Mark the protectionDomain of a class. From-SVN: r60834
567 lines
16 KiB
C++
567 lines
16 KiB
C++
// boehm.cc - interface between libjava and Boehm GC.
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/* Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation
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This file is part of libgcj.
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This software is copyrighted work licensed under the terms of the
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Libgcj License. Please consult the file "LIBGCJ_LICENSE" for
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details. */
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#include <config.h>
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#include <stdio.h>
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#include <jvm.h>
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#include <gcj/cni.h>
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#include <java/lang/Class.h>
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#include <java/lang/reflect/Modifier.h>
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#include <java-interp.h>
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// More nastiness: the GC wants to define TRUE and FALSE. We don't
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// need the Java definitions (themselves a hack), so we undefine them.
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#undef TRUE
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#undef FALSE
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extern "C"
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{
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#include <private/gc_pmark.h>
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#include <gc_gcj.h>
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#ifdef THREAD_LOCAL_ALLOC
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# define GC_REDIRECT_TO_LOCAL
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# include <gc_local_alloc.h>
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#endif
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// These aren't declared in any Boehm GC header.
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void GC_finalize_all (void);
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ptr_t GC_debug_generic_malloc (size_t size, int k, GC_EXTRA_PARAMS);
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};
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#define MAYBE_MARK(Obj, Top, Limit, Source, Exit) \
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Top=GC_MARK_AND_PUSH((GC_PTR)Obj, Top, Limit, (GC_PTR *)Source)
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// `kind' index used when allocating Java arrays.
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static int array_kind_x;
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// Freelist used for Java arrays.
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static ptr_t *array_free_list;
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// Lock used to protect access to Boehm's GC_enable/GC_disable functions.
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static _Jv_Mutex_t disable_gc_mutex;
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// This is called by the GC during the mark phase. It marks a Java
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// object. We use `void *' arguments and return, and not what the
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// Boehm GC wants, to avoid pollution in our headers.
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void *
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_Jv_MarkObj (void *addr, void *msp, void *msl, void * /* env */)
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{
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mse *mark_stack_ptr = (mse *) msp;
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mse *mark_stack_limit = (mse *) msl;
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jobject obj = (jobject) addr;
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// FIXME: if env is 1, this object was allocated through the debug
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// interface, and addr points to the beginning of the debug header.
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// In that case, we should really add the size of the header to addr.
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_Jv_VTable *dt = *(_Jv_VTable **) addr;
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// The object might not yet have its vtable set, or it might
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// really be an object on the freelist. In either case, the vtable slot
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// will either be 0, or it will point to a cleared object.
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// This assumes Java objects have size at least 3 words,
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// including the header. But this should remain true, since this
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// should only be used with debugging allocation or with large objects.
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if (__builtin_expect (! dt || !(dt -> get_finalizer()), false))
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return mark_stack_ptr;
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jclass klass = dt->clas;
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ptr_t p;
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# ifndef JV_HASH_SYNCHRONIZATION
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// Every object has a sync_info pointer.
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p = (ptr_t) obj->sync_info;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, obj, o1label);
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# endif
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// Mark the object's class.
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p = (ptr_t) klass;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, obj, o2label);
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if (__builtin_expect (klass == &java::lang::Class::class$, false))
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{
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// Currently we allocate some of the memory referenced from class objects
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// as pointerfree memory, and then mark it more intelligently here.
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// We ensure that the ClassClass mark descriptor forces invocation of
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// this procedure.
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// Correctness of this is subtle, but it looks OK to me for now. For the incremental
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// collector, we need to make sure that the class object is written whenever
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// any of the subobjects are altered and may need rescanning. This may be tricky
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// during construction, and this may not be the right way to do this with
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// incremental collection.
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// If we overflow the mark stack, we will rescan the class object, so we should
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// be OK. The same applies if we redo the mark phase because win32 unmapped part
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// of our root set. - HB
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jclass c = (jclass) addr;
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p = (ptr_t) c->name;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c3label);
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p = (ptr_t) c->superclass;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c4label);
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for (int i = 0; i < c->constants.size; ++i)
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{
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/* FIXME: We could make this more precise by using the tags -KKT */
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p = (ptr_t) c->constants.data[i].p;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c5label);
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}
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#ifdef INTERPRETER
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if (_Jv_IsInterpretedClass (c))
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{
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p = (ptr_t) c->constants.tags;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c5alabel);
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p = (ptr_t) c->constants.data;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c5blabel);
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p = (ptr_t) c->vtable;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c5clabel);
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}
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#endif
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// If the class is an array, then the methods field holds a
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// pointer to the element class. If the class is primitive,
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// then the methods field holds a pointer to the array class.
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p = (ptr_t) c->methods;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c6label);
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// The vtable might have been set, but the rest of the class
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// could still be uninitialized. If this is the case, then
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// c.isArray will SEGV. We check for this, and if it is the
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// case we just return.
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if (__builtin_expect (c->name == NULL, false))
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return mark_stack_ptr;
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if (! c->isArray() && ! c->isPrimitive())
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{
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// Scan each method in the cases where `methods' really
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// points to a methods structure.
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for (int i = 0; i < c->method_count; ++i)
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{
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p = (ptr_t) c->methods[i].name;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c,
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cm1label);
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p = (ptr_t) c->methods[i].signature;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c,
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cm2label);
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}
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}
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// Mark all the fields.
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p = (ptr_t) c->fields;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c8label);
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for (int i = 0; i < c->field_count; ++i)
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{
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_Jv_Field* field = &c->fields[i];
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#ifndef COMPACT_FIELDS
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p = (ptr_t) field->name;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c8alabel);
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#endif
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p = (ptr_t) field->type;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c8blabel);
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// For the interpreter, we also need to mark the memory
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// containing static members
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if ((field->flags & java::lang::reflect::Modifier::STATIC))
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{
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p = (ptr_t) field->u.addr;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c8clabel);
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// also, if the static member is a reference,
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// mark also the value pointed to. We check for isResolved
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// since marking can happen before memory is allocated for
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// static members.
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if (JvFieldIsRef (field) && field->isResolved())
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{
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jobject val = *(jobject*) field->u.addr;
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p = (ptr_t) val;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit,
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c, c8elabel);
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}
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}
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}
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p = (ptr_t) c->vtable;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, c9label);
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p = (ptr_t) c->interfaces;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, cAlabel);
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for (int i = 0; i < c->interface_count; ++i)
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{
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p = (ptr_t) c->interfaces[i];
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, cClabel);
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}
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p = (ptr_t) c->loader;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, cBlabel);
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p = (ptr_t) c->arrayclass;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, cDlabel);
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p = (ptr_t) c->protectionDomain;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c, cPlabel);
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#ifdef INTERPRETER
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if (_Jv_IsInterpretedClass (c))
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{
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_Jv_InterpClass* ic = (_Jv_InterpClass*) c;
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p = (ptr_t) ic->interpreted_methods;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, ic, cElabel);
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for (int i = 0; i < c->method_count; i++)
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{
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p = (ptr_t) ic->interpreted_methods[i];
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, ic, \
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cFlabel);
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// Mark the direct-threaded code.
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if ((c->methods[i].accflags
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& java::lang::reflect::Modifier::NATIVE) == 0)
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{
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_Jv_InterpMethod *im
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= (_Jv_InterpMethod *) ic->interpreted_methods[i];
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if (im)
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{
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p = (ptr_t) im->prepared;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, ic, \
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cFlabel);
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}
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}
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// The interpreter installs a heap-allocated trampoline
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// here, so we'll mark it.
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p = (ptr_t) c->methods[i].ncode;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, c,
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cm3label);
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}
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p = (ptr_t) ic->field_initializers;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, ic, cGlabel);
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}
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#endif
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}
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else
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{
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// NOTE: each class only holds information about the class
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// itself. So we must do the marking for the entire inheritance
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// tree in order to mark all fields. FIXME: what about
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// interfaces? We skip Object here, because Object only has a
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// sync_info, and we handled that earlier.
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// Note: occasionally `klass' can be null. For instance, this
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// can happen if a GC occurs between the point where an object
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// is allocated and where the vtbl slot is set.
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while (klass && klass != &java::lang::Object::class$)
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{
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jfieldID field = JvGetFirstInstanceField (klass);
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jint max = JvNumInstanceFields (klass);
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for (int i = 0; i < max; ++i)
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{
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if (JvFieldIsRef (field))
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{
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jobject val = JvGetObjectField (obj, field);
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p = (ptr_t) val;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit,
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obj, elabel);
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}
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field = field->getNextField ();
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}
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klass = klass->getSuperclass();
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}
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}
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return mark_stack_ptr;
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}
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// This is called by the GC during the mark phase. It marks a Java
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// array (of objects). We use `void *' arguments and return, and not
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// what the Boehm GC wants, to avoid pollution in our headers.
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void *
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_Jv_MarkArray (void *addr, void *msp, void *msl, void * /*env*/)
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{
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mse *mark_stack_ptr = (mse *) msp;
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mse *mark_stack_limit = (mse *) msl;
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jobjectArray array = (jobjectArray) addr;
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_Jv_VTable *dt = *(_Jv_VTable **) addr;
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// Assumes size >= 3 words. That's currently true since arrays have
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// a vtable, sync pointer, and size. If the sync pointer goes away,
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// we may need to round up the size.
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if (__builtin_expect (! dt || !(dt -> get_finalizer()), false))
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return mark_stack_ptr;
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jclass klass = dt->clas;
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ptr_t p;
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# ifndef JV_HASH_SYNCHRONIZATION
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// Every object has a sync_info pointer.
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p = (ptr_t) array->sync_info;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, array, e1label);
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# endif
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// Mark the object's class.
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p = (ptr_t) klass;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, &(dt -> clas), o2label);
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for (int i = 0; i < JvGetArrayLength (array); ++i)
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{
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jobject obj = elements (array)[i];
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p = (ptr_t) obj;
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MAYBE_MARK (p, mark_stack_ptr, mark_stack_limit, array, e2label);
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}
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return mark_stack_ptr;
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}
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// Generate a GC marking descriptor for a class.
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//
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// We assume that the gcj mark proc has index 0. This is a dubious assumption,
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// since another one could be registered first. But the compiler also
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// knows this, so in that case everything else will break, too.
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#define GCJ_DEFAULT_DESCR GC_MAKE_PROC(GC_GCJ_RESERVED_MARK_PROC_INDEX,0)
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void *
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_Jv_BuildGCDescr(jclass)
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{
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/* FIXME: We should really look at the class and build the descriptor. */
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return (void *)(GCJ_DEFAULT_DESCR);
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}
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// Allocate some space that is known to be pointer-free.
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void *
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_Jv_AllocBytes (jsize size)
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{
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void *r = GC_MALLOC_ATOMIC (size);
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// We have to explicitly zero memory here, as the GC doesn't
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// guarantee that PTRFREE allocations are zeroed. Note that we
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// don't have to do this for other allocation types because we set
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// the `ok_init' flag in the type descriptor.
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memset (r, 0, size);
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return r;
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}
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// Allocate space for a new Java array.
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// Used only for arrays of objects.
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void *
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_Jv_AllocArray (jsize size, jclass klass)
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{
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void *obj;
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const jsize min_heap_addr = 16*1024;
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// A heuristic. If size is less than this value, the size
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// stored in the array can't possibly be misinterpreted as
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// a pointer. Thus we lose nothing by scanning the object
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// completely conservatively, since no misidentification can
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// take place.
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#ifdef GC_DEBUG
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// There isn't much to lose by scanning this conservatively.
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// If we didn't, the mark proc would have to understand that
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// it needed to skip the header.
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obj = GC_MALLOC(size);
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#else
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if (size < min_heap_addr)
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obj = GC_MALLOC(size);
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else
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obj = GC_generic_malloc (size, array_kind_x);
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#endif
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*((_Jv_VTable **) obj) = klass->vtable;
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return obj;
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}
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/* Allocate space for a new non-Java object, which does not have the usual
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Java object header but may contain pointers to other GC'ed objects. */
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void *
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_Jv_AllocRawObj (jsize size)
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{
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return (void *) GC_MALLOC (size);
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}
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static void
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call_finalizer (GC_PTR obj, GC_PTR client_data)
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{
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_Jv_FinalizerFunc *fn = (_Jv_FinalizerFunc *) client_data;
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jobject jobj = (jobject) obj;
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(*fn) (jobj);
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}
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void
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_Jv_RegisterFinalizer (void *object, _Jv_FinalizerFunc *meth)
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{
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GC_REGISTER_FINALIZER_NO_ORDER (object, call_finalizer, (GC_PTR) meth,
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NULL, NULL);
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}
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void
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_Jv_RunFinalizers (void)
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{
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GC_invoke_finalizers ();
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}
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void
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_Jv_RunAllFinalizers (void)
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{
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GC_finalize_all ();
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}
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void
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_Jv_RunGC (void)
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{
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GC_gcollect ();
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}
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long
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_Jv_GCTotalMemory (void)
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{
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return GC_get_heap_size ();
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}
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long
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_Jv_GCFreeMemory (void)
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{
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return GC_get_free_bytes ();
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}
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void
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_Jv_GCSetInitialHeapSize (size_t size)
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{
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size_t current = GC_get_heap_size ();
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if (size > current)
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GC_expand_hp (size - current);
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}
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void
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_Jv_GCSetMaximumHeapSize (size_t size)
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{
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GC_set_max_heap_size ((GC_word) size);
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}
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// From boehm's misc.c
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extern "C" void GC_enable();
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extern "C" void GC_disable();
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void
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_Jv_DisableGC (void)
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{
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_Jv_MutexLock (&disable_gc_mutex);
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GC_disable();
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_Jv_MutexUnlock (&disable_gc_mutex);
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}
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void
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_Jv_EnableGC (void)
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{
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_Jv_MutexLock (&disable_gc_mutex);
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GC_enable();
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_Jv_MutexUnlock (&disable_gc_mutex);
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}
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static void * handle_out_of_memory(size_t)
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{
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_Jv_ThrowNoMemory();
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}
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void
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_Jv_InitGC (void)
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{
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int proc;
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// Ignore pointers that do not point to the start of an object.
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GC_all_interior_pointers = 0;
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// Configure the collector to use the bitmap marking descriptors that we
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// stash in the class vtable.
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GC_init_gcj_malloc (0, (void *) _Jv_MarkObj);
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// Cause an out of memory error to be thrown from the allocators,
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// instead of returning 0. This is cheaper than checking on allocation.
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GC_oom_fn = handle_out_of_memory;
|
||
|
||
GC_java_finalization = 1;
|
||
|
||
// We use a different mark procedure for object arrays. This code
|
||
// configures a different object `kind' for object array allocation and
|
||
// marking. FIXME: see above.
|
||
array_free_list = (ptr_t *) GC_generic_malloc_inner ((MAXOBJSZ + 1)
|
||
* sizeof (ptr_t),
|
||
PTRFREE);
|
||
memset (array_free_list, 0, (MAXOBJSZ + 1) * sizeof (ptr_t));
|
||
|
||
proc = GC_n_mark_procs++;
|
||
GC_mark_procs[proc] = (GC_mark_proc) _Jv_MarkArray;
|
||
|
||
array_kind_x = GC_n_kinds++;
|
||
GC_obj_kinds[array_kind_x].ok_freelist = array_free_list;
|
||
GC_obj_kinds[array_kind_x].ok_reclaim_list = 0;
|
||
GC_obj_kinds[array_kind_x].ok_descriptor = GC_MAKE_PROC (proc, 0);
|
||
GC_obj_kinds[array_kind_x].ok_relocate_descr = FALSE;
|
||
GC_obj_kinds[array_kind_x].ok_init = TRUE;
|
||
|
||
_Jv_MutexInit (&disable_gc_mutex);
|
||
}
|
||
|
||
#ifdef JV_HASH_SYNCHRONIZATION
|
||
// Allocate an object with a fake vtable pointer, which causes only
|
||
// the first field (beyond the fake vtable pointer) to be traced.
|
||
// Eventually this should probably be generalized.
|
||
|
||
static _Jv_VTable trace_one_vtable = {
|
||
0, // class pointer
|
||
(void *)(2 * sizeof(void *)),
|
||
// descriptor; scan 2 words incl. vtable ptr.
|
||
// Least significant bits must be zero to
|
||
// identify this as a length descriptor
|
||
{0} // First method
|
||
};
|
||
|
||
void *
|
||
_Jv_AllocTraceOne (jsize size /* includes vtable slot */)
|
||
{
|
||
return GC_GCJ_MALLOC (size, &trace_one_vtable);
|
||
}
|
||
|
||
// Ditto for two words.
|
||
// the first field (beyond the fake vtable pointer) to be traced.
|
||
// Eventually this should probably be generalized.
|
||
|
||
static _Jv_VTable trace_two_vtable =
|
||
{
|
||
0, // class pointer
|
||
(void *)(3 * sizeof(void *)),
|
||
// descriptor; scan 3 words incl. vtable ptr.
|
||
{0} // First method
|
||
};
|
||
|
||
void *
|
||
_Jv_AllocTraceTwo (jsize size /* includes vtable slot */)
|
||
{
|
||
return GC_GCJ_MALLOC (size, &trace_two_vtable);
|
||
}
|
||
|
||
#endif /* JV_HASH_SYNCHRONIZATION */
|
||
|
||
void
|
||
_Jv_GCInitializeFinalizers (void (*notifier) (void))
|
||
{
|
||
GC_finalize_on_demand = 1;
|
||
GC_finalizer_notifier = notifier;
|
||
}
|
||
|
||
void
|
||
_Jv_GCRegisterDisappearingLink (jobject *objp)
|
||
{
|
||
GC_general_register_disappearing_link ((GC_PTR *) objp, (GC_PTR) *objp);
|
||
}
|
||
|
||
jboolean
|
||
_Jv_GCCanReclaimSoftReference (jobject)
|
||
{
|
||
// For now, always reclaim soft references. FIXME.
|
||
return true;
|
||
}
|