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#ifndef SHARE_GC_SHARED_SPACE_HPP
#define SHARE_GC_SHARED_SPACE_HPP
#include "gc/shared/blockOffsetTable.hpp"
#include "gc/shared/cardTable.hpp"
#include "gc/shared/workgroup.hpp"
#include "memory/allocation.hpp"
#include "memory/iterator.hpp"
#include "memory/memRegion.hpp"
#include "oops/markWord.hpp"
#include "runtime/mutexLocker.hpp"
#include "utilities/align.hpp"
#include "utilities/macros.hpp"
// A space is an abstraction for the "storage units" backing
// up the generation abstraction. It includes specific
// implementations for keeping track of free and used space,
// for iterating over objects and free blocks, etc.
// Forward decls.
class Space;
class BlockOffsetArray;
class BlockOffsetArrayContigSpace;
class Generation;
class CompactibleSpace;
class BlockOffsetTable;
class CardTableRS;
class DirtyCardToOopClosure;
// A Space describes a heap area. Class Space is an abstract
// base class.
//
// Space supports allocation, size computation and GC support is provided.
//
// Invariant: bottom() and end() are on page_size boundaries and
// bottom() <= top() <= end()
// top() is inclusive and end() is exclusive.
class Space: public CHeapObj<mtGC> {
friend class VMStructs;
protected:
HeapWord* _bottom;
HeapWord* _end;
// Used in support of save_marks()
HeapWord* _saved_mark_word;
// A sequential tasks done structure. This supports
// parallel GC, where we have threads dynamically
// claiming sub-tasks from a larger parallel task.
SequentialSubTasksDone _par_seq_tasks;
Space():
_bottom(NULL), _end(NULL) { }
public:
// Accessors
HeapWord* bottom() const { return _bottom; }
HeapWord* end() const { return _end; }
virtual void set_bottom(HeapWord* value) { _bottom = value; }
virtual void set_end(HeapWord* value) { _end = value; }
virtual HeapWord* saved_mark_word() const { return _saved_mark_word; }
void set_saved_mark_word(HeapWord* p) { _saved_mark_word = p; }
// Returns true if this object has been allocated since a
// generation's "save_marks" call.
virtual bool obj_allocated_since_save_marks(const oop obj) const {
return (HeapWord*)obj >= saved_mark_word();
}
// Returns a subregion of the space containing only the allocated objects in
// the space.
virtual MemRegion used_region() const = 0;
// Returns a region that is guaranteed to contain (at least) all objects
// allocated at the time of the last call to "save_marks". If the space
// initializes its DirtyCardToOopClosure's specifying the "contig" option
// (that is, if the space is contiguous), then this region must contain only
// such objects: the memregion will be from the bottom of the region to the
// saved mark. Otherwise, the "obj_allocated_since_save_marks" method of
// the space must distinguish between objects in the region allocated before
// and after the call to save marks.
MemRegion used_region_at_save_marks() const {
return MemRegion(bottom(), saved_mark_word());
}
// Initialization.
// "initialize" should be called once on a space, before it is used for
// any purpose. The "mr" arguments gives the bounds of the space, and
// the "clear_space" argument should be true unless the memory in "mr" is
// known to be zeroed.
virtual void initialize(MemRegion mr, bool clear_space, bool mangle_space);
// The "clear" method must be called on a region that may have
// had allocation performed in it, but is now to be considered empty.
virtual void clear(bool mangle_space);
// For detecting GC bugs. Should only be called at GC boundaries, since
// some unused space may be used as scratch space during GC's.
// We also call this when expanding a space to satisfy an allocation
// request. See bug #4668531
virtual void mangle_unused_area() = 0;
virtual void mangle_unused_area_complete() = 0;
// Testers
bool is_empty() const { return used() == 0; }
bool not_empty() const { return used() > 0; }
// Returns true iff the given the space contains the
// given address as part of an allocated object. For
// certain kinds of spaces, this might be a potentially
// expensive operation. To prevent performance problems
// on account of its inadvertent use in product jvm's,
// we restrict its use to assertion checks only.
bool is_in(const void* p) const {
return used_region().contains(p);
}
bool is_in(oop obj) const {
return is_in((void*)obj);
}
// Returns true iff the given reserved memory of the space contains the
// given address.
bool is_in_reserved(const void* p) const { return _bottom <= p && p < _end; }
// Returns true iff the given block is not allocated.
virtual bool is_free_block(const HeapWord* p) const = 0;
// Test whether p is double-aligned
static bool is_aligned(void* p) {
return ::is_aligned(p, sizeof(double));
}
// Size computations. Sizes are in bytes.
size_t capacity() const { return byte_size(bottom(), end()); }
virtual size_t used() const = 0;
virtual size_t free() const = 0;
// Iterate over all the ref-containing fields of all objects in the
// space, calling "cl.do_oop" on each. Fields in objects allocated by
// applications of the closure are not included in the iteration.
virtual void oop_iterate(OopIterateClosure* cl);
// Iterate over all objects in the space, calling "cl.do_object" on
// each. Objects allocated by applications of the closure are not
// included in the iteration.
virtual void object_iterate(ObjectClosure* blk) = 0;
// Create and return a new dirty card to oop closure. Can be
// overridden to return the appropriate type of closure
// depending on the type of space in which the closure will
// operate. ResourceArea allocated.
virtual DirtyCardToOopClosure* new_dcto_cl(OopIterateClosure* cl,
CardTable::PrecisionStyle precision,
HeapWord* boundary,
bool parallel);
// If "p" is in the space, returns the address of the start of the
// "block" that contains "p". We say "block" instead of "object" since
// some heaps may not pack objects densely; a chunk may either be an
// object or a non-object. If "p" is not in the space, return NULL.
virtual HeapWord* block_start_const(const void* p) const = 0;
// The non-const version may have benevolent side effects on the data
// structure supporting these calls, possibly speeding up future calls.
// The default implementation, however, is simply to call the const
// version.
virtual HeapWord* block_start(const void* p);
// Requires "addr" to be the start of a chunk, and returns its size.
// "addr + size" is required to be the start of a new chunk, or the end
// of the active area of the heap.
virtual size_t block_size(const HeapWord* addr) const = 0;
// Requires "addr" to be the start of a block, and returns "TRUE" iff
// the block is an object.
virtual bool block_is_obj(const HeapWord* addr) const = 0;
// Requires "addr" to be the start of a block, and returns "TRUE" iff
// the block is an object and the object is alive.
virtual bool obj_is_alive(const HeapWord* addr) const;
// Allocation (return NULL if full). Assumes the caller has established
// mutually exclusive access to the space.
virtual HeapWord* allocate(size_t word_size) = 0;
// Allocation (return NULL if full). Enforces mutual exclusion internally.
virtual HeapWord* par_allocate(size_t word_size) = 0;
#if INCLUDE_SERIALGC
// Mark-sweep-compact support: all spaces can update pointers to objects
// moving as a part of compaction.
virtual void adjust_pointers() = 0;
#endif
virtual void print() const;
virtual void print_on(outputStream* st) const;
virtual void print_short() const;
virtual void print_short_on(outputStream* st) const;
// Accessor for parallel sequential tasks.
SequentialSubTasksDone* par_seq_tasks() { return &_par_seq_tasks; }
// IF "this" is a ContiguousSpace, return it, else return NULL.
virtual ContiguousSpace* toContiguousSpace() {
return NULL;
}
// Debugging
virtual void verify() const = 0;
};
// A MemRegionClosure (ResourceObj) whose "do_MemRegion" function applies an
// OopClosure to (the addresses of) all the ref-containing fields that could
// be modified by virtue of the given MemRegion being dirty. (Note that
// because of the imprecise nature of the write barrier, this may iterate
// over oops beyond the region.)
// This base type for dirty card to oop closures handles memory regions
// in non-contiguous spaces with no boundaries, and should be sub-classed
// to support other space types. See ContiguousDCTOC for a sub-class
// that works with ContiguousSpaces.
class DirtyCardToOopClosure: public MemRegionClosureRO {
protected:
OopIterateClosure* _cl;
Space* _sp;
CardTable::PrecisionStyle _precision;
HeapWord* _boundary; // If non-NULL, process only non-NULL oops
// pointing below boundary.
HeapWord* _min_done; // ObjHeadPreciseArray precision requires
// a downwards traversal; this is the
// lowest location already done (or,
// alternatively, the lowest address that
// shouldn't be done again. NULL means infinity.)
NOT_PRODUCT(HeapWord* _last_bottom;)
NOT_PRODUCT(HeapWord* _last_explicit_min_done;)
// Get the actual top of the area on which the closure will
// operate, given where the top is assumed to be (the end of the
// memory region passed to do_MemRegion) and where the object
// at the top is assumed to start. For example, an object may
// start at the top but actually extend past the assumed top,
// in which case the top becomes the end of the object.
virtual HeapWord* get_actual_top(HeapWord* top, HeapWord* top_obj);
// Walk the given memory region from bottom to (actual) top
// looking for objects and applying the oop closure (_cl) to
// them. The base implementation of this treats the area as
// blocks, where a block may or may not be an object. Sub-
// classes should override this to provide more accurate
// or possibly more efficient walking.
virtual void walk_mem_region(MemRegion mr, HeapWord* bottom, HeapWord* top);
public:
DirtyCardToOopClosure(Space* sp, OopIterateClosure* cl,
CardTable::PrecisionStyle precision,
HeapWord* boundary) :
_cl(cl), _sp(sp), _precision(precision), _boundary(boundary),
_min_done(NULL) {
NOT_PRODUCT(_last_bottom = NULL);
NOT_PRODUCT(_last_explicit_min_done = NULL);
}
void do_MemRegion(MemRegion mr);
void set_min_done(HeapWord* min_done) {
_min_done = min_done;
NOT_PRODUCT(_last_explicit_min_done = _min_done);
}
#ifndef PRODUCT
void set_last_bottom(HeapWord* last_bottom) {
_last_bottom = last_bottom;
}
#endif
};
// A structure to represent a point at which objects are being copied
// during compaction.
class CompactPoint : public StackObj {
public:
Generation* gen;
CompactibleSpace* space;
HeapWord* threshold;
CompactPoint(Generation* g = NULL) :
gen(g), space(NULL), threshold(0) {}
};
// A space that supports compaction operations. This is usually, but not
// necessarily, a space that is normally contiguous. But, for example, a
// free-list-based space whose normal collection is a mark-sweep without
// compaction could still support compaction in full GC's.
//
// The compaction operations are implemented by the
// scan_and_{adjust_pointers,compact,forward} function templates.
// The following are, non-virtual, auxiliary functions used by these function templates:
// - scan_limit()
// - scanned_block_is_obj()
// - scanned_block_size()
// - adjust_obj_size()
// - obj_size()
// These functions are to be used exclusively by the scan_and_* function templates,
// and must be defined for all (non-abstract) subclasses of CompactibleSpace.
//
// NOTE: Any subclasses to CompactibleSpace wanting to change/define the behavior
// in any of the auxiliary functions must also override the corresponding
// prepare_for_compaction/adjust_pointers/compact functions using them.
// If not, such changes will not be used or have no effect on the compaction operations.
//
// This translates to the following dependencies:
// Overrides/definitions of
// - scan_limit
// - scanned_block_is_obj
// - scanned_block_size
// require override/definition of prepare_for_compaction().
// Similar dependencies exist between
// - adjust_obj_size and adjust_pointers()
// - obj_size and compact().
//
// Additionally, this also means that changes to block_size() or block_is_obj() that
// should be effective during the compaction operations must provide a corresponding
// definition of scanned_block_size/scanned_block_is_obj respectively.
class CompactibleSpace: public Space {
friend class VMStructs;
private:
HeapWord* _compaction_top;
CompactibleSpace* _next_compaction_space;
// Auxiliary functions for scan_and_{forward,adjust_pointers,compact} support.
inline size_t adjust_obj_size(size_t size) const {
return size;
}
inline size_t obj_size(const HeapWord* addr) const;
template <class SpaceType>
static inline void verify_up_to_first_dead(SpaceType* space) NOT_DEBUG_RETURN;
template <class SpaceType>
static inline void clear_empty_region(SpaceType* space);
public:
CompactibleSpace() :
_compaction_top(NULL), _next_compaction_space(NULL) {}
virtual void initialize(MemRegion mr, bool clear_space, bool mangle_space);
virtual void clear(bool mangle_space);
// Used temporarily during a compaction phase to hold the value
// top should have when compaction is complete.
HeapWord* compaction_top() const { return _compaction_top; }
void set_compaction_top(HeapWord* value) {
assert(value == NULL || (value >= bottom() && value <= end()),
"should point inside space");
_compaction_top = value;
}
// Perform operations on the space needed after a compaction
// has been performed.
virtual void reset_after_compaction() = 0;
// Returns the next space (in the current generation) to be compacted in
// the global compaction order. Also is used to select the next
// space into which to compact.
virtual CompactibleSpace* next_compaction_space() const {
return _next_compaction_space;
}
void set_next_compaction_space(CompactibleSpace* csp) {
_next_compaction_space = csp;
}
#if INCLUDE_SERIALGC
// MarkSweep support phase2
// Start the process of compaction of the current space: compute
// post-compaction addresses, and insert forwarding pointers. The fields
// "cp->gen" and "cp->compaction_space" are the generation and space into
// which we are currently compacting. This call updates "cp" as necessary,
// and leaves the "compaction_top" of the final value of
// "cp->compaction_space" up-to-date. Offset tables may be updated in
// this phase as if the final copy had occurred; if so, "cp->threshold"
// indicates when the next such action should be taken.
virtual void prepare_for_compaction(CompactPoint* cp) = 0;
// MarkSweep support phase3
virtual void adjust_pointers();
// MarkSweep support phase4
virtual void compact();
#endif // INCLUDE_SERIALGC
// The maximum percentage of objects that can be dead in the compacted
// live part of a compacted space ("deadwood" support.)
virtual size_t allowed_dead_ratio() const { return 0; };
// Some contiguous spaces may maintain some data structures that should
// be updated whenever an allocation crosses a boundary. This function
// returns the first such boundary.
// (The default implementation returns the end of the space, so the
// boundary is never crossed.)
virtual HeapWord* initialize_threshold() { return end(); }
// "q" is an object of the given "size" that should be forwarded;
// "cp" names the generation ("gen") and containing "this" (which must
// also equal "cp->space"). "compact_top" is where in "this" the
// next object should be forwarded to. If there is room in "this" for
// the object, insert an appropriate forwarding pointer in "q".
// If not, go to the next compaction space (there must
// be one, since compaction must succeed -- we go to the first space of
// the previous generation if necessary, updating "cp"), reset compact_top
// and then forward. In either case, returns the new value of "compact_top".
// If the forwarding crosses "cp->threshold", invokes the "cross_threshold"
// function of the then-current compaction space, and updates "cp->threshold
// accordingly".
virtual HeapWord* forward(oop q, size_t size, CompactPoint* cp,
HeapWord* compact_top);
// Return a size with adjustments as required of the space.
virtual size_t adjust_object_size_v(size_t size) const { return size; }
void set_first_dead(HeapWord* value) { _first_dead = value; }
void set_end_of_live(HeapWord* value) { _end_of_live = value; }
protected:
// Used during compaction.
HeapWord* _first_dead;
HeapWord* _end_of_live;
// This the function is invoked when an allocation of an object covering
// "start" to "end occurs crosses the threshold; returns the next
// threshold. (The default implementation does nothing.)
virtual HeapWord* cross_threshold(HeapWord* start, HeapWord* the_end) {
return end();
}
// Below are template functions for scan_and_* algorithms (avoiding virtual calls).
// The space argument should be a subclass of CompactibleSpace, implementing
// scan_limit(), scanned_block_is_obj(), and scanned_block_size(),
// and possibly also overriding obj_size(), and adjust_obj_size().
// These functions should avoid virtual calls whenever possible.
#if INCLUDE_SERIALGC
// Frequently calls adjust_obj_size().
template <class SpaceType>
static inline void scan_and_adjust_pointers(SpaceType* space);
#endif
// Frequently calls obj_size().
template <class SpaceType>
static inline void scan_and_compact(SpaceType* space);
// Frequently calls scanned_block_is_obj() and scanned_block_size().
// Requires the scan_limit() function.
template <class SpaceType>
static inline void scan_and_forward(SpaceType* space, CompactPoint* cp);
};
class GenSpaceMangler;
// A space in which the free area is contiguous. It therefore supports
// faster allocation, and compaction.
class ContiguousSpace: public CompactibleSpace {
friend class VMStructs;
// Allow scan_and_forward function to call (private) overrides for auxiliary functions on this class
template <typename SpaceType>
friend void CompactibleSpace::scan_and_forward(SpaceType* space, CompactPoint* cp);
private:
// Auxiliary functions for scan_and_forward support.
// See comments for CompactibleSpace for more information.
inline HeapWord* scan_limit() const {
return top();
}
inline bool scanned_block_is_obj(const HeapWord* addr) const {
return true; // Always true, since scan_limit is top
}
inline size_t scanned_block_size(const HeapWord* addr) const;
protected:
HeapWord* _top;
HeapWord* _concurrent_iteration_safe_limit;
// A helper for mangling the unused area of the space in debug builds.
GenSpaceMangler* _mangler;
GenSpaceMangler* mangler() { return _mangler; }
// Allocation helpers (return NULL if full).
inline HeapWord* allocate_impl(size_t word_size);
inline HeapWord* par_allocate_impl(size_t word_size);
public:
ContiguousSpace();
~ContiguousSpace();
virtual void initialize(MemRegion mr, bool clear_space, bool mangle_space);
virtual void clear(bool mangle_space);
// Accessors
HeapWord* top() const { return _top; }
void set_top(HeapWord* value) { _top = value; }
void set_saved_mark() { _saved_mark_word = top(); }
void reset_saved_mark() { _saved_mark_word = bottom(); }
bool saved_mark_at_top() const { return saved_mark_word() == top(); }
// In debug mode mangle (write it with a particular bit
// pattern) the unused part of a space.
// Used to save the an address in a space for later use during mangling.
void set_top_for_allocations(HeapWord* v) PRODUCT_RETURN;
// Used to save the space's current top for later use during mangling.
void set_top_for_allocations() PRODUCT_RETURN;
// Mangle regions in the space from the current top up to the
// previously mangled part of the space.
void mangle_unused_area() PRODUCT_RETURN;
// Mangle [top, end)
void mangle_unused_area_complete() PRODUCT_RETURN;
// Do some sparse checking on the area that should have been mangled.
void check_mangled_unused_area(HeapWord* limit) PRODUCT_RETURN;
// Check the complete area that should have been mangled.
// This code may be NULL depending on the macro DEBUG_MANGLING.
void check_mangled_unused_area_complete() PRODUCT_RETURN;
// Size computations: sizes in bytes.
size_t capacity() const { return byte_size(bottom(), end()); }
size_t used() const { return byte_size(bottom(), top()); }
size_t free() const { return byte_size(top(), end()); }
virtual bool is_free_block(const HeapWord* p) const;
// In a contiguous space we have a more obvious bound on what parts
// contain objects.
MemRegion used_region() const { return MemRegion(bottom(), top()); }
// Allocation (return NULL if full)
virtual HeapWord* allocate(size_t word_size);
virtual HeapWord* par_allocate(size_t word_size);
HeapWord* allocate_aligned(size_t word_size);
// Iteration
void oop_iterate(OopIterateClosure* cl);
void object_iterate(ObjectClosure* blk);
HeapWord* concurrent_iteration_safe_limit() {
assert(_concurrent_iteration_safe_limit <= top(),
"_concurrent_iteration_safe_limit update missed");
return _concurrent_iteration_safe_limit;
}
// changes the safe limit, all objects from bottom() to the new
// limit should be properly initialized
void set_concurrent_iteration_safe_limit(HeapWord* new_limit) {
assert(new_limit <= top(), "uninitialized objects in the safe range");
_concurrent_iteration_safe_limit = new_limit;
}
// Compaction support
virtual void reset_after_compaction() {
assert(compaction_top() >= bottom() && compaction_top() <= end(), "should point inside space");
set_top(compaction_top());
// set new iteration safe limit
set_concurrent_iteration_safe_limit(compaction_top());
}
// Override.
DirtyCardToOopClosure* new_dcto_cl(OopIterateClosure* cl,
CardTable::PrecisionStyle precision,
HeapWord* boundary,
bool parallel);
// Apply "blk->do_oop" to the addresses of all reference fields in objects
// starting with the _saved_mark_word, which was noted during a generation's
// save_marks and is required to denote the head of an object.
// Fields in objects allocated by applications of the closure
// *are* included in the iteration.
// Updates _saved_mark_word to point to just after the last object
// iterated over.
template <typename OopClosureType>
void oop_since_save_marks_iterate(OopClosureType* blk);
// Same as object_iterate, but starting from "mark", which is required
// to denote the start of an object. Objects allocated by
// applications of the closure *are* included in the iteration.
virtual void object_iterate_from(HeapWord* mark, ObjectClosure* blk);
// Very inefficient implementation.
virtual HeapWord* block_start_const(const void* p) const;
size_t block_size(const HeapWord* p) const;
// If a block is in the allocated area, it is an object.
bool block_is_obj(const HeapWord* p) const { return p < top(); }
// Addresses for inlined allocation
HeapWord** top_addr() { return &_top; }
HeapWord** end_addr() { return &_end; }
#if INCLUDE_SERIALGC
// Overrides for more efficient compaction support.
void prepare_for_compaction(CompactPoint* cp);
#endif
virtual void print_on(outputStream* st) const;
// Checked dynamic downcasts.
virtual ContiguousSpace* toContiguousSpace() {
return this;
}
// Debugging
virtual void verify() const;
// Used to increase collection frequency. "factor" of 0 means entire
// space.
void allocate_temporary_filler(int factor);
};
// A dirty card to oop closure that does filtering.
// It knows how to filter out objects that are outside of the _boundary.
class FilteringDCTOC : public DirtyCardToOopClosure {
protected:
// Override.
void walk_mem_region(MemRegion mr,
HeapWord* bottom, HeapWord* top);
// Walk the given memory region, from bottom to top, applying
// the given oop closure to (possibly) all objects found. The
// given oop closure may or may not be the same as the oop
// closure with which this closure was created, as it may
// be a filtering closure which makes use of the _boundary.
// We offer two signatures, so the FilteringClosure static type is
// apparent.
virtual void walk_mem_region_with_cl(MemRegion mr,
HeapWord* bottom, HeapWord* top,
OopIterateClosure* cl) = 0;
virtual void walk_mem_region_with_cl(MemRegion mr,
HeapWord* bottom, HeapWord* top,
FilteringClosure* cl) = 0;
public:
FilteringDCTOC(Space* sp, OopIterateClosure* cl,
CardTable::PrecisionStyle precision,
HeapWord* boundary) :
DirtyCardToOopClosure(sp, cl, precision, boundary) {}
};
// A dirty card to oop closure for contiguous spaces
// (ContiguousSpace and sub-classes).
// It is a FilteringClosure, as defined above, and it knows:
//
// 1. That the actual top of any area in a memory region
// contained by the space is bounded by the end of the contiguous
// region of the space.
// 2. That the space is really made up of objects and not just
// blocks.
class ContiguousSpaceDCTOC : public FilteringDCTOC {
protected:
// Overrides.
HeapWord* get_actual_top(HeapWord* top, HeapWord* top_obj);
virtual void walk_mem_region_with_cl(MemRegion mr,
HeapWord* bottom, HeapWord* top,
OopIterateClosure* cl);
virtual void walk_mem_region_with_cl(MemRegion mr,
HeapWord* bottom, HeapWord* top,
FilteringClosure* cl);
public:
ContiguousSpaceDCTOC(ContiguousSpace* sp, OopIterateClosure* cl,
CardTable::PrecisionStyle precision,
HeapWord* boundary) :
FilteringDCTOC(sp, cl, precision, boundary)
{}
};
// A ContigSpace that Supports an efficient "block_start" operation via
// a BlockOffsetArray (whose BlockOffsetSharedArray may be shared with
// other spaces.) This is the abstract base class for old generation
// (tenured) spaces.
class OffsetTableContigSpace: public ContiguousSpace {
friend class VMStructs;
protected:
BlockOffsetArrayContigSpace _offsets;
Mutex _par_alloc_lock;
public:
// Constructor
OffsetTableContigSpace(BlockOffsetSharedArray* sharedOffsetArray,
MemRegion mr);
void set_bottom(HeapWord* value);
void set_end(HeapWord* value);
void clear(bool mangle_space);
inline HeapWord* block_start_const(const void* p) const;
// Add offset table update.
virtual inline HeapWord* allocate(size_t word_size);
inline HeapWord* par_allocate(size_t word_size);
// MarkSweep support phase3
virtual HeapWord* initialize_threshold();
virtual HeapWord* cross_threshold(HeapWord* start, HeapWord* end);
virtual void print_on(outputStream* st) const;
// Debugging
void verify() const;
};
// Class TenuredSpace is used by TenuredGeneration
class TenuredSpace: public OffsetTableContigSpace {
friend class VMStructs;
protected:
// Mark sweep support
size_t allowed_dead_ratio() const;
public:
// Constructor
TenuredSpace(BlockOffsetSharedArray* sharedOffsetArray,
MemRegion mr) :
OffsetTableContigSpace(sharedOffsetArray, mr) {}
};
#endif // SHARE_GC_SHARED_SPACE_HPP