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*
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* 2 along with this work; if not, write to the Free Software Foundation,
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#ifndef SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGION_INLINE_HPP
#define SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGION_INLINE_HPP
#include "gc_implementation/g1/g1BlockOffsetTable.inline.hpp"
#include "gc_implementation/g1/g1CollectedHeap.hpp"
#include "gc_implementation/g1/heapRegion.hpp"
#include "memory/space.hpp"
#include "oops/oop.inline.hpp"
#include "runtime/atomic.inline.hpp"
// This version requires locking.
inline HeapWord* G1OffsetTableContigSpace::allocate_impl(size_t size,
HeapWord* const end_value) {
HeapWord* obj = top();
if (pointer_delta(end_value, obj) >= size) {
HeapWord* new_top = obj + size;
set_top(new_top);
assert(is_aligned(obj) && is_aligned(new_top), "checking alignment");
return obj;
} else {
return NULL;
}
}
// This version is lock-free.
inline HeapWord* G1OffsetTableContigSpace::par_allocate_impl(size_t size,
HeapWord* const end_value) {
do {
HeapWord* obj = top();
if (pointer_delta(end_value, obj) >= size) {
HeapWord* new_top = obj + size;
HeapWord* result = (HeapWord*)Atomic::cmpxchg_ptr(new_top, top_addr(), obj);
// result can be one of two:
// the old top value: the exchange succeeded
// otherwise: the new value of the top is returned.
if (result == obj) {
assert(is_aligned(obj) && is_aligned(new_top), "checking alignment");
return obj;
}
} else {
return NULL;
}
} while (true);
}
inline HeapWord* G1OffsetTableContigSpace::allocate(size_t size) {
HeapWord* res = allocate_impl(size, end());
if (res != NULL) {
_offsets.alloc_block(res, size);
}
return res;
}
// Because of the requirement of keeping "_offsets" up to date with the
// allocations, we sequentialize these with a lock. Therefore, best if
// this is used for larger LAB allocations only.
inline HeapWord* G1OffsetTableContigSpace::par_allocate(size_t size) {
MutexLocker x(&_par_alloc_lock);
return allocate(size);
}
inline HeapWord* G1OffsetTableContigSpace::block_start(const void* p) {
return _offsets.block_start(p);
}
inline HeapWord*
G1OffsetTableContigSpace::block_start_const(const void* p) const {
return _offsets.block_start_const(p);
}
inline bool
HeapRegion::block_is_obj(const HeapWord* p) const {
G1CollectedHeap* g1h = G1CollectedHeap::heap();
if (ClassUnloadingWithConcurrentMark) {
return !g1h->is_obj_dead(oop(p), this);
}
return p < top();
}
inline size_t
HeapRegion::block_size(const HeapWord *addr) const {
if (addr == top()) {
return pointer_delta(end(), addr);
}
if (block_is_obj(addr)) {
return oop(addr)->size();
}
assert(ClassUnloadingWithConcurrentMark,
err_msg("All blocks should be objects if G1 Class Unloading isn't used. "
"HR: ["PTR_FORMAT", "PTR_FORMAT", "PTR_FORMAT") "
"addr: " PTR_FORMAT,
p2i(bottom()), p2i(top()), p2i(end()), p2i(addr)));
// Old regions' dead objects may have dead classes
// We need to find the next live object in some other
// manner than getting the oop size
G1CollectedHeap* g1h = G1CollectedHeap::heap();
HeapWord* next = g1h->concurrent_mark()->prevMarkBitMap()->
getNextMarkedWordAddress(addr, prev_top_at_mark_start());
assert(next > addr, "must get the next live object");
return pointer_delta(next, addr);
}
inline HeapWord* HeapRegion::par_allocate_no_bot_updates(size_t word_size) {
assert(is_young(), "we can only skip BOT updates on young regions");
return par_allocate_impl(word_size, end());
}
inline HeapWord* HeapRegion::allocate_no_bot_updates(size_t word_size) {
assert(is_young(), "we can only skip BOT updates on young regions");
return allocate_impl(word_size, end());
}
inline void HeapRegion::note_start_of_marking() {
_next_marked_bytes = 0;
_next_top_at_mark_start = top();
}
inline void HeapRegion::note_end_of_marking() {
_prev_top_at_mark_start = _next_top_at_mark_start;
_prev_marked_bytes = _next_marked_bytes;
_next_marked_bytes = 0;
assert(_prev_marked_bytes <=
(size_t) pointer_delta(prev_top_at_mark_start(), bottom()) *
HeapWordSize, "invariant");
}
inline void HeapRegion::note_start_of_copying(bool during_initial_mark) {
if (is_survivor()) {
// This is how we always allocate survivors.
assert(_next_top_at_mark_start == bottom(), "invariant");
} else {
if (during_initial_mark) {
// During initial-mark we'll explicitly mark any objects on old
// regions that are pointed to by roots. Given that explicit
// marks only make sense under NTAMS it'd be nice if we could
// check that condition if we wanted to. Given that we don't
// know where the top of this region will end up, we simply set
// NTAMS to the end of the region so all marks will be below
// NTAMS. We'll set it to the actual top when we retire this region.
_next_top_at_mark_start = end();
} else {
// We could have re-used this old region as to-space over a
// couple of GCs since the start of the concurrent marking
// cycle. This means that [bottom,NTAMS) will contain objects
// copied up to and including initial-mark and [NTAMS, top)
// will contain objects copied during the concurrent marking cycle.
assert(top() >= _next_top_at_mark_start, "invariant");
}
}
}
inline void HeapRegion::note_end_of_copying(bool during_initial_mark) {
if (is_survivor()) {
// This is how we always allocate survivors.
assert(_next_top_at_mark_start == bottom(), "invariant");
} else {
if (during_initial_mark) {
// See the comment for note_start_of_copying() for the details
// on this.
assert(_next_top_at_mark_start == end(), "pre-condition");
_next_top_at_mark_start = top();
} else {
// See the comment for note_start_of_copying() for the details
// on this.
assert(top() >= _next_top_at_mark_start, "invariant");
}
}
}
inline bool HeapRegion::in_collection_set() const {
return G1CollectedHeap::heap()->is_in_cset(this);
}
#endif // SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGION_INLINE_HPP