463 // Private inline function, for direct internal use and providing the
464 // implementation of the public not-inline function.
465 MAYBE_INLINE_EVACUATION
466 oop G1ParScanThreadState::do_copy_to_survivor_space(G1HeapRegionAttr const region_attr,
467                                                     oop const old,
468                                                     markWord const old_mark) {
469   assert(region_attr.is_in_cset(),
470          "Unexpected region attr type: %s", region_attr.get_type_str());
471 
472   // NOTE: With compact headers, it is not safe to load the Klass* from old, because
473   // that would access the mark-word, that might change at any time by concurrent
474   // workers.
475   // This mark word would refer to a forwardee, which may not yet have completed
476   // copying. Therefore we must load the Klass* from the mark-word that we already
477   // loaded. This is safe, because we only enter here if not yet forwarded.
478   assert(!old_mark.is_forwarded(), "precondition");
479   Klass* klass = UseCompactObjectHeaders
480       ? old_mark.klass()
481       : old->klass();
482 
483   const size_t word_sz = old->size_given_klass(klass);

484 
485   // JNI only allows pinning of typeArrays, so we only need to keep those in place.
486   if (region_attr.is_pinned() && klass->is_typeArray_klass()) {
487     return handle_evacuation_failure_par(old, old_mark, klass, region_attr, word_sz, true /* cause_pinned */);
488   }
489 
490   uint age = 0;
491   G1HeapRegionAttr dest_attr = next_region_attr(region_attr, old_mark, age);
492   G1HeapRegion* const from_region = _g1h->heap_region_containing(old);
493   uint node_index = from_region->node_index();
494 
495   HeapWord* obj_ptr = _plab_allocator->plab_allocate(dest_attr, word_sz, node_index);
496 
497   // PLAB allocations should succeed most of the time, so we'll
498   // normally check against null once and that's it.
499   if (obj_ptr == nullptr) {
500     obj_ptr = allocate_copy_slow(&dest_attr, klass, word_sz, age, node_index);
501     if (obj_ptr == nullptr) {
502       // This will either forward-to-self, or detect that someone else has
503       // installed a forwarding pointer.
504       return handle_evacuation_failure_par(old, old_mark, klass, region_attr, word_sz, false /* cause_pinned */);
505     }
506   }
507 
508   assert(obj_ptr != nullptr, "when we get here, allocation should have succeeded");
509   assert(_g1h->is_in_reserved(obj_ptr), "Allocated memory should be in the heap");
510 
511   // Should this evacuation fail?
512   if (inject_allocation_failure(from_region->hrm_index())) {
513     // Doing this after all the allocation attempts also tests the
514     // undo_allocation() method too.
515     undo_allocation(dest_attr, obj_ptr, word_sz, node_index);
516     return handle_evacuation_failure_par(old, old_mark, klass, region_attr, word_sz, false /* cause_pinned */);
517   }
518 
519   // We're going to allocate linearly, so might as well prefetch ahead.
520   Prefetch::write(obj_ptr, PrefetchCopyIntervalInBytes);
521   Copy::aligned_disjoint_words(cast_from_oop<HeapWord*>(old), obj_ptr, word_sz);
522 
523   const oop obj = cast_to_oop(obj_ptr);
524   // Because the forwarding is done with memory_order_relaxed there is no
525   // ordering with the above copy.  Clients that get the forwardee must not
526   // examine its contents without other synchronization, since the contents
527   // may not be up to date for them.
528   const oop forward_ptr = old->forward_to_atomic(obj, old_mark, memory_order_relaxed);
529   if (forward_ptr == nullptr) {
530 
531     {
532       const uint young_index = from_region->young_index_in_cset();
533       assert((from_region->is_young() && young_index >  0) ||
534              (!from_region->is_young() && young_index == 0), "invariant" );
535       _surviving_young_words[young_index] += word_sz;
536     }
537 


538     if (dest_attr.is_young()) {
539       if (age < markWord::max_age) {
540         age++;
541         obj->incr_age();
542       }
543       _age_table.add(age, word_sz);
544     } else {
545       update_bot_after_copying(obj, word_sz);
546     }
547 
548     {
549       // Skip the card enqueue iff the object (obj) is in survivor region.
550       // However, G1HeapRegion::is_survivor() is too expensive here.
551       // Instead, we use dest_attr.is_young() because the two values are always
552       // equal: successfully allocated young regions must be survivor regions.
553       assert(dest_attr.is_young() == _g1h->heap_region_containing(obj)->is_survivor(), "must be");
554       G1SkipCardMarkSetter x(&_scanner, dest_attr.is_young());
555       do_iterate_object(obj, old, klass, region_attr, dest_attr, age);
556     }
557 

463 // Private inline function, for direct internal use and providing the
464 // implementation of the public not-inline function.
465 MAYBE_INLINE_EVACUATION
466 oop G1ParScanThreadState::do_copy_to_survivor_space(G1HeapRegionAttr const region_attr,
467                                                     oop const old,
468                                                     markWord const old_mark) {
469   assert(region_attr.is_in_cset(),
470          "Unexpected region attr type: %s", region_attr.get_type_str());
471 
472   // NOTE: With compact headers, it is not safe to load the Klass* from old, because
473   // that would access the mark-word, that might change at any time by concurrent
474   // workers.
475   // This mark word would refer to a forwardee, which may not yet have completed
476   // copying. Therefore we must load the Klass* from the mark-word that we already
477   // loaded. This is safe, because we only enter here if not yet forwarded.
478   assert(!old_mark.is_forwarded(), "precondition");
479   Klass* klass = UseCompactObjectHeaders
480       ? old_mark.klass()
481       : old->klass();
482 
483   const size_t old_size = old->size_given_mark_and_klass(old_mark, klass);
484   const size_t word_sz = old->copy_size(old_size, old_mark);
485 
486   // JNI only allows pinning of typeArrays, so we only need to keep those in place.
487   if (region_attr.is_pinned() && klass->is_typeArray_klass()) {
488     return handle_evacuation_failure_par(old, old_mark, klass, region_attr, word_sz, true /* cause_pinned */);
489   }
490 
491   uint age = 0;
492   G1HeapRegionAttr dest_attr = next_region_attr(region_attr, old_mark, age);
493   G1HeapRegion* const from_region = _g1h->heap_region_containing(old);
494   uint node_index = from_region->node_index();
495 
496   HeapWord* obj_ptr = _plab_allocator->plab_allocate(dest_attr, word_sz, node_index);
497 
498   // PLAB allocations should succeed most of the time, so we'll
499   // normally check against null once and that's it.
500   if (obj_ptr == nullptr) {
501     obj_ptr = allocate_copy_slow(&dest_attr, klass, word_sz, age, node_index);
502     if (obj_ptr == nullptr) {
503       // This will either forward-to-self, or detect that someone else has
504       // installed a forwarding pointer.
505       return handle_evacuation_failure_par(old, old_mark, klass, region_attr, word_sz, false /* cause_pinned */);
506     }
507   }
508 
509   assert(obj_ptr != nullptr, "when we get here, allocation should have succeeded");
510   assert(_g1h->is_in_reserved(obj_ptr), "Allocated memory should be in the heap");
511 
512   // Should this evacuation fail?
513   if (inject_allocation_failure(from_region->hrm_index())) {
514     // Doing this after all the allocation attempts also tests the
515     // undo_allocation() method too.
516     undo_allocation(dest_attr, obj_ptr, word_sz, node_index);
517     return handle_evacuation_failure_par(old, old_mark, klass, region_attr, word_sz, false /* cause_pinned */);
518   }
519 
520   // We're going to allocate linearly, so might as well prefetch ahead.
521   Prefetch::write(obj_ptr, PrefetchCopyIntervalInBytes);
522   Copy::aligned_disjoint_words(cast_from_oop<HeapWord*>(old), obj_ptr, old_size);
523 
524   const oop obj = cast_to_oop(obj_ptr);
525   // Because the forwarding is done with memory_order_relaxed there is no
526   // ordering with the above copy.  Clients that get the forwardee must not
527   // examine its contents without other synchronization, since the contents
528   // may not be up to date for them.
529   const oop forward_ptr = old->forward_to_atomic(obj, old_mark, memory_order_relaxed);
530   if (forward_ptr == nullptr) {
531 
532     {
533       const uint young_index = from_region->young_index_in_cset();
534       assert((from_region->is_young() && young_index >  0) ||
535              (!from_region->is_young() && young_index == 0), "invariant" );
536       _surviving_young_words[young_index] += word_sz;
537     }
538 
539     obj->initialize_hash_if_necessary(old);
540 
541     if (dest_attr.is_young()) {
542       if (age < markWord::max_age) {
543         age++;
544         obj->incr_age();
545       }
546       _age_table.add(age, word_sz);
547     } else {
548       update_bot_after_copying(obj, word_sz);
549     }
550 
551     {
552       // Skip the card enqueue iff the object (obj) is in survivor region.
553       // However, G1HeapRegion::is_survivor() is too expensive here.
554       // Instead, we use dest_attr.is_young() because the two values are always
555       // equal: successfully allocated young regions must be survivor regions.
556       assert(dest_attr.is_young() == _g1h->heap_region_containing(obj)->is_survivor(), "must be");
557       G1SkipCardMarkSetter x(&_scanner, dest_attr.is_young());
558       do_iterate_object(obj, old, klass, region_attr, dest_attr, age);
559     }
560