Mercurial > hg > truffle
view src/share/vm/memory/space.inline.hpp @ 20198:c49dcaf78a65
8042737: Introduce umbrella header prefetch.inline.hpp
Reviewed-by: twisti, stefank
| author | goetz |
|---|---|
| date | Thu, 08 May 2014 15:37:17 +0200 |
| parents | b9a9ed0f8eeb |
| children |
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/* * Copyright (c) 2000, 2012, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #ifndef SHARE_VM_MEMORY_SPACE_INLINE_HPP #define SHARE_VM_MEMORY_SPACE_INLINE_HPP #include "gc_interface/collectedHeap.hpp" #include "memory/space.hpp" #include "memory/universe.hpp" #include "runtime/prefetch.inline.hpp" #include "runtime/safepoint.hpp" inline HeapWord* Space::block_start(const void* p) { return block_start_const(p); } #define SCAN_AND_FORWARD(cp,scan_limit,block_is_obj,block_size) { \ /* Compute the new addresses for the live objects and store it in the mark \ * Used by universe::mark_sweep_phase2() \ */ \ HeapWord* compact_top; /* This is where we are currently compacting to. */ \ \ /* We're sure to be here before any objects are compacted into this \ * space, so this is a good time to initialize this: \ */ \ set_compaction_top(bottom()); \ \ if (cp->space == NULL) { \ assert(cp->gen != NULL, "need a generation"); \ assert(cp->threshold == NULL, "just checking"); \ assert(cp->gen->first_compaction_space() == this, "just checking"); \ cp->space = cp->gen->first_compaction_space(); \ compact_top = cp->space->bottom(); \ cp->space->set_compaction_top(compact_top); \ cp->threshold = cp->space->initialize_threshold(); \ } else { \ compact_top = cp->space->compaction_top(); \ } \ \ /* We allow some amount of garbage towards the bottom of the space, so \ * we don't start compacting before there is a significant gain to be made.\ * Occasionally, we want to ensure a full compaction, which is determined \ * by the MarkSweepAlwaysCompactCount parameter. \ */ \ uint invocations = MarkSweep::total_invocations(); \ bool skip_dead = ((invocations % MarkSweepAlwaysCompactCount) != 0); \ \ size_t allowed_deadspace = 0; \ if (skip_dead) { \ const size_t ratio = allowed_dead_ratio(); \ allowed_deadspace = (capacity() * ratio / 100) / HeapWordSize; \ } \ \ HeapWord* q = bottom(); \ HeapWord* t = scan_limit(); \ \ HeapWord* end_of_live= q; /* One byte beyond the last byte of the last \ live object. */ \ HeapWord* first_dead = end();/* The first dead object. */ \ LiveRange* liveRange = NULL; /* The current live range, recorded in the \ first header of preceding free area. */ \ _first_dead = first_dead; \ \ const intx interval = PrefetchScanIntervalInBytes; \ \ while (q < t) { \ assert(!block_is_obj(q) || \ oop(q)->mark()->is_marked() || oop(q)->mark()->is_unlocked() || \ oop(q)->mark()->has_bias_pattern(), \ "these are the only valid states during a mark sweep"); \ if (block_is_obj(q) && oop(q)->is_gc_marked()) { \ /* prefetch beyond q */ \ Prefetch::write(q, interval); \ size_t size = block_size(q); \ compact_top = cp->space->forward(oop(q), size, cp, compact_top); \ q += size; \ end_of_live = q; \ } else { \ /* run over all the contiguous dead objects */ \ HeapWord* end = q; \ do { \ /* prefetch beyond end */ \ Prefetch::write(end, interval); \ end += block_size(end); \ } while (end < t && (!block_is_obj(end) || !oop(end)->is_gc_marked()));\ \ /* see if we might want to pretend this object is alive so that \ * we don't have to compact quite as often. \ */ \ if (allowed_deadspace > 0 && q == compact_top) { \ size_t sz = pointer_delta(end, q); \ if (insert_deadspace(allowed_deadspace, q, sz)) { \ compact_top = cp->space->forward(oop(q), sz, cp, compact_top); \ q = end; \ end_of_live = end; \ continue; \ } \ } \ \ /* otherwise, it really is a free region. */ \ \ /* for the previous LiveRange, record the end of the live objects. */ \ if (liveRange) { \ liveRange->set_end(q); \ } \ \ /* record the current LiveRange object. \ * liveRange->start() is overlaid on the mark word. \ */ \ liveRange = (LiveRange*)q; \ liveRange->set_start(end); \ liveRange->set_end(end); \ \ /* see if this is the first dead region. */ \ if (q < first_dead) { \ first_dead = q; \ } \ \ /* move on to the next object */ \ q = end; \ } \ } \ \ assert(q == t, "just checking"); \ if (liveRange != NULL) { \ liveRange->set_end(q); \ } \ _end_of_live = end_of_live; \ if (end_of_live < first_dead) { \ first_dead = end_of_live; \ } \ _first_dead = first_dead; \ \ /* save the compaction_top of the compaction space. */ \ cp->space->set_compaction_top(compact_top); \ } #define SCAN_AND_ADJUST_POINTERS(adjust_obj_size) { \ /* adjust all the interior pointers to point at the new locations of objects \ * Used by MarkSweep::mark_sweep_phase3() */ \ \ HeapWord* q = bottom(); \ HeapWord* t = _end_of_live; /* Established by "prepare_for_compaction". */ \ \ assert(_first_dead <= _end_of_live, "Stands to reason, no?"); \ \ if (q < t && _first_dead > q && \ !oop(q)->is_gc_marked()) { \ /* we have a chunk of the space which hasn't moved and we've \ * reinitialized the mark word during the previous pass, so we can't \ * use is_gc_marked for the traversal. */ \ HeapWord* end = _first_dead; \ \ while (q < end) { \ /* I originally tried to conjoin "block_start(q) == q" to the \ * assertion below, but that doesn't work, because you can't \ * accurately traverse previous objects to get to the current one \ * after their pointers have been \ * updated, until the actual compaction is done. dld, 4/00 */ \ assert(block_is_obj(q), \ "should be at block boundaries, and should be looking at objs"); \ \ /* point all the oops to the new location */ \ size_t size = oop(q)->adjust_pointers(); \ size = adjust_obj_size(size); \ \ q += size; \ } \ \ if (_first_dead == t) { \ q = t; \ } else { \ /* $$$ This is funky. Using this to read the previously written \ * LiveRange. See also use below. */ \ q = (HeapWord*)oop(_first_dead)->mark()->decode_pointer(); \ } \ } \ \ const intx interval = PrefetchScanIntervalInBytes; \ \ debug_only(HeapWord* prev_q = NULL); \ while (q < t) { \ /* prefetch beyond q */ \ Prefetch::write(q, interval); \ if (oop(q)->is_gc_marked()) { \ /* q is alive */ \ /* point all the oops to the new location */ \ size_t size = oop(q)->adjust_pointers(); \ size = adjust_obj_size(size); \ debug_only(prev_q = q); \ q += size; \ } else { \ /* q is not a live object, so its mark should point at the next \ * live object */ \ debug_only(prev_q = q); \ q = (HeapWord*) oop(q)->mark()->decode_pointer(); \ assert(q > prev_q, "we should be moving forward through memory"); \ } \ } \ \ assert(q == t, "just checking"); \ } #define SCAN_AND_COMPACT(obj_size) { \ /* Copy all live objects to their new location \ * Used by MarkSweep::mark_sweep_phase4() */ \ \ HeapWord* q = bottom(); \ HeapWord* const t = _end_of_live; \ debug_only(HeapWord* prev_q = NULL); \ \ if (q < t && _first_dead > q && \ !oop(q)->is_gc_marked()) { \ debug_only( \ /* we have a chunk of the space which hasn't moved and we've reinitialized \ * the mark word during the previous pass, so we can't use is_gc_marked for \ * the traversal. */ \ HeapWord* const end = _first_dead; \ \ while (q < end) { \ size_t size = obj_size(q); \ assert(!oop(q)->is_gc_marked(), \ "should be unmarked (special dense prefix handling)"); \ debug_only(prev_q = q); \ q += size; \ } \ ) /* debug_only */ \ \ if (_first_dead == t) { \ q = t; \ } else { \ /* $$$ Funky */ \ q = (HeapWord*) oop(_first_dead)->mark()->decode_pointer(); \ } \ } \ \ const intx scan_interval = PrefetchScanIntervalInBytes; \ const intx copy_interval = PrefetchCopyIntervalInBytes; \ while (q < t) { \ if (!oop(q)->is_gc_marked()) { \ /* mark is pointer to next marked oop */ \ debug_only(prev_q = q); \ q = (HeapWord*) oop(q)->mark()->decode_pointer(); \ assert(q > prev_q, "we should be moving forward through memory"); \ } else { \ /* prefetch beyond q */ \ Prefetch::read(q, scan_interval); \ \ /* size and destination */ \ size_t size = obj_size(q); \ HeapWord* compaction_top = (HeapWord*)oop(q)->forwardee(); \ \ /* prefetch beyond compaction_top */ \ Prefetch::write(compaction_top, copy_interval); \ \ /* copy object and reinit its mark */ \ assert(q != compaction_top, "everything in this pass should be moving"); \ Copy::aligned_conjoint_words(q, compaction_top, size); \ oop(compaction_top)->init_mark(); \ assert(oop(compaction_top)->klass() != NULL, "should have a class"); \ \ debug_only(prev_q = q); \ q += size; \ } \ } \ \ /* Let's remember if we were empty before we did the compaction. */ \ bool was_empty = used_region().is_empty(); \ /* Reset space after compaction is complete */ \ reset_after_compaction(); \ /* We do this clear, below, since it has overloaded meanings for some */ \ /* space subtypes. For example, OffsetTableContigSpace's that were */ \ /* compacted into will have had their offset table thresholds updated */ \ /* continuously, but those that weren't need to have their thresholds */ \ /* re-initialized. Also mangles unused area for debugging. */ \ if (used_region().is_empty()) { \ if (!was_empty) clear(SpaceDecorator::Mangle); \ } else { \ if (ZapUnusedHeapArea) mangle_unused_area(); \ } \ } inline HeapWord* OffsetTableContigSpace::allocate(size_t size) { HeapWord* res = ContiguousSpace::allocate(size); 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* OffsetTableContigSpace::par_allocate(size_t size) { MutexLocker x(&_par_alloc_lock); // This ought to be just "allocate", because of the lock above, but that // ContiguousSpace::allocate asserts that either the allocating thread // holds the heap lock or it is the VM thread and we're at a safepoint. // The best I (dld) could figure was to put a field in ContiguousSpace // meaning "locking at safepoint taken care of", and set/reset that // here. But this will do for now, especially in light of the comment // above. Perhaps in the future some lock-free manner of keeping the // coordination. HeapWord* res = ContiguousSpace::par_allocate(size); if (res != NULL) { _offsets.alloc_block(res, size); } return res; } inline HeapWord* OffsetTableContigSpace::block_start_const(const void* p) const { return _offsets.block_start(p); } #endif // SHARE_VM_MEMORY_SPACE_INLINE_HPP