/* * Copyright (c) 2017, 2019, Red Hat, Inc. All rights reserved. * * 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. * */ #include "precompiled.hpp" #include "gc/shenandoah/shenandoahAsserts.hpp" #include "gc/shenandoah/shenandoahForwarding.inline.hpp" #include "gc/shenandoah/shenandoahPhaseTimings.hpp" #include "gc/shenandoah/shenandoahHeap.inline.hpp" #include "gc/shenandoah/shenandoahHeapRegion.inline.hpp" #include "gc/shenandoah/shenandoahRootProcessor.hpp" #include "gc/shenandoah/shenandoahTaskqueue.inline.hpp" #include "gc/shenandoah/shenandoahUtils.hpp" #include "gc/shenandoah/shenandoahVerifier.hpp" #include "memory/allocation.hpp" #include "memory/iterator.inline.hpp" #include "memory/resourceArea.hpp" // Avoid name collision on verify_oop (defined in macroAssembler_arm.hpp) #ifdef verify_oop #undef verify_oop #endif class ShenandoahVerifyOopClosure : public BasicOopIterateClosure { private: const char* _phase; ShenandoahVerifier::VerifyOptions _options; ShenandoahVerifierStack* _stack; ShenandoahHeap* _heap; MarkBitMap* _map; ShenandoahLivenessData* _ld; void* _interior_loc; oop _loc; public: ShenandoahVerifyOopClosure(ShenandoahVerifierStack* stack, MarkBitMap* map, ShenandoahLivenessData* ld, const char* phase, ShenandoahVerifier::VerifyOptions options) : _phase(phase), _options(options), _stack(stack), _heap(ShenandoahHeap::heap()), _map(map), _ld(ld), _interior_loc(NULL), _loc(NULL) { } private: void check(ShenandoahAsserts::SafeLevel level, oop obj, bool test, const char* label) { if (!test) { ShenandoahAsserts::print_failure(level, obj, _interior_loc, _loc, _phase, label, __FILE__, __LINE__); } } template void do_oop_work(T* p) { T o = RawAccess<>::oop_load(p); if (!CompressedOops::is_null(o)) { oop obj = CompressedOops::decode_not_null(o); // Single threaded verification can use faster non-atomic stack and bitmap // methods. // // For performance reasons, only fully verify non-marked field values. // We are here when the host object for *p is already marked. HeapWord* addr = (HeapWord*) obj; if (_map->parMark(addr)) { verify_oop_at(p, obj); _stack->push(ShenandoahVerifierTask(obj)); } } } void verify_oop(oop obj) { // Perform consistency checks with gradually decreasing safety level. This guarantees // that failure report would not try to touch something that was not yet verified to be // safe to process. check(ShenandoahAsserts::_safe_unknown, obj, _heap->is_in(obj), "oop must be in heap"); check(ShenandoahAsserts::_safe_unknown, obj, check_obj_alignment(obj), "oop must be aligned"); ShenandoahHeapRegion *obj_reg = _heap->heap_region_containing(obj); Klass* obj_klass = obj->klass_or_null(); // Verify that obj is not in dead space: { // Do this before touching obj->size() check(ShenandoahAsserts::_safe_unknown, obj, obj_klass != NULL, "Object klass pointer should not be NULL"); check(ShenandoahAsserts::_safe_unknown, obj, Metaspace::contains(obj_klass), "Object klass pointer must go to metaspace"); HeapWord *obj_addr = (HeapWord *) obj; check(ShenandoahAsserts::_safe_unknown, obj, obj_addr < obj_reg->top(), "Object start should be within the region"); if (!obj_reg->is_humongous()) { check(ShenandoahAsserts::_safe_unknown, obj, (obj_addr + obj->size()) <= obj_reg->top(), "Object end should be within the region"); } else { size_t humongous_start = obj_reg->index(); size_t humongous_end = humongous_start + (obj->size() >> ShenandoahHeapRegion::region_size_words_shift()); for (size_t idx = humongous_start + 1; idx < humongous_end; idx++) { check(ShenandoahAsserts::_safe_unknown, obj, _heap->get_region(idx)->is_humongous_continuation(), "Humongous object is in continuation that fits it"); } } // ------------ obj is safe at this point -------------- check(ShenandoahAsserts::_safe_oop, obj, obj_reg->is_active(), "Object should be in active region"); switch (_options._verify_liveness) { case ShenandoahVerifier::_verify_liveness_disable: // skip break; case ShenandoahVerifier::_verify_liveness_complete: Atomic::add((uint) obj->size(), &_ld[obj_reg->index()]); // fallthrough for fast failure for un-live regions: case ShenandoahVerifier::_verify_liveness_conservative: check(ShenandoahAsserts::_safe_oop, obj, obj_reg->has_live(), "Object must belong to region with live data"); break; default: assert(false, "Unhandled liveness verification"); } } oop fwd = (oop) ShenandoahForwarding::get_forwardee_raw_unchecked(obj); ShenandoahHeapRegion* fwd_reg = NULL; if (obj != fwd) { check(ShenandoahAsserts::_safe_oop, obj, _heap->is_in(fwd), "Forwardee must be in heap"); check(ShenandoahAsserts::_safe_oop, obj, !CompressedOops::is_null(fwd), "Forwardee is set"); check(ShenandoahAsserts::_safe_oop, obj, check_obj_alignment(fwd), "Forwardee must be aligned"); // Do this before touching fwd->size() Klass* fwd_klass = fwd->klass_or_null(); check(ShenandoahAsserts::_safe_oop, obj, fwd_klass != NULL, "Forwardee klass pointer should not be NULL"); check(ShenandoahAsserts::_safe_oop, obj, Metaspace::contains(fwd_klass), "Forwardee klass pointer must go to metaspace"); check(ShenandoahAsserts::_safe_oop, obj, obj_klass == fwd_klass, "Forwardee klass pointer must go to metaspace"); fwd_reg = _heap->heap_region_containing(fwd); // Verify that forwardee is not in the dead space: check(ShenandoahAsserts::_safe_oop, obj, !fwd_reg->is_humongous(), "Should have no humongous forwardees"); HeapWord *fwd_addr = (HeapWord *) fwd; check(ShenandoahAsserts::_safe_oop, obj, fwd_addr < fwd_reg->top(), "Forwardee start should be within the region"); check(ShenandoahAsserts::_safe_oop, obj, (fwd_addr + fwd->size()) <= fwd_reg->top(), "Forwardee end should be within the region"); oop fwd2 = (oop) ShenandoahForwarding::get_forwardee_raw_unchecked(fwd); check(ShenandoahAsserts::_safe_oop, obj, fwd == fwd2, "Double forwarding"); } else { fwd_reg = obj_reg; } // ------------ obj and fwd are safe at this point -------------- switch (_options._verify_marked) { case ShenandoahVerifier::_verify_marked_disable: // skip break; case ShenandoahVerifier::_verify_marked_incomplete: check(ShenandoahAsserts::_safe_all, obj, _heap->marking_context()->is_marked(obj), "Must be marked in incomplete bitmap"); break; case ShenandoahVerifier::_verify_marked_complete: check(ShenandoahAsserts::_safe_all, obj, _heap->complete_marking_context()->is_marked(obj), "Must be marked in complete bitmap"); break; default: assert(false, "Unhandled mark verification"); } switch (_options._verify_forwarded) { case ShenandoahVerifier::_verify_forwarded_disable: // skip break; case ShenandoahVerifier::_verify_forwarded_none: { check(ShenandoahAsserts::_safe_all, obj, obj == fwd, "Should not be forwarded"); break; } case ShenandoahVerifier::_verify_forwarded_allow: { if (obj != fwd) { check(ShenandoahAsserts::_safe_all, obj, obj_reg != fwd_reg, "Forwardee should be in another region"); } break; } default: assert(false, "Unhandled forwarding verification"); } switch (_options._verify_cset) { case ShenandoahVerifier::_verify_cset_disable: // skip break; case ShenandoahVerifier::_verify_cset_none: check(ShenandoahAsserts::_safe_all, obj, !_heap->in_collection_set(obj), "Should not have references to collection set"); break; case ShenandoahVerifier::_verify_cset_forwarded: if (_heap->in_collection_set(obj)) { check(ShenandoahAsserts::_safe_all, obj, obj != fwd, "Object in collection set, should have forwardee"); } break; default: assert(false, "Unhandled cset verification"); } } public: /** * Verify object with known interior reference. * @param p interior reference where the object is referenced from; can be off-heap * @param obj verified object */ template void verify_oop_at(T* p, oop obj) { _interior_loc = p; verify_oop(obj); _interior_loc = NULL; } /** * Verify object without known interior reference. * Useful when picking up the object at known offset in heap, * but without knowing what objects reference it. * @param obj verified object */ void verify_oop_standalone(oop obj) { _interior_loc = NULL; verify_oop(obj); _interior_loc = NULL; } /** * Verify oop fields from this object. * @param obj host object for verified fields */ void verify_oops_from(oop obj) { _loc = obj; obj->oop_iterate(this); _loc = NULL; } virtual void do_oop(oop* p) { do_oop_work(p); } virtual void do_oop(narrowOop* p) { do_oop_work(p); } }; class ShenandoahCalculateRegionStatsClosure : public ShenandoahHeapRegionClosure { private: size_t _used, _committed, _garbage; public: ShenandoahCalculateRegionStatsClosure() : _used(0), _committed(0), _garbage(0) {}; void heap_region_do(ShenandoahHeapRegion* r) { _used += r->used(); _garbage += r->garbage(); _committed += r->is_committed() ? ShenandoahHeapRegion::region_size_bytes() : 0; } size_t used() { return _used; } size_t committed() { return _committed; } size_t garbage() { return _garbage; } }; class ShenandoahVerifyHeapRegionClosure : public ShenandoahHeapRegionClosure { private: ShenandoahHeap* _heap; const char* _phase; ShenandoahVerifier::VerifyRegions _regions; public: ShenandoahVerifyHeapRegionClosure(const char* phase, ShenandoahVerifier::VerifyRegions regions) : _heap(ShenandoahHeap::heap()), _phase(phase), _regions(regions) {}; void print_failure(ShenandoahHeapRegion* r, const char* label) { ResourceMark rm; ShenandoahMessageBuffer msg("Shenandoah verification failed; %s: %s\n\n", _phase, label); stringStream ss; r->print_on(&ss); msg.append("%s", ss.as_string()); report_vm_error(__FILE__, __LINE__, msg.buffer()); } void verify(ShenandoahHeapRegion* r, bool test, const char* msg) { if (!test) { print_failure(r, msg); } } void heap_region_do(ShenandoahHeapRegion* r) { switch (_regions) { case ShenandoahVerifier::_verify_regions_disable: break; case ShenandoahVerifier::_verify_regions_notrash: verify(r, !r->is_trash(), "Should not have trash regions"); break; case ShenandoahVerifier::_verify_regions_nocset: verify(r, !r->is_cset(), "Should not have cset regions"); break; case ShenandoahVerifier::_verify_regions_notrash_nocset: verify(r, !r->is_trash(), "Should not have trash regions"); verify(r, !r->is_cset(), "Should not have cset regions"); break; default: ShouldNotReachHere(); } verify(r, r->capacity() == ShenandoahHeapRegion::region_size_bytes(), "Capacity should match region size"); verify(r, r->bottom() <= r->top(), "Region top should not be less than bottom"); verify(r, r->bottom() <= _heap->marking_context()->top_at_mark_start(r), "Region TAMS should not be less than bottom"); verify(r, _heap->marking_context()->top_at_mark_start(r) <= r->top(), "Complete TAMS should not be larger than top"); verify(r, r->get_live_data_bytes() <= r->capacity(), "Live data cannot be larger than capacity"); verify(r, r->garbage() <= r->capacity(), "Garbage cannot be larger than capacity"); verify(r, r->used() <= r->capacity(), "Used cannot be larger than capacity"); verify(r, r->get_shared_allocs() <= r->capacity(), "Shared alloc count should not be larger than capacity"); verify(r, r->get_tlab_allocs() <= r->capacity(), "TLAB alloc count should not be larger than capacity"); verify(r, r->get_gclab_allocs() <= r->capacity(), "GCLAB alloc count should not be larger than capacity"); verify(r, r->get_shared_allocs() + r->get_tlab_allocs() + r->get_gclab_allocs() == r->used(), "Accurate accounting: shared + TLAB + GCLAB = used"); verify(r, !r->is_empty() || !r->has_live(), "Empty regions should not have live data"); verify(r, r->is_cset() == _heap->collection_set()->is_in(r), "Transitional: region flags and collection set agree"); } }; class ShenandoahVerifierReachableTask : public AbstractGangTask { private: const char* _label; ShenandoahRootVerifier* _verifier; ShenandoahVerifier::VerifyOptions _options; ShenandoahHeap* _heap; ShenandoahLivenessData* _ld; MarkBitMap* _bitmap; volatile size_t _processed; public: ShenandoahVerifierReachableTask(MarkBitMap* bitmap, ShenandoahLivenessData* ld, ShenandoahRootVerifier* verifier, const char* label, ShenandoahVerifier::VerifyOptions options) : AbstractGangTask("Shenandoah Parallel Verifier Reachable Task"), _label(label), _verifier(verifier), _options(options), _heap(ShenandoahHeap::heap()), _ld(ld), _bitmap(bitmap), _processed(0) {}; size_t processed() { return _processed; } virtual void work(uint worker_id) { ResourceMark rm; ShenandoahVerifierStack stack; // On level 2, we need to only check the roots once. // On level 3, we want to check the roots, and seed the local stack. // It is a lesser evil to accept multiple root scans at level 3, because // extended parallelism would buy us out. if (((ShenandoahVerifyLevel == 2) && (worker_id == 0)) || (ShenandoahVerifyLevel >= 3)) { ShenandoahVerifyOopClosure cl(&stack, _bitmap, _ld, ShenandoahMessageBuffer("%s, Roots", _label), _options); if (_heap->unload_classes()) { _verifier->strong_roots_do(&cl); } else { _verifier->roots_do(&cl); } } size_t processed = 0; if (ShenandoahVerifyLevel >= 3) { ShenandoahVerifyOopClosure cl(&stack, _bitmap, _ld, ShenandoahMessageBuffer("%s, Reachable", _label), _options); while (!stack.is_empty()) { processed++; ShenandoahVerifierTask task = stack.pop(); cl.verify_oops_from(task.obj()); } } Atomic::add(processed, &_processed); } }; class ShenandoahVerifierMarkedRegionTask : public AbstractGangTask { private: const char* _label; ShenandoahVerifier::VerifyOptions _options; ShenandoahHeap *_heap; MarkBitMap* _bitmap; ShenandoahLivenessData* _ld; volatile size_t _claimed; volatile size_t _processed; public: ShenandoahVerifierMarkedRegionTask(MarkBitMap* bitmap, ShenandoahLivenessData* ld, const char* label, ShenandoahVerifier::VerifyOptions options) : AbstractGangTask("Shenandoah Parallel Verifier Marked Region"), _label(label), _options(options), _heap(ShenandoahHeap::heap()), _bitmap(bitmap), _ld(ld), _claimed(0), _processed(0) {}; size_t processed() { return _processed; } virtual void work(uint worker_id) { ShenandoahVerifierStack stack; ShenandoahVerifyOopClosure cl(&stack, _bitmap, _ld, ShenandoahMessageBuffer("%s, Marked", _label), _options); while (true) { size_t v = Atomic::add(1u, &_claimed) - 1; if (v < _heap->num_regions()) { ShenandoahHeapRegion* r = _heap->get_region(v); if (!r->is_humongous() && !r->is_trash()) { work_regular(r, stack, cl); } else if (r->is_humongous_start()) { work_humongous(r, stack, cl); } } else { break; } } } virtual void work_humongous(ShenandoahHeapRegion *r, ShenandoahVerifierStack& stack, ShenandoahVerifyOopClosure& cl) { size_t processed = 0; HeapWord* obj = r->bottom(); if (_heap->complete_marking_context()->is_marked((oop)obj)) { verify_and_follow(obj, stack, cl, &processed); } Atomic::add(processed, &_processed); } virtual void work_regular(ShenandoahHeapRegion *r, ShenandoahVerifierStack &stack, ShenandoahVerifyOopClosure &cl) { size_t processed = 0; MarkBitMap* mark_bit_map = _heap->complete_marking_context()->mark_bit_map(); HeapWord* tams = _heap->complete_marking_context()->top_at_mark_start(r); // Bitmaps, before TAMS if (tams > r->bottom()) { HeapWord* start = r->bottom(); HeapWord* addr = mark_bit_map->getNextMarkedWordAddress(start, tams); while (addr < tams) { verify_and_follow(addr, stack, cl, &processed); addr += 1; if (addr < tams) { addr = mark_bit_map->getNextMarkedWordAddress(addr, tams); } } } // Size-based, after TAMS { HeapWord* limit = r->top(); HeapWord* addr = tams; while (addr < limit) { verify_and_follow(addr, stack, cl, &processed); addr += oop(addr)->size(); } } Atomic::add(processed, &_processed); } void verify_and_follow(HeapWord *addr, ShenandoahVerifierStack &stack, ShenandoahVerifyOopClosure &cl, size_t *processed) { if (!_bitmap->parMark(addr)) return; // Verify the object itself: oop obj = oop(addr); cl.verify_oop_standalone(obj); // Verify everything reachable from that object too, hopefully realizing // everything was already marked, and never touching further: cl.verify_oops_from(obj); (*processed)++; while (!stack.is_empty()) { ShenandoahVerifierTask task = stack.pop(); cl.verify_oops_from(task.obj()); (*processed)++; } } }; class VerifyThreadGCState : public ThreadClosure { private: const char* _label; char _expected; public: VerifyThreadGCState(const char* label, char expected) : _expected(expected) {} void do_thread(Thread* t) { char actual = ShenandoahThreadLocalData::gc_state(t); if (actual != _expected) { fatal("%s: Thread %s: expected gc-state %d, actual %d", _label, t->name(), _expected, actual); } } }; class ShenandoahGCStateResetter : public StackObj { private: ShenandoahHeap* const _heap; char _gc_state; public: ShenandoahGCStateResetter() : _heap(ShenandoahHeap::heap()) { _gc_state = _heap->gc_state(); _heap->_gc_state.clear(); } ~ShenandoahGCStateResetter() { _heap->_gc_state.set(_gc_state); assert(_heap->gc_state() == _gc_state, "Should be restored"); } }; void ShenandoahVerifier::verify_at_safepoint(const char *label, VerifyForwarded forwarded, VerifyMarked marked, VerifyCollectionSet cset, VerifyLiveness liveness, VerifyRegions regions, VerifyGCState gcstate) { guarantee(ShenandoahSafepoint::is_at_shenandoah_safepoint(), "only when nothing else happens"); guarantee(ShenandoahVerify, "only when enabled, and bitmap is initialized in ShenandoahHeap::initialize"); // Avoid side-effect of changing workers' active thread count, but bypass concurrent/parallel protocol check ShenandoahPushWorkerScope verify_worker_scope(_heap->workers(), _heap->max_workers(), false /*bypass check*/); log_info(gc,start)("Verify %s, Level " INTX_FORMAT, label, ShenandoahVerifyLevel); // GC state checks { char expected = -1; bool enabled; switch (gcstate) { case _verify_gcstate_disable: enabled = false; break; case _verify_gcstate_forwarded: enabled = true; expected = ShenandoahHeap::HAS_FORWARDED; break; case _verify_gcstate_evacuation: enabled = true; expected = ShenandoahHeap::HAS_FORWARDED | ShenandoahHeap::EVACUATION; break; case _verify_gcstate_stable: enabled = true; expected = ShenandoahHeap::STABLE; break; default: enabled = false; assert(false, "Unhandled gc-state verification"); } if (enabled) { char actual = _heap->gc_state(); if (actual != expected) { fatal("%s: Global gc-state: expected %d, actual %d", label, expected, actual); } VerifyThreadGCState vtgcs(label, expected); Threads::java_threads_do(&vtgcs); } } // Deactivate barriers temporarily: Verifier wants plain heap accesses ShenandoahGCStateResetter resetter; // Heap size checks { ShenandoahHeapLocker lock(_heap->lock()); ShenandoahCalculateRegionStatsClosure cl; _heap->heap_region_iterate(&cl); size_t heap_used = _heap->used(); guarantee(cl.used() == heap_used, "%s: heap used size must be consistent: heap-used = " SIZE_FORMAT "%s, regions-used = " SIZE_FORMAT "%s", label, byte_size_in_proper_unit(heap_used), proper_unit_for_byte_size(heap_used), byte_size_in_proper_unit(cl.used()), proper_unit_for_byte_size(cl.used())); size_t heap_committed = _heap->committed(); guarantee(cl.committed() == heap_committed, "%s: heap committed size must be consistent: heap-committed = " SIZE_FORMAT "%s, regions-committed = " SIZE_FORMAT "%s", label, byte_size_in_proper_unit(heap_committed), proper_unit_for_byte_size(heap_committed), byte_size_in_proper_unit(cl.committed()), proper_unit_for_byte_size(cl.committed())); } // Internal heap region checks if (ShenandoahVerifyLevel >= 1) { ShenandoahVerifyHeapRegionClosure cl(label, regions); _heap->heap_region_iterate(&cl); } OrderAccess::fence(); _heap->make_parsable(false); // Allocate temporary bitmap for storing marking wavefront: _verification_bit_map->clear(); // Allocate temporary array for storing liveness data ShenandoahLivenessData* ld = NEW_C_HEAP_ARRAY(ShenandoahLivenessData, _heap->num_regions(), mtGC); Copy::fill_to_bytes((void*)ld, _heap->num_regions()*sizeof(ShenandoahLivenessData), 0); const VerifyOptions& options = ShenandoahVerifier::VerifyOptions(forwarded, marked, cset, liveness, regions, gcstate); // Steps 1-2. Scan root set to get initial reachable set. Finish walking the reachable heap. // This verifies what application can see, since it only cares about reachable objects. size_t count_reachable = 0; if (ShenandoahVerifyLevel >= 2) { ShenandoahRootVerifier verifier; ShenandoahVerifierReachableTask task(_verification_bit_map, ld, &verifier, label, options); _heap->workers()->run_task(&task); count_reachable = task.processed(); } // Step 3. Walk marked objects. Marked objects might be unreachable. This verifies what collector, // not the application, can see during the region scans. There is no reason to process the objects // that were already verified, e.g. those marked in verification bitmap. There is interaction with TAMS: // before TAMS, we verify the bitmaps, if available; after TAMS, we walk until the top(). It mimics // what marked_object_iterate is doing, without calling into that optimized (and possibly incorrect) // version size_t count_marked = 0; if (ShenandoahVerifyLevel >= 4 && marked == _verify_marked_complete) { guarantee(_heap->marking_context()->is_complete(), "Marking context should be complete"); ShenandoahVerifierMarkedRegionTask task(_verification_bit_map, ld, label, options); _heap->workers()->run_task(&task); count_marked = task.processed(); } else { guarantee(ShenandoahVerifyLevel < 4 || marked == _verify_marked_incomplete || marked == _verify_marked_disable, "Should be"); } // Step 4. Verify accumulated liveness data, if needed. Only reliable if verification level includes // marked objects. if (ShenandoahVerifyLevel >= 4 && marked == _verify_marked_complete && liveness == _verify_liveness_complete) { for (size_t i = 0; i < _heap->num_regions(); i++) { ShenandoahHeapRegion* r = _heap->get_region(i); juint verf_live = 0; if (r->is_humongous()) { // For humongous objects, test if start region is marked live, and if so, // all humongous regions in that chain have live data equal to their "used". juint start_live = OrderAccess::load_acquire(&ld[r->humongous_start_region()->index()]); if (start_live > 0) { verf_live = (juint)(r->used() / HeapWordSize); } } else { verf_live = OrderAccess::load_acquire(&ld[r->index()]); } size_t reg_live = r->get_live_data_words(); if (reg_live != verf_live) { ResourceMark rm; stringStream ss; r->print_on(&ss); fatal("%s: Live data should match: region-live = " SIZE_FORMAT ", verifier-live = " UINT32_FORMAT "\n%s", label, reg_live, verf_live, ss.as_string()); } } } log_info(gc)("Verify %s, Level " INTX_FORMAT " (" SIZE_FORMAT " reachable, " SIZE_FORMAT " marked)", label, ShenandoahVerifyLevel, count_reachable, count_marked); FREE_C_HEAP_ARRAY(ShenandoahLivenessData, ld); } void ShenandoahVerifier::verify_generic(VerifyOption vo) { verify_at_safepoint( "Generic Verification", _verify_forwarded_allow, // conservatively allow forwarded _verify_marked_disable, // do not verify marked: lots ot time wasted checking dead allocations _verify_cset_disable, // cset may be inconsistent _verify_liveness_disable, // no reliable liveness data _verify_regions_disable, // no reliable region data _verify_gcstate_disable // no data about gcstate ); } void ShenandoahVerifier::verify_before_concmark() { verify_at_safepoint( "Before Mark", _verify_forwarded_none, // UR should have fixed up _verify_marked_disable, // do not verify marked: lots ot time wasted checking dead allocations _verify_cset_none, // UR should have fixed this _verify_liveness_disable, // no reliable liveness data _verify_regions_notrash, // no trash regions _verify_gcstate_stable // there are no forwarded objects ); } void ShenandoahVerifier::verify_after_concmark() { verify_at_safepoint( "After Mark", _verify_forwarded_none, // no forwarded references _verify_marked_complete, // bitmaps as precise as we can get _verify_cset_none, // no references to cset anymore _verify_liveness_complete, // liveness data must be complete here _verify_regions_disable, // trash regions not yet recycled _verify_gcstate_stable // mark should have stabilized the heap ); } void ShenandoahVerifier::verify_before_evacuation() { verify_at_safepoint( "Before Evacuation", _verify_forwarded_none, // no forwarded references _verify_marked_complete, // walk over marked objects too _verify_cset_disable, // non-forwarded references to cset expected _verify_liveness_complete, // liveness data must be complete here _verify_regions_disable, // trash regions not yet recycled _verify_gcstate_stable // mark should have stabilized the heap ); } void ShenandoahVerifier::verify_during_evacuation() { verify_at_safepoint( "During Evacuation", _verify_forwarded_allow, // some forwarded references are allowed _verify_marked_disable, // walk only roots _verify_cset_disable, // some cset references are not forwarded yet _verify_liveness_disable, // liveness data might be already stale after pre-evacs _verify_regions_disable, // trash regions not yet recycled _verify_gcstate_evacuation // evacuation is in progress ); } void ShenandoahVerifier::verify_after_evacuation() { verify_at_safepoint( "After Evacuation", _verify_forwarded_allow, // objects are still forwarded _verify_marked_complete, // bitmaps might be stale, but alloc-after-mark should be well _verify_cset_forwarded, // all cset refs are fully forwarded _verify_liveness_disable, // no reliable liveness data anymore _verify_regions_notrash, // trash regions have been recycled already _verify_gcstate_forwarded // evacuation produced some forwarded objects ); } void ShenandoahVerifier::verify_before_updaterefs() { verify_at_safepoint( "Before Updating References", _verify_forwarded_allow, // forwarded references allowed _verify_marked_complete, // bitmaps might be stale, but alloc-after-mark should be well _verify_cset_forwarded, // all cset refs are fully forwarded _verify_liveness_disable, // no reliable liveness data anymore _verify_regions_notrash, // trash regions have been recycled already _verify_gcstate_forwarded // evacuation should have produced some forwarded objects ); } void ShenandoahVerifier::verify_after_updaterefs() { verify_at_safepoint( "After Updating References", _verify_forwarded_none, // no forwarded references _verify_marked_complete, // bitmaps might be stale, but alloc-after-mark should be well _verify_cset_none, // no cset references, all updated _verify_liveness_disable, // no reliable liveness data anymore _verify_regions_nocset, // no cset regions, trash regions have appeared _verify_gcstate_stable // update refs had cleaned up forwarded objects ); } void ShenandoahVerifier::verify_after_degenerated() { verify_at_safepoint( "After Degenerated GC", _verify_forwarded_none, // all objects are non-forwarded _verify_marked_complete, // all objects are marked in complete bitmap _verify_cset_none, // no cset references _verify_liveness_disable, // no reliable liveness data anymore _verify_regions_notrash_nocset, // no trash, no cset _verify_gcstate_stable // degenerated refs had cleaned up forwarded objects ); } void ShenandoahVerifier::verify_before_fullgc() { verify_at_safepoint( "Before Full GC", _verify_forwarded_allow, // can have forwarded objects _verify_marked_disable, // do not verify marked: lots ot time wasted checking dead allocations _verify_cset_disable, // cset might be foobared _verify_liveness_disable, // no reliable liveness data anymore _verify_regions_disable, // no reliable region data here _verify_gcstate_disable // no reliable gcstate data ); } void ShenandoahVerifier::verify_after_fullgc() { verify_at_safepoint( "After Full GC", _verify_forwarded_none, // all objects are non-forwarded _verify_marked_complete, // all objects are marked in complete bitmap _verify_cset_none, // no cset references _verify_liveness_disable, // no reliable liveness data anymore _verify_regions_notrash_nocset, // no trash, no cset _verify_gcstate_stable // full gc cleaned up everything ); } class ShenandoahVerifyNoForwared : public OopClosure { private: template void do_oop_work(T* p) { T o = RawAccess<>::oop_load(p); if (!CompressedOops::is_null(o)) { oop obj = CompressedOops::decode_not_null(o); oop fwd = (oop) ShenandoahForwarding::get_forwardee_raw_unchecked(obj); if (obj != fwd) { ShenandoahAsserts::print_failure(ShenandoahAsserts::_safe_all, obj, p, NULL, "Verify Roots", "Should not be forwarded", __FILE__, __LINE__); } } } public: void do_oop(narrowOop* p) { do_oop_work(p); } void do_oop(oop* p) { do_oop_work(p); } }; class ShenandoahVerifyInToSpaceClosure : public OopClosure { private: template void do_oop_work(T* p) { T o = RawAccess<>::oop_load(p); if (!CompressedOops::is_null(o)) { oop obj = CompressedOops::decode_not_null(o); ShenandoahHeap* heap = ShenandoahHeap::heap(); if (!heap->marking_context()->is_marked(obj)) { ShenandoahAsserts::print_failure(ShenandoahAsserts::_safe_all, obj, p, NULL, "Verify Roots In To-Space", "Should be marked", __FILE__, __LINE__); } if (heap->in_collection_set(obj)) { ShenandoahAsserts::print_failure(ShenandoahAsserts::_safe_all, obj, p, NULL, "Verify Roots In To-Space", "Should not be in collection set", __FILE__, __LINE__); } oop fwd = (oop) ShenandoahForwarding::get_forwardee_raw_unchecked(obj); if (obj != fwd) { ShenandoahAsserts::print_failure(ShenandoahAsserts::_safe_all, obj, p, NULL, "Verify Roots In To-Space", "Should not be forwarded", __FILE__, __LINE__); } } } public: void do_oop(narrowOop* p) { do_oop_work(p); } void do_oop(oop* p) { do_oop_work(p); } }; void ShenandoahVerifier::verify_roots_in_to_space() { ShenandoahRootVerifier verifier; ShenandoahVerifyInToSpaceClosure cl; verifier.oops_do(&cl); } void ShenandoahVerifier::verify_roots_no_forwarded() { ShenandoahRootVerifier verifier; ShenandoahVerifyNoForwared cl; verifier.oops_do(&cl); } void ShenandoahVerifier::verify_roots_no_forwarded_except(ShenandoahRootVerifier::RootTypes types) { ShenandoahRootVerifier verifier; verifier.excludes(types); ShenandoahVerifyNoForwared cl; verifier.oops_do(&cl); }