CoreCLR
CoreCLR
在这篇中我将讲述GC Collector内部的实现, 这是CoreCLR中除了JIT以外最复杂部分,下面一些概念目前尚未有公开的文档和书籍讲到。
为了分析这部分我花了一个多月的时间,期间也多次向CoreCLR的开发组提问过,我有信心以下内容都是比较准确的,但如果你发现了错误或者有疑问的地方请指出来,
以下的内容基于CoreCLR 1.1.0的源代码分析,以后可能会有所改变。
因为内容过长,我分成了两篇,这一篇分析代码,下一篇实际使用LLDB跟踪GC收集垃圾的处理。
需要的预备知识
- 看过BOTR中GC设计的文档 原文 译文
- 看过我之前的系列文章, 碰到不明白的可以先跳过但最少需要看一遍
- 对c中的指针有一定了解
- 对常用数据结构有一定了解, 例如链表
- 对基础c++语法有一定了解, 高级语法和STL不需要因为微软只用了低级语法
GC的触发
GC一般在已预留的内存不够用或者已经分配量超过阈值时触发,场景包括:
不能给分配上下文指定新的空间时
当调用try_allocate_more_space不能从segment结尾或自由对象列表获取新的空间时会触发GC, 详细可以看我上一篇中分析的代码。
分配的数据量达到一定阈值时
阈值储存在各个heap的dd_min_gc_size(初始值), dd_desired_allocation(动态调整值), dd_new_allocation(消耗值)中,每次给分配上下文指定空间时会减少dd_new_allocation。
如果dd_new_allocation变为负数或者与dd_desired_allocation的比例小于一定值则触发GC,
触发完GC以后会重新调整dd_new_allocation到dd_desired_allocation。
参考new_allocation_limit, new_allocation_allowed和check_for_full_gc函数。
值得一提的是可以在.Net程序中使用GC.RegisterForFullGCNotification可以设置触发GC需要的dd_new_allocation / dd_desired_allocation的比例(会储存在fgn_maxgen_percent和fgn_loh_percent中), 设置一个大于0的比例可以让GC触发的更加频繁。
StressGC
允许手动设置特殊的GC触发策略, 参考这个文档
作为例子,你可以试着在运行程序前运行export COMPlus_GCStress=1
GCStrees会通过调用GCStress<gc_on_alloc>::MaybeTrigger(acontext)
触发,
如果你设置了COMPlus_GCStressStart环境变量,在调用MaybeTrigger一定次数后会强制触发GC,另外还有COMPlus_GCStressStartAtJit等参数,请参考上面的文档。
默认StressGC不会启用。
手动触发GC
在.Net程序中使用GC.Collect可以触发手动触发GC,我相信你们都知道。
调用.Net中的GC.Collect会调用CoreCLR中的GCHeap::GarbageCollect => GarbageCollectTry => GarbageCollectGeneration。
GC的处理
以下函数大部分都在gc.cpp里,在这个文件里的函数我就不一一标出文件了。
GC的入口点
GC的入口点是GCHeap::GarbageCollectGeneration函数,这个函数的主要作用是停止运行引擎和调用各个gc_heap的gc_heap::garbage_collect函数
因为这一篇重点在于GC做出的处理,我将不对如何停止运行引擎和后台GC做出详细的解释,希望以后可以再写一篇文章讲述
// 第一个参数是回收垃圾的代, 例如等于1时会回收gen 0和gen 1的垃圾
// 第二个参数是触发GC的原因
size_t
GCHeap::GarbageCollectGeneration (unsigned int gen, gc_reason reason)
{
dprintf (2, ("triggered a GC!"));
// 获取gc_heap实例,意义不大
#ifdef MULTIPLE_HEAPS
gc_heap* hpt = gc_heap::g_heaps[0];
#else
gc_heap* hpt = 0;
#endif //MULTIPLE_HEAPS
// 获取当前线程和dd数据
Thread* current_thread = GetThread();
BOOL cooperative_mode = TRUE;
dynamic_data* dd = hpt->dynamic_data_of (gen);
size_t localCount = dd_collection_count (dd);
// 获取GC锁, 防止重复触发GC
enter_spin_lock (&gc_heap::gc_lock);
dprintf (SPINLOCK_LOG, ("GC Egc"));
ASSERT_HOLDING_SPIN_LOCK(&gc_heap::gc_lock);
//don't trigger another GC if one was already in progress
//while waiting for the lock
{
size_t col_count = dd_collection_count (dd);
if (localCount != col_count)
{
#ifdef SYNCHRONIZATION_STATS
gc_lock_contended++;
#endif //SYNCHRONIZATION_STATS
dprintf (SPINLOCK_LOG, ("no need GC Lgc"));
leave_spin_lock (&gc_heap::gc_lock);
// We don't need to release msl here 'cause this means a GC
// has happened and would have release all msl's.
return col_count;
}
}
// 统计GC的开始时间(包括停止运行引擎使用的时间)
#ifdef COUNT_CYCLES
int gc_start = GetCycleCount32();
#endif //COUNT_CYCLES
#ifdef TRACE_GC
#ifdef COUNT_CYCLES
AllocDuration += GetCycleCount32() - AllocStart;
#else
AllocDuration += clock() - AllocStart;
#endif //COUNT_CYCLES
#endif //TRACE_GC
// 设置触发GC的原因
gc_heap::g_low_memory_status = (reason == reason_lowmemory) ||
(reason == reason_lowmemory_blocking) ||
g_bLowMemoryFromHost;
if (g_bLowMemoryFromHost)
reason = reason_lowmemory_host;
gc_trigger_reason = reason;
// 重设GC结束的事件
// 以下说的"事件"的作用和"信号量", .Net中的"Monitor"一样
#ifdef MULTIPLE_HEAPS
for (int i = 0; i < gc_heap::n_heaps; i++)
{
gc_heap::g_heaps[i]->reset_gc_done();
}
#else
gc_heap::reset_gc_done();
#endif //MULTIPLE_HEAPS
// 标记gc已开始, 全局静态变量
gc_heap::gc_started = TRUE;
// 停止运行引擎
{
init_sync_log_stats();
#ifndef MULTIPLE_HEAPS
// 让当前线程进入preemptive模式
// 最终会调用Thread::EnablePreemptiveGC
// 设置线程的m_fPreemptiveGCDisabled等于0
cooperative_mode = gc_heap::enable_preemptive (current_thread);
dprintf (2, ("Suspending EE"));
BEGIN_TIMING(suspend_ee_during_log);
// 停止运行引擎,这里我只做简单解释
// - 调用ThreadSuspend::SuspendEE
// - 调用LockThreadStore锁住线程集合直到RestartEE
// - 设置GCHeap中全局事件WaitForGCEvent
// - 调用ThreadStore::TrapReturingThreads
// - 设置全局变量g_TrapReturningThreads,jit会生成检查这个全局变量的代码
// - 调用SuspendRuntime, 停止除了当前线程以外的线程,如果线程在cooperative模式则劫持并停止,如果线程在preemptive模式则阻止进入cooperative模式
GCToEEInterface::SuspendEE(GCToEEInterface::SUSPEND_FOR_GC);
END_TIMING(suspend_ee_during_log);
// 再次判断是否应该执行gc
// 目前如果设置了NoGCRegion(gc_heap::settings.pause_mode == pause_no_gc)则会进一步检查
// https://msdn.microsoft.com/en-us/library/system.runtime.gclatencymode(v=vs.110).aspx
gc_heap::proceed_with_gc_p = gc_heap::should_proceed_with_gc();
// 设置当前线程离开preemptive模式
gc_heap::disable_preemptive (current_thread, cooperative_mode);
if (gc_heap::proceed_with_gc_p)
pGenGCHeap->settings.init_mechanisms();
else
gc_heap::update_collection_counts_for_no_gc();
#endif //!MULTIPLE_HEAPS
}
// MAP_EVENT_MONITORS(EE_MONITOR_GARBAGE_COLLECTIONS, NotifyEvent(EE_EVENT_TYPE_GC_STARTED, 0));
// 统计GC的开始时间
#ifdef TRACE_GC
#ifdef COUNT_CYCLES
unsigned start;
unsigned finish;
start = GetCycleCount32();
#else
clock_t start;
clock_t finish;
start = clock();
#endif //COUNT_CYCLES
PromotedObjectCount = 0;
#endif //TRACE_GC
// 当前收集代的序号
// 后面看到condemned generation时都表示"当前收集代"
unsigned int condemned_generation_number = gen;
// We want to get a stack from the user thread that triggered the GC
// instead of on the GC thread which is the case for Server GC.
// But we are doing it for Workstation GC as well to be uniform.
FireEtwGCTriggered((int) reason, GetClrInstanceId());
// 进入GC处理
// 如果有多个heap(服务器GC),可以使用各个heap的线程并行处理
// 如果只有一个heap(工作站GC),直接在当前线程处理
#ifdef MULTIPLE_HEAPS
GcCondemnedGeneration = condemned_generation_number;
// 当前线程进入preemptive模式
cooperative_mode = gc_heap::enable_preemptive (current_thread);
BEGIN_TIMING(gc_during_log);
// gc_heap::gc_thread_function在收到这个信号以后会进入GC处理
// 在里面也会判断proceed_with_gc_p
gc_heap::ee_suspend_event.Set();
// 等待所有线程处理完毕
gc_heap::wait_for_gc_done();
END_TIMING(gc_during_log);
// 当前线程离开preemptive模式
gc_heap::disable_preemptive (current_thread, cooperative_mode);
condemned_generation_number = GcCondemnedGeneration;
#else
// 在当前线程中进入GC处理
if (gc_heap::proceed_with_gc_p)
{
BEGIN_TIMING(gc_during_log);
pGenGCHeap->garbage_collect (condemned_generation_number);
END_TIMING(gc_during_log);
}
#endif //MULTIPLE_HEAPS
// 统计GC的结束时间
#ifdef TRACE_GC
#ifdef COUNT_CYCLES
finish = GetCycleCount32();
#else
finish = clock();
#endif //COUNT_CYCLES
GcDuration += finish - start;
dprintf (3,
("<GC# %d> Condemned: %d, Duration: %d, total: %d Alloc Avg: %d, Small Objects:%d Large Objects:%d",
VolatileLoad(&pGenGCHeap->settings.gc_index), condemned_generation_number,
finish - start, GcDuration,
AllocCount ? (AllocDuration / AllocCount) : 0,
AllocSmallCount, AllocBigCount));
AllocCount = 0;
AllocDuration = 0;
#endif // TRACE_GC
#ifdef BACKGROUND_GC
// We are deciding whether we should fire the alloc wait end event here
// because in begin_foreground we could be calling end_foreground
// if we need to retry.
if (gc_heap::alloc_wait_event_p)
{
hpt->fire_alloc_wait_event_end (awr_fgc_wait_for_bgc);
gc_heap::alloc_wait_event_p = FALSE;
}
#endif //BACKGROUND_GC
// 重启运行引擎
#ifndef MULTIPLE_HEAPS
#ifdef BACKGROUND_GC
if (!gc_heap::dont_restart_ee_p)
{
#endif //BACKGROUND_GC
BEGIN_TIMING(restart_ee_during_log);
// 重启运行引擎,这里我只做简单解释
// - 调用SetGCDone
// - 调用ResumeRuntime
// - 调用UnlockThreadStore
GCToEEInterface::RestartEE(TRUE);
END_TIMING(restart_ee_during_log);
#ifdef BACKGROUND_GC
}
#endif //BACKGROUND_GC
#endif //!MULTIPLE_HEAPS
#ifdef COUNT_CYCLES
printf ("GC: %d Time: %d\n", GcCondemnedGeneration,
GetCycleCount32() - gc_start);
#endif //COUNT_CYCLES
// 设置gc_done_event事件和释放gc锁
// 如果有多个heap, 这里的处理会在gc_thread_function中完成
#ifndef MULTIPLE_HEAPS
process_sync_log_stats();
gc_heap::gc_started = FALSE;
gc_heap::set_gc_done();
dprintf (SPINLOCK_LOG, ("GC Lgc"));
leave_spin_lock (&gc_heap::gc_lock);
#endif //!MULTIPLE_HEAPS
#ifdef FEATURE_PREMORTEM_FINALIZATION
if ((!pGenGCHeap->settings.concurrent && pGenGCHeap->settings.found_finalizers) ||
FinalizerThread::HaveExtraWorkForFinalizer())
{
FinalizerThread::EnableFinalization();
}
#endif // FEATURE_PREMORTEM_FINALIZATION
return dd_collection_count (dd);
}
以下是gc_heap::garbage_collect
函数,这个函数也是GC的入口点函数,
主要作用是针对gc_heap
做gc开始前和结束后的清理工作,例如重设各个线程的分配上下文和修改gc参数
// 第一个参数是回收垃圾的代
int gc_heap::garbage_collect (int n)
{
// 枚举线程
// - 统计目前用的分配上下文数量
// - 在分配上下文的alloc_ptr和limit之间创建free object
// - 设置所有分配上下文的alloc_ptr和limit到0
//reset the number of alloc contexts
alloc_contexts_used = 0;
fix_allocation_contexts (TRUE);
// 清理在gen 0范围的brick table
// brick table将在下面解释
#ifdef MULTIPLE_HEAPS
clear_gen0_bricks();
#endif //MULTIPLE_HEAPS
// 如果开始了NoGCRegion,并且disallowFullBlockingGC等于true,则跳过这次GC
// https://msdn.microsoft.com/en-us/library/dn906204(v=vs.110).aspx
if ((settings.pause_mode == pause_no_gc) && current_no_gc_region_info.minimal_gc_p)
{
#ifdef MULTIPLE_HEAPS
gc_t_join.join(this, gc_join_minimal_gc);
if (gc_t_join.joined())
{
#endif //MULTIPLE_HEAPS
#ifdef MULTIPLE_HEAPS
// this is serialized because we need to get a segment
for (int i = 0; i < n_heaps; i++)
{
if (!(g_heaps[i]->expand_soh_with_minimal_gc()))
current_no_gc_region_info.start_status = start_no_gc_no_memory;
}
#else
if (!expand_soh_with_minimal_gc())
current_no_gc_region_info.start_status = start_no_gc_no_memory;
#endif //MULTIPLE_HEAPS
update_collection_counts_for_no_gc();
#ifdef MULTIPLE_HEAPS
gc_t_join.restart();
}
#endif //MULTIPLE_HEAPS
goto done;
}
// 清空gc_data_per_heap和fgm_result
init_records();
memset (&fgm_result, 0, sizeof (fgm_result));
// 设置收集理由到settings成员中
// settings成员的类型是gc_mechanisms, 里面的值已在前面初始化过,将会贯穿整个gc过程使用
settings.reason = gc_trigger_reason;
verify_pinned_queue_p = FALSE;
#if defined(ENABLE_PERF_COUNTERS) || defined(FEATURE_EVENT_TRACE)
num_pinned_objects = 0;
#endif //ENABLE_PERF_COUNTERS || FEATURE_EVENT_TRACE
#ifdef STRESS_HEAP
if (settings.reason == reason_gcstress)
{
settings.reason = reason_induced;
settings.stress_induced = TRUE;
}
#endif // STRESS_HEAP
#ifdef MULTIPLE_HEAPS
// 根据环境重新决定应该收集的代
// 这里的处理比较杂,大概包括了以下的处理
// - 备份dd_new_allocation到dd_gc_new_allocation
// - 必要时修改收集的代, 例如最大代的阈值用完或者需要低延迟的时候
// - 必要时设置settings.promotion = true (启用对象升代, 例如代0对象gc后变代1)
// - 算法是 通过卡片标记的对象 / 通过卡片扫描的对象 < 30% 则启用对象升代(dt_low_card_table_efficiency_p)
// - 这个比例储存在`generation_skip_ratio`中
// - Card Table将在下面解释,意义是如果前一代的对象不够多则需要把后一代的对象升代
//align all heaps on the max generation to condemn
dprintf (3, ("Joining for max generation to condemn"));
condemned_generation_num = generation_to_condemn (n,
&blocking_collection,
&elevation_requested,
FALSE);
gc_t_join.join(this, gc_join_generation_determined);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
// 判断是否要打印更多的除错信息,除错用
#ifdef TRACE_GC
int gc_count = (int)dd_collection_count (dynamic_data_of (0));
if (gc_count >= g_pConfig->GetGCtraceStart())
trace_gc = 1;
if (gc_count >= g_pConfig->GetGCtraceEnd())
trace_gc = 0;
#endif //TRACE_GC
// 复制(合并)各个heap的card table和brick table到全局
#ifdef MULTIPLE_HEAPS
#if !defined(SEG_MAPPING_TABLE) && !defined(FEATURE_BASICFREEZE)
// 释放已删除的segment索引的节点
//delete old slots from the segment table
seg_table->delete_old_slots();
#endif //!SEG_MAPPING_TABLE && !FEATURE_BASICFREEZE
for (int i = 0; i < n_heaps; i++)
{
//copy the card and brick tables
if (g_card_table != g_heaps[i]->card_table)
{
g_heaps[i]->copy_brick_card_table();
}
g_heaps[i]->rearrange_large_heap_segments();
if (!recursive_gc_sync::background_running_p())
{
g_heaps[i]->rearrange_small_heap_segments();
}
}
#else //MULTIPLE_HEAPS
#ifdef BACKGROUND_GC
//delete old slots from the segment table
#if !defined(SEG_MAPPING_TABLE) && !defined(FEATURE_BASICFREEZE)
// 释放已删除的segment索引的节点
seg_table->delete_old_slots();
#endif //!SEG_MAPPING_TABLE && !FEATURE_BASICFREEZE
// 删除空segment
rearrange_large_heap_segments();
if (!recursive_gc_sync::background_running_p())
{
rearrange_small_heap_segments();
}
#endif //BACKGROUND_GC
// check for card table growth
if (g_card_table != card_table)
copy_brick_card_table();
#endif //MULTIPLE_HEAPS
// 合并各个heap的elevation_requested和blocking_collection选项
BOOL should_evaluate_elevation = FALSE;
BOOL should_do_blocking_collection = FALSE;
#ifdef MULTIPLE_HEAPS
int gen_max = condemned_generation_num;
for (int i = 0; i < n_heaps; i++)
{
if (gen_max < g_heaps[i]->condemned_generation_num)
gen_max = g_heaps[i]->condemned_generation_num;
if ((!should_evaluate_elevation) && (g_heaps[i]->elevation_requested))
should_evaluate_elevation = TRUE;
if ((!should_do_blocking_collection) && (g_heaps[i]->blocking_collection))
should_do_blocking_collection = TRUE;
}
settings.condemned_generation = gen_max;
//logically continues after GC_PROFILING.
#else //MULTIPLE_HEAPS
// 单gc_heap(工作站GC)时的处理
// 根据环境重新决定应该收集的代,解释看上面
settings.condemned_generation = generation_to_condemn (n,
&blocking_collection,
&elevation_requested,
FALSE);
should_evaluate_elevation = elevation_requested;
should_do_blocking_collection = blocking_collection;
#endif //MULTIPLE_HEAPS
settings.condemned_generation = joined_generation_to_condemn (
should_evaluate_elevation,
settings.condemned_generation,
&should_do_blocking_collection
STRESS_HEAP_ARG(n)
);
STRESS_LOG1(LF_GCROOTS|LF_GC|LF_GCALLOC, LL_INFO10,
"condemned generation num: %d\n", settings.condemned_generation);
record_gcs_during_no_gc();
// 如果收集代大于1(目前只有2,也就是full gc)则启用对象升代
if (settings.condemned_generation > 1)
settings.promotion = TRUE;
#ifdef HEAP_ANALYZE
// At this point we've decided what generation is condemned
// See if we've been requested to analyze survivors after the mark phase
if (AnalyzeSurvivorsRequested(settings.condemned_generation))
{
heap_analyze_enabled = TRUE;
}
#endif // HEAP_ANALYZE
// 统计GC性能的处理,这里不分析
#ifdef GC_PROFILING
// If we're tracking GCs, then we need to walk the first generation
// before collection to track how many items of each class has been
// allocated.
UpdateGenerationBounds();
GarbageCollectionStartedCallback(settings.condemned_generation, settings.reason == reason_induced);
{
BEGIN_PIN_PROFILER(CORProfilerTrackGC());
size_t profiling_context = 0;
#ifdef MULTIPLE_HEAPS
int hn = 0;
for (hn = 0; hn < gc_heap::n_heaps; hn++)
{
gc_heap* hp = gc_heap::g_heaps [hn];
// When we're walking objects allocated by class, then we don't want to walk the large
// object heap because then it would count things that may have been around for a while.
hp->walk_heap (&AllocByClassHelper, (void *)&profiling_context, 0, FALSE);
}
#else
// When we're walking objects allocated by class, then we don't want to walk the large
// object heap because then it would count things that may have been around for a while.
gc_heap::walk_heap (&AllocByClassHelper, (void *)&profiling_context, 0, FALSE);
#endif //MULTIPLE_HEAPS
// Notify that we've reached the end of the Gen 0 scan
g_profControlBlock.pProfInterface->EndAllocByClass(&profiling_context);
END_PIN_PROFILER();
}
#endif // GC_PROFILING
// 后台GC的处理,这里不分析
#ifdef BACKGROUND_GC
if ((settings.condemned_generation == max_generation) &&
(recursive_gc_sync::background_running_p()))
{
//TODO BACKGROUND_GC If we just wait for the end of gc, it won't woork
// because we have to collect 0 and 1 properly
// in particular, the allocation contexts are gone.
// For now, it is simpler to collect max_generation-1
settings.condemned_generation = max_generation - 1;
dprintf (GTC_LOG, ("bgc - 1 instead of 2"));
}
if ((settings.condemned_generation == max_generation) &&
(should_do_blocking_collection == FALSE) &&
gc_can_use_concurrent &&
!temp_disable_concurrent_p &&
((settings.pause_mode == pause_interactive) || (settings.pause_mode == pause_sustained_low_latency)))
{
keep_bgc_threads_p = TRUE;
c_write (settings.concurrent, TRUE);
}
#endif //BACKGROUND_GC
// 当前gc的标识序号(会在gc1 => update_collection_counts函数里面更新)
settings.gc_index = (uint32_t)dd_collection_count (dynamic_data_of (0)) + 1;
// 通知运行引擎GC开始工作
// 这里会做出一些处理例如释放JIT中已删除的HostCodeHeap的内存
// Call the EE for start of GC work
// just one thread for MP GC
GCToEEInterface::GcStartWork (settings.condemned_generation,
max_generation);
// TODO: we could fire an ETW event to say this GC as a concurrent GC but later on due to not being able to
// create threads or whatever, this could be a non concurrent GC. Maybe for concurrent GC we should fire
// it in do_background_gc and if it failed to be a CGC we fire it in gc1... in other words, this should be
// fired in gc1.
// 更新一些统计用计数器和数据
do_pre_gc();
// 继续(唤醒)后台GC线程
#ifdef MULTIPLE_HEAPS
gc_start_event.Reset();
//start all threads on the roots.
dprintf(3, ("Starting all gc threads for gc"));
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
// 更新统计数据
{
int gen_num_for_data = max_generation + 1;
for (int i = 0; i <= gen_num_for_data; i++)
{
gc_data_per_heap.gen_data[i].size_before = generation_size (i);
generation* gen = generation_of (i);
gc_data_per_heap.gen_data[i].free_list_space_before = generation_free_list_space (gen);
gc_data_per_heap.gen_data[i].free_obj_space_before = generation_free_obj_space (gen);
}
}
// 打印出错信息
descr_generations (TRUE);
// descr_card_table();
// 如果不使用Write Barrier而是Write Watch时则需要更新Card Table
// 默认windows和linux编译的CoreCLR都会使用Write Barrier
// Write Barrier和Card Table将在下面解释
#ifdef NO_WRITE_BARRIER
fix_card_table();
#endif //NO_WRITE_BARRIER
// 检查gc_heap的状态,除错用
#ifdef VERIFY_HEAP
if ((g_pConfig->GetHeapVerifyLevel() & EEConfig::HEAPVERIFY_GC) &&
!(g_pConfig->GetHeapVerifyLevel() & EEConfig::HEAPVERIFY_POST_GC_ONLY))
{
verify_heap (TRUE);
}
if (g_pConfig->GetHeapVerifyLevel() & EEConfig::HEAPVERIFY_BARRIERCHECK)
checkGCWriteBarrier();
#endif // VERIFY_HEAP
// 调用GC的主函数`gc1`
// 后台GC的处理我在这一篇中将不会解释,希望以后可以专门写一篇解释后台GC
#ifdef BACKGROUND_GC
if (settings.concurrent)
{
// We need to save the settings because we'll need to restore it after each FGC.
assert (settings.condemned_generation == max_generation);
settings.compaction = FALSE;
saved_bgc_settings = settings;
#ifdef MULTIPLE_HEAPS
if (heap_number == 0)
{
for (int i = 0; i < n_heaps; i++)
{
prepare_bgc_thread (g_heaps[i]);
}
dprintf (2, ("setting bgc_threads_sync_event"));
bgc_threads_sync_event.Set();
}
else
{
bgc_threads_sync_event.Wait(INFINITE, FALSE);
dprintf (2, ("bgc_threads_sync_event is signalled"));
}
#else
prepare_bgc_thread(0);
#endif //MULTIPLE_HEAPS
#ifdef MULTIPLE_HEAPS
gc_t_join.join(this, gc_join_start_bgc);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
do_concurrent_p = TRUE;
do_ephemeral_gc_p = FALSE;
#ifdef MULTIPLE_HEAPS
dprintf(2, ("Joined to perform a background GC"));
for (int i = 0; i < n_heaps; i++)
{
gc_heap* hp = g_heaps[i];
if (!(hp->bgc_thread) || !hp->commit_mark_array_bgc_init (hp->mark_array))
{
do_concurrent_p = FALSE;
break;
}
else
{
hp->background_saved_lowest_address = hp->lowest_address;
hp->background_saved_highest_address = hp->highest_address;
}
}
#else
do_concurrent_p = (!!bgc_thread && commit_mark_array_bgc_init (mark_array));
if (do_concurrent_p)
{
background_saved_lowest_address = lowest_address;
background_saved_highest_address = highest_address;
}
#endif //MULTIPLE_HEAPS
if (do_concurrent_p)
{
#ifdef FEATURE_USE_SOFTWARE_WRITE_WATCH_FOR_GC_HEAP
SoftwareWriteWatch::EnableForGCHeap();
#endif //FEATURE_USE_SOFTWARE_WRITE_WATCH_FOR_GC_HEAP
#ifdef MULTIPLE_HEAPS
for (int i = 0; i < n_heaps; i++)
g_heaps[i]->current_bgc_state = bgc_initialized;
#else
current_bgc_state = bgc_initialized;
#endif //MULTIPLE_HEAPS
int gen = check_for_ephemeral_alloc();
// always do a gen1 GC before we start BGC.
// This is temporary for testing purpose.
//int gen = max_generation - 1;
dont_restart_ee_p = TRUE;
if (gen == -1)
{
// If we decide to not do a GC before the BGC we need to
// restore the gen0 alloc context.
#ifdef MULTIPLE_HEAPS
for (int i = 0; i < n_heaps; i++)
{
generation_allocation_pointer (g_heaps[i]->generation_of (0)) = 0;
generation_allocation_limit (g_heaps[i]->generation_of (0)) = 0;
}
#else
generation_allocation_pointer (youngest_generation) = 0;
generation_allocation_limit (youngest_generation) = 0;
#endif //MULTIPLE_HEAPS
}
else
{
do_ephemeral_gc_p = TRUE;
settings.init_mechanisms();
settings.condemned_generation = gen;
settings.gc_index = (size_t)dd_collection_count (dynamic_data_of (0)) + 2;
do_pre_gc();
// TODO BACKGROUND_GC need to add the profiling stuff here.
dprintf (GTC_LOG, ("doing gen%d before doing a bgc", gen));
}
//clear the cards so they don't bleed in gen 1 during collection
// shouldn't this always be done at the beginning of any GC?
//clear_card_for_addresses (
// generation_allocation_start (generation_of (0)),
// heap_segment_allocated (ephemeral_heap_segment));
if (!do_ephemeral_gc_p)
{
do_background_gc();
}
}
else
{
settings.compaction = TRUE;
c_write (settings.concurrent, FALSE);
}
#ifdef MULTIPLE_HEAPS
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
if (do_concurrent_p)
{
// At this point we are sure we'll be starting a BGC, so save its per heap data here.
// global data is only calculated at the end of the GC so we don't need to worry about
// FGCs overwriting it.
memset (&bgc_data_per_heap, 0, sizeof (bgc_data_per_heap));
memcpy (&bgc_data_per_heap, &gc_data_per_heap, sizeof(gc_data_per_heap));
if (do_ephemeral_gc_p)
{
dprintf (2, ("GC threads running, doing gen%d GC", settings.condemned_generation));
gen_to_condemn_reasons.init();
gen_to_condemn_reasons.set_condition (gen_before_bgc);
gc_data_per_heap.gen_to_condemn_reasons.init (&gen_to_condemn_reasons);
gc1();
#ifdef MULTIPLE_HEAPS
gc_t_join.join(this, gc_join_bgc_after_ephemeral);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
#ifdef MULTIPLE_HEAPS
do_post_gc();
#endif //MULTIPLE_HEAPS
settings = saved_bgc_settings;
assert (settings.concurrent);
do_background_gc();
#ifdef MULTIPLE_HEAPS
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
}
}
else
{
dprintf (2, ("couldn't create BGC threads, reverting to doing a blocking GC"));
gc1();
}
}
else
#endif //BACKGROUND_GC
{
gc1();
}
#ifndef MULTIPLE_HEAPS
allocation_running_time = (size_t)GCToOSInterface::GetLowPrecisionTimeStamp();
allocation_running_amount = dd_new_allocation (dynamic_data_of (0));
fgn_last_alloc = dd_new_allocation (dynamic_data_of (0));
#endif //MULTIPLE_HEAPS
done:
if (settings.pause_mode == pause_no_gc)
allocate_for_no_gc_after_gc();
int gn = settings.condemned_generation;
return gn;
}
GC的主函数
GC的主函数是gc1
,包含了GC中最关键的处理,也是这一篇中需要重点讲解的部分。
gc1
中的总体流程在BOTR文档已经有初步的介绍:
- 首先是
mark phase
,标记存活的对象 - 然后是
plan phase
,决定要压缩还是要清扫 - 如果要压缩则进入
relocate phase
和compact phase
- 如果要清扫则进入
sweep phase
在看具体的代码之前让我们一起复习之前讲到的Object
的结构
GC使用其中的2个bit来保存标记(marked)
和固定(pinned)
标记(marked)
表示对象是存活的,不应该被收集,储存在MethodTable指针 & 1中固定(pinned)
表示对象不能被移动(压缩时不要移动这个对象), 储存在对象头 & 0x20000000中
这两个bit会在mark_phase
中被标记,在plan_phase
中被清除,不会残留到GC结束后
再复习堆段(heap segment)的结构
一个gc_heap中有两个segment链表,一个是小对象(gen 0~gen 2)用的链表,一个是大对象(gen 3)用的链表,
其中链表的最后一个节点是ephemeral heap segment
,只用来保存gen 0和gen 1的对象,各个代都有一个开始地址,在开始地址之后的对象属于这个代或更年轻的代。
gc_heap::gc1
函数的代码如下
//internal part of gc used by the serial and concurrent version
void gc_heap::gc1()
{
#ifdef BACKGROUND_GC
assert (settings.concurrent == (uint32_t)(bgc_thread_id.IsCurrentThread()));
#endif //BACKGROUND_GC
// 开始统计各个阶段的时间,这些是全局变量
#ifdef TIME_GC
mark_time = plan_time = reloc_time = compact_time = sweep_time = 0;
#endif //TIME_GC
// 验证小对象的segment列表(gen0~2的segment),除错用
verify_soh_segment_list();
int n = settings.condemned_generation;
// gc的标识序号+1
update_collection_counts ();
// 调用mark_phase和plan_phase(包括relocate, compact, sweep)
// 后台GC这一篇不解释,请跳到#endif //BACKGROUND_GC
#ifdef BACKGROUND_GC
bgc_alloc_lock->check();
#endif //BACKGROUND_GC
// 打印除错信息
free_list_info (max_generation, "beginning");
// 设置当前收集代
vm_heap->GcCondemnedGeneration = settings.condemned_generation;
assert (g_card_table == card_table);
{
// 设置收集范围
// 如果收集gen 2则从最小的地址一直到最大的地址
// 否则从收集代的开始地址一直到短暂的堆段(ephemeral heap segment)的预留地址
if (n == max_generation)
{
gc_low = lowest_address;
gc_high = highest_address;
}
else
{
gc_low = generation_allocation_start (generation_of (n));
gc_high = heap_segment_reserved (ephemeral_heap_segment);
}
#ifdef BACKGROUND_GC
if (settings.concurrent)
{
#ifdef TRACE_GC
time_bgc_last = GetHighPrecisionTimeStamp();
#endif //TRACE_GC
fire_bgc_event (BGCBegin);
concurrent_print_time_delta ("BGC");
//#ifdef WRITE_WATCH
//reset_write_watch (FALSE);
//#endif //WRITE_WATCH
concurrent_print_time_delta ("RW");
background_mark_phase();
free_list_info (max_generation, "after mark phase");
background_sweep();
free_list_info (max_generation, "after sweep phase");
}
else
#endif //BACKGROUND_GC
{
// 调用mark_phase标记存活的对象
// 请看下面的详解
mark_phase (n, FALSE);
// 设置对象结构有可能不合法,因为plan_phase中可能会对对象做出临时性的破坏
GCScan::GcRuntimeStructuresValid (FALSE);
// 调用plan_phase计划是否要压缩还是清扫
// 这个函数内部会完成压缩或者清扫,请看下面的详解
plan_phase (n);
// 重新设置对象结构合法
GCScan::GcRuntimeStructuresValid (TRUE);
}
}
// 记录gc结束时间
size_t end_gc_time = GetHighPrecisionTimeStamp();
// printf ("generation: %d, elapsed time: %Id\n", n, end_gc_time - dd_time_clock (dynamic_data_of (0)));
// 调整generation_pinned_allocated(固定对象的大小)和generation_allocation_size(分配的大小)
//adjust the allocation size from the pinned quantities.
for (int gen_number = 0; gen_number <= min (max_generation,n+1); gen_number++)
{
generation* gn = generation_of (gen_number);
if (settings.compactin)
{
generation_pinned_allocated (gn) += generation_pinned_allocation_compact_size (gn);
generation_allocation_size (generation_of (gen_number)) += generation_pinned_allocation_compact_size (gn);
}
else
{
generation_pinned_allocated (gn) += generation_pinned_allocation_sweep_size (gn);
generation_allocation_size (generation_of (gen_number)) += generation_pinned_allocation_sweep_size (gn);
}
generation_pinned_allocation_sweep_size (gn) = 0;
generation_pinned_allocation_compact_size (gn) = 0;
}
// 更新gc_data_per_heap, 和打印除错信息
#ifdef BACKGROUND_GC
if (settings.concurrent)
{
dynamic_data* dd = dynamic_data_of (n);
dd_gc_elapsed_time (dd) = end_gc_time - dd_time_clock (dd);
free_list_info (max_generation, "after computing new dynamic data");
gc_history_per_heap* current_gc_data_per_heap = get_gc_data_per_heap();
for (int gen_number = 0; gen_number < max_generation; gen_number++)
{
dprintf (2, ("end of BGC: gen%d new_alloc: %Id",
gen_number, dd_desired_allocation (dynamic_data_of (gen_number))));
current_gc_data_per_heap->gen_data[gen_number].size_after = generation_size (gen_number);
current_gc_data_per_heap->gen_data[gen_number].free_list_space_after = generation_free_list_space (generation_of (gen_number));
current_gc_data_per_heap->gen_data[gen_number].free_obj_space_after = generation_free_obj_space (generation_of (gen_number));
}
}
else
#endif //BACKGROUND_GC
{
free_list_info (max_generation, "end");
for (int gen_number = 0; gen_number <= n; gen_number++)
{
dynamic_data* dd = dynamic_data_of (gen_number);
dd_gc_elapsed_time (dd) = end_gc_time - dd_time_clock (dd);
compute_new_dynamic_data (gen_number);
}
if (n != max_generation)
{
int gen_num_for_data = ((n < (max_generation - 1)) ? (n + 1) : (max_generation + 1));
for (int gen_number = (n + 1); gen_number <= gen_num_for_data; gen_number++)
{
get_gc_data_per_heap()->gen_data[gen_number].size_after = generation_size (gen_number);
get_gc_data_per_heap()->gen_data[gen_number].free_list_space_after = generation_free_list_space (generation_of (gen_number));
get_gc_data_per_heap()->gen_data[gen_number].free_obj_space_after = generation_free_obj_space (generation_of (gen_number));
}
}
get_gc_data_per_heap()->maxgen_size_info.running_free_list_efficiency = (uint32_t)(generation_allocator_efficiency (generation_of (max_generation)) * 100);
free_list_info (max_generation, "after computing new dynamic data");
if (heap_number == 0)
{
dprintf (GTC_LOG, ("GC#%d(gen%d) took %Idms",
dd_collection_count (dynamic_data_of (0)),
settings.condemned_generation,
dd_gc_elapsed_time (dynamic_data_of (0))));
}
for (int gen_number = 0; gen_number <= (max_generation + 1); gen_number++)
{
dprintf (2, ("end of FGC/NGC: gen%d new_alloc: %Id",
gen_number, dd_desired_allocation (dynamic_data_of (gen_number))));
}
}
// 更新收集代+1代的动态数据(dd)
if (n < max_generation)
{
compute_promoted_allocation (1 + n);
dynamic_data* dd = dynamic_data_of (1 + n);
size_t new_fragmentation = generation_free_list_space (generation_of (1 + n)) +
generation_free_obj_space (generation_of (1 + n));
#ifdef BACKGROUND_GC
if (current_c_gc_state != c_gc_state_planning)
#endif //BACKGROUND_GC
{
if (settings.promotion)
{
dd_fragmentation (dd) = new_fragmentation;
}
else
{
//assert (dd_fragmentation (dd) == new_fragmentation);
}
}
}
// 更新ephemeral_low(gen 1的开始的地址)和ephemeral_high(ephemeral_heap_segment的预留地址)
#ifdef BACKGROUND_GC
if (!settings.concurrent)
#endif //BACKGROUND_GC
{
adjust_ephemeral_limits(!!IsGCThread());
}
#ifdef BACKGROUND_GC
assert (ephemeral_low == generation_allocation_start (generation_of ( max_generation -1)));
assert (ephemeral_high == heap_segment_reserved (ephemeral_heap_segment));
#endif //BACKGROUND_GC
// 如果fgn_maxgen_percent有设置并且收集的是代1则检查是否要收集代2, 否则通知full_gc_end_event事件
if (fgn_maxgen_percent)
{
if (settings.condemned_generation == (max_generation - 1))
{
check_for_full_gc (max_generation - 1, 0);
}
else if (settings.condemned_generation == max_generation)
{
if (full_gc_approach_event_set
#ifdef MULTIPLE_HEAPS
&& (heap_number == 0)
#endif //MULTIPLE_HEAPS
)
{
dprintf (2, ("FGN-GC: setting gen2 end event"));
full_gc_approach_event.Reset();
#ifdef BACKGROUND_GC
// By definition WaitForFullGCComplete only succeeds if it's full, *blocking* GC, otherwise need to return N/A
fgn_last_gc_was_concurrent = settings.concurrent ? TRUE : FALSE;
#endif //BACKGROUND_GC
full_gc_end_event.Set();
full_gc_approach_event_set = false;
}
}
}
// 重新决定分配量(allocation_quantum)
// 这里的 dd_new_allocation 已经重新设置过
// 分配量 = 离下次启动gc需要分配的大小 / (2 * 已用的分配上下文数量), 最小1K, 最大8K
// 如果很快就要重新启动gc, 或者用的分配上下文较多(浪费较多), 则需要减少分配量
// 大部分情况下这里的分配量都会设置为默认的8K
#ifdef BACKGROUND_GC
if (!settings.concurrent)
#endif //BACKGROUND_GC
{
//decide on the next allocation quantum
if (alloc_contexts_used >= 1)
{
allocation_quantum = Align (min ((size_t)CLR_SIZE,
(size_t)max (1024, get_new_allocation (0) / (2 * alloc_contexts_used))),
get_alignment_constant(FALSE));
dprintf (3, ("New allocation quantum: %d(0x%Ix)", allocation_quantum, allocation_quantum));
}
}
// 重设Write Watch,默认会用Write barrier所以这里不会被调用
#ifdef NO_WRITE_BARRIER
reset_write_watch(FALSE);
#endif //NO_WRITE_BARRIER
// 打印出错信息
descr_generations (FALSE);
descr_card_table();
// 验证小对象的segment列表(gen0~2的segment),除错用
verify_soh_segment_list();
#ifdef BACKGROUND_GC
add_to_history_per_heap();
if (heap_number == 0)
{
add_to_history();
}
#endif // BACKGROUND_GC
#ifdef GC_STATS
if (GCStatistics::Enabled() && heap_number == 0)
g_GCStatistics.AddGCStats(settings,
dd_gc_elapsed_time(dynamic_data_of(settings.condemned_generation)));
#endif // GC_STATS
#ifdef TIME_GC
fprintf (stdout, "%d,%d,%d,%d,%d,%d\n",
n, mark_time, plan_time, reloc_time, compact_time, sweep_time);
#endif //TIME_GC
#ifdef BACKGROUND_GC
assert (settings.concurrent == (uint32_t)(bgc_thread_id.IsCurrentThread()));
#endif //BACKGROUND_GC
// 检查heap状态,除错用
// 如果是后台gc还需要停止运行引擎,验证完以后再重启
#if defined(VERIFY_HEAP) || (defined (FEATURE_EVENT_TRACE) && defined(BACKGROUND_GC))
if (FALSE
#ifdef VERIFY_HEAP
// Note that right now g_pConfig->GetHeapVerifyLevel always returns the same
// value. If we ever allow randomly adjusting this as the process runs,
// we cannot call it this way as joins need to match - we must have the same
// value for all heaps like we do with bgc_heap_walk_for_etw_p.
|| (g_pConfig->GetHeapVerifyLevel() & EEConfig::HEAPVERIFY_GC)
#endif
#if defined(FEATURE_EVENT_TRACE) && defined(BACKGROUND_GC)
|| (bgc_heap_walk_for_etw_p && settings.concurrent)
#endif
)
{
#ifdef BACKGROUND_GC
Thread* current_thread = GetThread();
BOOL cooperative_mode = TRUE;
if (settings.concurrent)
{
cooperative_mode = enable_preemptive (current_thread);
#ifdef MULTIPLE_HEAPS
bgc_t_join.join(this, gc_join_suspend_ee_verify);
if (bgc_t_join.joined())
{
bgc_threads_sync_event.Reset();
dprintf(2, ("Joining BGC threads to suspend EE for verify heap"));
bgc_t_join.restart();
}
if (heap_number == 0)
{
suspend_EE();
bgc_threads_sync_event.Set();
}
else
{
bgc_threads_sync_event.Wait(INFINITE, FALSE);
dprintf (2, ("bgc_threads_sync_event is signalled"));
}
#else
suspend_EE();
#endif //MULTIPLE_HEAPS
//fix the allocation area so verify_heap can proceed.
fix_allocation_contexts (FALSE);
}
#endif //BACKGROUND_GC
#ifdef BACKGROUND_GC
assert (settings.concurrent == (uint32_t)(bgc_thread_id.IsCurrentThread()));
#ifdef FEATURE_EVENT_TRACE
if (bgc_heap_walk_for_etw_p && settings.concurrent)
{
make_free_lists_for_profiler_for_bgc();
}
#endif // FEATURE_EVENT_TRACE
#endif //BACKGROUND_GC
#ifdef VERIFY_HEAP
if (g_pConfig->GetHeapVerifyLevel() & EEConfig::HEAPVERIFY_GC)
verify_heap (FALSE);
#endif // VERIFY_HEAP
#ifdef BACKGROUND_GC
if (settings.concurrent)
{
repair_allocation_contexts (TRUE);
#ifdef MULTIPLE_HEAPS
bgc_t_join.join(this, gc_join_restart_ee_verify);
if (bgc_t_join.joined())
{
bgc_threads_sync_event.Reset();
dprintf(2, ("Joining BGC threads to restart EE after verify heap"));
bgc_t_join.restart();
}
if (heap_number == 0)
{
restart_EE();
bgc_threads_sync_event.Set();
}
else
{
bgc_threads_sync_event.Wait(INFINITE, FALSE);
dprintf (2, ("bgc_threads_sync_event is signalled"));
}
#else
restart_EE();
#endif //MULTIPLE_HEAPS
disable_preemptive (current_thread, cooperative_mode);
}
#endif //BACKGROUND_GC
}
#endif // defined(VERIFY_HEAP) || (defined(FEATURE_EVENT_TRACE) && defined(BACKGROUND_GC))
// 如果有多个heap(服务器GC),平均各个heap的阈值(dd_gc_new_allocation, dd_new_allocation, dd_desired_allocation)
// 其他服务器GC和工作站GC的共通处理请跳到#else看
#ifdef MULTIPLE_HEAPS
if (!settings.concurrent)
{
gc_t_join.join(this, gc_join_done);
if (gc_t_join.joined ())
{
gc_heap::internal_gc_done = false;
//equalize the new desired size of the generations
int limit = settings.condemned_generation;
if (limit == max_generation)
{
limit = max_generation+1;
}
for (int gen = 0; gen <= limit; gen++)
{
size_t total_desired = 0;
for (int i = 0; i < gc_heap::n_heaps; i++)
{
gc_heap* hp = gc_heap::g_heaps[i];
dynamic_data* dd = hp->dynamic_data_of (gen);
size_t temp_total_desired = total_desired + dd_desired_allocation (dd);
if (temp_total_desired < total_desired)
{
// we overflowed.
total_desired = (size_t)MAX_PTR;
break;
}
total_desired = temp_total_desired;
}
size_t desired_per_heap = Align (total_desired/gc_heap::n_heaps,
get_alignment_constant ((gen != (max_generation+1))));
if (gen == 0)
{
#if 1 //subsumed by the linear allocation model
// to avoid spikes in mem usage due to short terms fluctuations in survivorship,
// apply some smoothing.
static size_t smoothed_desired_per_heap = 0;
size_t smoothing = 3; // exponential smoothing factor
if (smoothing > VolatileLoad(&settings.gc_index))
smoothing = VolatileLoad(&settings.gc_index);
smoothed_desired_per_heap = desired_per_heap / smoothing + ((smoothed_desired_per_heap / smoothing) * (smoothing-1));
dprintf (1, ("sn = %Id n = %Id", smoothed_desired_per_heap, desired_per_heap));
desired_per_heap = Align(smoothed_desired_per_heap, get_alignment_constant (true));
#endif //0
// if desired_per_heap is close to min_gc_size, trim it
// down to min_gc_size to stay in the cache
gc_heap* hp = gc_heap::g_heaps[0];
dynamic_data* dd = hp->dynamic_data_of (gen);
size_t min_gc_size = dd_min_gc_size(dd);
// if min GC size larger than true on die cache, then don't bother
// limiting the desired size
if ((min_gc_size <= GCToOSInterface::GetLargestOnDieCacheSize(TRUE) / GCToOSInterface::GetLogicalCpuCount()) &&
desired_per_heap <= 2*min_gc_size)
{
desired_per_heap = min_gc_size;
}
#ifdef BIT64
desired_per_heap = joined_youngest_desired (desired_per_heap);
dprintf (2, ("final gen0 new_alloc: %Id", desired_per_heap));
#endif // BIT64
gc_data_global.final_youngest_desired = desired_per_heap;
}
#if 1 //subsumed by the linear allocation model
if (gen == (max_generation + 1))
{
// to avoid spikes in mem usage due to short terms fluctuations in survivorship,
// apply some smoothing.
static size_t smoothed_desired_per_heap_loh = 0;
size_t smoothing = 3; // exponential smoothing factor
size_t loh_count = dd_collection_count (dynamic_data_of (max_generation));
if (smoothing > loh_count)
smoothing = loh_count;
smoothed_desired_per_heap_loh = desired_per_heap / smoothing + ((smoothed_desired_per_heap_loh / smoothing) * (smoothing-1));
dprintf( 2, ("smoothed_desired_per_heap_loh = %Id desired_per_heap = %Id", smoothed_desired_per_heap_loh, desired_per_heap));
desired_per_heap = Align(smoothed_desired_per_heap_loh, get_alignment_constant (false));
}
#endif //0
for (int i = 0; i < gc_heap::n_heaps; i++)
{
gc_heap* hp = gc_heap::g_heaps[i];
dynamic_data* dd = hp->dynamic_data_of (gen);
dd_desired_allocation (dd) = desired_per_heap;
dd_gc_new_allocation (dd) = desired_per_heap;
dd_new_allocation (dd) = desired_per_heap;
if (gen == 0)
{
hp->fgn_last_alloc = desired_per_heap;
}
}
}
#ifdef FEATURE_LOH_COMPACTION
BOOL all_heaps_compacted_p = TRUE;
#endif //FEATURE_LOH_COMPACTION
for (int i = 0; i < gc_heap::n_heaps; i++)
{
gc_heap* hp = gc_heap::g_heaps[i];
hp->decommit_ephemeral_segment_pages();
hp->rearrange_large_heap_segments();
#ifdef FEATURE_LOH_COMPACTION
all_heaps_compacted_p &= hp->loh_compacted_p;
#endif //FEATURE_LOH_COMPACTION
}
#ifdef FEATURE_LOH_COMPACTION
check_loh_compact_mode (all_heaps_compacted_p);
#endif //FEATURE_LOH_COMPACTION
fire_pevents();
gc_t_join.restart();
}
alloc_context_count = 0;
heap_select::mark_heap (heap_number);
}
#else
// 以下处理服务器GC和工作站共通,你可以在#else上面找到对应的代码
// 设置统计数据(最年轻代的gc阈值)
gc_data_global.final_youngest_desired =
dd_desired_allocation (dynamic_data_of (0));
// 如果大对象的堆(loh)压缩模式是仅1次(once)且所有heap的loh都压缩过则重置loh的压缩模式
check_loh_compact_mode (loh_compacted_p);
// 释放ephemeral segment中未用到的内存(页)
decommit_ephemeral_segment_pages();
// 触发etw事件,统计用
fire_pevents();
if (!(settings.concurrent))
{
// 删除空的大对象segment
rearrange_large_heap_segments();
// 通知运行引擎GC已完成(GcDone, 目前不会做出实质的处理)并且更新一些统计数据
do_post_gc();
}
#ifdef BACKGROUND_GC
recover_bgc_settings();
#endif //BACKGROUND_GC
#endif//MULTIPLE_HEAPS
}
接下来我们将分别分析GC中的五个阶段(mark_phase, plan_phase, relocate_phase, compact_phase, sweep_phase)的内部处理
标记阶段(mark_phase)
这个阶段的作用是找出收集垃圾的范围(gc_low ~ gc_high)中有哪些对象是存活的,如果存活则标记(m_pMethTab |= 1),
另外还会根据GC Handle查找有哪些对象是固定的(pinned),如果对象固定则标记(m_uSyncBlockValue |= 0x20000000)。
简单解释下GC Handle和Pinned Object,GC Handle用于在托管代码中调用非托管代码时可以决定传递的指针的处理,
一个类型是Pinned的GC Handle可以防止GC在压缩时移动对象,这样非托管代码中保存的指针地址不会失效,详细可以看微软的文档。
在继续看代码之前我们先来了解Card Table的概念:
Card Table
如果你之前已经了解过GC,可能知道有的语言实现GC会有一个根对象,从根对象一直扫描下去可以找到所有存活的对象。
但这样有一个缺陷,如果对象很多,扫描的时间也会相应的变长,为了提高效率,CoreCLR使用了分代GC(包括之前的.Net Framework都是分代GC),
分代GC可以只选择扫描一部分的对象(年轻的对象更有可能被回收)而不是全部对象,那么分代GC的扫描是如何实现的?
在CoreCLR中对象之间的引用(例如B是A的成员或者B在数组A中,可以称作A引用B)一般包含以下情况
- 各个线程栈(stack)和寄存器(register)中的对象引用堆段(heap segment)中的对象
- CoreCLR有办法可以检测到Managed Thread中在栈和寄存器中的对象
- 这些对象是根对象(GC Root)的一种
- GC Handle表中的句柄引用堆段(heap segment)中的对象
- 这些对象也是根对象的一种
- 析构队列中的对象引用堆段(heap segment)中的对象
- 这些对象也是根对象的一种
- 同代对象之间的引用
- 隔代对象之间的引用
请考虑下图的情况,我们这次只想扫描gen 0,栈中的对象A引用了gen 1的对象B,对象B引用了gen 0的对象C,
在扫描的时候因为B不在扫描范围(gc_low ~ gc_high)中,CoreCLR不会去继续跟踪B的引用,
如果这时候gen 0中无其他对象引用对象C,是否会导致对象C被误回收?
为了解决这种情况导致的问题,CoreCLR使用了Card Table,所谓Card Table就是专门记录跨代引用的一个数组
当我们设置B.member = C
的时候,JIT会把赋值替换为JIT_WriteBarrier(&B.member, C)
(或同等的其他函数)JIT_WriteBarrier
函数中会设置*dst = ref
,并且如果ref
在ephemeral heap segment
中(ref可能是gen 0或gen 1的对象)时,
设置dst
在Card Table中所属的字节为0xff
,Card Table中一个字节默认涵盖的范围在32位下是1024字节,在64位下是2048字节。
需要注意的是这里的dst
是B.member
的地址而不是B
的地址,B.member
的地址会是B
的地址加一定的偏移值,
而B
自身的地址不一定会在Card Table中得到标记,我们之后可以根据B.member
的地址得到B
的地址(可以看find_first_object
函数)。
有了Card Table以后,只回收年轻代(非Full GC)时除了扫描根对象以外我们还需要扫描Card Table中标记的范围来防止误回收对象。
JIT_WriteBarrier
函数的代码如下
// This function is a JIT helper, but it must NOT use HCIMPL2 because it
// modifies Thread state that will not be restored if an exception occurs
// inside of memset. A normal EH unwind will not occur.
extern "C" HCIMPL2_RAW(VOID, JIT_WriteBarrier, Object **dst, Object *ref)
{
// Must use static contract here, because if an AV occurs, a normal EH
// unwind will not occur, and destructors will not run.
STATIC_CONTRACT_MODE_COOPERATIVE;
STATIC_CONTRACT_THROWS;
STATIC_CONTRACT_GC_NOTRIGGER;
#ifdef FEATURE_COUNT_GC_WRITE_BARRIERS
IncUncheckedBarrierCount();
#endif
// no HELPER_METHOD_FRAME because we are MODE_COOPERATIVE, GC_NOTRIGGER
*dst = ref;
// If the store above succeeded, "dst" should be in the heap.
assert(GCHeap::GetGCHeap()->IsHeapPointer((void*)dst));
#ifdef WRITE_BARRIER_CHECK
updateGCShadow(dst, ref); // support debugging write barrier
#endif
#ifdef FEATURE_USE_SOFTWARE_WRITE_WATCH_FOR_GC_HEAP
if (SoftwareWriteWatch::IsEnabledForGCHeap())
{
SoftwareWriteWatch::SetDirty(dst, sizeof(*dst));
}
#endif // FEATURE_USE_SOFTWARE_WRITE_WATCH_FOR_GC_HEAP
#ifdef FEATURE_COUNT_GC_WRITE_BARRIERS
if((BYTE*) dst >= g_ephemeral_low && (BYTE*) dst < g_ephemeral_high)
{
UncheckedDestInEphem++;
}
#endif
if((BYTE*) ref >= g_ephemeral_low && (BYTE*) ref < g_ephemeral_high)
{
#ifdef FEATURE_COUNT_GC_WRITE_BARRIERS
UncheckedAfterRefInEphemFilter++;
#endif
BYTE* pCardByte = (BYTE *)VolatileLoadWithoutBarrier(&g_card_table) + card_byte((BYTE *)dst);
if(*pCardByte != 0xFF)
{
#ifdef FEATURE_COUNT_GC_WRITE_BARRIERS
UncheckedAfterAlreadyDirtyFilter++;
#endif
*pCardByte = 0xFF;
}
}
}
HCIMPLEND_RAW
card_byte
macro的代码如下
#if defined(_WIN64)
// Card byte shift is different on 64bit.
#define card_byte_shift 11
#else
#define card_byte_shift 10
#endif
#define card_byte(addr) (((size_t)(addr)) >> card_byte_shift)
#define card_bit(addr) (1 << ((((size_t)(addr)) >> (card_byte_shift - 3)) & 7))
标记阶段(mark_phase)的代码
gc_heap::mark_phase
函数的代码如下:
void gc_heap::mark_phase (int condemned_gen_number, BOOL mark_only_p)
{
assert (settings.concurrent == FALSE);
// 扫描上下文
ScanContext sc;
sc.thread_number = heap_number;
sc.promotion = TRUE;
sc.concurrent = FALSE;
dprintf(2,("---- Mark Phase condemning %d ----", condemned_gen_number));
// 是否Full GC
BOOL full_p = (condemned_gen_number == max_generation);
// 统计标记阶段的开始时间
#ifdef TIME_GC
unsigned start;
unsigned finish;
start = GetCycleCount32();
#endif //TIME_GC
// 重置动态数据(dd)
int gen_to_init = condemned_gen_number;
if (condemned_gen_number == max_generation)
{
gen_to_init = max_generation + 1;
}
for (int gen_idx = 0; gen_idx <= gen_to_init; gen_idx++)
{
dynamic_data* dd = dynamic_data_of (gen_idx);
dd_begin_data_size (dd) = generation_size (gen_idx) -
dd_fragmentation (dd) -
Align (size (generation_allocation_start (generation_of (gen_idx))));
dprintf (2, ("begin data size for gen%d is %Id", gen_idx, dd_begin_data_size (dd)));
dd_survived_size (dd) = 0;
dd_pinned_survived_size (dd) = 0;
dd_artificial_pinned_survived_size (dd) = 0;
dd_added_pinned_size (dd) = 0;
#ifdef SHORT_PLUGS
dd_padding_size (dd) = 0;
#endif //SHORT_PLUGS
#if defined (RESPECT_LARGE_ALIGNMENT) || defined (FEATURE_STRUCTALIGN)
dd_num_npinned_plugs (dd) = 0;
#endif //RESPECT_LARGE_ALIGNMENT || FEATURE_STRUCTALIGN
}
#ifdef FFIND_OBJECT
if (gen0_must_clear_bricks > 0)
gen0_must_clear_bricks--;
#endif //FFIND_OBJECT
size_t last_promoted_bytes = 0;
// 重设mark stack
// mark_stack_array在GC各个阶段有不同的用途,在mark phase中的用途是用来标记对象时代替递归防止爆栈
promoted_bytes (heap_number) = 0;
reset_mark_stack();
#ifdef SNOOP_STATS
memset (&snoop_stat, 0, sizeof(snoop_stat));
snoop_stat.heap_index = heap_number;
#endif //SNOOP_STATS
// 启用scable marking时
// 服务器GC上会启用,工作站GC上不会启用
// scable marking这篇中不会分析
#ifdef MH_SC_MARK
if (full_p)
{
//initialize the mark stack
for (int i = 0; i < max_snoop_level; i++)
{
((uint8_t**)(mark_stack_array))[i] = 0;
}
mark_stack_busy() = 1;
}
#endif //MH_SC_MARK
static uint32_t num_sizedrefs = 0;
// scable marking的处理
#ifdef MH_SC_MARK
static BOOL do_mark_steal_p = FALSE;
#endif //MH_SC_MARK
#ifdef MULTIPLE_HEAPS
gc_t_join.join(this, gc_join_begin_mark_phase);
if (gc_t_join.joined())
{
#endif //MULTIPLE_HEAPS
num_sizedrefs = SystemDomain::System()->GetTotalNumSizedRefHandles();
#ifdef MULTIPLE_HEAPS
// scable marking的处理
#ifdef MH_SC_MARK
if (full_p)
{
size_t total_heap_size = get_total_heap_size();
if (total_heap_size > (100 * 1024 * 1024))
{
do_mark_steal_p = TRUE;
}
else
{
do_mark_steal_p = FALSE;
}
}
else
{
do_mark_steal_p = FALSE;
}
#endif //MH_SC_MARK
gc_t_join.restart();
}
#endif //MULTIPLE_HEAPS
{
// 初始化mark list, full gc时不会使用
#ifdef MARK_LIST
//set up the mark lists from g_mark_list
assert (g_mark_list);
#ifdef MULTIPLE_HEAPS
mark_list = &g_mark_list [heap_number*mark_list_size];
#else
mark_list = g_mark_list;
#endif //MULTIPLE_HEAPS
//dont use the mark list for full gc
//because multiple segments are more complex to handle and the list
//is likely to overflow
if (condemned_gen_number != max_generation)
mark_list_end = &mark_list [mark_list_size-1];
else
mark_list_end = &mark_list [0];
mark_list_index = &mark_list [0];
#endif //MARK_LIST
shigh = (uint8_t*) 0;
slow = MAX_PTR;
//%type% category = quote (mark);
// 如果当前是Full GC并且有类型是SizedRef的GC Handle时把它们作为根对象扫描
// 参考https://github.com/dotnet/coreclr/blob/release/1.1.0/src/gc/objecthandle.h#L177
// SizedRef是一个非公开类型的GC Handle(其他还有RefCounted),目前还看不到有代码使用
if ((condemned_gen_number == max_generation) && (num_sizedrefs > 0))
{
GCScan::GcScanSizedRefs(GCHeap::Promote, condemned_gen_number, max_generation, &sc);
fire_mark_event (heap_number, ETW::GC_ROOT_SIZEDREF, (promoted_bytes (heap_number) - last_promoted_bytes));
last_promoted_bytes = promoted_bytes (heap_number);
#ifdef MULTIPLE_HEAPS
gc_t_join.join(this, gc_join_scan_sizedref_done);
if (gc_t_join.joined())
{
dprintf(3, ("Done with marking all sized refs. Starting all gc thread for marking other strong roots"));
gc_t_join.restart();
}
#endif //MULTIPLE_HEAPS
}
dprintf(3,("Marking Roots"));
// 扫描根对象(各个线程中栈和寄存器中的对象)
// 这里的GcScanRoots是一个高阶函数,会扫描根对象和根对象引用的对象,并对它们调用传入的`GCHeap::Promote`函数
// 在下面的relocate phase还会传入`GCHeap::Relocate`给`GcScanRoots`
// BOTR中有一份专门的文档介绍了如何实现栈扫描,地址是
// https://github.com/dotnet/coreclr/blob/master/Documentation/botr/stackwalking.md
// 这个函数的内部处理要贴代码的话会非常的长,这里我只贴调用流程
// GcScanRoots的处理
// 枚举线程
// 调用 ScanStackRoots(pThread, fn, sc);
// 调用 pThread->StackWalkFrames
// 调用 StackWalkFramesEx
// 使用 StackFrameIterator 枚举栈中的所有帧
// 调用 StackFrameIterator::Next
// 调用 StackFrameIterator::Filter
// 调用 MakeStackwalkerCallback 处理单帧
// 调用 GcStackCrawlCallBack
// 如果 IsFrameless 则调用 EECodeManager::EnumGcRefs
// 调用 GcInfoDecoder::EnumerateLiveSlots
// 调用 GcInfoDecoder::ReportSlotToGC
// 如果是寄存器中的对象则调用 GcInfoDecoder::ReportRegisterToGC
// 如果是栈上的对象则调用 GcInfoDecoder::ReportStackSlotToGC
// 调用 GcEnumObject
// 调用 GCHeap::Promote, 接下来和下面的一样
// 如果 !IsFrameless 则调用 FrameBase::GcScanRoots
// 继承函数的处理 GCFrame::GcScanRoots
// 调用 GCHeap::Promote
// 调用 gc_heap::mark_object_simple
// 调用 gc_mark1, 第一次标记时会返回true
// 调用 CObjectHeader::IsMarked !!(((size_t)RawGetMethodTable()) & GC_MARKED)
// 调用 CObjectHeader::SetMarked RawSetMethodTable((MethodTable *) (((size_t) RawGetMethodTable()) | GC_MARKED));
// 如果对象未被标记过,调用 go_through_object_cl (macro) 枚举对象的所有成员
// 对成员对象调用mark_object_simple1,和mark_object_simple的区别是,mark_object_simple1使用mark_stack_array来循环标记对象
// 使用mark_stack_array代替递归可以防止爆栈
// 注意mark_stack_array也有大小限制,如果超过了(overflow)不会扩展(grow),而是记录并交给下面的GcDhInitialScan处理
GCScan::GcScanRoots(GCHeap::Promote,
condemned_gen_number, max_generation,
&sc);
// 调用通知事件通知有多少字节在这一次被标记
fire_mark_event (heap_number, ETW::GC_ROOT_STACK, (promoted_bytes (heap_number) - last_promoted_bytes));
last_promoted_bytes = promoted_bytes (heap_number);
#ifdef BACKGROUND_GC
if (recursive_gc_sync::background_running_p())
{
scan_background_roots (GCHeap::Promote, heap_number, &sc);
}
#endif //BACKGROUND_GC
// 扫描当前关键析构(Critical Finalizer)队列中对象的引用
// 非关键析构队列中的对象会在下面的ScanForFinalization中扫描
// 关于析构队列可以参考这些URL
// https://github.com/dotnet/coreclr/blob/master/Documentation/botr/threading.md
// http://stackoverflow.com/questions/1268525/what-are-the-finalizer-queue-and-controlthreadmethodentry
// http://stackoverflow.com/questions/9030126/why-classes-with-finalizers-need-more-than-one-garbage-collection-cycle
// https://msdn.microsoft.com/en-us/library/system.runtime.constrainedexecution.criticalfinalizerobject(v=vs.110).aspx
// https://msdn.microsoft.com/en-us/library/system.runtime.constrainedexecution(v=vs.110).aspx
#ifdef FEATURE_PREMORTEM_FINALIZATION
dprintf(3, ("Marking finalization data"));
finalize_queue->GcScanRoots(GCHeap::Promote, heap_number, 0);
#endif // FEATURE_PREMORTEM_FINALIZATION
// 调用通知事件通知有多少字节在这一次被标记
fire_mark_event (heap_number, ETW::GC_ROOT_FQ, (promoted_bytes (heap_number) - last_promoted_bytes));
last_promoted_bytes = promoted_bytes (heap_number);
// MTHTS
{
// 扫描GC Handle引用的对象
// 如果GC Handle的类型是Pinned同时会设置对象为pinned
// 设置对象为pinned的流程如下
// GCScan::GcScanHandles
// Ref_TracePinningRoots
// HndScanHandlersForGC
// TableScanHandles
// SegmentScanByTypeMap
// BlockScanBlocksEphemeral
// BlockScanBlocksEphemeralWorker
// ScanConsecutiveHandlesWithoutUserData
// PinObject
// GCHeap::Promote(pRef, (ScanContext *)lpl, GC_CALL_PINNED)
// 判断flags包含GC_CALL_PINNED时调用 gc_heap::pin_object
// 如果对象在扫描范围(gc_low ~ gc_high)时调用set_pinned(o)
// GetHeader()->SetGCBit()
// m_uSyncBlockValue |= BIT_SBLK_GC_RESERVE
// 这里会标记包括来源于静态字段的引用
dprintf(3,("Marking handle table"));
GCScan::GcScanHandles(GCHeap::Promote,
condemned_gen_number, max_generation,
&sc);
// 调用通知事件通知有多少字节在这一次被标记
fire_mark_event (heap_number, ETW::GC_ROOT_HANDLES, (promoted_bytes (heap_number) - last_promoted_bytes));
last_promoted_bytes = promoted_bytes (heap_number);
}
// 扫描根对象完成了,如果不是Full GC接下来还需要扫描Card Table
// 记录扫描Card Table之前标记的字节数量(存活的字节数量)
#ifdef TRACE_GC
size_t promoted_before_cards = promoted_bytes (heap_number);
#endif //TRACE_GC
// Full GC不需要扫Card Table
dprintf (3, ("before cards: %Id", promoted_before_cards));
if (!full_p)
{
#ifdef CARD_BUNDLE
#ifdef MULTIPLE_HEAPS
if (gc_t_join.r_join(this, gc_r_join_update_card_bundle))
{
#endif //MULTIPLE_HEAPS
// 从Write Watch更新Card Table的索引(Card Bundles)
// 当内存空间过大时,扫描Card Table的效率会变低,使用Card Bundle可以标记Card Table中的哪些区域需要扫描
// 在作者环境的下Card Bundle不启用
update_card_table_bundle ();
#ifdef MULTIPLE_HEAPS
gc_t_join.r_restart();
}
#endif //MULTIPLE_HEAPS
#endif //CARD_BUNDLE
// 标记对象的函数,需要分析时使用特殊的函数
card_fn mark_object_fn = &gc_heap::mark_object_simple;
#ifdef HEAP_ANALYZE
heap_analyze_success = TRUE;
if (heap_analyze_enabled)
{
internal_root_array_index = 0;
current_obj = 0;
current_obj_size = 0;
mark_object_fn = &gc_heap::ha_mark_object_simple;
}
#endif //HEAP_ANALYZE
// 遍历Card Table标记小对象
// 像之前所说的Card Table中对应的区域包含的是成员的地址,不一定包含来源对象的开始地址,find_first_object函数可以支持找到来源对象的开始地址
// 这个函数除了调用mark_object_simple标记找到的对象以外,还会更新`generation_skip_ratio`这个成员,算法如下
// n_gen 通过卡片标记的对象数量, gc_low ~ gc_high
// n_eph 通过卡片扫描的对象数量, 上一代的开始地址 ~ gc_high (cg_pointers_found的累加)
// 表示扫描的对象中有多少%的对象被标记了
// generation_skip_ratio = (n_eph > 400) ? (n_gen * 1.0 / n_eph * 100) : 100
// `generation_skip_ratio`会影响到对象是否升代,请搜索上面关于`generation_skip_ratio`的注释
dprintf(3,("Marking cross generation pointers"));
mark_through_cards_for_segments (mark_object_fn, FALSE);
// 遍历Card Table标记大对象
// 处理和前面一样,只是扫描的范围是大对象的segment
// 这里也会算出generation_skip_ratio,如果算出的generation_skip_ratio比原来的generation_skip_ratio要小则使用算出的值
dprintf(3,("Marking cross generation pointers for large objects"));
mark_through_cards_for_large_objects (mark_object_fn, FALSE);
// 调用通知事件通知有多少字节在这一次被标记
dprintf (3, ("marked by cards: %Id",
(promoted_bytes (heap_number) - promoted_before_cards)));
fire_mark_event (heap_number, ETW::GC_ROOT_OLDER, (promoted_bytes (heap_number) - last_promoted_bytes));
last_promoted_bytes = promoted_bytes (heap_number);
}
}
// scable marking的处理
#ifdef MH_SC_MARK
if (do_mark_steal_p)
{
mark_steal();
}
#endif //MH_SC_MARK
// 处理HNDTYPE_DEPENDENT类型的GC Handle
// 这个GC Handle的意义是保存两个对象primary和secondary,告诉primary引用了secondary
// 如果primary已标记则secondary也会被标记
// 这里还会处理之前发生的mark_stack_array溢出(循环标记对象时子对象过多导致mark_stack_array容不下)
// 这次不一定会完成,下面还会等待线程同步后(服务器GC下)再扫一遍
// Dependent handles need to be scanned with a special algorithm (see the header comment on
// scan_dependent_handles for more detail). We perform an initial scan without synchronizing with other
// worker threads or processing any mark stack overflow. This is not guaranteed to complete the operation
// but in a common case (where there are no dependent handles that are due to be collected) it allows us
// to optimize away further scans. The call to scan_dependent_handles is what will cycle through more
// iterations if required and will also perform processing of any mark stack overflow once the dependent
// handle table has been fully promoted.
GCScan::GcDhInitialScan(GCHeap::Promote, condemned_gen_number, max_generation, &sc);
scan_dependent_handles(condemned_gen_number, &sc, true);
// 通知标记阶段完成扫描根对象(和Card Table)
#ifdef MULTIPLE_HEAPS
dprintf(3, ("Joining for short weak handle scan"));
gc_t_join.join(this, gc_join_null_dead_short_weak);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
#ifdef HEAP_ANALYZE
heap_analyze_enabled = FALSE;
DACNotifyGcMarkEnd(condemned_gen_number);
#endif // HEAP_ANALYZE
GCToEEInterface::AfterGcScanRoots (condemned_gen_number, max_generation, &sc);
#ifdef MULTIPLE_HEAPS
if (!full_p)
{
// we used r_join and need to reinitialize states for it here.
gc_t_join.r_init();
}
//start all threads on the roots.
dprintf(3, ("Starting all gc thread for short weak handle scan"));
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
// 处理HNDTYPE_WEAK_SHORT类型的GC Handle
// 设置未被标记的对象的弱引用(Weak Reference)为null
// 这里传的GCHeap::Promote参数不会被用到
// 下面扫描完非关键析构队列还会扫描HNDTYPE_WEAK_LONG类型的GC Handle,请看下面的注释
// null out the target of short weakref that were not promoted.
GCScan::GcShortWeakPtrScan(GCHeap::Promote, condemned_gen_number, max_generation,&sc);
// MTHTS: keep by single thread
#ifdef MULTIPLE_HEAPS
dprintf(3, ("Joining for finalization"));
gc_t_join.join(this, gc_join_scan_finalization);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
#ifdef MULTIPLE_HEAPS
//start all threads on the roots.
dprintf(3, ("Starting all gc thread for Finalization"));
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
//Handle finalization.
size_t promoted_bytes_live = promoted_bytes (heap_number);
// 扫描当前非关键析构队列中对象的引用
#ifdef FEATURE_PREMORTEM_FINALIZATION
dprintf (3, ("Finalize marking"));
finalize_queue->ScanForFinalization (GCHeap::Promote, condemned_gen_number, mark_only_p, __this);
#ifdef GC_PROFILING
if (CORProfilerTrackGC())
{
finalize_queue->WalkFReachableObjects (__this);
}
#endif //GC_PROFILING
#endif // FEATURE_PREMORTEM_FINALIZATION
// 再扫一遍HNDTYPE_DEPENDENT类型的GC Handle
// Scan dependent handles again to promote any secondaries associated with primaries that were promoted
// for finalization. As before scan_dependent_handles will also process any mark stack overflow.
scan_dependent_handles(condemned_gen_number, &sc, false);
#ifdef MULTIPLE_HEAPS
dprintf(3, ("Joining for weak pointer deletion"));
gc_t_join.join(this, gc_join_null_dead_long_weak);
if (gc_t_join.joined())
{
//start all threads on the roots.
dprintf(3, ("Starting all gc thread for weak pointer deletion"));
gc_t_join.restart();
}
#endif //MULTIPLE_HEAPS
// 处理HNDTYPE_WEAK_LONG或HNDTYPE_REFCOUNTED类型的GC Handle
// 设置未被标记的对象的弱引用(Weak Reference)为null
// 这里传的GCHeap::Promote参数不会被用到
// HNDTYPE_WEAK_LONG和HNDTYPE_WEAK_SHORT的区别是,HNDTYPE_WEAK_SHORT会忽略从非关键析构队列的引用而HNDTYPE_WEAK_LONG不会
// null out the target of long weakref that were not promoted.
GCScan::GcWeakPtrScan (GCHeap::Promote, condemned_gen_number, max_generation, &sc);
// 如果使用了mark list并且并行化(服务器GC下)这里会进行排序(如果定义了PARALLEL_MARK_LIST_SORT)
// MTHTS: keep by single thread
#ifdef MULTIPLE_HEAPS
#ifdef MARK_LIST
#ifdef PARALLEL_MARK_LIST_SORT
// unsigned long start = GetCycleCount32();
sort_mark_list();
// printf("sort_mark_list took %u cycles\n", GetCycleCount32() - start);
#endif //PARALLEL_MARK_LIST_SORT
#endif //MARK_LIST
dprintf (3, ("Joining for sync block cache entry scanning"));
gc_t_join.join(this, gc_join_null_dead_syncblk);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
// 删除不再使用的同步索引块,并且设置对应对象的索引值为0
// scan for deleted entries in the syncblk cache
GCScan::GcWeakPtrScanBySingleThread (condemned_gen_number, max_generation, &sc);
#ifdef FEATURE_APPDOMAIN_RESOURCE_MONITORING
if (g_fEnableARM)
{
size_t promoted_all_heaps = 0;
#ifdef MULTIPLE_HEAPS
for (int i = 0; i < n_heaps; i++)
{
promoted_all_heaps += promoted_bytes (i);
}
#else
promoted_all_heaps = promoted_bytes (heap_number);
#endif //MULTIPLE_HEAPS
// 记录这次标记(存活)的字节数
SystemDomain::RecordTotalSurvivedBytes (promoted_all_heaps);
}
#endif //FEATURE_APPDOMAIN_RESOURCE_MONITORING
#ifdef MULTIPLE_HEAPS
// 以下是服务器GC下的处理
// 如果使用了mark list并且并行化(服务器GC下)这里会进行压缩并排序(如果不定义PARALLEL_MARK_LIST_SORT)
#ifdef MARK_LIST
#ifndef PARALLEL_MARK_LIST_SORT
//compact g_mark_list and sort it.
combine_mark_lists();
#endif //PARALLEL_MARK_LIST_SORT
#endif //MARK_LIST
// 如果之前未决定要升代,这里再给一次机会判断是否要升代
// 算法分析
// dd_min_gc_size是每分配多少byte的对象就触发gc的阈值
// 第0代1倍, 第1代2倍, 再乘以0.1合计
// dd = 上一代的动态数据
// older_gen_size = 上次gc后的对象大小合计 + 从上次gc以来一共新分配了多少byte
// 如果m > 上一代的大小, 或者本次标记的对象大小 > m则启用升代
// 意义是如果上一代过小,或者这次标记(存活)的对象过多则需要升代
//decide on promotion
if (!settings.promotion)
{
size_t m = 0;
for (int n = 0; n <= condemned_gen_number;n++)
{
m += (size_t)(dd_min_gc_size (dynamic_data_of (n))*(n+1)*0.1);
}
for (int i = 0; i < n_heaps; i++)
{
dynamic_data* dd = g_heaps[i]->dynamic_data_of (min (condemned_gen_number +1,
max_generation));
size_t older_gen_size = (dd_current_size (dd) +
(dd_desired_allocation (dd) -
dd_new_allocation (dd)));
if ((m > (older_gen_size)) ||
(promoted_bytes (i) > m))
{
settings.promotion = TRUE;
}
}
}
// scable marking的处理
#ifdef SNOOP_STATS
if (do_mark_steal_p)
{
size_t objects_checked_count = 0;
size_t zero_ref_count = 0;
size_t objects_marked_count = 0;
size_t check_level_count = 0;
size_t busy_count = 0;
size_t interlocked_count = 0;
size_t partial_mark_parent_count = 0;
size_t stolen_or_pm_count = 0;
size_t stolen_entry_count = 0;
size_t pm_not_ready_count = 0;
size_t normal_count = 0;
size_t stack_bottom_clear_count = 0;
for (int i = 0; i < n_heaps; i++)
{
gc_heap* hp = g_heaps[i];
hp->print_snoop_stat();
objects_checked_count += hp->snoop_stat.objects_checked_count;
zero_ref_count += hp->snoop_stat.zero_ref_count;
objects_marked_count += hp->snoop_stat.objects_marked_count;
check_level_count += hp->snoop_stat.check_level_count;
busy_count += hp->snoop_stat.busy_count;
interlocked_count += hp->snoop_stat.interlocked_count;
partial_mark_parent_count += hp->snoop_stat.partial_mark_parent_count;
stolen_or_pm_count += hp->snoop_stat.stolen_or_pm_count;
stolen_entry_count += hp->snoop_stat.stolen_entry_count;
pm_not_ready_count += hp->snoop_stat.pm_not_ready_count;
normal_count += hp->snoop_stat.normal_count;
stack_bottom_clear_count += hp->snoop_stat.stack_bottom_clear_count;
}
fflush (stdout);
printf ("-------total stats-------\n");
printf ("%8s | %8s | %8s | %8s | %8s | %8s | %8s | %8s | %8s | %8s | %8s | %8s\n",
"checked", "zero", "marked", "level", "busy", "xchg", "pmparent", "s_pm", "stolen", "nready", "normal", "clear");
printf ("%8d | %8d | %8d | %8d | %8d | %8d | %8d | %8d | %8d | %8d | %8d | %8d\n",
objects_checked_count,
zero_ref_count,
objects_marked_count,
check_level_count,
busy_count,
interlocked_count,
partial_mark_parent_count,
stolen_or_pm_count,
stolen_entry_count,
pm_not_ready_count,
normal_count,
stack_bottom_clear_count);
}
#endif //SNOOP_STATS
//start all threads.
dprintf(3, ("Starting all threads for end of mark phase"));
gc_t_join.restart();
#else //MULTIPLE_HEAPS
// 以下是工作站GC下的处理
// 如果之前未决定要升代,这里再给一次机会判断是否要升代
// 算法和前面一样,但是不是乘以0.1而是乘以0.06
//decide on promotion
if (!settings.promotion)
{
size_t m = 0;
for (int n = 0; n <= condemned_gen_number;n++)
{
m += (size_t)(dd_min_gc_size (dynamic_data_of (n))*(n+1)*0.06);
}
dynamic_data* dd = dynamic_data_of (min (condemned_gen_number +1,
max_generation));
size_t older_gen_size = (dd_current_size (dd) +
(dd_desired_allocation (dd) -
dd_new_allocation (dd)));
dprintf (2, ("promotion threshold: %Id, promoted bytes: %Id size n+1: %Id",
m, promoted_bytes (heap_number), older_gen_size));
if ((m > older_gen_size) ||
(promoted_bytes (heap_number) > m))
{
settings.promotion = TRUE;
}
}
#endif //MULTIPLE_HEAPS
}
// 如果使用了mark list并且并行化(服务器GC下)这里会进行归并(如果定义了PARALLEL_MARK_LIST_SORT)
#ifdef MULTIPLE_HEAPS
#ifdef MARK_LIST
#ifdef PARALLEL_MARK_LIST_SORT
// start = GetCycleCount32();
merge_mark_lists();
// printf("merge_mark_lists took %u cycles\n", GetCycleCount32() - start);
#endif //PARALLEL_MARK_LIST_SORT
#endif //MARK_LIST
#endif //MULTIPLE_HEAPS
// 统计标记的对象大小
#ifdef BACKGROUND_GC
total_promoted_bytes = promoted_bytes (heap_number);
#endif //BACKGROUND_GC
promoted_bytes (heap_number) -= promoted_bytes_live;
// 统计标记阶段的结束时间
#ifdef TIME_GC
finish = GetCycleCount32();
mark_time = finish - start;
#endif //TIME_GC
dprintf(2,("---- End of mark phase ----"));
}
接下来我们看下GCHeap::Promote
函数,在plan_phase
中扫描到的对象都会调用这个函数进行标记,
这个函数名称虽然叫Promote
但是里面只负责对对象进行标记,被标记的对象不一定会升代
void GCHeap::Promote(Object** ppObject, ScanContext* sc, uint32_t flags)
{
THREAD_NUMBER_FROM_CONTEXT;
#ifndef MULTIPLE_HEAPS
const int thread = 0;
#endif //!MULTIPLE_HEAPS
uint8_t* o = (uint8_t*)*ppObject;
if (o == 0)
return;
#ifdef DEBUG_DestroyedHandleValue
// we can race with destroy handle during concurrent scan
if (o == (uint8_t*)DEBUG_DestroyedHandleValue)
return;
#endif //DEBUG_DestroyedHandleValue
HEAP_FROM_THREAD;
gc_heap* hp = gc_heap::heap_of (o);
dprintf (3, ("Promote %Ix", (size_t)o));
// 如果传入的o不一定是对象的开始地址,则需要重新找到o属于的对象
#ifdef INTERIOR_POINTERS
if (flags & GC_CALL_INTERIOR)
{
if ((o < hp->gc_low) || (o >= hp->gc_high))
{
return;
}
if ( (o = hp->find_object (o, hp->gc_low)) == 0)
{
return;
}
}
#endif //INTERIOR_POINTERS
// 启用conservative GC时有可能会对自由对象调用这个函数,这里需要额外判断
#ifdef FEATURE_CONSERVATIVE_GC
// For conservative GC, a value on stack may point to middle of a free object.
// In this case, we don't need to promote the pointer.
if (g_pConfig->GetGCConservative()
&& ((CObjectHeader*)o)->IsFree())
{
return;
}
#endif
// 验证对象是否可以标记,除错用
#ifdef _DEBUG
((CObjectHeader*)o)->ValidatePromote(sc, flags);
#else
UNREFERENCED_PARAMETER(sc);
#endif //_DEBUG
// 如果需要标记对象固定(pinned)则调用`pin_object`
// 请看上面对`PinObject`函数的描述
// `pin_object`函数会设置对象的同步索引块 |= 0x20000000
if (flags & GC_CALL_PINNED)
hp->pin_object (o, (uint8_t**) ppObject, hp->gc_low, hp->gc_high);
// 如果有特殊的设置则20次固定一次对象
#ifdef STRESS_PINNING
if ((++n_promote % 20) == 1)
hp->pin_object (o, (uint8_t**) ppObject, hp->gc_low, hp->gc_high);
#endif //STRESS_PINNING
#ifdef FEATURE_APPDOMAIN_RESOURCE_MONITORING
size_t promoted_size_begin = hp->promoted_bytes (thread);
#endif //FEATURE_APPDOMAIN_RESOURCE_MONITORING
// 如果对象在gc范围中则调用`mark_object_simple`
// 如果对象不在gc范围则会跳过,这也是前面提到的需要Card Table的原因
if ((o >= hp->gc_low) && (o < hp->gc_high))
{
hpt->mark_object_simple (&o THREAD_NUMBER_ARG);
}
// 记录标记的大小
#ifdef FEATURE_APPDOMAIN_RESOURCE_MONITORING
size_t promoted_size_end = hp->promoted_bytes (thread);
if (g_fEnableARM)
{
if (sc->pCurrentDomain)
{
sc->pCurrentDomain->RecordSurvivedBytes ((promoted_size_end - promoted_size_begin), thread);
}
}
#endif //FEATURE_APPDOMAIN_RESOURCE_MONITORING
STRESS_LOG_ROOT_PROMOTE(ppObject, o, o ? header(o)->GetMethodTable() : NULL);
}
再看下mark_object_simple
函数
//this method assumes that *po is in the [low. high[ range
void
gc_heap::mark_object_simple (uint8_t** po THREAD_NUMBER_DCL)
{
uint8_t* o = *po;
#ifdef MULTIPLE_HEAPS
#else //MULTIPLE_HEAPS
const int thread = 0;
#endif //MULTIPLE_HEAPS
{
#ifdef SNOOP_STATS
snoop_stat.objects_checked_count++;
#endif //SNOOP_STATS
// gc_mark1会设置对象中指向Method Table的指针 |= 1
// 如果对象是第一次标记会返回true
if (gc_mark1 (o))
{
// 更新gc_heap的成员slow和shigh(已标记对象的最小和最大地址)
// 如果使用了mark list则把对象加到mark list中
m_boundary (o);
// 记录已标记的对象大小
size_t s = size (o);
promoted_bytes (thread) += s;
{
// 枚举对象o的所有成员,包括o自己
go_through_object_cl (method_table(o), o, s, poo,
{
uint8_t* oo = *poo;
// 如果成员在gc扫描范围中则标记该成员
if (gc_mark (oo, gc_low, gc_high))
{
// 如果使用了mark list则把对象加到mark list中
m_boundary (oo);
// 记录已标记的对象大小
size_t obj_size = size (oo);
promoted_bytes (thread) += obj_size;
// 如果成员下还包含其他可以收集的成员,需要进一步标记
// 因为引用的层数可能很多导致爆栈,mark_object_simple1会使用mark_stack_array循环标记对象而不是用递归
if (contain_pointers_or_collectible (oo))
mark_object_simple1 (oo, oo THREAD_NUMBER_ARG);
}
}
);
}
}
}
}
经过标记阶段以后,在堆中存活的对象都被设置了marked标记,如果对象是固定的还会被设置pinned标记
接下来是计划阶段plan_phase
:
计划阶段(plan_phase)
在这个阶段首先会模拟压缩和构建Brick Table,在模拟完成后判断是否应该进行实际的压缩,
如果进行实际的压缩则进入重定位阶段(relocate_phase)和压缩阶段(compact_phase),否则进入清扫阶段(sweep_phase),
在继续看代码之前我们需要先了解计划阶段如何模拟压缩和什么是Brick Table。
计划阶段如何模拟压缩
计划阶段首先会根据相邻的已标记的对象创建plug,用于加快处理速度和减少需要的内存空间,我们假定一段内存中的对象如下图
计划阶段会为这一段对象创建2个unpinned plug
和一个pinned plug
:
第一个plug是unpinned plug
,包含了对象B, C,不固定地址
第二个plug是pinned plug
,包含了对象E, F, G,固定地址
第三个plug是unpinned plug
,包含了对象H,不固定地址
各个plug的信息保存在开始地址之前的一段内存中,结构如下
struct plug_and_gap
{
// 在这个plug之前有多少空间是未被标记(可回收)的
ptrdiff_t gap;
// 压缩这个plug中的对象时需要移动的偏移值,一般是负数
ptrdiff_t reloc;
union
{
// 左边节点和右边节点
pair m_pair;
int lr; //for clearing the entire pair in one instruction
};
// 填充对象(防止覆盖同步索引块)
plug m_plug;
};
眼尖的会发现上面的图有两个问题
- 对象G不是pinned但是也被归到pinned plug里了
- 这是因为pinned plug会把下一个对象也拉进来防止pinned object的末尾被覆盖,具体请看下面的代码
- 第三个plug把对象G的结尾给覆盖(破坏)了
- 对于这种情况原来的内容会备份到
saved_post_plug
中,具体请看下面的代码
- 对于这种情况原来的内容会备份到
多个plug会构建成一棵树,例如上面的三个plug会构建成这样的树:
第一个plug: { gap: 24, reloc: 未定义, m_pair: { left: 0, right: 0 } }
第二个plug: { gap: 132, reloc: 0, m_pair: { left: -356, right: 206 } }
第三个plug: { gap: 24, reloc: 未定义, m_pair: { left: 0, right 0 } }
第二个plug的left
和right
保存的是离子节点plug的偏移值,
第三个plug的gap
比较特殊,可能你们会觉得应该是0但是会被设置为24(sizeof(gap_reloc_pair)),这个大小在实际复制第二个plug(compact_plug)的时候会加回来。
当计划阶段找到一个plug的开始时,
如果这个plug是pinned plug
则加到mark_stack_array
队列中。
当计划阶段找到一个plug的结尾时,
如果这个plug是pinned plug
则设置这个plug的大小并移动队列顶部(mark_stack_tos),
否则使用使用函数allocate_in_condemned_generations
计算把这个plug移动到前面(压缩)时的偏移值,
allocate_in_condemned_generations
的原理请看下图
函数allocate_in_condemned_generations
不会实际的移动内存和修改指针,它只设置了plug的reloc
成员,
这里需要注意的是如果有pinned plug
并且前面的空间不够,会从pinned plug
的结尾开始计算,
同时出队列以后的plug B
在mark_stack_array
中的len
会被设置为前面一段空间的大小,也就是32+39=71
。
现在让我们思考一个问题,如果我们遇到一个对象x,如何求出对象x应该移动到的位置?
我们需要根据对象x找到它所在的plug,然后根据这个plug的reloc
移动,查找plug使用的索引就是接下来要说的Brick Table
。
Brick Table
brick_table
是一个类型为short*
的数组,用于快速索引plug,如图
根据所属的brick不同,会构建多个plug树(避免plug树过大),然后设置根节点的信息到brick_table
中,
brick中的值如果是正值则表示brick对应的开始地址离根节点plug的偏移值+1,
如果是负值则表示plug树横跨了多个brick,需要到前面的brick查找。
brick_table
相关的代码如下,我们可以看到在64位下brick的大小是4096,在32位下brick的大小是2048
#if defined (_TARGET_AMD64_)
#define brick_size ((size_t)4096)
#else
#define brick_size ((size_t)2048)
#endif //_TARGET_AMD64_
inline
size_t gc_heap::brick_of (uint8_t* add)
{
return (size_t)(add - lowest_address) / brick_size;
}
inline
uint8_t* gc_heap::brick_address (size_t brick)
{
return lowest_address + (brick_size * brick);
}
void gc_heap::clear_brick_table (uint8_t* from, uint8_t* end)
{
for (size_t i = brick_of (from);i < brick_of (end); i++)
brick_table[i] = 0;
}
//codes for the brick entries:
//entry == 0 -> not assigned
//entry >0 offset is entry-1
//entry <0 jump back entry bricks
inline
void gc_heap::set_brick (size_t index, ptrdiff_t val)
{
if (val < -32767)
{
val = -32767;
}
assert (val < 32767);
if (val >= 0)
brick_table [index] = (short)val+1;
else
brick_table [index] = (short)val;
}
inline
int gc_heap::brick_entry (size_t index)
{
int val = brick_table [index];
if (val == 0)
{
return -32768;
}
else if (val < 0)
{
return val;
}
else
return val-1;
}
brick_table
中出现负值的情况是因为plug横跨幅度比较大,超过了单个brick的时候后面的brick就会设为负值,
如果对象地址在上图的1001或1002,查找这个对象对应的plug会从1000的plug树开始。
另外1002中的值不一定需要是-2,-1也是有效的,如果是-1会一直向前查找直到找到正值的brick。
在上面我们提到的问题可以通过brick_table
解决,可以看下面relocate_address
函数的代码。brick_table
在gc过程中会储存plug树,但是在gc完成后(gc不执行时)会储存各个brick中地址最大的plug,用于给find_first_object
等函数定位对象的开始地址使用。
对于Pinned Plug的特殊处理
pinned plug
除了会在plug树和brick table
中,还会保存在mark_stack_array
队列中,类型是mark
。
因为unpinned plug
和pinned plug
相邻会导致原来的内容被plug信息覆盖,mark
中还会保存以下的特殊信息
- saved_pre_plug
- 如果这个pinned plug覆盖了上一个unpinned plug的结尾,这里会保存覆盖前的原始内容
- saved_pre_plug_reloc
- 同上,但是这个值用于重定位和压缩阶段(中间会交换)
- saved_post_plug
- 如果这个pinned plug被下一个unpinned plug覆盖了结尾,这里会保存覆盖前的原始内容
- saved_post_plug_reloc
- 同上,但是这个值用于重定位和压缩阶段(中间会交换)
- saved_pre_plug_info_reloc_start
- 被覆盖的saved_pre_plug内容在重定位后的地址,如果重定位未发生则可以直接用(first - sizeof (plug_and_gap))
- saved_post_plug_info_start
- 被覆盖的saved_post_plug内容的地址,注意pinned plug不会被重定位
- saved_pre_p
- 是否保存了saved_pre_plug
- 如果覆盖的内容包含了对象的开头(对象比较小,整个都被覆盖了)
- 这里还会保存对象离各个引用成员的偏移值的bitmap (enque_pinned_plug)
- saved_post_p
- 是否保存了saved_post_p
- 如果覆盖的内容包含了对象的开头(对象比较小,整个都被覆盖了)
- 这里还会保存对象离各个引用成员的偏移值的bitmap (save_post_plug_info)
mark_stack_array
中的len
意义会在入队和出队时有所改变,
入队时len
代表pinned plug
的大小,
出队后len
代表pinned plug
离最后的模拟压缩分配地址的空间(这个空间可以变成free object)。
mark_stack_array
mark_stack_array
的结构如下图:
入队时mark_stack_tos
增加,出队时mark_stack_bos
增加,空间不够时会扩展然后mark_stack_array_length
会增加。
计划阶段判断使用压缩(compact)还是清扫(sweep)的依据是什么
计划阶段模拟压缩的时候创建plug,设置reloc
等等只是为了接下来的压缩做准备,既不会修改指针地址也不会移动内存。
在做完这些工作之后计划阶段会首先判断应不应该进行压缩,如果不进行压缩而是进行清扫,这些计算结果都会浪费掉。
判断是否使用压缩的根据主要有
- 系统空余空闲是否过少,如果过少触发swap可能会明显的拖低性能,这时候应该尝试压缩
- 碎片空间大小(fragmentation) >= 阈值(dd_fragmentation_limit)
- 碎片空间大小(fragmentation) / 收集代的大小(包括更年轻的代) >= 阈值(dd_fragmentation_burden_limit)
其他还有一些零碎的判断,将在下面的decide_on_compacting
函数的代码中讲解。
对象的升代与降代
在很多介绍.Net GC的书籍中都有提到过,经过GC以后对象会升代,例如gen 0中的对象在一次GC后如果存活下来会变为gen 1。
在CoreCLR中,对象的升代需要满足一定条件,某些特殊情况下不会升代,甚至会降代(gen1变为gen0)。
对象升代的条件如下:
- 计划阶段(plan_phase)选择清扫(sweep)时会启用升代
- 入口点(garbage_collect)判断当前是Full GC时会启用升代
dt_low_card_table_efficiency_p
成立时会启用升代- 请在前面查找
dt_low_card_table_efficiency_p
查看该处的解释
- 请在前面查找
- 计划阶段(plan_phase)判断上一代过小,或者这次标记(存活)的对象过多时启用升代
- 请在后面查找
promoted_bytes (i) > m
查看该处的解释
- 请在后面查找
如果升代的条件不满足,则原来在gen 0的对象GC后仍然会在gen 0,
某些特殊条件下还会发生降代,如下图:
在模拟压缩时,原来在gen 1的对象会归到gen 2(pinned object不一定),原来在gen 0的对象会归到gen 1,
但是如果所有unpinned plug都已经压缩到前面,后面还有残留的pinned plug时,后面残留的pinned plug中的对象则会不升代或者降代,
当这种情况发生时计划阶段会设置demotion_low
来标记被降代的范围。
如果最终选择了清扫(sweep)则上图中的情况不会发生。
计划代边界
计划阶段在模拟压缩的时候还会计划代边界(generation::plan_allocation_start),
计划代边界的工作主要在process_ephemeral_boundaries
, plan_generation_start
, plan_generation_starts
函数中完成。
大部分情况下函数process_ephemeral_boundaries
会用来计划gen 1的边界,如果不升代这个函数还会计划gen 0的边界,
当判断当前计划的plug大于或等于下一代的边界时,例如大于等于gen 0的边界时则会设置gen 1的边界在这个plug的前面。
最终选择压缩(compact)时,会把新的代边界设置成计划代边界(请看fix_generation_bounds
函数),
最终选择清扫(sweep)时,计划代边界不会被使用(请看make_free_lists
函数和make_free_list_in_brick
函数)。
计划阶段(plan_phase)的代码
gc_heap::plan_phase
函数的代码如下
void gc_heap::plan_phase (int condemned_gen_number)
{
// 如果收集代是gen 1则记录原来gen 2的大小
size_t old_gen2_allocated = 0;
size_t old_gen2_size = 0;
if (condemned_gen_number == (max_generation - 1))
{
old_gen2_allocated = generation_free_list_allocated (generation_of (max_generation));
old_gen2_size = generation_size (max_generation);
}
assert (settings.concurrent == FALSE);
// 统计计划阶段的开始时间
// %type% category = quote (plan);
#ifdef TIME_GC
unsigned start;
unsigned finish;
start = GetCycleCount32();
#endif //TIME_GC
dprintf (2,("---- Plan Phase ---- Condemned generation %d, promotion: %d",
condemned_gen_number, settings.promotion ? 1 : 0));
// 收集代的对象
generation* condemned_gen1 = generation_of (condemned_gen_number);
// 判断之前是否使用了mark list
// 标记对象较少时用mark list可以提升速度
#ifdef MARK_LIST
BOOL use_mark_list = FALSE;
uint8_t** mark_list_next = &mark_list[0];
#ifdef GC_CONFIG_DRIVEN
dprintf (3, ("total number of marked objects: %Id (%Id)",
(mark_list_index - &mark_list[0]), ((mark_list_end - &mark_list[0]))));
#else
dprintf (3, ("mark_list length: %Id",
(mark_list_index - &mark_list[0])));
#endif //GC_CONFIG_DRIVEN
if ((condemned_gen_number < max_generation) &&
(mark_list_index <= mark_list_end)
#ifdef BACKGROUND_GC
&& (!recursive_gc_sync::background_running_p())
#endif //BACKGROUND_GC
)
{
#ifndef MULTIPLE_HEAPS
_sort (&mark_list[0], mark_list_index-1, 0);
//printf ("using mark list at GC #%d", dd_collection_count (dynamic_data_of (0)));
//verify_qsort_array (&mark_list[0], mark_list_index-1);
#endif //!MULTIPLE_HEAPS
use_mark_list = TRUE;
get_gc_data_per_heap()->set_mechanism_bit (gc_mark_list_bit);
}
else
{
dprintf (3, ("mark_list not used"));
}
#endif //MARK_LIST
// 清除read only segment中的marked bit
#ifdef FEATURE_BASICFREEZE
if ((generation_start_segment (condemned_gen1) != ephemeral_heap_segment) &&
ro_segments_in_range)
{
sweep_ro_segments (generation_start_segment (condemned_gen1));
}
#endif // FEATURE_BASICFREEZE
// 根据之前使用m_boundary记录的slow和shigh快速清扫slow前面和shigh后面的垃圾对象
// shigh等于0表示无对象存活
// if (shigh != (uint8_t*)0)
// 对于slow, 调用make_unused_array
// 对于shigh, 设置heap_segment_allocated
// 对于范围外的segment, heap_segment_allocated (seg) = heap_segment_mem (seg); // 整个segment都被清空,后面可删除
// else
// 第一个segment, heap_segment_allocated (seg) = generation_allocation_start (condemned_gen1);
// 后面的segment, heap_segment_allocated (seg) = heap_segment_mem (seg); // 整个segment都被清空,后面可删除
#ifndef MULTIPLE_HEAPS
if (shigh != (uint8_t*)0)
{
heap_segment* seg = heap_segment_rw (generation_start_segment (condemned_gen1));
PREFIX_ASSUME(seg != NULL);
heap_segment* fseg = seg;
do
{
if (slow > heap_segment_mem (seg) &&
slow < heap_segment_reserved (seg))
{
if (seg == fseg)
{
uint8_t* o = generation_allocation_start (condemned_gen1) +
Align (size (generation_allocation_start (condemned_gen1)));
if (slow > o)
{
assert ((slow - o) >= (int)Align (min_obj_size));
#ifdef BACKGROUND_GC
if (current_c_gc_state == c_gc_state_marking)
{
bgc_clear_batch_mark_array_bits (o, slow);
}
#endif //BACKGROUND_GC
make_unused_array (o, slow - o);
}
}
else
{
assert (condemned_gen_number == max_generation);
make_unused_array (heap_segment_mem (seg),
slow - heap_segment_mem (seg));
}
}
if (in_range_for_segment (shigh, seg))
{
#ifdef BACKGROUND_GC
if (current_c_gc_state == c_gc_state_marking)
{
bgc_clear_batch_mark_array_bits ((shigh + Align (size (shigh))), heap_segment_allocated (seg));
}
#endif //BACKGROUND_GC
heap_segment_allocated (seg) = shigh + Align (size (shigh));
}
// test if the segment is in the range of [slow, shigh]
if (!((heap_segment_reserved (seg) >= slow) &&
(heap_segment_mem (seg) <= shigh)))
{
// shorten it to minimum
heap_segment_allocated (seg) = heap_segment_mem (seg);
}
seg = heap_segment_next_rw (seg);
} while (seg);
}
else
{
heap_segment* seg = heap_segment_rw (generation_start_segment (condemned_gen1));
PREFIX_ASSUME(seg != NULL);
heap_segment* sseg = seg;
do
{
// shorten it to minimum
if (seg == sseg)
{
// no survivors make all generations look empty
uint8_t* o = generation_allocation_start (condemned_gen1) +
Align (size (generation_allocation_start (condemned_gen1)));
#ifdef BACKGROUND_GC
if (current_c_gc_state == c_gc_state_marking)
{
bgc_clear_batch_mark_array_bits (o, heap_segment_allocated (seg));
}
#endif //BACKGROUND_GC
heap_segment_allocated (seg) = o;
}
else
{
assert (condemned_gen_number == max_generation);
#ifdef BACKGROUND_GC
if (current_c_gc_state == c_gc_state_marking)
{
bgc_clear_batch_mark_array_bits (heap_segment_mem (seg), heap_segment_allocated (seg));
}
#endif //BACKGROUND_GC
heap_segment_allocated (seg) = heap_segment_mem (seg);
}
seg = heap_segment_next_rw (seg);
} while (seg);
}
#endif //MULTIPLE_HEAPS
// 当前计划的segment,会随着计划向后移动
heap_segment* seg1 = heap_segment_rw (generation_start_segment (condemned_gen1));
PREFIX_ASSUME(seg1 != NULL);
// 当前计划的segment的结束地址
uint8_t* end = heap_segment_allocated (seg1);
// 收集代的第一个对象(地址)
uint8_t* first_condemned_address = generation_allocation_start (condemned_gen1);
// 当前计划的对象
uint8_t* x = first_condemned_address;
assert (!marked (x));
// 当前plug的结束地址
uint8_t* plug_end = x;
// 当前plug树的根节点
uint8_t* tree = 0;
// 构建plug树使用的序列
size_t sequence_number = 0;
// 上一次的plug节点
uint8_t* last_node = 0;
// 当前计划的brick
size_t current_brick = brick_of (x);
// 是否从计划代开始模拟分配(这个变量后面还会设为true)
BOOL allocate_in_condemned = ((condemned_gen_number == max_generation)||
(settings.promotion == FALSE));
// 当前计划的旧代和新代,这两个变量用于重新决定代边界(generation_allocation_start)
int active_old_gen_number = condemned_gen_number;
int active_new_gen_number = (allocate_in_condemned ? condemned_gen_number:
(1 + condemned_gen_number));
// 收集代的上一代(如果收集代是gen 2这里会设为gen 2)
generation* older_gen = 0;
// 模拟分配的代
generation* consing_gen = condemned_gen1;
// older_gen的原始数据备份
alloc_list r_free_list [MAX_BUCKET_COUNT];
size_t r_free_list_space = 0;
size_t r_free_obj_space = 0;
size_t r_older_gen_free_list_allocated = 0;
size_t r_older_gen_condemned_allocated = 0;
size_t r_older_gen_end_seg_allocated = 0;
uint8_t* r_allocation_pointer = 0;
uint8_t* r_allocation_limit = 0;
uint8_t* r_allocation_start_region = 0;
heap_segment* r_allocation_segment = 0;
#ifdef FREE_USAGE_STATS
size_t r_older_gen_free_space[NUM_GEN_POWER2];
#endif //FREE_USAGE_STATS
// 在计划之前备份older_gen的数据
if ((condemned_gen_number < max_generation))
{
older_gen = generation_of (min (max_generation, 1 + condemned_gen_number));
generation_allocator (older_gen)->copy_to_alloc_list (r_free_list);
r_free_list_space = generation_free_list_space (older_gen);
r_free_obj_space = generation_free_obj_space (older_gen);
#ifdef FREE_USAGE_STATS
memcpy (r_older_gen_free_space, older_gen->gen_free_spaces, sizeof (r_older_gen_free_space));
#endif //FREE_USAGE_STATS
generation_allocate_end_seg_p (older_gen) = FALSE;
r_older_gen_free_list_allocated = generation_free_list_allocated (older_gen);
r_older_gen_condemned_allocated = generation_condemned_allocated (older_gen);
r_older_gen_end_seg_allocated = generation_end_seg_allocated (older_gen);
r_allocation_limit = generation_allocation_limit (older_gen);
r_allocation_pointer = generation_allocation_pointer (older_gen);
r_allocation_start_region = generation_allocation_context_start_region (older_gen);
r_allocation_segment = generation_allocation_segment (older_gen);
heap_segment* start_seg = heap_segment_rw (generation_start_segment (older_gen));
PREFIX_ASSUME(start_seg != NULL);
if (start_seg != ephemeral_heap_segment)
{
assert (condemned_gen_number == (max_generation - 1));
while (start_seg && (start_seg != ephemeral_heap_segment))
{
assert (heap_segment_allocated (start_seg) >=
heap_segment_mem (start_seg));
assert (heap_segment_allocated (start_seg) <=
heap_segment_reserved (start_seg));
heap_segment_plan_allocated (start_seg) =
heap_segment_allocated (start_seg);
start_seg = heap_segment_next_rw (start_seg);
}
}
}
// 重设收集代以后的的所有segment的plan_allocated(计划分配的对象大小合计)
//reset all of the segment allocated sizes
{
heap_segment* seg2 = heap_segment_rw (generation_start_segment (condemned_gen1));
PREFIX_ASSUME(seg2 != NULL);
while (seg2)
{
heap_segment_plan_allocated (seg2) =
heap_segment_mem (seg2);
seg2 = heap_segment_next_rw (seg2);
}
}
// 重设gen 0 ~ 收集代的数据
int condemned_gn = condemned_gen_number;
int bottom_gen = 0;
init_free_and_plug();
while (condemned_gn >= bottom_gen)
{
generation* condemned_gen2 = generation_of (condemned_gn);
generation_allocator (condemned_gen2)->clear();
generation_free_list_space (condemned_gen2) = 0;
generation_free_obj_space (condemned_gen2) = 0;
generation_allocation_size (condemned_gen2) = 0;
generation_condemned_allocated (condemned_gen2) = 0;
generation_pinned_allocated (condemned_gen2) = 0;
generation_free_list_allocated(condemned_gen2) = 0;
generation_end_seg_allocated (condemned_gen2) = 0;
// 执行清扫(sweep)时对应代增加的固定对象(pinned object)大小
generation_pinned_allocation_sweep_size (condemned_gen2) = 0;
// 执行压缩(compact)时对应代增加的固定对象(pinned object)大小
generation_pinned_allocation_compact_size (condemned_gen2) = 0;
#ifdef FREE_USAGE_STATS
generation_pinned_free_obj_space (condemned_gen2) = 0;
generation_allocated_in_pinned_free (condemned_gen2) = 0;
generation_allocated_since_last_pin (condemned_gen2) = 0;
#endif //FREE_USAGE_STATS
// 计划的代边界
generation_plan_allocation_start (condemned_gen2) = 0;
generation_allocation_segment (condemned_gen2) =
heap_segment_rw (generation_start_segment (condemned_gen2));
PREFIX_ASSUME(generation_allocation_segment(condemned_gen2) != NULL);
// 设置分配上下文地址,模拟压缩时使用
if (generation_start_segment (condemned_gen2) != ephemeral_heap_segment)
{
generation_allocation_pointer (condemned_gen2) =
heap_segment_mem (generation_allocation_segment (condemned_gen2));
}
else
{
generation_allocation_pointer (condemned_gen2) = generation_allocation_start (condemned_gen2);
}
generation_allocation_limit (condemned_gen2) = generation_allocation_pointer (condemned_gen2);
generation_allocation_context_start_region (condemned_gen2) = generation_allocation_pointer (condemned_gen2);
condemned_gn--;
}
// 在处理所有对象之前是否要先决定一个代的边界
// 不升代或者收集代是gen 2(Full GC)时需要
BOOL allocate_first_generation_start = FALSE;
if (allocate_in_condemned)
{
allocate_first_generation_start = TRUE;
}
dprintf(3,( " From %Ix to %Ix", (size_t)x, (size_t)end));
// 记录对象降代(原来gen 1的对象变为gen 0)的情况
// 关于不升代和降代的条件和处理将在下面解释
demotion_low = MAX_PTR;
demotion_high = heap_segment_allocated (ephemeral_heap_segment);
// 判断是否应该阻止gen 1中的固定对象降代
// 如果只是收集原因只是因为dt_low_card_table_efficiency_p则需要阻止降代
// demote_gen1_p = false时会在下面调用advance_pins_for_demotion函数
// If we are doing a gen1 only because of cards, it means we should not demote any pinned plugs
// from gen1. They should get promoted to gen2.
demote_gen1_p = !(settings.promotion &&
(settings.condemned_generation == (max_generation - 1)) &&
gen_to_condemn_reasons.is_only_condition (gen_low_card_p));
total_ephemeral_size = 0;
// 打印除错信息
print_free_and_plug ("BP");
// 打印除错信息
for (int gen_idx = 0; gen_idx <= max_generation; gen_idx++)
{
generation* temp_gen = generation_of (gen_idx);
dprintf (2, ("gen%d start %Ix, plan start %Ix",
gen_idx,
generation_allocation_start (temp_gen),
generation_plan_allocation_start (temp_gen)));
}
// 触发etw时间
BOOL fire_pinned_plug_events_p = ETW_EVENT_ENABLED(MICROSOFT_WINDOWS_DOTNETRUNTIME_PRIVATE_PROVIDER_Context, PinPlugAtGCTime);
size_t last_plug_len = 0;
// 开始模拟压缩
// 会创建plug,设置brick table和模拟plug的移动
while (1)
{
// 应该处理下个segment
if (x >= end)
{
assert (x == end);
assert (heap_segment_allocated (seg1) == end);
heap_segment_allocated (seg1) = plug_end;
// 设置brick table
current_brick = update_brick_table (tree, current_brick, x, plug_end);
dprintf (3, ("end of seg: new tree, sequence# 0"));
sequence_number = 0;
tree = 0;
// 有下一个segment,继续处理
if (heap_segment_next_rw (seg1))
{
seg1 = heap_segment_next_rw (seg1);
end = heap_segment_allocated (seg1);
plug_end = x = heap_segment_mem (seg1);
current_brick = brick_of (x);
dprintf(3,( " From %Ix to %Ix", (size_t)x, (size_t)end));
continue;
}
// 无下一个segment,跳出模拟压缩的循环
else
{
break;
}
}
// 上一个plug是否unpinned plug
BOOL last_npinned_plug_p = FALSE;
// 上一个plug是否pinned plug
BOOL last_pinned_plug_p = FALSE;
// 上一个pinned plug的地址,合并pinned plug时使用
// last_pinned_plug is the beginning of the last pinned plug. If we merge a plug into a pinned
// plug we do not change the value of last_pinned_plug. This happens with artificially pinned plugs -
// it can be merged with a previous pinned plug and a pinned plug after it can be merged with it.
uint8_t* last_pinned_plug = 0;
size_t num_pinned_plugs_in_plug = 0;
// 当前plug的最后一个对象的地址
uint8_t* last_object_in_plug = 0;
// 枚举segment中的对象,如果第一个对象未被标记不会进入以下的处理
while ((x < end) && marked (x))
{
// 记录plug的开始
uint8_t* plug_start = x;
uint8_t* saved_plug_end = plug_end;
// 当前plug中的对象是否pinned object
// 会轮流切换
BOOL pinned_plug_p = FALSE;
BOOL npin_before_pin_p = FALSE;
BOOL saved_last_npinned_plug_p = last_npinned_plug_p;
uint8_t* saved_last_object_in_plug = last_object_in_plug;
BOOL merge_with_last_pin_p = FALSE;
size_t added_pinning_size = 0;
size_t artificial_pinned_size = 0;
// 预先保存一部分plug信息
// 设置这个plug和上一个plug的结尾之间的gap
// 如果当前plug是pinned plug
// - 调用enque_pinned_plug把plug信息保存到mark_stack_array队列
// - enque_pinned_plug不会设置长度(len)和移动队列顶部(mark_stack_tos),这部分工作会在set_pinned_info完成
// - 检测当前pinned plug是否覆盖了前一个unpinned plug的结尾
// - 如果覆盖了需要把原来的内容复制到saved_pre_plug和saved_pre_plug_reloc (函数enque_pinned_plug)
// 如果当前plug是unpinned plug
// - 检测当前unpinned plug是否覆盖了前一个pinned plug的结尾
// - 如果覆盖了需要把原来的内容复制到saved_post_plug和saved_post_plug_reloc (函数save_post_plug_info)
store_plug_gap_info (plug_start, plug_end, last_npinned_plug_p, last_pinned_plug_p,
last_pinned_plug, pinned_plug_p, last_object_in_plug,
merge_with_last_pin_p, last_plug_len);
#ifdef FEATURE_STRUCTALIGN
int requiredAlignment = ((CObjectHeader*)plug_start)->GetRequiredAlignment();
size_t alignmentOffset = OBJECT_ALIGNMENT_OFFSET;
#endif // FEATURE_STRUCTALIGN
{
// 枚举接下来的对象,如果对象未被标记,或者对象是否固定和pinned_plug_p不一致则中断
// 这里枚举到的对象都会归到同一个plug里面
uint8_t* xl = x;
while ((xl < end) && marked (xl) && (pinned (xl) == pinned_plug_p))
{
assert (xl < end);
// 清除pinned bit
// 像前面所说的,GC里面marked和pinned标记都是临时使用的,在计划阶段会被清除
if (pinned(xl))
{
clear_pinned (xl);
}
#ifdef FEATURE_STRUCTALIGN
else
{
int obj_requiredAlignment = ((CObjectHeader*)xl)->GetRequiredAlignment();
if (obj_requiredAlignment > requiredAlignment)
{
requiredAlignment = obj_requiredAlignment;
alignmentOffset = xl - plug_start + OBJECT_ALIGNMENT_OFFSET;
}
}
#endif // FEATURE_STRUCTALIGN
// 清除marked bit
clear_marked (xl);
dprintf(4, ("+%Ix+", (size_t)xl));
assert ((size (xl) > 0));
assert ((size (xl) <= LARGE_OBJECT_SIZE));
// 记录当前plug的最后一个对象
last_object_in_plug = xl;
// 下一个对象
xl = xl + Align (size (xl));
Prefetch (xl);
}
BOOL next_object_marked_p = ((xl < end) && marked (xl));
// 如果当前plug是pinned plug但下一个不是,代表当前plug的结尾需要被覆盖掉做下一个plug的信息
// 我们不想动pinned plug的内容,所以这里需要牺牲下一个对象,把下一个对象拉到这个plug里面
if (pinned_plug_p)
{
// If it is pinned we need to extend to the next marked object as we can't use part of
// a pinned object to make the artificial gap (unless the last 3 ptr sized words are all
// references but for now I am just using the next non pinned object for that).
if (next_object_marked_p)
{
clear_marked (xl);
last_object_in_plug = xl;
size_t extra_size = Align (size (xl));
xl = xl + extra_size;
added_pinning_size = extra_size;
}
}
else
{
// 当前plug是unpinned plug,下一个plug是pinned plug
if (next_object_marked_p)
npin_before_pin_p = TRUE;
}
assert (xl <= end);
x = xl;
}
dprintf (3, ( "%Ix[", (size_t)x));
// 设置plug的结尾
plug_end = x;
// plug大小 = 结尾 - 开头
size_t ps = plug_end - plug_start;
last_plug_len = ps;
dprintf (3, ( "%Ix[(%Ix)", (size_t)x, ps));
uint8_t* new_address = 0;
// 有时候如果一个unpinned plug很大,我们想人工固定它(artificially pinned plug)
// 如果前一个plug也是pinned plug则和前一个plug整合到一个,否则进入mark_stack_array队列中
if (!pinned_plug_p)
{
if (allocate_in_condemned &&
(settings.condemned_generation == max_generation) &&
(ps > (OS_PAGE_SIZE)))
{
ptrdiff_t reloc = plug_start - generation_allocation_pointer (consing_gen);
//reloc should >=0 except when we relocate
//across segments and the dest seg is higher then the src
if ((ps > (8*OS_PAGE_SIZE)) &&
(reloc > 0) &&
((size_t)reloc < (ps/16)))
{
dprintf (3, ("Pinning %Ix; reloc would have been: %Ix",
(size_t)plug_start, reloc));
// The last plug couldn't have been a npinned plug or it would have
// included this plug.
assert (!saved_last_npinned_plug_p);
if (last_pinned_plug)
{
dprintf (3, ("artificially pinned plug merged with last pinned plug"));
merge_with_last_pin_p = TRUE;
}
else
{
enque_pinned_plug (plug_start, FALSE, 0);
last_pinned_plug = plug_start;
}
convert_to_pinned_plug (last_npinned_plug_p, last_pinned_plug_p, pinned_plug_p,
ps, artificial_pinned_size);
}
}
}
// 如果在做Full GC或者不升代,决定第一个代的边界
// plan_generation_start用于计划代的边界(generation_plan_generation_start)
// Full GC时gen 2的边界会在这里决定
if (allocate_first_generation_start)
{
allocate_first_generation_start = FALSE;
plan_generation_start (condemned_gen1, consing_gen, plug_start);
assert (generation_plan_allocation_start (condemned_gen1));
}
// 如果模拟的segment是ephemeral heap segment
// 在这里决定gen 1的边界
// 如果不升代这里也会决定gen 0的边界
if (seg1 == ephemeral_heap_segment)
{
process_ephemeral_boundaries (plug_start, active_new_gen_number,
active_old_gen_number,
consing_gen,
allocate_in_condemned);
}
dprintf (3, ("adding %Id to gen%d surv", ps, active_old_gen_number));
// 统计存活的对象大小
dynamic_data* dd_active_old = dynamic_data_of (active_old_gen_number);
dd_survived_size (dd_active_old) += ps;
// 模拟压缩的时候有可能会要求把当前unpinned plug转换为pinned plug
BOOL convert_to_pinned_p = FALSE;
// 如果plug是unpinned plug,模拟压缩
if (!pinned_plug_p)
{
#if defined (RESPECT_LARGE_ALIGNMENT) || defined (FEATURE_STRUCTALIGN)
dd_num_npinned_plugs (dd_active_old)++;
#endif //RESPECT_LARGE_ALIGNMENT || FEATURE_STRUCTALIGN
// 更新统计信息
add_gen_plug (active_old_gen_number, ps);
if (allocate_in_condemned)
{
verify_pins_with_post_plug_info("before aic");
// 在收集代分配,必要时跳过pinned plug,返回新的地址
new_address =
allocate_in_condemned_generations (consing_gen,
ps,
active_old_gen_number,
#ifdef SHORT_PLUGS
&convert_to_pinned_p,
(npin_before_pin_p ? plug_end : 0),
seg1,
#endif //SHORT_PLUGS
plug_start REQD_ALIGN_AND_OFFSET_ARG);
verify_pins_with_post_plug_info("after aic");
}
else
{
// 在上一代分配,必要时跳过pinned plug,返回新的地址
new_address = allocate_in_older_generation (older_gen, ps, active_old_gen_number, plug_start REQD_ALIGN_AND_OFFSET_ARG);
if (new_address != 0)
{
if (settings.condemned_generation == (max_generation - 1))
{
dprintf (3, (" NA: %Ix-%Ix -> %Ix, %Ix (%Ix)",
plug_start, plug_end,
(size_t)new_address, (size_t)new_address + (plug_end - plug_start),
(size_t)(plug_end - plug_start)));
}
}
else
{
// 失败时(空间不足)改为在收集代分配
allocate_in_condemned = TRUE;
new_address = allocate_in_condemned_generations (consing_gen, ps, active_old_gen_number,
#ifdef SHORT_PLUGS
&convert_to_pinned_p,
(npin_before_pin_p ? plug_end : 0),
seg1,
#endif //SHORT_PLUGS
plug_start REQD_ALIGN_AND_OFFSET_ARG);
}
}
// 如果要求把当前unpinned plug转换为pinned plug
if (convert_to_pinned_p)
{
assert (last_npinned_plug_p != FALSE);
assert (last_pinned_plug_p == FALSE);
convert_to_pinned_plug (last_npinned_plug_p, last_pinned_plug_p, pinned_plug_p,
ps, artificial_pinned_size);
enque_pinned_plug (plug_start, FALSE, 0);
last_pinned_plug = plug_start;
}
else
{
// 找不到空间(不移动这个plug)时验证是在ephemeral heap segment的末尾
// 这里还不会设置reloc,到下面的set_node_relocation_distance才会设
if (!new_address)
{
//verify that we are at then end of the ephemeral segment
assert (generation_allocation_segment (consing_gen) ==
ephemeral_heap_segment);
//verify that we are near the end
assert ((generation_allocation_pointer (consing_gen) + Align (ps)) <
heap_segment_allocated (ephemeral_heap_segment));
assert ((generation_allocation_pointer (consing_gen) + Align (ps)) >
(heap_segment_allocated (ephemeral_heap_segment) + Align (min_obj_size)));
}
else
{
#ifdef SIMPLE_DPRINTF
dprintf (3, ("(%Ix)[%Ix->%Ix, NA: [%Ix(%Id), %Ix[: %Ix(%d)",
(size_t)(node_gap_size (plug_start)),
plug_start, plug_end, (size_t)new_address, (size_t)(plug_start - new_address),
(size_t)new_address + ps, ps,
(is_plug_padded (plug_start) ? 1 : 0)));
#endif //SIMPLE_DPRINTF
#ifdef SHORT_PLUGS
if (is_plug_padded (plug_start))
{
dprintf (3, ("%Ix was padded", plug_start));
dd_padding_size (dd_active_old) += Align (min_obj_size);
}
#endif //SHORT_PLUGS
}
}
}
// 如果当前plug是pinned plug
if (pinned_plug_p)
{
if (fire_pinned_plug_events_p)
FireEtwPinPlugAtGCTime(plug_start, plug_end,
(merge_with_last_pin_p ? 0 : (uint8_t*)node_gap_size (plug_start)),
GetClrInstanceId());
// 和上一个pinned plug合并
if (merge_with_last_pin_p)
{
merge_with_last_pinned_plug (last_pinned_plug, ps);
}
// 设置队列中的pinned plug大小(len)并移动队列顶部(mark_stack_tos++)
else
{
assert (last_pinned_plug == plug_start);
set_pinned_info (plug_start, ps, consing_gen);
}
// pinned plug不能移动,新地址和原地址一样
new_address = plug_start;
dprintf (3, ( "(%Ix)PP: [%Ix, %Ix[%Ix](m:%d)",
(size_t)(node_gap_size (plug_start)), (size_t)plug_start,
(size_t)plug_end, ps,
(merge_with_last_pin_p ? 1 : 0)));
// 统计存活对象的大小,固定对象的大小和人工固定对象的大小
dprintf (3, ("adding %Id to gen%d pinned surv", plug_end - plug_start, active_old_gen_number));
dd_pinned_survived_size (dd_active_old) += plug_end - plug_start;
dd_added_pinned_size (dd_active_old) += added_pinning_size;
dd_artificial_pinned_survived_size (dd_active_old) += artificial_pinned_size;
// 如果需要禁止降代gen 1的对象,记录在gen 1中最后一个pinned plug的结尾
if (!demote_gen1_p && (active_old_gen_number == (max_generation - 1)))
{
last_gen1_pin_end = plug_end;
}
}
#ifdef _DEBUG
// detect forward allocation in the same segment
assert (!((new_address > plug_start) &&
(new_address < heap_segment_reserved (seg1))));
#endif //_DEBUG
// 如果不合并到上一个pinned plug
// 在这里可以设置偏移值(reloc)和更新brick table了
if (!merge_with_last_pin_p)
{
// 如果已经在下一个brick
// 把之前的plug树设置到之前的brick中,并重设plug树
// 如果之前的plug跨了多个brick,update_brick_table会设置后面的brick为-1
if (current_brick != brick_of (plug_start))
{
current_brick = update_brick_table (tree, current_brick, plug_start, saved_plug_end);
sequence_number = 0;
tree = 0;
}
// 更新plug的偏移值(reloc)
// 这里的偏移值会用在后面的重定位阶段(relocate_phase)和压缩阶段(compact_phase)
set_node_relocation_distance (plug_start, (new_address - plug_start));
// 构建plug树
if (last_node && (node_relocation_distance (last_node) ==
(node_relocation_distance (plug_start) +
(int)node_gap_size (plug_start))))
{
//dprintf(3,( " Lb"));
dprintf (3, ("%Ix Lb", plug_start));
set_node_left (plug_start);
}
if (0 == sequence_number)
{
dprintf (2, ("sn: 0, tree is set to %Ix", plug_start));
tree = plug_start;
}
verify_pins_with_post_plug_info("before insert node");
tree = insert_node (plug_start, ++sequence_number, tree, last_node);
dprintf (3, ("tree is %Ix (b: %Ix) after insert_node", tree, brick_of (tree)));
last_node = plug_start;
// 这个处理只用于除错
// 如果这个plug是unpinned plug并且覆盖了上一个pinned plug的结尾
// 把覆盖的内容复制到pinned plug关联的saved_post_plug_debug
#ifdef _DEBUG
// If we detect if the last plug is pinned plug right before us, we should save this gap info
if (!pinned_plug_p)
{
if (mark_stack_tos > 0)
{
mark& m = mark_stack_array[mark_stack_tos - 1];
if (m.has_post_plug_info())
{
uint8_t* post_plug_info_start = m.saved_post_plug_info_start;
size_t* current_plug_gap_start = (size_t*)(plug_start - sizeof (plug_and_gap));
if ((uint8_t*)current_plug_gap_start == post_plug_info_start)
{
dprintf (3, ("Ginfo: %Ix, %Ix, %Ix",
*current_plug_gap_start, *(current_plug_gap_start + 1),
*(current_plug_gap_start + 2)));
memcpy (&(m.saved_post_plug_debug), current_plug_gap_start, sizeof (gap_reloc_pair));
}
}
}
}
#endif //_DEBUG
verify_pins_with_post_plug_info("after insert node");
}
}
if (num_pinned_plugs_in_plug > 1)
{
dprintf (3, ("more than %Id pinned plugs in this plug", num_pinned_plugs_in_plug));
}
// 跳过未标记的对象找到下一个已标记的对象
// 如果有mark_list可以加快找到下一个已标记对象的速度
{
#ifdef MARK_LIST
if (use_mark_list)
{
while ((mark_list_next < mark_list_index) &&
(*mark_list_next <= x))
{
mark_list_next++;
}
if ((mark_list_next < mark_list_index)
#ifdef MULTIPLE_HEAPS
&& (*mark_list_next < end) //for multiple segments
#endif //MULTIPLE_HEAPS
)
x = *mark_list_next;
else
x = end;
}
else
#endif //MARK_LIST
{
uint8_t* xl = x;
#ifdef BACKGROUND_GC
if (current_c_gc_state == c_gc_state_marking)
{
assert (recursive_gc_sync::background_running_p());
while ((xl < end) && !marked (xl))
{
dprintf (4, ("-%Ix-", (size_t)xl));
assert ((size (xl) > 0));
background_object_marked (xl, TRUE);
xl = xl + Align (size (xl));
Prefetch (xl);
}
}
else
#endif //BACKGROUND_GC
{
// 跳过未标记的对象
while ((xl < end) && !marked (xl))
{
dprintf (4, ("-%Ix-", (size_t)xl));
assert ((size (xl) > 0));
xl = xl + Align (size (xl));
Prefetch (xl);
}
}
assert (xl <= end);
// 找到了下一个已标记的对象,或者当前segment中的对象已经搜索完毕
x = xl;
}
}
}
// 处理mark_stack_array中尚未出队的pinned plug
// 这些plug已经在所有已压缩的unpinned plug后面,我们可以把这些pinned plug降级(降到gen 0),也可以防止它们降级
while (!pinned_plug_que_empty_p())
{
// 计算代边界和处理降代
// 不在ephemeral heap segment的pinned plug不会被降代
// 前面调用的process_ephemeral_boundaries中有相同的处理
if (settings.promotion)
{
uint8_t* pplug = pinned_plug (oldest_pin());
if (in_range_for_segment (pplug, ephemeral_heap_segment))
{
consing_gen = ensure_ephemeral_heap_segment (consing_gen);
//allocate all of the generation gaps
while (active_new_gen_number > 0)
{
active_new_gen_number--;
if (active_new_gen_number == (max_generation - 1))
{
// 如果要防止gen 1的pinned plug降代则需要调用调用advance_pins_for_demotion跳过(出队)它们
// 在原来gen 0中的pinned plug不会改变
maxgen_pinned_compact_before_advance = generation_pinned_allocation_compact_size (generation_of (max_generation));
if (!demote_gen1_p)
advance_pins_for_demotion (consing_gen);
}
// 计划剩余的代边界
generation* gen = generation_of (active_new_gen_number);
plan_generation_start (gen, consing_gen, 0);
// 代边界被设置到pinned plug之前的时候需要记录降代的范围(降代已经实际发生,设置demotion_low是记录降代的范围)
if (demotion_low == MAX_PTR)
{
demotion_low = pplug;
dprintf (3, ("end plan: dlow->%Ix", demotion_low));
}
dprintf (2, ("(%d)gen%d plan start: %Ix",
heap_number, active_new_gen_number, (size_t)generation_plan_allocation_start (gen)));
assert (generation_plan_allocation_start (gen));
}
}
}
// 所有pinned plug都已出队时跳出
if (pinned_plug_que_empty_p())
break;
// 出队一个pinned plug
size_t entry = deque_pinned_plug();
mark* m = pinned_plug_of (entry);
uint8_t* plug = pinned_plug (m);
size_t len = pinned_len (m);
// 检测这个pinned plug是否在cosing_gen的allocation segment之外
// 如果不在需要调整allocation segment,等会需要把generation_allocation_pointer设置为plug + len
// detect pinned block in different segment (later) than
// allocation segment
heap_segment* nseg = heap_segment_rw (generation_allocation_segment (consing_gen));
while ((plug < generation_allocation_pointer (consing_gen)) ||
(plug >= heap_segment_allocated (nseg)))
{
assert ((plug < heap_segment_mem (nseg)) ||
(plug > heap_segment_reserved (nseg)));
//adjust the end of the segment to be the end of the plug
assert (generation_allocation_pointer (consing_gen)>=
heap_segment_mem (nseg));
assert (generation_allocation_pointer (consing_gen)<=
heap_segment_committed (nseg));
heap_segment_plan_allocated (nseg) =
generation_allocation_pointer (consing_gen);
//switch allocation segment
nseg = heap_segment_next_rw (nseg);
generation_allocation_segment (consing_gen) = nseg;
//reset the allocation pointer and limits
generation_allocation_pointer (consing_gen) =
heap_segment_mem (nseg);
}
// 出队以后设置len = pinned plug - generation_allocation_pointer (consing_gen)
// 表示pinned plug的开始地址离最后的模拟压缩分配地址的空间,这个空间可以变成free object
set_new_pin_info (m, generation_allocation_pointer (consing_gen));
dprintf (2, ("pin %Ix b: %Ix->%Ix", plug, brick_of (plug),
(size_t)(brick_table[brick_of (plug)])));
// 设置模拟压缩分配地址到plug的结尾
generation_allocation_pointer (consing_gen) = plug + len;
generation_allocation_limit (consing_gen) =
generation_allocation_pointer (consing_gen);
//Add the size of the pinned plug to the right pinned allocations
//find out which gen this pinned plug came from
int frgn = object_gennum (plug);
// 统计清扫时会多出的pinned object大小
// 加到上一代中(pinned object升代)
if ((frgn != (int)max_generation) && settings.promotion)
{
generation_pinned_allocation_sweep_size ((generation_of (frgn +1))) += len;
}
}
// 计划剩余所有代的边界
// 大部分情况下(升代 + 无降代)这里会设置gen 0的边界,也就是在现有的所有存活对象之后
plan_generation_starts (consing_gen);
// 打印除错信息
print_free_and_plug ("AP");
// 打印除错信息
{
#ifdef SIMPLE_DPRINTF
for (int gen_idx = 0; gen_idx <= max_generation; gen_idx++)
{
generation* temp_gen = generation_of (gen_idx);
dynamic_data* temp_dd = dynamic_data_of (gen_idx);
int added_pinning_ratio = 0;
int artificial_pinned_ratio = 0;
if (dd_pinned_survived_size (temp_dd) != 0)
{
added_pinning_ratio = (int)((float)dd_added_pinned_size (temp_dd) * 100 / (float)dd_pinned_survived_size (temp_dd));
artificial_pinned_ratio = (int)((float)dd_artificial_pinned_survived_size (temp_dd) * 100 / (float)dd_pinned_survived_size (temp_dd));
}
size_t padding_size =
#ifdef SHORT_PLUGS
dd_padding_size (temp_dd);
#else
0;
#endif //SHORT_PLUGS
dprintf (1, ("gen%d: %Ix, %Ix(%Id), NON PIN alloc: %Id, pin com: %Id, sweep: %Id, surv: %Id, pinsurv: %Id(%d%% added, %d%% art), np surv: %Id, pad: %Id",
gen_idx,
generation_allocation_start (temp_gen),
generation_plan_allocation_start (temp_gen),
(size_t)(generation_plan_allocation_start (temp_gen) - generation_allocation_start (temp_gen)),
generation_allocation_size (temp_gen),
generation_pinned_allocation_compact_size (temp_gen),
generation_pinned_allocation_sweep_size (temp_gen),
dd_survived_size (temp_dd),
dd_pinned_survived_size (temp_dd),
added_pinning_ratio,
artificial_pinned_ratio,
(dd_survived_size (temp_dd) - dd_pinned_survived_size (temp_dd)),
padding_size));
}
#endif //SIMPLE_DPRINTF
}
// 继续打印除错信息,并且更新gen 2的统计信息
if (settings.condemned_generation == (max_generation - 1 ))
{
size_t plan_gen2_size = generation_plan_size (max_generation);
size_t growth = plan_gen2_size - old_gen2_size;
if (growth > 0)
{
dprintf (1, ("gen2 grew %Id (end seg alloc: %Id, gen1 c alloc: %Id",
growth, generation_end_seg_allocated (generation_of (max_generation)),
generation_condemned_allocated (generation_of (max_generation - 1))));
}
else
{
dprintf (1, ("gen2 shrank %Id (end seg alloc: %Id, gen1 c alloc: %Id",
(old_gen2_size - plan_gen2_size), generation_end_seg_allocated (generation_of (max_generation)),
generation_condemned_allocated (generation_of (max_generation - 1))));
}
generation* older_gen = generation_of (settings.condemned_generation + 1);
size_t rejected_free_space = generation_free_obj_space (older_gen) - r_free_obj_space;
size_t free_list_allocated = generation_free_list_allocated (older_gen) - r_older_gen_free_list_allocated;
size_t end_seg_allocated = generation_end_seg_allocated (older_gen) - r_older_gen_end_seg_allocated;
size_t condemned_allocated = generation_condemned_allocated (older_gen) - r_older_gen_condemned_allocated;
dprintf (1, ("older gen's free alloc: %Id->%Id, seg alloc: %Id->%Id, condemned alloc: %Id->%Id",
r_older_gen_free_list_allocated, generation_free_list_allocated (older_gen),
r_older_gen_end_seg_allocated, generation_end_seg_allocated (older_gen),
r_older_gen_condemned_allocated, generation_condemned_allocated (older_gen)));
dprintf (1, ("this GC did %Id free list alloc(%Id bytes free space rejected), %Id seg alloc and %Id condemned alloc, gen1 condemned alloc is %Id",
free_list_allocated, rejected_free_space, end_seg_allocated,
condemned_allocated, generation_condemned_allocated (generation_of (settings.condemned_generation))));
maxgen_size_increase* maxgen_size_info = &(get_gc_data_per_heap()->maxgen_size_info);
maxgen_size_info->free_list_allocated = free_list_allocated;
maxgen_size_info->free_list_rejected = rejected_free_space;
maxgen_size_info->end_seg_allocated = end_seg_allocated;
maxgen_size_info->condemned_allocated = condemned_allocated;
maxgen_size_info->pinned_allocated = maxgen_pinned_compact_before_advance;
maxgen_size_info->pinned_allocated_advance = generation_pinned_allocation_compact_size (generation_of (max_generation)) - maxgen_pinned_compact_before_advance;
#ifdef FREE_USAGE_STATS
int free_list_efficiency = 0;
if ((free_list_allocated + rejected_free_space) != 0)
free_list_efficiency = (int)(((float) (free_list_allocated) / (float)(free_list_allocated + rejected_free_space)) * (float)100);
int running_free_list_efficiency = (int)(generation_allocator_efficiency(older_gen)*100);
dprintf (1, ("gen%d free list alloc effi: %d%%, current effi: %d%%",
older_gen->gen_num,
free_list_efficiency, running_free_list_efficiency));
dprintf (1, ("gen2 free list change"));
for (int j = 0; j < NUM_GEN_POWER2; j++)
{
dprintf (1, ("[h%d][#%Id]: 2^%d: F: %Id->%Id(%Id), P: %Id",
heap_number,
settings.gc_index,
(j + 10), r_older_gen_free_space[j], older_gen->gen_free_spaces[j],
(ptrdiff_t)(r_older_gen_free_space[j] - older_gen->gen_free_spaces[j]),
(generation_of(max_generation - 1))->gen_plugs[j]));
}
#endif //FREE_USAGE_STATS
}
// 计算碎片空间大小fragmentation
// 这个是判断是否要压缩的依据之一
// 算法简略如下
// frag = (heap_segment_allocated(ephemeral_heap_segment) - generation_allocation_pointer (consing_gen))
// for segment in non_ephemeral_segments
// frag += heap_segment_allocated (seg) - heap_segment_plan_allocated (seg)
// for plug in dequed_plugs
// frag += plug.len
size_t fragmentation =
generation_fragmentation (generation_of (condemned_gen_number),
consing_gen,
heap_segment_allocated (ephemeral_heap_segment));
dprintf (2,("Fragmentation: %Id", fragmentation));
dprintf (2,("---- End of Plan phase ----"));
// 统计计划阶段的结束时间
#ifdef TIME_GC
finish = GetCycleCount32();
plan_time = finish - start;
#endif //TIME_GC
// We may update write barrier code. We assume here EE has been suspended if we are on a GC thread.
assert(GCHeap::IsGCInProgress());
// 是否要扩展(使用新的segment heap segment)
BOOL should_expand = FALSE;
// 是否要压缩
BOOL should_compact= FALSE;
ephemeral_promotion = FALSE;
// 如果内存太小应该强制开启压缩
#ifdef BIT64
if ((!settings.concurrent) &&
((condemned_gen_number < max_generation) &&
((settings.gen0_reduction_count > 0) || (settings.entry_memory_load >= 95))))
{
dprintf (2, ("gen0 reduction count is %d, condemning %d, mem load %d",
settings.gen0_reduction_count,
condemned_gen_number,
settings.entry_memory_load));
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact,
((settings.gen0_reduction_count > 0) ? compact_fragmented_gen0 : compact_high_mem_load));
// 如果ephemeal heap segment空间较少应该换一个新的segment
if ((condemned_gen_number >= (max_generation - 1)) &&
dt_low_ephemeral_space_p (tuning_deciding_expansion))
{
dprintf (2, ("Not enough space for all ephemeral generations with compaction"));
should_expand = TRUE;
}
}
else
{
#endif // BIT64
// 判断是否要压缩
// 请看下面函数decide_on_compacting的代码解释
should_compact = decide_on_compacting (condemned_gen_number, fragmentation, should_expand);
#ifdef BIT64
}
#endif // BIT64
// 判断是否要压缩大对象的堆
#ifdef FEATURE_LOH_COMPACTION
loh_compacted_p = FALSE;
#endif //FEATURE_LOH_COMPACTION
if (condemned_gen_number == max_generation)
{
#ifdef FEATURE_LOH_COMPACTION
if (settings.loh_compaction)
{
// 针对大对象的堆模拟压缩,和前面创建plug计算reloc的处理差不多,但是一个plug中只有一个对象,也不会有plug树
// 保存plug信息使用的类型是loh_obj_and_pad
if (plan_loh())
{
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_loh_forced);
loh_compacted_p = TRUE;
}
}
else
{
// 清空loh_pinned_queue
if ((heap_number == 0) && (loh_pinned_queue))
{
loh_pinned_queue_decay--;
if (!loh_pinned_queue_decay)
{
delete loh_pinned_queue;
loh_pinned_queue = 0;
}
}
}
// 如果不需要压缩大对象的堆,在这里执行清扫
// 把未标记的对象合并到一个free object并且加到free list中
// 请参考后面sweep phase的代码解释
if (!loh_compacted_p)
#endif //FEATURE_LOH_COMPACTION
{
#if defined(GC_PROFILING) || defined(FEATURE_EVENT_TRACE)
if (ShouldTrackMovementForProfilerOrEtw())
notify_profiler_of_surviving_large_objects();
#endif // defined(GC_PROFILING) || defined(FEATURE_EVENT_TRACE)
sweep_large_objects();
}
}
else
{
settings.loh_compaction = FALSE;
}
#ifdef MULTIPLE_HEAPS
// 如果存在多个heap(服务器GC)还需要投票重新决定should_compact和should_expand
// 这里的一些处理(例如删除大对象segment和设置settings.demotion)是服务器GC和工作站GC都会做的
new_heap_segment = NULL;
if (should_compact && should_expand)
gc_policy = policy_expand;
else if (should_compact)
gc_policy = policy_compact;
else
gc_policy = policy_sweep;
//vote for result of should_compact
dprintf (3, ("Joining for compaction decision"));
gc_t_join.join(this, gc_join_decide_on_compaction);
if (gc_t_join.joined())
{
// 删除空的(无存活对象的)大对象segment
//safe place to delete large heap segments
if (condemned_gen_number == max_generation)
{
for (int i = 0; i < n_heaps; i++)
{
g_heaps [i]->rearrange_large_heap_segments ();
}
}
settings.demotion = FALSE;
int pol_max = policy_sweep;
#ifdef GC_CONFIG_DRIVEN
BOOL is_compaction_mandatory = FALSE;
#endif //GC_CONFIG_DRIVEN
int i;
for (i = 0; i < n_heaps; i++)
{
if (pol_max < g_heaps[i]->gc_policy)
pol_max = policy_compact;
// set the demotion flag is any of the heap has demotion
if (g_heaps[i]->demotion_high >= g_heaps[i]->demotion_low)
{
(g_heaps[i]->get_gc_data_per_heap())->set_mechanism_bit (gc_demotion_bit);
settings.demotion = TRUE;
}
#ifdef GC_CONFIG_DRIVEN
if (!is_compaction_mandatory)
{
int compact_reason = (g_heaps[i]->get_gc_data_per_heap())->get_mechanism (gc_heap_compact);
if (compact_reason >= 0)
{
if (gc_heap_compact_reason_mandatory_p[compact_reason])
is_compaction_mandatory = TRUE;
}
}
#endif //GC_CONFIG_DRIVEN
}
#ifdef GC_CONFIG_DRIVEN
if (!is_compaction_mandatory)
{
// If compaction is not mandatory we can feel free to change it to a sweeping GC.
// Note that we may want to change this to only checking every so often instead of every single GC.
if (should_do_sweeping_gc (pol_max >= policy_compact))
{
pol_max = policy_sweep;
}
else
{
if (pol_max == policy_sweep)
pol_max = policy_compact;
}
}
#endif //GC_CONFIG_DRIVEN
for (i = 0; i < n_heaps; i++)
{
if (pol_max > g_heaps[i]->gc_policy)
g_heaps[i]->gc_policy = pol_max;
//get the segment while we are serialized
if (g_heaps[i]->gc_policy == policy_expand)
{
g_heaps[i]->new_heap_segment =
g_heaps[i]->soh_get_segment_to_expand();
if (!g_heaps[i]->new_heap_segment)
{
set_expand_in_full_gc (condemned_gen_number);
//we are out of memory, cancel the expansion
g_heaps[i]->gc_policy = policy_compact;
}
}
}
BOOL is_full_compacting_gc = FALSE;
if ((gc_policy >= policy_compact) && (condemned_gen_number == max_generation))
{
full_gc_counts[gc_type_compacting]++;
is_full_compacting_gc = TRUE;
}
for (i = 0; i < n_heaps; i++)
{
//copy the card and brick tables
if (g_card_table!= g_heaps[i]->card_table)
{
g_heaps[i]->copy_brick_card_table();
}
if (is_full_compacting_gc)
{
g_heaps[i]->loh_alloc_since_cg = 0;
}
}
//start all threads on the roots.
dprintf(3, ("Starting all gc threads after compaction decision"));
gc_t_join.restart();
}
//reset the local variable accordingly
should_compact = (gc_policy >= policy_compact);
should_expand = (gc_policy >= policy_expand);
#else //MULTIPLE_HEAPS
// 删除空的(无存活对象的)大对象segment
//safe place to delete large heap segments
if (condemned_gen_number == max_generation)
{
rearrange_large_heap_segments ();
}
// 如果有对象被降代,则设置settings.demotion = true
settings.demotion = ((demotion_high >= demotion_low) ? TRUE : FALSE);
if (settings.demotion)
get_gc_data_per_heap()->set_mechanism_bit (gc_demotion_bit);
// 如果压缩不是必须的,根据用户提供的特殊设置重新设置should_compact
#ifdef GC_CONFIG_DRIVEN
BOOL is_compaction_mandatory = FALSE;
int compact_reason = get_gc_data_per_heap()->get_mechanism (gc_heap_compact);
if (compact_reason >= 0)
is_compaction_mandatory = gc_heap_compact_reason_mandatory_p[compact_reason];
if (!is_compaction_mandatory)
{
if (should_do_sweeping_gc (should_compact))
should_compact = FALSE;
else
should_compact = TRUE;
}
#endif //GC_CONFIG_DRIVEN
if (should_compact && (condemned_gen_number == max_generation))
{
full_gc_counts[gc_type_compacting]++;
loh_alloc_since_cg = 0;
}
#endif //MULTIPLE_HEAPS
// 进入重定位和压缩阶段
if (should_compact)
{
dprintf (2,( "**** Doing Compacting GC ****"));
// 如果应该使用新的ephemeral heap segment,调用expand_heap
// expand_heap有可能会复用前面的segment,也有可能重新生成一个segment
if (should_expand)
{
#ifndef MULTIPLE_HEAPS
heap_segment* new_heap_segment = soh_get_segment_to_expand();
#endif //!MULTIPLE_HEAPS
if (new_heap_segment)
{
consing_gen = expand_heap(condemned_gen_number,
consing_gen,
new_heap_segment);
}
// If we couldn't get a new segment, or we were able to
// reserve one but no space to commit, we couldn't
// expand heap.
if (ephemeral_heap_segment != new_heap_segment)
{
set_expand_in_full_gc (condemned_gen_number);
should_expand = FALSE;
}
}
generation_allocation_limit (condemned_gen1) =
generation_allocation_pointer (condemned_gen1);
if ((condemned_gen_number < max_generation))
{
generation_allocator (older_gen)->commit_alloc_list_changes();
// 如果 generation_allocation_limit 等于 heap_segment_plan_allocated
// 设置 heap_segment_plan_allocated 等于 generation_allocation_pointer
// 设置 generation_allocation_limit 等于 generation_allocation_pointer
// 否则
// 在alloc_ptr到limit的空间创建一个free object, 不加入free list
// Fix the allocation area of the older generation
fix_older_allocation_area (older_gen);
}
assert (generation_allocation_segment (consing_gen) ==
ephemeral_heap_segment);
#if defined(GC_PROFILING) || defined(FEATURE_EVENT_TRACE)
if (ShouldTrackMovementForProfilerOrEtw())
{
record_survived_for_profiler(condemned_gen_number, first_condemned_address);
}
#endif // defined(GC_PROFILING) || defined(FEATURE_EVENT_TRACE)
// 调用重定位阶段
// 这里会修改所有需要移动的对象的指针地址,但是不会移动它们的内容
// 具体代码请看后面
relocate_phase (condemned_gen_number, first_condemned_address);
// 调用压缩阶段
// 这里会复制对象的内容到它们移动到的地址
// 具体代码请看后面
compact_phase (condemned_gen_number, first_condemned_address,
(!settings.demotion && settings.promotion));
// fix_generation_bounds做的事情如下
// - 应用各个代的计划代边界
// - generation_allocation_start (gen) = generation_plan_allocation_start (gen)
// - generation_allocation_pointer (gen) = 0;
// - generation_allocation_limit (gen) = 0;
// - 代边界的开始会留一段min_obj_size的空间,把这段空间变为free object
// - 如果ephemeral segment已改变则设置旧ephemeral segment的start到allocated的整个范围到Card Table
// - 设置ephemeral_heap_segment的allocated到plan_allocated
fix_generation_bounds (condemned_gen_number, consing_gen);
assert (generation_allocation_limit (youngest_generation) ==
generation_allocation_pointer (youngest_generation));
// 删除空的(无存活对象的)小对象segment
// 修复segment链表,如果ephemeral heap segment因为expand_heap改变了这里会重新正确的链接各个segment
// 修复segment的处理
// - 如果segment的next是null且堆段不是ephemeral segment, 则next = ephemeral segment
// - 如果segment是ephemeral_heap_segment并且有next, 则单独把这个segment抽出来(prev.next = next)
// - 调用delete_heap_segment删除无存活对象的segment
// - 设置heap_segment_allocated (seg) = heap_segment_plan_allocated (seg)
// - 如果segment不是ephemeral segment, 则调用decommit_heap_segment_pages释放allocated到committed的内存
if (condemned_gen_number >= (max_generation -1))
{
#ifdef MULTIPLE_HEAPS
// this needs be serialized just because we have one
// segment_standby_list/seg_table for all heaps. We should make it at least
// so that when hoarding is not on we don't need this join because
// decommitting memory can take a long time.
//must serialize on deleting segments
gc_t_join.join(this, gc_join_rearrange_segs_compaction);
if (gc_t_join.joined())
{
for (int i = 0; i < n_heaps; i++)
{
g_heaps[i]->rearrange_heap_segments(TRUE);
}
gc_t_join.restart();
}
#else
rearrange_heap_segments(TRUE);
#endif //MULTIPLE_HEAPS
// 重新设置第0代和第1代的generation_start_segment和generation_allocation_segment到新的ephemeral_heap_segment
if (should_expand)
{
//fix the start_segment for the ephemeral generations
for (int i = 0; i < max_generation; i++)
{
generation* gen = generation_of (i);
generation_start_segment (gen) = ephemeral_heap_segment;
generation_allocation_segment (gen) = ephemeral_heap_segment;
}
}
}
{
// 因为析构队列中的对象分代储存,这里根据升代或者降代移动析构队列中的对象
#ifdef FEATURE_PREMORTEM_FINALIZATION
finalize_queue->UpdatePromotedGenerations (condemned_gen_number,
(!settings.demotion && settings.promotion));
#endif // FEATURE_PREMORTEM_FINALIZATION
#ifdef MULTIPLE_HEAPS
dprintf(3, ("Joining after end of compaction"));
gc_t_join.join(this, gc_join_adjust_handle_age_compact);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
#ifdef MULTIPLE_HEAPS
//join all threads to make sure they are synchronized
dprintf(3, ("Restarting after Promotion granted"));
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
// 更新GC Handle表中记录的代数
// GcPromotionsGranted的处理:
// 调用 Ref_AgeHandles(condemned, max_gen, (uintptr_t)sc)
// GcDemote的处理:
// 调用 Ref_RejuvenateHandles (condemned, max_gen, (uintptr_t)sc)
// Ref_AgeHandles的处理:
// 扫描g_HandleTableMap中的HandleTable, 逐个调用 BlockAgeBlocks
// BlockAgeBlocks会增加rgGeneration+uBlock~uCount中的数字
// 0x00ffffff => 0x01ffffff => 0x02ffffff
// #define COMPUTE_AGED_CLUMPS(gen, msk) APPLY_CLUMP_ADDENDS(gen, COMPUTE_CLUMP_ADDENDS(gen, msk))
// #define COMPUTE_AGED_CLUMPS(gen, msk) gen + COMPUTE_CLUMP_ADDENDS(gen, msk)
// #define COMPUTE_AGED_CLUMPS(gen, msk) gen + MAKE_CLUMP_MASK_ADDENDS(COMPUTE_CLUMP_MASK(gen, msk))
// #define COMPUTE_AGED_CLUMPS(gen, msk) gen + MAKE_CLUMP_MASK_ADDENDS((((gen & GEN_CLAMP) - msk) & GEN_MASK))
// #define COMPUTE_AGED_CLUMPS(gen, msk) gen + (((((gen & GEN_CLAMP) - msk) & GEN_MASK)) >> GEN_INC_SHIFT)
// #define COMPUTE_AGED_CLUMPS(gen, msk) gen + (((((gen & 0x3F3F3F3F) - msk) & 0x40404040)) >> 6)
// #define GEN_FULLGC PREFOLD_FILL_INTO_AGEMASK(GEN_AGE_LIMIT)
// #define GEN_FULLGC PREFOLD_FILL_INTO_AGEMASK(0x3E3E3E3E)
// #define GEN_FULLGC (1 + (0x3E3E3E3E) + (~GEN_FILL))
// #define GEN_FULLGC (1 + (0x3E3E3E3E) + (~0x80808080))
// #define GEN_FULLGC 0xbfbfbfbe
// Ref_RejuvenateHandles的处理:
// 扫描g_HandleTableMap中的HandleTable, 逐个调用 BlockResetAgeMapForBlocks
// BlockAgeBlocks会减少rgGeneration+uBlock~uCount中的数字
// 取决于该block中的handle中最年轻的代数
// rgGeneration
// 一个block对应4 byte, 第一个byte代表该block中的GCHandle的代
ScanContext sc;
sc.thread_number = heap_number;
sc.promotion = FALSE;
sc.concurrent = FALSE;
// new generations bounds are set can call this guy
if (settings.promotion && !settings.demotion)
{
dprintf (2, ("Promoting EE roots for gen %d",
condemned_gen_number));
GCScan::GcPromotionsGranted(condemned_gen_number,
max_generation, &sc);
}
else if (settings.demotion)
{
dprintf (2, ("Demoting EE roots for gen %d",
condemned_gen_number));
GCScan::GcDemote (condemned_gen_number, max_generation, &sc);
}
}
// 把各个pinned plug前面的空余空间(出队后的len)变为free object并加到free list中
{
gen0_big_free_spaces = 0;
// 队列底部等于0
reset_pinned_queue_bos();
unsigned int gen_number = min (max_generation, 1 + condemned_gen_number);
generation* gen = generation_of (gen_number);
uint8_t* low = generation_allocation_start (generation_of (gen_number-1));
uint8_t* high = heap_segment_allocated (ephemeral_heap_segment);
while (!pinned_plug_que_empty_p())
{
// 出队
mark* m = pinned_plug_of (deque_pinned_plug());
size_t len = pinned_len (m);
uint8_t* arr = (pinned_plug (m) - len);
dprintf(3,("free [%Ix%Ix[ pin",
(size_t)arr, (size_t)arr + len));
if (len != 0)
{
// 在pinned plug前的空余空间创建free object
assert (len >= Align (min_obj_size));
make_unused_array (arr, len);
// fix fully contained bricks + first one
// if the array goes beyong the first brick
size_t start_brick = brick_of (arr);
size_t end_brick = brick_of (arr + len);
// 如果free object横跨多个brick,更新brick表
if (end_brick != start_brick)
{
dprintf (3,
("Fixing bricks [%Ix, %Ix[ to point to unused array %Ix",
start_brick, end_brick, (size_t)arr));
set_brick (start_brick,
arr - brick_address (start_brick));
size_t brick = start_brick+1;
while (brick < end_brick)
{
set_brick (brick, start_brick - brick);
brick++;
}
}
// 判断要加到哪个代的free list中
//when we take an old segment to make the new
//ephemeral segment. we can have a bunch of
//pinned plugs out of order going to the new ephemeral seg
//and then the next plugs go back to max_generation
if ((heap_segment_mem (ephemeral_heap_segment) <= arr) &&
(heap_segment_reserved (ephemeral_heap_segment) > arr))
{
while ((low <= arr) && (high > arr))
{
gen_number--;
assert ((gen_number >= 1) || (demotion_low != MAX_PTR) ||
settings.demotion || !settings.promotion);
dprintf (3, ("new free list generation %d", gen_number));
gen = generation_of (gen_number);
if (gen_number >= 1)
low = generation_allocation_start (generation_of (gen_number-1));
else
low = high;
}
}
else
{
dprintf (3, ("new free list generation %d", max_generation));
gen_number = max_generation;
gen = generation_of (gen_number);
}
// 加到free list中
dprintf(3,("threading it into generation %d", gen_number));
thread_gap (arr, len, gen);
add_gen_free (gen_number, len);
}
}
}
#ifdef _DEBUG
for (int x = 0; x <= max_generation; x++)
{
assert (generation_allocation_start (generation_of (x)));
}
#endif //_DEBUG
// 如果已经升代了,原来gen 0的对象会变为gen 1
// 清理当前gen 1在Card Table中的标记
if (!settings.demotion && settings.promotion)
{
//clear card for generation 1. generation 0 is empty
clear_card_for_addresses (
generation_allocation_start (generation_of (1)),
generation_allocation_start (generation_of (0)));
}
// 如果已经升代了,确认代0的只包含一个对象(一个最小大小的free object)
if (settings.promotion && !settings.demotion)
{
uint8_t* start = generation_allocation_start (youngest_generation);
MAYBE_UNUSED_VAR(start);
assert (heap_segment_allocated (ephemeral_heap_segment) ==
(start + Align (size (start))));
}
}
// 进入清扫阶段
// 清扫阶段的关键处理在make_free_lists中,目前你看不到叫`sweep_phase`的函数,这里就是sweep phase
else
{
// 清扫阶段必须升代
//force promotion for sweep
settings.promotion = TRUE;
settings.compaction = FALSE;
ScanContext sc;
sc.thread_number = heap_number;
sc.promotion = FALSE;
sc.concurrent = FALSE;
dprintf (2, ("**** Doing Mark and Sweep GC****"));
// 恢复对旧代成员的备份
if ((condemned_gen_number < max_generation))
{
generation_allocator (older_gen)->copy_from_alloc_list (r_free_list);
generation_free_list_space (older_gen) = r_free_list_space;
generation_free_obj_space (older_gen) = r_free_obj_space;
generation_free_list_allocated (older_gen) = r_older_gen_free_list_allocated;
generation_end_seg_allocated (older_gen) = r_older_gen_end_seg_allocated;
generation_condemned_allocated (older_gen) = r_older_gen_condemned_allocated;
generation_allocation_limit (older_gen) = r_allocation_limit;
generation_allocation_pointer (older_gen) = r_allocation_pointer;
generation_allocation_context_start_region (older_gen) = r_allocation_start_region;
generation_allocation_segment (older_gen) = r_allocation_segment;
}
// 如果 generation_allocation_limit 等于 heap_segment_plan_allocated
// 设置 heap_segment_plan_allocated 等于 generation_allocation_pointer
// 设置 generation_allocation_limit 等于 generation_allocation_pointer
// 否则
// 在alloc_ptr到limit的空间创建一个free object, 不加入free list
if ((condemned_gen_number < max_generation))
{
// Fix the allocation area of the older generation
fix_older_allocation_area (older_gen);
}
#if defined(GC_PROFILING) || defined(FEATURE_EVENT_TRACE)
if (ShouldTrackMovementForProfilerOrEtw())
{
record_survived_for_profiler(condemned_gen_number, first_condemned_address);
}
#endif // defined(GC_PROFILING) || defined(FEATURE_EVENT_TRACE)
// 把不使用的空间变为free object并存到free list
gen0_big_free_spaces = 0;
make_free_lists (condemned_gen_number);
// 恢复在saved_pre_plug和saved_post_plug保存的原始数据
recover_saved_pinned_info();
// 因为析构队列中的对象分代储存,这里根据升代或者降代移动析构队列中的对象
#ifdef FEATURE_PREMORTEM_FINALIZATION
finalize_queue->UpdatePromotedGenerations (condemned_gen_number, TRUE);
#endif // FEATURE_PREMORTEM_FINALIZATION
// MTHTS: leave single thread for HT processing on plan_phase
#ifdef MULTIPLE_HEAPS
dprintf(3, ("Joining after end of sweep"));
gc_t_join.join(this, gc_join_adjust_handle_age_sweep);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
// 更新GCHandle表中记录的代数
GCScan::GcPromotionsGranted(condemned_gen_number,
max_generation, &sc);
// 删除空的(无存活对象的)小对象segment和修复segment链表
// 上面有详细的注释
if (condemned_gen_number >= (max_generation -1))
{
#ifdef MULTIPLE_HEAPS
for (int i = 0; i < n_heaps; i++)
{
g_heaps[i]->rearrange_heap_segments(FALSE);
}
#else
rearrange_heap_segments(FALSE);
#endif //MULTIPLE_HEAPS
}
#ifdef MULTIPLE_HEAPS
//join all threads to make sure they are synchronized
dprintf(3, ("Restarting after Promotion granted"));
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
#ifdef _DEBUG
for (int x = 0; x <= max_generation; x++)
{
assert (generation_allocation_start (generation_of (x)));
}
#endif //_DEBUG
// 因为已经升代了,原来gen 0的对象会变为gen 1
// 清理当前gen 1在Card Table中的标记
//clear card for generation 1. generation 0 is empty
clear_card_for_addresses (
generation_allocation_start (generation_of (1)),
generation_allocation_start (generation_of (0)));
assert ((heap_segment_allocated (ephemeral_heap_segment) ==
(generation_allocation_start (youngest_generation) +
Align (min_obj_size))));
}
//verify_partial();
}
process_ephemeral_boundaries
函数的代码:
如果当前模拟的segment是ephemeral heap segment,这个函数会在模拟当前plug的压缩前调用决定计划代边界
void gc_heap::process_ephemeral_boundaries (uint8_t* x,
int& active_new_gen_number,
int& active_old_gen_number,
generation*& consing_gen,
BOOL& allocate_in_condemned)
{
retry:
// 判断是否要设置计划代边界
// 例如当前启用升代
// - active_old_gen_number是1,active_new_gen_number是2
// - 判断plug属于gen 0的时候会计划gen 1(active_new_gen_number--)的边界
// 例如当前不启用升代
// - active_old_gen_number是1,active_new_gen_number是1
// - 判断plug属于gen 0的时候会计划gen 0(active_new_gen_number--)的边界
if ((active_old_gen_number > 0) &&
(x >= generation_allocation_start (generation_of (active_old_gen_number - 1))))
{
dprintf (1, ("crossing gen%d, x is %Ix", active_old_gen_number - 1, x));
if (!pinned_plug_que_empty_p())
{
dprintf (1, ("oldest pin: %Ix(%Id)",
pinned_plug (oldest_pin()),
(x - pinned_plug (oldest_pin()))));
}
// 如果升代
// active_old_gen_number: 2 => 1 => 0
// active_new_gen_number: 2 => 2 => 1
// 如果不升代
// active_old_gen_number: 2 => 1 => 0
// active_new_gen_number: 2 => 1 => 0
if (active_old_gen_number <= (settings.promotion ? (max_generation - 1) : max_generation))
{
active_new_gen_number--;
}
active_old_gen_number--;
assert ((!settings.promotion) || (active_new_gen_number>0));
if (active_new_gen_number == (max_generation - 1))
{
// 打印和设置统计信息
#ifdef FREE_USAGE_STATS
if (settings.condemned_generation == max_generation)
{
// We need to do this before we skip the rest of the pinned plugs.
generation* gen_2 = generation_of (max_generation);
generation* gen_1 = generation_of (max_generation - 1);
size_t total_num_pinned_free_spaces_left = 0;
// We are about to allocate gen1, check to see how efficient fitting in gen2 pinned free spaces is.
for (int j = 0; j < NUM_GEN_POWER2; j++)
{
dprintf (1, ("[h%d][#%Id]2^%d: current: %Id, S: 2: %Id, 1: %Id(%Id)",
heap_number,
settings.gc_index,
(j + 10),
gen_2->gen_current_pinned_free_spaces[j],
gen_2->gen_plugs[j], gen_1->gen_plugs[j],
(gen_2->gen_plugs[j] + gen_1->gen_plugs[j])));
total_num_pinned_free_spaces_left += gen_2->gen_current_pinned_free_spaces[j];
}
float pinned_free_list_efficiency = 0;
size_t total_pinned_free_space = generation_allocated_in_pinned_free (gen_2) + generation_pinned_free_obj_space (gen_2);
if (total_pinned_free_space != 0)
{
pinned_free_list_efficiency = (float)(generation_allocated_in_pinned_free (gen_2)) / (float)total_pinned_free_space;
}
dprintf (1, ("[h%d] gen2 allocated %Id bytes with %Id bytes pinned free spaces (effi: %d%%), %Id (%Id) left",
heap_number,
generation_allocated_in_pinned_free (gen_2),
total_pinned_free_space,
(int)(pinned_free_list_efficiency * 100),
generation_pinned_free_obj_space (gen_2),
total_num_pinned_free_spaces_left));
}
#endif //FREE_USAGE_STATS
// 出队mark_stack_array中不属于ephemeral heap segment的pinned plug,不能让它们降代
//Go past all of the pinned plugs for this generation.
while (!pinned_plug_que_empty_p() &&
(!in_range_for_segment ((pinned_plug (oldest_pin())), ephemeral_heap_segment)))
{
size_t entry = deque_pinned_plug();
mark* m = pinned_plug_of (entry);
uint8_t* plug = pinned_plug (m);
size_t len = pinned_len (m);
// detect pinned block in different segment (later) than
// allocation segment, skip those until the oldest pin is in the ephemeral seg.
// adjust the allocation segment along the way (at the end it will
// be the ephemeral segment.
heap_segment* nseg = heap_segment_in_range (generation_allocation_segment (consing_gen));
PREFIX_ASSUME(nseg != NULL);
while (!((plug >= generation_allocation_pointer (consing_gen))&&
(plug < heap_segment_allocated (nseg))))
{
//adjust the end of the segment to be the end of the plug
assert (generation_allocation_pointer (consing_gen)>=
heap_segment_mem (nseg));
assert (generation_allocation_pointer (consing_gen)<=
heap_segment_committed (nseg));
heap_segment_plan_allocated (nseg) =
generation_allocation_pointer (consing_gen);
//switch allocation segment
nseg = heap_segment_next_rw (nseg);
generation_allocation_segment (consing_gen) = nseg;
//reset the allocation pointer and limits
generation_allocation_pointer (consing_gen) =
heap_segment_mem (nseg);
}
set_new_pin_info (m, generation_allocation_pointer (consing_gen));
assert(pinned_len(m) == 0 || pinned_len(m) >= Align(min_obj_size));
generation_allocation_pointer (consing_gen) = plug + len;
generation_allocation_limit (consing_gen) =
generation_allocation_pointer (consing_gen);
}
allocate_in_condemned = TRUE;
consing_gen = ensure_ephemeral_heap_segment (consing_gen);
}
// active_new_gen_number不等于gen2的时候计划它的边界
// gen2的边界不会在这里计划,而是在前面(allocate_first_generation_start)
if (active_new_gen_number != max_generation)
{
// 防止降代的时候把所有pinned plug出队
if (active_new_gen_number == (max_generation - 1))
{
maxgen_pinned_compact_before_advance = generation_pinned_allocation_compact_size (generation_of (max_generation));
if (!demote_gen1_p)
advance_pins_for_demotion (consing_gen);
}
// 根据当前的generaion_allocation_pointer(alloc_ptr)计划代边界
plan_generation_start (generation_of (active_new_gen_number), consing_gen, x);
dprintf (1, ("process eph: allocated gen%d start at %Ix",
active_new_gen_number,
generation_plan_allocation_start (generation_of (active_new_gen_number))));
// 如果队列中仍然有pinned plug
if ((demotion_low == MAX_PTR) && !pinned_plug_que_empty_p())
{
// 并且最老(最左边)的pinned plug的代数不是0的时候
uint8_t* pplug = pinned_plug (oldest_pin());
if (object_gennum (pplug) > 0)
{
// 表示从这个pinned plug和后面的pinned plug都被降代了
// 设置降代范围
demotion_low = pplug;
dprintf (3, ("process eph: dlow->%Ix", demotion_low));
}
}
assert (generation_plan_allocation_start (generation_of (active_new_gen_number)));
}
goto retry;
}
}
gc_heap::plan_generation_start
函数的代码如下:
根据当前的generaion_allocation_pointer(alloc_ptr)计划代边界
void gc_heap::plan_generation_start (generation* gen, generation* consing_gen, uint8_t* next_plug_to_allocate)
{
// 特殊处理
// 如果某些pinned plug很大(大于demotion_plug_len_th(6MB)),把它们出队防止降代
#ifdef BIT64
// We should never demote big plugs to gen0.
if (gen == youngest_generation)
{
heap_segment* seg = ephemeral_heap_segment;
size_t mark_stack_large_bos = mark_stack_bos;
size_t large_plug_pos = 0;
while (mark_stack_large_bos < mark_stack_tos)
{
if (mark_stack_array[mark_stack_large_bos].len > demotion_plug_len_th)
{
while (mark_stack_bos <= mark_stack_large_bos)
{
size_t entry = deque_pinned_plug();
size_t len = pinned_len (pinned_plug_of (entry));
uint8_t* plug = pinned_plug (pinned_plug_of(entry));
if (len > demotion_plug_len_th)
{
dprintf (2, ("ps(%d): S %Ix (%Id)(%Ix)", gen->gen_num, plug, len, (plug+len)));
}
pinned_len (pinned_plug_of (entry)) = plug - generation_allocation_pointer (consing_gen);
assert(mark_stack_array[entry].len == 0 ||
mark_stack_array[entry].len >= Align(min_obj_size));
generation_allocation_pointer (consing_gen) = plug + len;
generation_allocation_limit (consing_gen) = heap_segment_plan_allocated (seg);
set_allocator_next_pin (consing_gen);
}
}
mark_stack_large_bos++;
}
}
#endif // BIT64
// 在当前consing_gen的generation_allocation_ptr创建一个最小的对象
// 以这个对象的开始地址作为计划代边界
// 这里的处理是保证代与代之间最少有一个对象(初始化代的时候也会这样保证)
generation_plan_allocation_start (gen) =
allocate_in_condemned_generations (consing_gen, Align (min_obj_size), -1);
// 压缩后会根据这个大小把这里的空间变为一个free object
generation_plan_allocation_start_size (gen) = Align (min_obj_size);
// 如果接下来的空间很小(小于min_obj_size),则把接下来的空间也加到上面的初始对象里
size_t allocation_left = (size_t)(generation_allocation_limit (consing_gen) - generation_allocation_pointer (consing_gen));
if (next_plug_to_allocate)
{
size_t dist_to_next_plug = (size_t)(next_plug_to_allocate - generation_allocation_pointer (consing_gen));
if (allocation_left > dist_to_next_plug)
{
allocation_left = dist_to_next_plug;
}
}
if (allocation_left < Align (min_obj_size))
{
generation_plan_allocation_start_size (gen) += allocation_left;
generation_allocation_pointer (consing_gen) += allocation_left;
}
dprintf (1, ("plan alloc gen%d(%Ix) start at %Ix (ptr: %Ix, limit: %Ix, next: %Ix)", gen->gen_num,
generation_plan_allocation_start (gen),
generation_plan_allocation_start_size (gen),
generation_allocation_pointer (consing_gen), generation_allocation_limit (consing_gen),
next_plug_to_allocate));
}
gc_heap::plan_generation_starts
函数的代码如下:
这个函数会在模拟压缩所有对象后调用,用于计划剩余的代边界,如果启用了升代这里会计划gen 0的边界
void gc_heap::plan_generation_starts (generation*& consing_gen)
{
//make sure that every generation has a planned allocation start
int gen_number = settings.condemned_generation;
while (gen_number >= 0)
{
// 因为不能把gen 1和gen 0的边界放到其他segment中
// 这里需要确保consing_gen的allocation segment是ephemeral heap segment
if (gen_number < max_generation)
{
consing_gen = ensure_ephemeral_heap_segment (consing_gen);
}
// 如果这个代的边界尚未计划,则执行计划
generation* gen = generation_of (gen_number);
if (0 == generation_plan_allocation_start (gen))
{
plan_generation_start (gen, consing_gen, 0);
assert (generation_plan_allocation_start (gen));
}
gen_number--;
}
// 设置ephemeral heap segment的计划已分配大小
// now we know the planned allocation size
heap_segment_plan_allocated (ephemeral_heap_segment) =
generation_allocation_pointer (consing_gen);
}
gc_heap::generation_fragmentation
函数的代码如下:
size_t gc_heap::generation_fragmentation (generation* gen,
generation* consing_gen,
uint8_t* end)
{
size_t frag;
// 判断是否所有对象都压缩到了ephemeral heap segment之前
uint8_t* alloc = generation_allocation_pointer (consing_gen);
// If the allocation pointer has reached the ephemeral segment
// fine, otherwise the whole ephemeral segment is considered
// fragmentation
if (in_range_for_segment (alloc, ephemeral_heap_segment))
{
// 原allocated - 模拟压缩的结尾allocation_pointer
if (alloc <= heap_segment_allocated(ephemeral_heap_segment))
frag = end - alloc;
else
{
// 无一个对象存活,已经把allocated设到开始地址
// case when no survivors, allocated set to beginning
frag = 0;
}
dprintf (3, ("ephemeral frag: %Id", frag));
}
else
// 所有对象都压缩到了ephemeral heap segment之前
// 添加整个范围到frag
frag = (heap_segment_allocated (ephemeral_heap_segment) -
heap_segment_mem (ephemeral_heap_segment));
heap_segment* seg = heap_segment_rw (generation_start_segment (gen));
PREFIX_ASSUME(seg != NULL);
// 添加其他segment的原allocated - 计划allcated
while (seg != ephemeral_heap_segment)
{
frag += (heap_segment_allocated (seg) -
heap_segment_plan_allocated (seg));
dprintf (3, ("seg: %Ix, frag: %Id", (size_t)seg,
(heap_segment_allocated (seg) -
heap_segment_plan_allocated (seg))));
seg = heap_segment_next_rw (seg);
assert (seg);
}
// 添加所有pinned plug前面的空余空间
dprintf (3, ("frag: %Id discounting pinned plugs", frag));
//add the length of the dequeued plug free space
size_t bos = 0;
while (bos < mark_stack_bos)
{
frag += (pinned_len (pinned_plug_of (bos)));
bos++;
}
return frag;
}
gc_heap::decide_on_compacting
函数的代码如下:
BOOL gc_heap::decide_on_compacting (int condemned_gen_number,
size_t fragmentation,
BOOL& should_expand)
{
BOOL should_compact = FALSE;
should_expand = FALSE;
generation* gen = generation_of (condemned_gen_number);
dynamic_data* dd = dynamic_data_of (condemned_gen_number);
size_t gen_sizes = generation_sizes(gen);
// 碎片空间大小 / 收集代的大小(包括更年轻的代)
float fragmentation_burden = ( ((0 == fragmentation) || (0 == gen_sizes)) ? (0.0f) :
(float (fragmentation) / gen_sizes) );
dprintf (GTC_LOG, ("fragmentation: %Id (%d%%)", fragmentation, (int)(fragmentation_burden * 100.0)));
// 由Stress GC决定是否压缩
#ifdef STRESS_HEAP
// for pure GC stress runs we need compaction, for GC stress "mix"
// we need to ensure a better mix of compacting and sweeping collections
if (GCStress<cfg_any>::IsEnabled() && !settings.concurrent
&& !g_pConfig->IsGCStressMix())
should_compact = TRUE;
// 由Stress GC决定是否压缩
// 如果压缩次数不够清扫次数的十分之一则开启压缩
#ifdef GC_STATS
// in GC stress "mix" mode, for stress induced collections make sure we
// keep sweeps and compactions relatively balanced. do not (yet) force sweeps
// against the GC's determination, as it may lead to premature OOMs.
if (g_pConfig->IsGCStressMix() && settings.stress_induced)
{
int compactions = g_GCStatistics.cntCompactFGC+g_GCStatistics.cntCompactNGC;
int sweeps = g_GCStatistics.cntFGC + g_GCStatistics.cntNGC - compactions;
if (compactions < sweeps / 10)
{
should_compact = TRUE;
}
}
#endif // GC_STATS
#endif //STRESS_HEAP
// 判断是否强制压缩
if (g_pConfig->GetGCForceCompact())
should_compact = TRUE;
// 是否因为OOM(Out Of Memory)导致的GC,如果是则开启压缩
if ((condemned_gen_number == max_generation) && last_gc_before_oom)
{
should_compact = TRUE;
last_gc_before_oom = FALSE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_last_gc);
}
// gc原因中有压缩
if (settings.reason == reason_induced_compacting)
{
dprintf (2, ("induced compacting GC"));
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_induced_compacting);
}
dprintf (2, ("Fragmentation: %d Fragmentation burden %d%%",
fragmentation, (int) (100*fragmentation_burden)));
// 如果ephemeral heap segment的空间较少则开启压缩
if (!should_compact)
{
if (dt_low_ephemeral_space_p (tuning_deciding_compaction))
{
dprintf(GTC_LOG, ("compacting due to low ephemeral"));
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_low_ephemeral);
}
}
// 如果ephemeral heap segment的空间较少,并且当前不是Full GC还需要使用新的ephemeral heap segment
if (should_compact)
{
if ((condemned_gen_number >= (max_generation - 1)))
{
if (dt_low_ephemeral_space_p (tuning_deciding_expansion))
{
dprintf (GTC_LOG,("Not enough space for all ephemeral generations with compaction"));
should_expand = TRUE;
}
}
}
#ifdef BIT64
BOOL high_memory = FALSE;
#endif // BIT64
// 根据碎片空间大小判断
if (!should_compact)
{
// We are not putting this in dt_high_frag_p because it's not exactly
// high fragmentation - it's just enough planned fragmentation for us to
// want to compact. Also the "fragmentation" we are talking about here
// is different from anywhere else.
// 碎片空间大小 >= dd_fragmentation_limit 或者
// 碎片空间大小 / 收集代的大小(包括更年轻的代) >= dd_fragmentation_burden_limit 时开启压缩
// 作者机器上的dd_fragmentation_limit是200000, dd_fragmentation_burden_limit是0.25
BOOL frag_exceeded = ((fragmentation >= dd_fragmentation_limit (dd)) &&
(fragmentation_burden >= dd_fragmentation_burden_limit (dd)));
if (frag_exceeded)
{
#ifdef BACKGROUND_GC
// do not force compaction if this was a stress-induced GC
IN_STRESS_HEAP(if (!settings.stress_induced))
{
#endif // BACKGROUND_GC
assert (settings.concurrent == FALSE);
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_high_frag);
#ifdef BACKGROUND_GC
}
#endif // BACKGROUND_GC
}
// 如果占用内存过高则启用压缩
#ifdef BIT64
// check for high memory situation
if(!should_compact)
{
uint32_t num_heaps = 1;
#ifdef MULTIPLE_HEAPS
num_heaps = gc_heap::n_heaps;
#endif // MULTIPLE_HEAPS
ptrdiff_t reclaim_space = generation_size(max_generation) - generation_plan_size(max_generation);
if((settings.entry_memory_load >= high_memory_load_th) && (settings.entry_memory_load < v_high_memory_load_th))
{
if(reclaim_space > (int64_t)(min_high_fragmentation_threshold (entry_available_physical_mem, num_heaps)))
{
dprintf(GTC_LOG,("compacting due to fragmentation in high memory"));
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_high_mem_frag);
}
high_memory = TRUE;
}
else if(settings.entry_memory_load >= v_high_memory_load_th)
{
if(reclaim_space > (ptrdiff_t)(min_reclaim_fragmentation_threshold (num_heaps)))
{
dprintf(GTC_LOG,("compacting due to fragmentation in very high memory"));
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_vhigh_mem_frag);
}
high_memory = TRUE;
}
}
#endif // BIT64
}
// 测试是否可以在ephemeral_heap_segment.allocated后面提交一段内存(从系统获取一块物理内存)
// 如果失败则启用压缩
allocated (ephemeral_heap_segment);
size_t size = Align (min_obj_size)*(condemned_gen_number+1);
// The purpose of calling ensure_gap_allocation here is to make sure
// that we actually are able to commit the memory to allocate generation
// starts.
if ((should_compact == FALSE) &&
(ensure_gap_allocation (condemned_gen_number) == FALSE))
{
should_compact = TRUE;
get_gc_data_per_heap()->set_mechanism (gc_heap_compact, compact_no_gaps);
}
// 如果这次Full GC的效果比较差
// 需要减少Full GC的频率,should_lock_elevation可以把Full GC变为gen 1 GC
if (settings.condemned_generation == max_generation)
{
//check the progress
if (
#ifdef BIT64
(high_memory && !should_compact) ||
#endif // BIT64
(generation_plan_allocation_start (generation_of (max_generation - 1)) >=
generation_allocation_start (generation_of (max_generation - 1))))
{
dprintf (2, (" Elevation: gen2 size: %d, gen2 plan size: %d, no progress, elevation = locked",
generation_size (max_generation),
generation_plan_size (max_generation)));
//no progress -> lock
settings.should_lock_elevation = TRUE;
}
}
// 如果启用了NoGCRegion但是仍然启用了GC代表这是无法从SOH(Small Object Heap)或者LOH分配到内存导致的,需要启用压缩
if (settings.pause_mode == pause_no_gc)
{
should_compact = TRUE;
// 如果ephemeral heap segement压缩后的剩余空间不足还需要设置新的ephemeral heap segment
if ((size_t)(heap_segment_reserved (ephemeral_heap_segment) - heap_segment_plan_allocated (ephemeral_heap_segment))
< soh_allocation_no_gc)
{
should_expand = TRUE;
}
}
dprintf (2, ("will %s", (should_compact ? "compact" : "sweep")));
return should_compact;
}
计划阶段在模拟压缩和判断后会在内部包含重定位阶段(relocate_phase),压缩阶段(compact_phase)和清扫阶段(sweep_phase)的处理,
接下来我们仔细分析一下这三个阶段做了什么事情:
重定位阶段(relocate_phase)
重定位阶段的主要工作是修改对象的指针地址,例如A.Member的Member内存移动后,A中指向Member的指针地址也需要改变。
重定位阶段只会修改指针地址,复制内存会交给下面的压缩阶段(compact_phase)完成。
如下图:
图中对象A和对象B引用了对象C,重定位后各个对象还在原来的位置,只是成员的地址(指针)变化了。
还记得之前标记阶段(mark_phase)使用的GcScanRoots
等扫描函数吗?
这些扫描函数同样会在重定位阶段使用,只是执行的不是GCHeap::Promote
而是GCHeap::Relocate
。
重定位对象会借助计划阶段(plan_phase)构建的brick table
和plug树来进行快速的定位,然后对指针地址移动所属plug的reloc
位置。
重定位阶段(relocate_phase)的代码
gc_heap::relocate_phase
函数的代码如下:
void gc_heap::relocate_phase (int condemned_gen_number,
uint8_t* first_condemned_address)
{
// 生成扫描上下文
ScanContext sc;
sc.thread_number = heap_number;
sc.promotion = FALSE;
sc.concurrent = FALSE;
// 统计重定位阶段的开始时间
#ifdef TIME_GC
unsigned start;
unsigned finish;
start = GetCycleCount32();
#endif //TIME_GC
// %type% category = quote (relocate);
dprintf (2,("---- Relocate phase -----"));
#ifdef MULTIPLE_HEAPS
//join all threads to make sure they are synchronized
dprintf(3, ("Joining after end of plan"));
gc_t_join.join(this, gc_join_begin_relocate_phase);
if (gc_t_join.joined())
#endif //MULTIPLE_HEAPS
{
#ifdef MULTIPLE_HEAPS
//join all threads to make sure they are synchronized
dprintf(3, ("Restarting for relocation"));
gc_t_join.restart();
#endif //MULTIPLE_HEAPS
}
// 扫描根对象(各个线程中栈和寄存器中的对象)
// 对扫描到的各个对象调用`GCHeap::Relocate`函数
// 注意`GCHeap::Relocate`函数不会重定位子对象,这里只是用来重定位来源于根对象的引用
dprintf(3,("Relocating roots"));
GCScan::GcScanRoots(GCHeap::Relocate,
condemned_gen_number, max_generation, &sc);
verify_pins_with_post_plug_info("after reloc stack");
#ifdef BACKGROUND_GC
if (recursive_gc_sync::background_running_p())
{
scan_background_roots (GCHeap::Relocate, heap_number, &sc);
}
#endif //BACKGROUND_GC
// 非Full GC时,遍历Card Table重定位小对象
// 同上,`gc_heap::relocate_address`函数不会重定位子对象,这里只是用来重定位来源于旧代的引用
if (condemned_gen_number != max_generation)
{
dprintf(3,("Relocating cross generation pointers"));
mark_through_cards_for_segments (&gc_heap::relocate_address, TRUE);
verify_pins_with_post_plug_info("after reloc cards");
}
// 非Full GC时,遍历Card Table重定位大对象
// 同上,`gc_heap::relocate_address`函数不会重定位子对象,这里只是用来重定位来源于旧代的引用
if (condemned_gen_number != max_generation)
{
dprintf(3,("Relocating cross generation pointers for large objects"));
mark_through_cards_for_large_objects (&gc_heap::relocate_address, TRUE);
}
else
{
// Full GC时,如果启用了大对象压缩则压缩大对象的堆
#ifdef FEATURE_LOH_COMPACTION
if (loh_compacted_p)
{
assert (settings.condemned_generation == max_generation);
relocate_in_loh_compact();
}
else
#endif //FEATURE_LOH_COMPACTION
{
relocate_in_large_objects ();
}
}
// 重定位存活下来的对象中的引用(收集代中的对象)
// 枚举brick table对各个plug中的对象调用`relocate_obj_helper`重定位它们的成员
{
dprintf(3,("Relocating survivors"));
relocate_survivors (condemned_gen_number,
first_condemned_address);
}
// 扫描在析构队列中的对象
#ifdef FEATURE_PREMORTEM_FINALIZATION
dprintf(3,("Relocating finalization data"));
finalize_queue->RelocateFinalizationData (condemned_gen_number,
__this);
#endif // FEATURE_PREMORTEM_FINALIZATION
// 扫描在GC Handle表中的对象
// MTHTS
{
dprintf(3,("Relocating handle table"));
GCScan::GcScanHandles(GCHeap::Relocate,
condemned_gen_number, max_generation, &sc);
}
#ifdef MULTIPLE_HEAPS
//join all threads to make sure they are synchronized
dprintf(3, ("Joining after end of relocation"));
gc_t_join.join(this, gc_join_relocate_phase_done);
#endif //MULTIPLE_HEAPS
// 统计重定位阶段的结束时间
#ifdef TIME_GC
finish = GetCycleCount32();
reloc_time = finish - start;
#endif //TIME_GC
dprintf(2,( "---- End of Relocate phase ----"));
}
GCHeap::Relocate
函数的代码如下:
// ppObject是保存对象地址的地址,例如&A.Member
void GCHeap::Relocate (Object** ppObject, ScanContext* sc,
uint32_t flags)
{
UNREFERENCED_PARAMETER(sc);
// 对象的地址
uint8_t* object = (uint8_t*)(Object*)(*ppObject);
THREAD_NUMBER_FROM_CONTEXT;
//dprintf (3, ("Relocate location %Ix\n", (size_t)ppObject));
dprintf (3, ("R: %Ix", (size_t)ppObject));
// 空指针不处理
if (object == 0)
return;
// 获取对象所属的gc_heap
gc_heap* hp = gc_heap::heap_of (object);
// 验证对象是否合法,除错用
// 如果object不一定是对象的开始地址,则不做验证
#ifdef _DEBUG
if (!(flags & GC_CALL_INTERIOR))
{
// We cannot validate this object if it's in the condemned gen because it could
// be one of the objects that were overwritten by an artificial gap due to a pinned plug.
if (!((object >= hp->gc_low) && (object < hp->gc_high)))
{
((CObjectHeader*)object)->Validate(FALSE);
}
}
#endif //_DEBUG
dprintf (3, ("Relocate %Ix\n", (size_t)object));
uint8_t* pheader;
// 如果object不一定是对象的开始地址,找到对象的开始地址并重定位该开始地址,然后修改ppObject
// 例如object是0x10000008,对象的开始地址是0x10000000,重定位后是0x0fff0000则*ppObject会设为0x0fff0008
if ((flags & GC_CALL_INTERIOR) && gc_heap::settings.loh_compaction)
{
if (!((object >= hp->gc_low) && (object < hp->gc_high)))
{
return;
}
if (gc_heap::loh_object_p (object))
{
pheader = hp->find_object (object, 0);
if (pheader == 0)
{
return;
}
ptrdiff_t ref_offset = object - pheader;
hp->relocate_address(&pheader THREAD_NUMBER_ARG);
*ppObject = (Object*)(pheader + ref_offset);
return;
}
}
// 如果object是对象的开始地址则重定位object
{
pheader = object;
hp->relocate_address(&pheader THREAD_NUMBER_ARG);
*ppObject = (Object*)pheader;
}
STRESS_LOG_ROOT_RELOCATE(ppObject, object, pheader, ((!(flags & GC_CALL_INTERIOR)) ? ((Object*)object)->GetGCSafeMethodTable() : 0));
}
gc_heap::relocate_address
函数的代码如下:
void gc_heap::relocate_address (uint8_t** pold_address THREAD_NUMBER_DCL)
{
// 不在本次gc回收范围内的对象指针不需要移动
uint8_t* old_address = *pold_address;
if (!((old_address >= gc_low) && (old_address < gc_high)))
#ifdef MULTIPLE_HEAPS
{
UNREFERENCED_PARAMETER(thread);
if (old_address == 0)
return;
gc_heap* hp = heap_of (old_address);
if ((hp == this) ||
!((old_address >= hp->gc_low) && (old_address < hp->gc_high)))
return;
}
#else //MULTIPLE_HEAPS
return ;
#endif //MULTIPLE_HEAPS
// 根据对象找到对应的brick
// delta translates old_address into address_gc (old_address);
size_t brick = brick_of (old_address);
int brick_entry = brick_table [ brick ];
uint8_t* new_address = old_address;
if (! ((brick_entry == 0)))
{
retry:
{
// 如果是负数则向前继续找
while (brick_entry < 0)
{
brick = (brick + brick_entry);
brick_entry = brick_table [ brick ];
}
uint8_t* old_loc = old_address;
// 根据plug树搜索对象所在的plug
uint8_t* node = tree_search ((brick_address (brick) + brick_entry-1),
old_loc);
// 找到时确定新的地址,找不到时继续找前面的brick(有可能在上一个brick中)
if ((node <= old_loc))
new_address = (old_address + node_relocation_distance (node));
else
{
if (node_left_p (node))
{
dprintf(3,(" L: %Ix", (size_t)node));
new_address = (old_address +
(node_relocation_distance (node) +
node_gap_size (node)));
}
else
{
brick = brick - 1;
brick_entry = brick_table [ brick ];
goto retry;
}
}
}
// 修改对象指针的地址
*pold_address = new_address;
return;
}
// 如果对象是大对象,对象本身就是一个plug所以可以直接取到reloc
#ifdef FEATURE_LOH_COMPACTION
if (loh_compacted_p
#ifdef FEATURE_BASICFREEZE
&& !frozen_object_p((Object*)old_address)
#endif // FEATURE_BASICFREEZE
)
{
*pold_address = old_address + loh_node_relocation_distance (old_address);
}
else
#endif //FEATURE_LOH_COMPACTION
{
*pold_address = new_address;
}
}
gc_heap::relocate_survivors
函数的代码如下:
这个函数用于重定位存活下来的对象中的引用
void gc_heap::relocate_survivors (int condemned_gen_number,
uint8_t* first_condemned_address)
{
generation* condemned_gen = generation_of (condemned_gen_number);
uint8_t* start_address = first_condemned_address;
size_t current_brick = brick_of (start_address);
heap_segment* current_heap_segment = heap_segment_rw (generation_start_segment (condemned_gen));
PREFIX_ASSUME(current_heap_segment != NULL);
uint8_t* end_address = 0;
// 重设mark_stack_array队列
reset_pinned_queue_bos();
// 更新gc_heap中的oldest_pinned_plug对象
update_oldest_pinned_plug();
end_address = heap_segment_allocated (current_heap_segment);
size_t end_brick = brick_of (end_address - 1);
// 初始化重定位参数
relocate_args args;
// 本次gc的回收范围
args.low = gc_low;
args.high = gc_high;
// 当前的plug结尾是否被下一个plug覆盖了
args.is_shortened = FALSE
// last_plug或者last_plug后面的pinned plug
// 处理plug尾部数据覆盖时需要用到它
args.pinned_plug_entry = 0;
// 上一个plug,用于遍历树时可以从小地址到大地址遍历(中序遍历)
args.last_plug = 0;
while (1)
{
// 当前segment已经处理完
if (current_brick > end_brick)
{
// 处理最后一个plug,结尾地址是heap_segment_allocated
if (args.last_plug)
{
{
assert (!(args.is_shortened));
relocate_survivors_in_plug (args.last_plug,
heap_segment_allocated (current_heap_segment),
args.is_shortened,
args.pinned_plug_entry);
}
args.last_plug = 0;
}
// 如果有下一个segment则处理下一个
if (heap_segment_next_rw (current_heap_segment))
{
current_heap_segment = heap_segment_next_rw (current_heap_segment);
current_brick = brick_of (heap_segment_mem (current_heap_segment));
end_brick = brick_of (heap_segment_allocated (current_heap_segment)-1);
continue;
}
else
{
break;
}
}
{
// 如果当前brick有对应的plug树,处理当前brick
int brick_entry = brick_table [ current_brick ];
if (brick_entry >= 0)
{
relocate_survivors_in_brick (brick_address (current_brick) +
brick_entry -1,
&args);
}
}
current_brick++;
}
}
gc_heap::relocate_survivors_in_brick
函数的代码如下:
void gc_heap::relocate_survivors_in_brick (uint8_t* tree, relocate_args* args)
{
// 遍历plug树
// 会从小到大调用relocate_survivors_in_plug (中序遍历, 借助args->last_plug)
// 例如有这样的plug树
// a
// b c
// d e
// 枚举顺序是a b d e c
// 调用relocate_survivors_in_plug的顺序是d b e a c
assert ((tree != NULL));
dprintf (3, ("tree: %Ix, args->last_plug: %Ix, left: %Ix, right: %Ix, gap(t): %Ix",
tree, args->last_plug,
(tree + node_left_child (tree)),
(tree + node_right_child (tree)),
node_gap_size (tree)));
// 处理左节点
if (node_left_child (tree))
{
relocate_survivors_in_brick (tree + node_left_child (tree), args);
}
// 处理last_plug
{
uint8_t* plug = tree;
BOOL has_post_plug_info_p = FALSE;
BOOL has_pre_plug_info_p = FALSE;
// 如果这个plug是pinned plug
// 获取是否有has_pre_plug_info_p (是否覆盖了last_plug的尾部)
// 获取是否有has_post_plug_info_p (是否被下一个plug覆盖了尾部)
if (tree == oldest_pinned_plug)
{
args->pinned_plug_entry = get_oldest_pinned_entry (&has_pre_plug_info_p,
&has_post_plug_info_p);
assert (tree == pinned_plug (args->pinned_plug_entry));
dprintf (3, ("tree is the oldest pin: %Ix", tree));
}
// 处理last_plug
if (args->last_plug)
{
size_t gap_size = node_gap_size (tree);
// last_plug的结尾 = 当前plug的开始地址 - gap
uint8_t* gap = (plug - gap_size);
dprintf (3, ("tree: %Ix, gap: %Ix (%Ix)", tree, gap, gap_size));
assert (gap_size >= Align (min_obj_size));
uint8_t* last_plug_end = gap;
// last_plug的尾部是否被覆盖了
// args->is_shortened代表last_plug是pinned_plug,被下一个unpinned plug覆盖了尾部
// has_pre_plug_info_p代表last_plug是unpinned plug,被下一个pinned plug覆盖了尾部
BOOL check_last_object_p = (args->is_shortened || has_pre_plug_info_p);
// 处理last_plug,结尾地址是当前plug的开始地址 - gap
{
relocate_survivors_in_plug (args->last_plug, last_plug_end, check_last_object_p, args->pinned_plug_entry);
}
}
else
{
assert (!has_pre_plug_info_p);
}
// 设置last_plug
args->last_plug = plug;
// 设置是否被覆盖了尾部
args->is_shortened = has_post_plug_info_p;
if (has_post_plug_info_p)
{
dprintf (3, ("setting %Ix as shortened", plug));
}
dprintf (3, ("last_plug: %Ix(shortened: %d)", plug, (args->is_shortened ? 1 : 0)));
}
// 处理右节点
if (node_right_child (tree))
{
relocate_survivors_in_brick (tree + node_right_child (tree), args);
}
}
gc_heap::relocate_survivors_in_plug
函数的代码如下:
void gc_heap::relocate_survivors_in_plug (uint8_t* plug, uint8_t* plug_end,
BOOL check_last_object_p,
mark* pinned_plug_entry)
{
//dprintf(3,("Relocating pointers in Plug [%Ix,%Ix[", (size_t)plug, (size_t)plug_end));
dprintf (3,("RP: [%Ix,%Ix[", (size_t)plug, (size_t)plug_end));
// plug的结尾被覆盖过,需要特殊的处理
if (check_last_object_p)
{
relocate_shortened_survivor_helper (plug, plug_end, pinned_plug_entry);
}
// 一般的处理
else
{
relocate_survivor_helper (plug, plug_end);
}
}
gc_heap::relocate_survivor_helper
函数的代码如下:
void gc_heap::relocate_survivor_helper (uint8_t* plug, uint8_t* plug_end)
{
// 枚举plug中的对象,分别调用relocate_obj_helper函数
uint8_t* x = plug;
while (x < plug_end)
{
size_t s = size (x);
uint8_t* next_obj = x + Align (s);
Prefetch (next_obj);
relocate_obj_helper (x, s);
assert (s > 0);
x = next_obj;
}
}
gc_heap::relocate_obj_helper
函数的代码如下:
inline void
gc_heap::relocate_obj_helper (uint8_t* x, size_t s)
{
THREAD_FROM_HEAP;
// 判断对象中是否包含了引用
if (contain_pointers (x))
{
dprintf (3, ("$%Ix$", (size_t)x));
// 重定位这个对象的所有成员
// 注意这里不会包含对象自身(nostart)
go_through_object_nostart (method_table(x), x, s, pval,
{
uint8_t* child = *pval;
reloc_survivor_helper (pval);
if (child)
{
dprintf (3, ("%Ix->%Ix->%Ix", (uint8_t*)pval, child, *pval));
}
});
}
check_class_object_demotion (x);
}
gc_heap::reloc_survivor_helper
函数的代码如下:
inline void
gc_heap::reloc_survivor_helper (uint8_t** pval)
{
// 执行重定位,relocate_address函数上面有解释
THREAD_FROM_HEAP;
relocate_address (pval THREAD_NUMBER_ARG);
// 如果对象在降代范围中,需要设置来源位置在Card Table中的标记
check_demotion_helper (pval, (uint8_t*)pval);
}
gc_heap::relocate_shortened_survivor_helper
函数的代码如下:
void gc_heap::relocate_shortened_survivor_helper (uint8_t* plug, uint8_t* plug_end, mark* pinned_plug_entry)
{
uint8_t* x = plug;
// 如果p_plug == plug表示当前plug是pinned plug,结尾被下一个plug覆盖
// 如果p_plug != plug表示当前plug是unpinned plug,结尾被p_plug覆盖
uint8_t* p_plug = pinned_plug (pinned_plug_entry);
BOOL is_pinned = (plug == p_plug);
BOOL check_short_obj_p = (is_pinned ? pinned_plug_entry->post_short_p() : pinned_plug_entry->pre_short_p());
// 因为这个plug的结尾被覆盖了,下一个plug的gap是特殊gap,这里要加回去大小
plug_end += sizeof (gap_reloc_pair);
//dprintf (3, ("%s %Ix is shortened, and last object %s overwritten", (is_pinned ? "PP" : "NP"), plug, (check_short_obj_p ? "is" : "is not")));
dprintf (3, ("%s %Ix-%Ix short, LO: %s OW", (is_pinned ? "PP" : "NP"), plug, plug_end, (check_short_obj_p ? "is" : "is not")));
verify_pins_with_post_plug_info("begin reloc short surv");
// 枚举plug中的对象
while (x < plug_end)
{
// plug的最后一个对象被完全覆盖了,需要做特殊处理
if (check_short_obj_p && ((plug_end - x) < min_pre_pin_obj_size))
{
dprintf (3, ("last obj %Ix is short", x));
// 当前plug是pinned plug,结尾被下一个unpinned plug覆盖了
// 根据最后一个对象的成员bitmap重定位
if (is_pinned)
{
#ifdef COLLECTIBLE_CLASS
if (pinned_plug_entry->post_short_collectible_p())
unconditional_set_card_collectible (x);
#endif //COLLECTIBLE_CLASS
// Relocate the saved references based on bits set.
// 成员应该存在的地址(被覆盖的数据中),设置Card Table会使用这个地址
uint8_t** saved_plug_info_start = (uint8_t**)(pinned_plug_entry->get_post_plug_info_start());
// 成员真实存在的地址(备份数据中)
uint8_t** saved_info_to_relocate = (uint8_t**)(pinned_plug_entry->get_post_plug_reloc_info());
// 枚举成员的bitmap
for (size_t i = 0; i < pinned_plug_entry->get_max_short_bits(); i++)
{
// 如果成员存在则重定位该成员
if (pinned_plug_entry->post_short_bit_p (i))
{
reloc_ref_in_shortened_obj ((saved_plug_info_start + i), (saved_info_to_relocate + i));
}
}
}
// 当前plug是unpinned plug,结尾被下一个pinned plug覆盖了
// 处理和上面一样
else
{
#ifdef COLLECTIBLE_CLASS
if (pinned_plug_entry->pre_short_collectible_p())
unconditional_set_card_collectible (x);
#endif //COLLECTIBLE_CLASS
relocate_pre_plug_info (pinned_plug_entry);
// Relocate the saved references based on bits set.
uint8_t** saved_plug_info_start = (uint8_t**)(p_plug - sizeof (plug_and_gap));
uint8_t** saved_info_to_relocate = (uint8_t**)(pinned_plug_entry->get_pre_plug_reloc_info());
for (size_t i = 0; i < pinned_plug_entry->get_max_short_bits(); i++)
{
if (pinned_plug_entry->pre_short_bit_p (i))
{
reloc_ref_in_shortened_obj ((saved_plug_info_start + i), (saved_info_to_relocate + i));
}
}
}
// 处理完最后一个对象,可以跳出了
break;
}
size_t s = size (x);
uint8_t* next_obj = x + Align (s);
Prefetch (next_obj);
// 最后一个对象被覆盖了,但是只是覆盖了后半部分,不是全部被覆盖
if (next_obj >= plug_end)
{
dprintf (3, ("object %Ix is at the end of the plug %Ix->%Ix",
next_obj, plug, plug_end));
verify_pins_with_post_plug_info("before reloc short obj");
relocate_shortened_obj_helper (x, s, (x + Align (s) - sizeof (plug_and_gap)), pinned_plug_entry, is_pinned);
}
// 对象未被覆盖,调用一般的处理
else
{
relocate_obj_helper (x, s);
}
assert (s > 0);
x = next_obj;
}
verify_pins_with_post_plug_info("end reloc short surv");
}
gc_heap::reloc_ref_in_shortened_obj
函数的代码如下:
inline
void gc_heap::reloc_ref_in_shortened_obj (uint8_t** address_to_set_card, uint8_t** address_to_reloc)
{
THREAD_FROM_HEAP;
// 重定位对象
// 这里的address_to_reloc会在备份数据中
uint8_t* old_val = (address_to_reloc ? *address_to_reloc : 0);
relocate_address (address_to_reloc THREAD_NUMBER_ARG);
if (address_to_reloc)
{
dprintf (3, ("SR %Ix: %Ix->%Ix", (uint8_t*)address_to_reloc, old_val, *address_to_reloc));
}
// 如果对象在降代范围中,设置Card Table
// 这里的address_to_set_card会在被覆盖的数据中
//check_demotion_helper (current_saved_info_to_relocate, (uint8_t*)pval);
uint8_t* relocated_addr = *address_to_reloc;
if ((relocated_addr < demotion_high) &&
(relocated_addr >= demotion_low))
{
dprintf (3, ("set card for location %Ix(%Ix)",
(size_t)address_to_set_card, card_of((uint8_t*)address_to_set_card)));
set_card (card_of ((uint8_t*)address_to_set_card));
}
#ifdef MULTIPLE_HEAPS
// 不在当前heap时试着找到对象所在的heap并且用该heap处理
else if (settings.demotion)
{
gc_heap* hp = heap_of (relocated_addr);
if ((relocated_addr < hp->demotion_high) &&
(relocated_addr >= hp->demotion_low))
{
dprintf (3, ("%Ix on h%d, set card for location %Ix(%Ix)",
relocated_addr, hp->heap_number, (size_t)address_to_set_card, card_of((uint8_t*)address_to_set_card)));
set_card (card_of ((uint8_t*)address_to_set_card));
}
}
#endif //MULTIPLE_HEAPS
}
gc_heap::relocate_shortened_obj_helper
函数的代码如下:
inline
void gc_heap::relocate_shortened_obj_helper (uint8_t* x, size_t s, uint8_t* end, mark* pinned_plug_entry, BOOL is_pinned)
{
THREAD_FROM_HEAP;
uint8_t* plug = pinned_plug (pinned_plug_entry);
// 如果当前plug是unpinned plug, 代表邻接的pinned plug中保存的pre_plug_info_reloc_start可能已经被移动了
// 这里需要重定位pinned plug中保存的pre_plug_info_reloc_start (unpinned plug被覆盖的内容的开始地址)
if (!is_pinned)
{
//// Temporary - we just wanna make sure we are doing things right when padding is needed.
//if ((x + s) < plug)
//{
// dprintf (3, ("obj %Ix needed padding: end %Ix is %d bytes from pinned obj %Ix",
// x, (x + s), (plug- (x + s)), plug));
// GCToOSInterface::DebugBreak();
//}
relocate_pre_plug_info (pinned_plug_entry);
}
verify_pins_with_post_plug_info("after relocate_pre_plug_info");
uint8_t* saved_plug_info_start = 0;
uint8_t** saved_info_to_relocate = 0;
// saved_plug_info_start等于被覆盖的地址的开始
// saved_info_to_relocate等于原始内容的开始
if (is_pinned)
{
saved_plug_info_start = (uint8_t*)(pinned_plug_entry->get_post_plug_info_start());
saved_info_to_relocate = (uint8_t**)(pinned_plug_entry->get_post_plug_reloc_info());
}
else
{
saved_plug_info_start = (plug - sizeof (plug_and_gap));
saved_info_to_relocate = (uint8_t**)(pinned_plug_entry->get_pre_plug_reloc_info());
}
uint8_t** current_saved_info_to_relocate = 0;
uint8_t* child = 0;
dprintf (3, ("x: %Ix, pp: %Ix, end: %Ix", x, plug, end));
// 判断对象中是否包含了引用
if (contain_pointers (x))
{
dprintf (3,("$%Ix$", (size_t)x));
// 重定位这个对象的所有成员
// 注意这里不会包含对象自身(nostart)
go_through_object_nostart (method_table(x), x, s, pval,
{
dprintf (3, ("obj %Ix, member: %Ix->%Ix", x, (uint8_t*)pval, *pval));
// 成员所在的部分被覆盖了,调用reloc_ref_in_shortened_obj重定位
// pval = 成员应该存在的地址(被覆盖的数据中),设置Card Table会使用这个地址
// current_saved_info_to_relocate = 成员真实存在的地址(备份数据中)
if ((uint8_t*)pval >= end)
{
current_saved_info_to_relocate = saved_info_to_relocate + ((uint8_t*)pval - saved_plug_info_start) / sizeof (uint8_t**);
child = *current_saved_info_to_relocate;
reloc_ref_in_shortened_obj (pval, current_saved_info_to_relocate);
dprintf (3, ("last part: R-%Ix(saved: %Ix)->%Ix ->%Ix",
(uint8_t*)pval, current_saved_info_to_relocate, child, *current_saved_info_to_relocate));
}
// 成员所在的部分未被覆盖,调用一般的处理
else
{
reloc_survivor_helper (pval);
}
});
}
check_class_object_demotion (x);
}
重定位阶段(relocate_phase)只是修改了引用对象的地址,对象还在原来的位置,接下来进入压缩阶段(compact_phase):
压缩阶段(compact_phase)
压缩阶段负责把对象复制到之前模拟压缩到的地址上,简单点来讲就是用memcpy
复制这些对象到新的地址。
压缩阶段会使用之前构建的brick table和plug树快速的枚举对象。
gc_heap::compact_phase
函数的代码如下:
这个函数的代码是不是有点眼熟?它的流程和上面的relocate_survivors
很像,都是枚举brick table然后中序枚举plug树
void gc_heap::compact_phase (int condemned_gen_number,
uint8_t* first_condemned_address,
BOOL clear_cards)
{
// %type% category = quote (compact);
// 统计压缩阶段的开始时间
#ifdef TIME_GC
unsigned start;
unsigned finish;
start = GetCycleCount32();
#endif //TIME_GC
generation* condemned_gen = generation_of (condemned_gen_number);
uint8_t* start_address = first_condemned_address;
size_t current_brick = brick_of (start_address);
heap_segment* current_heap_segment = heap_segment_rw (generation_start_segment (condemned_gen));
PREFIX_ASSUME(current_heap_segment != NULL);
// 重设mark_stack_array队列
reset_pinned_queue_bos();
// 更新gc_heap中的oldest_pinned_plug对象
update_oldest_pinned_plug();
// 如果should_expand的时候重用了以前的segment作为ephemeral heap segment,则需要重新计算generation_allocation_size
// reused_seg会影响压缩参数中的check_gennum_p
BOOL reused_seg = expand_reused_seg_p();
if (reused_seg)
{
for (int i = 1; i <= max_generation; i++)
{
generation_allocation_size (generation_of (i)) = 0;
}
}
uint8_t* end_address = heap_segment_allocated (current_heap_segment);
size_t end_brick = brick_of (end_address-1);
// 初始化压缩参数
compact_args args;
// 上一个plug,用于遍历树时可以从小地址到大地址遍历(中序遍历)
args.last_plug = 0;
// 当前brick的最后一个plug,更新brick table时使用
args.before_last_plug = 0;
// 最后设置的brick,用于复制plug后更新brick table
args.current_compacted_brick = ~((size_t)1);
// 当前的plug结尾是否被下一个plug覆盖了
args.is_shortened = FALSE;
// last_plug或者last_plug后面的pinned plug
// 处理plug尾部数据覆盖时需要用到它
args.pinned_plug_entry = 0;
// 是否需要在复制对象时复制相应的Card Table范围
args.copy_cards_p = (condemned_gen_number >= 1) || !clear_cards;
// 重新计算generation_allocation_size时使用的参数
args.check_gennum_p = reused_seg;
if (args.check_gennum_p)
{
args.src_gennum = ((current_heap_segment == ephemeral_heap_segment) ? -1 : 2);
}
dprintf (2,("---- Compact Phase: %Ix(%Ix)----",
first_condemned_address, brick_of (first_condemned_address)));
#ifdef MULTIPLE_HEAPS
//restart
if (gc_t_join.joined())
{
#endif //MULTIPLE_HEAPS
#ifdef MULTIPLE_HEAPS
dprintf(3, ("Restarting for compaction"));
gc_t_join.restart();
}
#endif //MULTIPLE_HEAPS
// 再次重设mark_stack_array队列
reset_pinned_queue_bos();
// 判断是否需要压缩大对象的堆
#ifdef FEATURE_LOH_COMPACTION
if (loh_compacted_p)
{
compact_loh();
}
#endif //FEATURE_LOH_COMPACTION
// 循环brick table
if ((start_address < end_address) ||
(condemned_gen_number == max_generation))
{
while (1)
{
// 当前segment已经处理完
if (current_brick > end_brick)
{
// 处理最后一个plug,大小是heap_segment_allocated - last_plug
if (args.last_plug != 0)
{
dprintf (3, ("compacting last plug: %Ix", args.last_plug))
compact_plug (args.last_plug,
(heap_segment_allocated (current_heap_segment) - args.last_plug),
args.is_shortened,
&args);
}
// 如果有下一个segment则处理下一个
if (heap_segment_next_rw (current_heap_segment))
{
current_heap_segment = heap_segment_next_rw (current_heap_segment);
current_brick = brick_of (heap_segment_mem (current_heap_segment));
end_brick = brick_of (heap_segment_allocated (current_heap_segment)-1);
args.last_plug = 0;
// 更新src_gennum (如果segment是ephemeral_heap_segment则需要进一步判断)
if (args.check_gennum_p)
{
args.src_gennum = ((current_heap_segment == ephemeral_heap_segment) ? -1 : 2);
}
continue;
}
// 设置最后一个brick的偏移值, 给compact_plug善后
else
{
if (args.before_last_plug !=0)
{
dprintf (3, ("Fixing last brick %Ix to point to plug %Ix",
args.current_compacted_brick, (size_t)args.before_last_plug));
assert (args.current_compacted_brick != ~1u);
set_brick (args.current_compacted_brick,
args.before_last_plug - brick_address (args.current_compacted_brick));
}
break;
}
}
{
// 如果当前brick有对应的plug树,处理当前brick
int brick_entry = brick_table [ current_brick ];
dprintf (3, ("B: %Ix(%Ix)->%Ix",
current_brick, (size_t)brick_entry, (brick_address (current_brick) + brick_entry - 1)));
if (brick_entry >= 0)
{
compact_in_brick ((brick_address (current_brick) + brick_entry -1),
&args);
}
}
current_brick++;
}
}
// 复制已完毕
// 恢复备份的数据到被覆盖的部分
recover_saved_pinned_info();
// 统计压缩阶段的结束时间
#ifdef TIME_GC
finish = GetCycleCount32();
compact_time = finish - start;
#endif //TIME_GC
concurrent_print_time_delta ("compact end");
dprintf(2,("---- End of Compact phase ----"));
}
gc_heap::compact_in_brick
函数的代码如下:
这个函数和上面的relocate_survivors_in_brick
函数很像
void gc_heap::compact_in_brick (uint8_t* tree, compact_args* args)
{
assert (tree != NULL);
int left_node = node_left_child (tree);
int right_node = node_right_child (tree);
// 需要移动的偏移值,前面计划阶段模拟压缩时设置的reloc
ptrdiff_t relocation = node_relocation_distance (tree);
args->print();
// 处理左节点
if (left_node)
{
dprintf (3, ("B: L: %d->%Ix", left_node, (tree + left_node)));
compact_in_brick ((tree + left_node), args);
}
uint8_t* plug = tree;
BOOL has_pre_plug_info_p = FALSE;
BOOL has_post_plug_info_p = FALSE;
// 如果这个plug是pinned plug
// 获取是否有has_pre_plug_info_p (是否覆盖了last_plug的尾部)
// 获取是否有has_post_plug_info_p (是否被下一个plug覆盖了尾部)
if (tree == oldest_pinned_plug)
{
args->pinned_plug_entry = get_oldest_pinned_entry (&has_pre_plug_info_p,
&has_post_plug_info_p);
assert (tree == pinned_plug (args->pinned_plug_entry));
}
// 处理last_plug
if (args->last_plug != 0)
{
size_t gap_size = node_gap_size (tree);
// last_plug的结尾 = 当前plug的开始地址 - gap
uint8_t* gap = (plug - gap_size);
uint8_t* last_plug_end = gap;
// last_plug的大小 = last_plug的结尾 - last_plug的开始
size_t last_plug_size = (last_plug_end - args->last_plug);
dprintf (3, ("tree: %Ix, last_plug: %Ix, gap: %Ix(%Ix), last_plug_end: %Ix, size: %Ix",
tree, args->last_plug, gap, gap_size, last_plug_end, last_plug_size));
// last_plug的尾部是否被覆盖了
// args->is_shortened代表last_plug是pinned_plug,被下一个unpinned plug覆盖了尾部
// has_pre_plug_info_p代表last_plug是unpinned plug,被下一个pinned plug覆盖了尾部
BOOL check_last_object_p = (args->is_shortened || has_pre_plug_info_p);
if (!check_last_object_p)
{
assert (last_plug_size >= Align (min_obj_size));
}
// 处理last_plug
compact_plug (args->last_plug, last_plug_size, check_last_object_p, args);
}
else
{
// 第一个plug不可能覆盖前面的plug的结尾
assert (!has_pre_plug_info_p);
}
dprintf (3, ("set args last plug to plug: %Ix, reloc: %Ix", plug, relocation));
// 设置last_plug
args->last_plug = plug;
// 设置last_plugd移动偏移值
args->last_plug_relocation = relocation;
// 设置是否被覆盖了尾部
args->is_shortened = has_post_plug_info_p;
// 处理右节点
if (right_node)
{
dprintf (3, ("B: R: %d->%Ix", right_node, (tree + right_node)));
compact_in_brick ((tree + right_node), args);
}
}
gc_heap::compact_plug
函数的代码如下:
void gc_heap::compact_plug (uint8_t* plug, size_t size, BOOL check_last_object_p, compact_args* args)
{
args->print();
// 复制到的地址,plug + reloc
uint8_t* reloc_plug = plug + args->last_plug_relocation;
// 如果plug的结尾被覆盖过
if (check_last_object_p)
{
// 添加特殊gap的大小
size += sizeof (gap_reloc_pair);
mark* entry = args->pinned_plug_entry;
// 在复制内存前把被覆盖的内容和原始内容交换一下
// 复制内存后需要交换回去
if (args->is_shortened)
{
// 当前plug是pinned plug,被下一个unpinned plug覆盖
assert (entry->has_post_plug_info());
entry->swap_post_plug_and_saved();
}
else
{
// 当前plug是unpinned plug,被下一个pinned plug覆盖
assert (entry->has_pre_plug_info());
entry->swap_pre_plug_and_saved();
}
}
// 复制之前的brick中的偏移值
int old_brick_entry = brick_table [brick_of (plug)];
assert (node_relocation_distance (plug) == args->last_plug_relocation);
// 处理对齐和pad
#ifdef FEATURE_STRUCTALIGN
ptrdiff_t alignpad = node_alignpad(plug);
if (alignpad)
{
make_unused_array (reloc_plug - alignpad, alignpad);
if (brick_of (reloc_plug - alignpad) != brick_of (reloc_plug))
{
// The alignment padding is straddling one or more bricks;
// it has to be the last "object" of its first brick.
fix_brick_to_highest (reloc_plug - alignpad, reloc_plug);
}
}
#else // FEATURE_STRUCTALIGN
size_t unused_arr_size = 0;
BOOL already_padded_p = FALSE;
#ifdef SHORT_PLUGS
if (is_plug_padded (plug))
{
already_padded_p = TRUE;
clear_plug_padded (plug);
unused_arr_size = Align (min_obj_size);
}
#endif //SHORT_PLUGS
if (node_realigned (plug))
{
unused_arr_size += switch_alignment_size (already_padded_p);
}
if (unused_arr_size != 0)
{
make_unused_array (reloc_plug - unused_arr_size, unused_arr_size);
if (brick_of (reloc_plug - unused_arr_size) != brick_of (reloc_plug))
{
dprintf (3, ("fix B for padding: %Id: %Ix->%Ix",
unused_arr_size, (reloc_plug - unused_arr_size), reloc_plug));
// The alignment padding is straddling one or more bricks;
// it has to be the last "object" of its first brick.
fix_brick_to_highest (reloc_plug - unused_arr_size, reloc_plug);
}
}
#endif // FEATURE_STRUCTALIGN
#ifdef SHORT_PLUGS
if (is_plug_padded (plug))
{
make_unused_array (reloc_plug - Align (min_obj_size), Align (min_obj_size));
if (brick_of (reloc_plug - Align (min_obj_size)) != brick_of (reloc_plug))
{
// The alignment padding is straddling one or more bricks;
// it has to be the last "object" of its first brick.
fix_brick_to_highest (reloc_plug - Align (min_obj_size), reloc_plug);
}
}
#endif //SHORT_PLUGS
// 复制plug中的所有内容和对应的Card Table中的范围(如果copy_cards_p成立)
gcmemcopy (reloc_plug, plug, size, args->copy_cards_p);
// 重新统计generation_allocation_size
if (args->check_gennum_p)
{
int src_gennum = args->src_gennum;
if (src_gennum == -1)
{
src_gennum = object_gennum (plug);
}
int dest_gennum = object_gennum_plan (reloc_plug);
if (src_gennum < dest_gennum)
{
generation_allocation_size (generation_of (dest_gennum)) += size;
}
}
// 更新brick table
// brick table中会保存brick的最后一个plug的偏移值,跨越多个brick的时候后面的brick会是-1
size_t current_reloc_brick = args->current_compacted_brick;
// 如果已经到了下一个brick
// 设置上一个brick的值 = 上一个brick中最后的plug的偏移值, 或者-1
if (brick_of (reloc_plug) != current_reloc_brick)
{
dprintf (3, ("last reloc B: %Ix, current reloc B: %Ix",
current_reloc_brick, brick_of (reloc_plug)));
if (args->before_last_plug)
{
dprintf (3,(" fixing last brick %Ix to point to last plug %Ix(%Ix)",
current_reloc_brick,
args->before_last_plug,
(args->before_last_plug - brick_address (current_reloc_brick))));
{
set_brick (current_reloc_brick,
args->before_last_plug - brick_address (current_reloc_brick));
}
}
current_reloc_brick = brick_of (reloc_plug);
}
// 如果跨越了多个brick
size_t end_brick = brick_of (reloc_plug + size-1);
if (end_brick != current_reloc_brick)
{
// The plug is straddling one or more bricks
// It has to be the last plug of its first brick
dprintf (3,("plug spanning multiple bricks, fixing first brick %Ix to %Ix(%Ix)",
current_reloc_brick, (size_t)reloc_plug,
(reloc_plug - brick_address (current_reloc_brick))));
// 设置第一个brick中的偏移值
{
set_brick (current_reloc_brick,
reloc_plug - brick_address (current_reloc_brick));
}
// 把后面的brick设为-1,除了end_brick
// update all intervening brick
size_t brick = current_reloc_brick + 1;
dprintf (3,("setting intervening bricks %Ix->%Ix to -1",
brick, (end_brick - 1)));
while (brick < end_brick)
{
set_brick (brick, -1);
brick++;
}
// 如果end_brick中无其他plug,end_brick也会被设为-1
// brick_address (end_brick) - 1 - brick_address (end_brick) = -1
// code last brick offset as a plug address
args->before_last_plug = brick_address (end_brick) -1;
current_reloc_brick = end_brick;
dprintf (3, ("setting before last to %Ix, last brick to %Ix",
args->before_last_plug, current_reloc_brick));
}
// 如果只在一个brick中
else
{
// 记录当前brick中的最后一个plug
dprintf (3, ("still in the same brick: %Ix", end_brick));
args->before_last_plug = reloc_plug;
}
// 更新最后设置的brick
args->current_compacted_brick = current_reloc_brick;
// 复制完毕以后把被覆盖的内容和原始内容交换回去
// 注意如果plug移动的距离比覆盖的大小要少,这里会把复制后的内容给破坏掉
// 后面还需要使用recover_saved_pinned_info还原
if (check_last_object_p)
{
mark* entry = args->pinned_plug_entry;
if (args->is_shortened)
{
entry->swap_post_plug_and_saved();
}
else
{
entry->swap_pre_plug_and_saved();
}
}
}
gc_heap::gcmemcopy
函数的代码如下:
// POPO TODO: We should actually just recover the artifically made gaps here..because when we copy
// we always copy the earlier plugs first which means we won't need the gap sizes anymore. This way
// we won't need to individually recover each overwritten part of plugs.
inline
void gc_heap::gcmemcopy (uint8_t* dest, uint8_t* src, size_t len, BOOL copy_cards_p)
{
// 如果地址一样可以跳过
if (dest != src)
{
#ifdef BACKGROUND_GC
if (current_c_gc_state == c_gc_state_marking)
{
//TODO: should look to see whether we should consider changing this
// to copy a consecutive region of the mark array instead.
copy_mark_bits_for_addresses (dest, src, len);
}
#endif //BACKGROUND_GC
// 复制plug中的所有对象到新的地址上
// memcopy做的东西和memcpy一样,微软自己写的一个函数而已
//dprintf(3,(" Memcopy [%Ix->%Ix, %Ix->%Ix[", (size_t)src, (size_t)dest, (size_t)src+len, (size_t)dest+len));
dprintf(3,(" mc: [%Ix->%Ix, %Ix->%Ix[", (size_t)src, (size_t)dest, (size_t)src+len, (size_t)dest+len));
memcopy (dest - plug_skew, src - plug_skew, (int)len);
#ifdef FEATURE_USE_SOFTWARE_WRITE_WATCH_FOR_GC_HEAP
if (SoftwareWriteWatch::IsEnabledForGCHeap())
{
// The ranges [src - plug_kew .. src[ and [src + len - plug_skew .. src + len[ are ObjHeaders, which don't have GC
// references, and are not relevant for write watch. The latter range actually corresponds to the ObjHeader for the
// object at (src + len), so it can be ignored anyway.
SoftwareWriteWatch::SetDirtyRegion(dest, len - plug_skew);
}
#endif // FEATURE_USE_SOFTWARE_WRITE_WATCH_FOR_GC_HEAP
// 复制对应的Card Table范围
// copy_cards_p成立的时候复制src ~ src+len到dest
// copy_cards_p不成立的时候清除dest ~ dest+len
copy_cards_range (dest, src, len, copy_cards_p);
}
}
gc_heap::compact_loh
函数的代码如下:
void gc_heap::compact_loh()
{
assert (should_compact_loh());
generation* gen = large_object_generation;
heap_segment* start_seg = heap_segment_rw (generation_start_segment (gen));
PREFIX_ASSUME(start_seg != NULL);
heap_segment* seg = start_seg;
heap_segment* prev_seg = 0;
uint8_t* o = generation_allocation_start (gen);
//Skip the generation gap object
o = o + AlignQword (size (o));
// We don't need to ever realloc gen3 start so don't touch it.
uint8_t* free_space_start = o;
uint8_t* free_space_end = o;
generation_allocator (gen)->clear();
generation_free_list_space (gen) = 0;
generation_free_obj_space (gen) = 0;
loh_pinned_queue_bos = 0;
// 枚举大对象的堆
while (1)
{
// 当前segment处理完毕,处理下一个
if (o >= heap_segment_allocated (seg))
{
heap_segment* next_seg = heap_segment_next (seg);
// 如果当前segment为空,表示可以删掉这个segment
// 修改segment链表,把空的segment放到后面
if ((heap_segment_plan_allocated (seg) == heap_segment_mem (seg)) &&
(seg != start_seg) && !heap_segment_read_only_p (seg))
{
dprintf (3, ("Preparing empty large segment %Ix", (size_t)seg));
assert (prev_seg);
heap_segment_next (prev_seg) = next_seg;
heap_segment_next (seg) = freeable_large_heap_segment;
freeable_large_heap_segment = seg;
}
else
{
// 更新heap_segment_allocated
// 释放(decommit)未使用的内存空间
if (!heap_segment_read_only_p (seg))
{
// We grew the segment to accommondate allocations.
if (heap_segment_plan_allocated (seg) > heap_segment_allocated (seg))
{
if ((heap_segment_plan_allocated (seg) - plug_skew) > heap_segment_used (seg))
{
heap_segment_used (seg) = heap_segment_plan_allocated (seg) - plug_skew;
}
}
heap_segment_allocated (seg) = heap_segment_plan_allocated (seg);
dprintf (3, ("Trimming seg to %Ix[", heap_segment_allocated (seg)));
decommit_heap_segment_pages (seg, 0);
dprintf (1236, ("CLOH: seg: %Ix, alloc: %Ix, used: %Ix, committed: %Ix",
seg,
heap_segment_allocated (seg),
heap_segment_used (seg),
heap_segment_committed (seg)));
//heap_segment_used (seg) = heap_segment_allocated (seg) - plug_skew;
dprintf (1236, ("CLOH: used is set to %Ix", heap_segment_used (seg)));
}
prev_seg = seg;
}
// 处理下一个segment,不存在时跳出
seg = next_seg;
if (seg == 0)
break;
else
{
o = heap_segment_mem (seg);
}
}
// 如果对象已标记
if (marked (o))
{
free_space_end = o;
size_t size = AlignQword (size (o));
size_t loh_pad;
uint8_t* reloc = o;
// 清除标记
clear_marked (o);
// 如果对象是固定的
if (pinned (o))
{
// We are relying on the fact the pinned objects are always looked at in the same order
// in plan phase and in compact phase.
mark* m = loh_pinned_plug_of (loh_deque_pinned_plug());
uint8_t* plug = pinned_plug (m);
assert (plug == o);
loh_pad = pinned_len (m);
// 清除固定标记
clear_pinned (o);
}
else
{
loh_pad = AlignQword (loh_padding_obj_size);
// 复制对象内存
reloc += loh_node_relocation_distance (o);
gcmemcopy (reloc, o, size, TRUE);
}
// 添加loh_pad到free list
thread_gap ((reloc - loh_pad), loh_pad, gen);
// 处理下一个对象
o = o + size;
free_space_start = o;
if (o < heap_segment_allocated (seg))
{
assert (!marked (o));
}
}
else
{
// 跳过未标记对象
while (o < heap_segment_allocated (seg) && !marked (o))
{
o = o + AlignQword (size (o));
}
}
}
assert (loh_pinned_plug_que_empty_p());
dprintf (1235, ("after GC LOH size: %Id, free list: %Id, free obj: %Id\n\n",
generation_size (max_generation + 1),
generation_free_list_space (gen),
generation_free_obj_space (gen)));
}
gc_heap::recover_saved_pinned_info
函数的代码如下:
void gc_heap::recover_saved_pinned_info()
{
// 重设mark_stack_array队列
reset_pinned_queue_bos();
// 恢复各个pinned plug被覆盖或者覆盖的数据
while (!(pinned_plug_que_empty_p()))
{
mark* oldest_entry = oldest_pin();
oldest_entry->recover_plug_info();
#ifdef GC_CONFIG_DRIVEN
if (oldest_entry->has_pre_plug_info() && oldest_entry->has_post_plug_info())
record_interesting_data_point (idp_pre_and_post_pin);
else if (oldest_entry->has_pre_plug_info())
record_interesting_data_point (idp_pre_pin);
else if (oldest_entry->has_post_plug_info())
record_interesting_data_point (idp_post_pin);
#endif //GC_CONFIG_DRIVEN
deque_pinned_plug();
}
}
mark::recover_plug_info
函数的代码如下:
函数前面的注释讲的是之前复制plug的时候已经包含了被覆盖的内容(swap_pre_plug_and_saved
),
但是如果移动的位置小于3个指针的大小(注释中的< 3
应该是>= 3
)则复制完以后有可能再次被swap_pre_plug_and_saved
破坏掉。
// We should think about whether it's really necessary to have to copy back the pre plug
// info since it was already copied during compacting plugs. But if a plug doesn't move
// by < 3 ptr size, it means we'd have to recover pre plug info.
void recover_plug_info()
{
// 如果这个pinned plug覆盖了前一个unpinned plug的结尾,把备份的数据恢复回去
if (saved_pre_p)
{
// 如果已经压缩过,需要复制到重定位后的saved_pre_plug_info_reloc_start
// 并且使用saved_pre_plug_reloc备份(这个备份里面的成员也经过了重定位)
if (gc_heap::settings.compaction)
{
dprintf (3, ("%Ix: REC Pre: %Ix-%Ix",
first,
&saved_pre_plug_reloc,
saved_pre_plug_info_reloc_start));
memcpy (saved_pre_plug_info_reloc_start, &saved_pre_plug_reloc, sizeof (saved_pre_plug_reloc));
}
// 如果未压缩过,可以复制到这个pinned plug的前面
// 并且使用saved_pre_plug备份
else
{
dprintf (3, ("%Ix: REC Pre: %Ix-%Ix",
first,
&saved_pre_plug,
(first - sizeof (plug_and_gap))));
memcpy ((first - sizeof (plug_and_gap)), &saved_pre_plug, sizeof (saved_pre_plug));
}
}
// 如果这个pinned plug被下一个unpinned plug覆盖了结尾,把备份的数据恢复回去
if (saved_post_p)
{
// 因为pinned plug不会移动
// 这里的saved_post_plug_info_start不会改变
// 使用saved_post_plug_reloc备份(这个备份里面的成员也经过了重定位)
if (gc_heap::settings.compaction)
{
dprintf (3, ("%Ix: REC Post: %Ix-%Ix",
first,
&saved_post_plug_reloc,
saved_post_plug_info_start));
memcpy (saved_post_plug_info_start, &saved_post_plug_reloc, sizeof (saved_post_plug_reloc));
}
// 使用saved_pre_plug备份
else
{
dprintf (3, ("%Ix: REC Post: %Ix-%Ix",
first,
&saved_post_plug,
saved_post_plug_info_start));
memcpy (saved_post_plug_info_start, &saved_post_plug, sizeof (saved_post_plug));
}
}
}
压缩阶段结束以后还需要做一些收尾工作,请从上面plan_phase
中的fix_generation_bounds (condemned_gen_number, consing_gen);
继续看。
如果计划阶段不选择压缩,就会进入清扫阶段:
清扫阶段(sweep_phase)
清扫阶段负责把plug与plug之间的空间变为free object
然后加到对应代的free list
中,并且负责修改代边界。
加到free list
中的区域会在后面供分配新的上下文使用。
清扫阶段的主要工作在函数make_free_lists
中完成,名称叫sweep_phase
的函数目前不存在。
扫描plug时会使用计划阶段构建好的plug信息和brick table
,但模拟压缩的偏移值reloc
和计划代边界plan_allocation_start
不会被使用。
清扫阶段的代码
gc_heap::make_free_lists
函数的代码如下:
void gc_heap::make_free_lists (int condemned_gen_number)
{
// 统计清扫阶段的开始时间
#ifdef TIME_GC
unsigned start;
unsigned finish;
start = GetCycleCount32();
#endif //TIME_GC
//Promotion has to happen in sweep case.
assert (settings.promotion);
// 从收集代的第一个segment开始处理
generation* condemned_gen = generation_of (condemned_gen_number);
uint8_t* start_address = generation_allocation_start (condemned_gen);
size_t current_brick = brick_of (start_address);
heap_segment* current_heap_segment = heap_segment_rw (generation_start_segment (condemned_gen));
PREFIX_ASSUME(current_heap_segment != NULL);
uint8_t* end_address = heap_segment_allocated (current_heap_segment);
size_t end_brick = brick_of (end_address-1);
// 清扫阶段使用的参数
make_free_args args;
// 当前生成的free object应该归到的代序号
// 更新代边界的时候也会使用
args.free_list_gen_number = min (max_generation, 1 + condemned_gen_number);
// 超过这个值就需要更新free_list_gen_number和free_list_gen
// 在清扫阶段settings.promotion == true时
// generation_limit遇到gen 0或者gen 1的时候返回heap_segment_reserved (ephemeral_heap_segment),则原代0的对象归到代1
// generation_limit遇到gen 2的时候返回generation_allocation_start (generation_of ((gen_number - 2))),则原代1的对象归到代2
// MAX_PTR只是用来检测第一次使用的,后面会更新
args.current_gen_limit = (((condemned_gen_number == max_generation)) ?
MAX_PTR :
(generation_limit (args.free_list_gen_number)));
// 当前生成的free object应该归到的代
args.free_list_gen = generation_of (args.free_list_gen_number);
// 当前brick中地址最大的plug,用于更新brick表
args.highest_plug = 0;
// 开始遍历brick
if ((start_address < end_address) ||
(condemned_gen_number == max_generation))
{
while (1)
{
// 当前segment处理完毕
if ((current_brick > end_brick))
{
// 如果第一个segment无存活的对象,则重设它的heap_segment_allocated
// 并且设置generation_allocation_start (gen)等于这个空segment的开始地址
if (args.current_gen_limit == MAX_PTR)
{
//We had an empty segment
//need to allocate the generation start
generation* gen = generation_of (max_generation);
heap_segment* start_seg = heap_segment_rw (generation_start_segment (gen));
PREFIX_ASSUME(start_seg != NULL);
uint8_t* gap = heap_segment_mem (start_seg);
generation_allocation_start (gen) = gap;
heap_segment_allocated (start_seg) = gap + Align (min_obj_size);
// 确保代最少有一个对象
make_unused_array (gap, Align (min_obj_size));
// 更新代边界
reset_allocation_pointers (gen, gap);
dprintf (3, ("Start segment empty, fixing generation start of %d to: %Ix",
max_generation, (size_t)gap));
// 更新current_gen_limit
args.current_gen_limit = generation_limit (args.free_list_gen_number);
}
// 有下一个segment的时候继续处理下一个segment, 否则跳出
if (heap_segment_next_rw (current_heap_segment))
{
current_heap_segment = heap_segment_next_rw (current_heap_segment);
current_brick = brick_of (heap_segment_mem (current_heap_segment));
end_brick = brick_of (heap_segment_allocated (current_heap_segment)-1);
continue;
}
else
{
break;
}
}
{
// 如果brick中保存了对plug树的偏移值则
// 调用make_free_list_in_brick
// 设置brick到地址最大的plug
// 否则设置设为-1 (把-2, -3等等的都改为-1)
int brick_entry = brick_table [ current_brick ];
if ((brick_entry >= 0))
{
make_free_list_in_brick (brick_address (current_brick) + brick_entry-1, &args);
dprintf(3,("Fixing brick entry %Ix to %Ix",
current_brick, (size_t)args.highest_plug));
set_brick (current_brick,
(args.highest_plug - brick_address (current_brick)));
}
else
{
if ((brick_entry > -32768))
{
#ifdef _DEBUG
ptrdiff_t offset = brick_of (args.highest_plug) - current_brick;
if ((brick_entry != -32767) && (! ((offset == brick_entry))))
{
assert ((brick_entry == -1));
}
#endif //_DEBUG
//init to -1 for faster find_first_object
set_brick (current_brick, -1);
}
}
}
current_brick++;
}
}
{
// 设置剩余的代边界
int bottom_gen = 0;
args.free_list_gen_number--;
while (args.free_list_gen_number >= bottom_gen)
{
uint8_t* gap = 0;
generation* gen2 = generation_of (args.free_list_gen_number);
// 保证代中最少有一个对象
gap = allocate_at_end (Align(min_obj_size));
generation_allocation_start (gen2) = gap;
// 设置代边界
reset_allocation_pointers (gen2, gap);
dprintf(3,("Fixing generation start of %d to: %Ix",
args.free_list_gen_number, (size_t)gap));
PREFIX_ASSUME(gap != NULL);
// 代中第一个对象应该是free object
make_unused_array (gap, Align (min_obj_size));
args.free_list_gen_number--;
}
// 更新alloc_allocated成员到gen 0的开始边界
//reset the allocated size
uint8_t* start2 = generation_allocation_start (youngest_generation);
alloc_allocated = start2 + Align (size (start2));
}
// 统计清扫阶段的结束时间
#ifdef TIME_GC
finish = GetCycleCount32();
sweep_time = finish - start;
#endif //TIME_GC
}
gc_heap::make_free_list_in_brick
函数的代码如下:
void gc_heap::make_free_list_in_brick (uint8_t* tree, make_free_args* args)
{
assert ((tree != NULL));
{
int right_node = node_right_child (tree);
int left_node = node_left_child (tree);
args->highest_plug = 0;
if (! (0 == tree))
{
// 处理左边的节点
if (! (0 == left_node))
{
make_free_list_in_brick (tree + left_node, args);
}
// 处理当前节点
{
uint8_t* plug = tree;
// 当前plug前面的空余空间
size_t gap_size = node_gap_size (tree);
// 空余空间的开始
uint8_t* gap = (plug - gap_size);
dprintf (3,("Making free list %Ix len %d in %d",
//dprintf (3,("F: %Ix len %Ix in %d",
(size_t)gap, gap_size, args->free_list_gen_number));
// 记录当前brick中地址最大的plug
args->highest_plug = tree;
#ifdef SHORT_PLUGS
if (is_plug_padded (plug))
{
dprintf (3, ("%Ix padded", plug));
clear_plug_padded (plug);
}
#endif //SHORT_PLUGS
gen_crossing:
{
// 如果current_gen_limit等于MAX_PTR,表示我们需要先决定gen 2的边界
// 如果plug >= args->current_gen_limit并且plug在ephemeral heap segment,表示我们需要决定gen 1或gen 0的边界
// 决定的流程如下
// - 第一次current_gen_limit == MAX_PTR,在处理所有对象之前决定gen 2的边界
// - 第二次plug超过了generation_allocation_start (generation_of ((gen_number - 2)))并且在ephemeral heap segment中,决定gen 1的边界
// - 因为plug不会超过heap_segment_reserved (ephemeral_heap_segment),第三次会在上面的"设置剩余的代边界"中决定gen 0的边界
if ((args->current_gen_limit == MAX_PTR) ||
((plug >= args->current_gen_limit) &&
ephemeral_pointer_p (plug)))
{
dprintf(3,(" Crossing Generation boundary at %Ix",
(size_t)args->current_gen_limit));
// 在处理所有对象之前决定gen 2的边界时,不需要减1
if (!(args->current_gen_limit == MAX_PTR))
{
args->free_list_gen_number--;
args->free_list_gen = generation_of (args->free_list_gen_number);
}
dprintf(3,( " Fixing generation start of %d to: %Ix",
args->free_list_gen_number, (size_t)gap));
// 决定代边界
reset_allocation_pointers (args->free_list_gen, gap);
// 更新current_gen_limit用于决定下一个代的边界
args->current_gen_limit = generation_limit (args->free_list_gen_number);
// 保证代中最少有一个对象
// 如果这个gap比较大(大于最小对象大小 * 2),剩余的空间还可以在下面放到free list中
if ((gap_size >= (2*Align (min_obj_size))))
{
dprintf(3,(" Splitting the gap in two %Id left",
gap_size));
make_unused_array (gap, Align(min_obj_size));
gap_size = (gap_size - Align(min_obj_size));
gap = (gap + Align(min_obj_size));
}
else
{
make_unused_array (gap, gap_size);
gap_size = 0;
}
goto gen_crossing;
}
}
// 加到free list中
thread_gap (gap, gap_size, args->free_list_gen);
add_gen_free (args->free_list_gen->gen_num, gap_size);
}
// 处理右边的节点
if (! (0 == right_node))
{
make_free_list_in_brick (tree + right_node, args);
}
}
}
}
压缩阶段结束以后还需要做一些收尾工作,请从上面plan_phase
中的recover_saved_pinned_info();
继续看。
参考链接
https://github.com/dotnet/coreclr/blob/master/Documentation/botr/garbage-collection.md
https://raw.githubusercontent.com/dotnet/coreclr/release/1.1.0/src/gc/gc.cpp
https://github.com/dotnet/coreclr/blob/release/1.1.0/src/gc/gcimpl.h
https://github.com/dotnet/coreclr/blob/release/1.1.0/src/gc/gcpriv.h
https://github.com/dotnet/coreclr/issues/8959
https://github.com/dotnet/coreclr/issues/8995
https://github.com/dotnet/coreclr/issues/9053
https://github.com/dotnet/coreclr/issues/10137
https://github.com/dotnet/coreclr/issues/10305
https://github.com/dotnet/coreclr/issues/10141
写在最后
GC的实际处理远远比文档和书中写的要复杂,希望这一篇文章可以让你更加深入的理解CoreCLR,如果你发现了错误或者有疑问的地方请指出来,
另外这篇文章有一些部分尚未涵盖到,例如SuspendEE的原理,后台GC的处理和stackwalking等,希望以后可以再花时间去研究它们。
下一篇我将会实际使用LLDB跟踪GC收集垃圾的处理,再下一篇会写JIT相关的内容,敬请期待。
CoreCLR的更多相关文章
- CoreCLR源码探索(一) Object是什么
.Net程序员们每天都在和Object在打交道 如果你问一个.Net程序员什么是Object,他可能会信誓旦旦的告诉你"Object还不简单吗,就是所有类型的基类" 这个答案是对的 ...
- 【置顶】CoreCLR系列随笔
CoreCLR配置系列 在Windows上编译和调试CoreCLR GC探索系列 C++随笔:.NET CoreCLR之GC探索(1) C++随笔:.NET CoreCLR之GC探索(2) C++随笔 ...
- .NET CoreCLR开发人员指南(上)
1.为什么每一个CLR开发人员都需要读这篇文章 和所有的其他的大型代码库相比,CLR代码库有很多而且比较成熟的代码调试工具去检测BUG.对于程序员来说,理解这些规则和习惯写法非常的重要. 这篇文章让所 ...
- C++随笔:.NET CoreCLR之GC探索(4)
今天继续来 带大家讲解CoreCLR之GC,首先我们继续看这个GCSample,这篇文章是上一篇文章的继续,如果有不清楚的,还请翻到我写的上一篇随笔.下面我们继续: // Initialize fre ...
- C++随笔:.NET CoreCLR之GC探索(3)
有几天没写GC相关的文章了哈,今天我讲GC的方式是通过一个小的Sample来讲解,这个小的示例代码只有全部Build成功了才会有.地址为D:\coreclr2\coreclr\bin\obj\Wind ...
- C++随笔:从Hello World 探秘CoreCLR的内部(1)
紧接着上次的问题,上次的问题其实很简单,就是HelloWorld.exe运行失败,而本文的目的,就是成功调试HelloWorld这个控制台应用程序. 通过我的寻找,其实是一个名为TryRun的文件出了 ...
- 在Windows上编译和调试CoreCLR
生成CoreCLR - Windows篇 本文的唯一目的就是让你运行Hello World 运行环境 Window 7+ Visual studio 2015 确保C++ 工具已经被安装,默认是不安装 ...
- C++随笔:.NET CoreCLR之corleCLR核心探索之coreconsole(2)
这篇文章是上篇的续集,本文将会继续介绍coreconsole.cpp里面的逻辑.也许大家会看一些CLR的书,我承认我没有看过,因为我觉得一个人,他再NB,那也是他自己的眼光,而且说句难听的,CLR也不 ...
- C++随笔:.NET CoreCLR之corleCLR核心探索之coreconsole(1)
一看这个标题,是不去取名有点绕呢?或者是,还有些问题?报告LZ...你的标题取得有问题,是个病句!↖(^ω^)↗!!!先不要急,其实我今天带给大家的就是CoreCLR中的coreclr.其中它是在名字 ...
- C++随笔:.NET CoreCLR之GC探索(1)
一直是.NET程序员,但是.NET的核心其实还是C++,所以我准备花 一点时间来研究CoreCLR和CoreFX.希望这个系列的文章能给大家带来 帮助. GC的代码有很多很多,而且结构层次对于一个初学 ...
随机推荐
- 【boost】使用serialization库序列化子类
boost.serialization库是一个非常强大又易用的序列化库,用于对象的保存与持久化等. 使用base_object可以在序列化子类的同时也序列化父类,以此获得足够的信息来从文件或网络数据中 ...
- aop 例子(annotation方式实现)
面向切面编程(也叫面向方面),可以通过预编译方式和运行期动态代理实现在不修改源代码的情况下给程序动态统一添加功能的一种技术.AOP实际是GoF设计模式的延续,设计模式孜孜不倦追求的是调用者和被调用者之 ...
- About ListView
这一篇整理一些ListView的基本知识. PartA翻译自API Guide: (A)API Guide 使用Adapter建立(bind)Layout 当layout内容是动态的或者不是预先决定好 ...
- umount 卸载 无响应的 NFS 文件系统
当NFS Client 无法访问 NFS Server的适合,在Client上df操作等就会挂起. 这个适合需要将挂载的NFS卸载掉.在不知道挂载点的情况下,可以使用nfsstat -m 命令来查看. ...
- 集训Day5
生活还得继续 bzoj3771 题面让我笑了很长时间 给出 n个物品,价值为别为Xi且各不相同,现在可以取1个.2个或3个,问每种价值和有几种情况? *顺序不同算一种 很傻逼的一个母函数+容斥,用A( ...
- liunx命令之:命令链接ftp服务器
1. 连接ftp服务器 格式:ftp [hostname| ip-address]a)在linux命令行下输入: ftp 192.168.1.1 b)服务器询问你用户名和密码,分别输入用户名和相应密码 ...
- P2042 [NOI2005]维护数列[splay或非旋treap·毒瘤题]
P2042 [NOI2005]维护数列 数列区间和,最大子列和(必须不为空),支持翻转.修改值.插入删除. 练码力的题,很毒瘤.个人因为太菜了,对splay极其生疏,犯了大量错误,在此记录,望以后一定 ...
- VijosP1626:爱在心中
描述 “每个人都拥有一个梦,即使彼此不相同,能够与你分享,无论失败成功都会感动.爱因为在心中,平凡而不平庸,世界就像迷宫,却又让我们此刻相逢Our Home.” 在爱的国度里有N个人,在他们的心中都有 ...
- POJ2253(djkstra求最长最短边)
Frogger Time Limit: 1000MS Memory Limit: 65536K Total Submissions: 32257 Accepted: 10396 Descrip ...
- zk 09之:Curator之二:Path Cache监控zookeeper的node和path的状态
在实际应用开发中,当某个ZNode发生变化后我们需要得到通知并做一些后续处理,Curator Recipes提供了Path Cache 来帮助我们轻松实现watch ZNode. Path Cache ...