/* * Copyright (c) 2004, 2016, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #ifndef SHARE_VM_GC_SHARED_ADAPTIVESIZEPOLICY_HPP #define SHARE_VM_GC_SHARED_ADAPTIVESIZEPOLICY_HPP #include "gc/shared/collectedHeap.hpp" #include "gc/shared/gcCause.hpp" #include "gc/shared/gcUtil.hpp" #include "logging/log.hpp" #include "memory/allocation.hpp" #include "memory/universe.hpp" // This class keeps statistical information and computes the // size of the heap. // Forward decls class elapsedTimer; class SoftRefPolicy; class AdaptiveSizePolicy : public CHeapObj { friend class GCAdaptivePolicyCounters; friend class PSGCAdaptivePolicyCounters; friend class CMSGCAdaptivePolicyCounters; protected: enum GCPolicyKind { _gc_adaptive_size_policy, _gc_ps_adaptive_size_policy, _gc_cms_adaptive_size_policy }; virtual GCPolicyKind kind() const { return _gc_adaptive_size_policy; } enum SizePolicyTrueValues { decrease_old_gen_for_throughput_true = -7, decrease_young_gen_for_througput_true = -6, increase_old_gen_for_min_pauses_true = -5, decrease_old_gen_for_min_pauses_true = -4, decrease_young_gen_for_maj_pauses_true = -3, increase_young_gen_for_min_pauses_true = -2, increase_old_gen_for_maj_pauses_true = -1, decrease_young_gen_for_min_pauses_true = 1, decrease_old_gen_for_maj_pauses_true = 2, increase_young_gen_for_maj_pauses_true = 3, increase_old_gen_for_throughput_true = 4, increase_young_gen_for_througput_true = 5, decrease_young_gen_for_footprint_true = 6, decrease_old_gen_for_footprint_true = 7, decide_at_full_gc_true = 8 }; // Goal for the fraction of the total time during which application // threads run const double _throughput_goal; // Last calculated sizes, in bytes, and aligned size_t _eden_size; // calculated eden free space in bytes size_t _promo_size; // calculated cms gen free space in bytes size_t _survivor_size; // calculated survivor size in bytes // This is a hint for the heap: we've detected that GC times // are taking longer than GCTimeLimit allows. bool _gc_overhead_limit_exceeded; // Use for diagnostics only. If UseGCOverheadLimit is false, // this variable is still set. bool _print_gc_overhead_limit_would_be_exceeded; // Count of consecutive GC that have exceeded the // GC time limit criterion uint _gc_overhead_limit_count; // This flag signals that GCTimeLimit is being exceeded // but may not have done so for the required number of consecutive // collections // Minor collection timers used to determine both // pause and interval times for collections static elapsedTimer _minor_timer; // Major collection timers, used to determine both // pause and interval times for collections static elapsedTimer _major_timer; // Time statistics AdaptivePaddedAverage* _avg_minor_pause; AdaptiveWeightedAverage* _avg_minor_interval; AdaptiveWeightedAverage* _avg_minor_gc_cost; AdaptiveWeightedAverage* _avg_major_interval; AdaptiveWeightedAverage* _avg_major_gc_cost; // Footprint statistics AdaptiveWeightedAverage* _avg_young_live; AdaptiveWeightedAverage* _avg_eden_live; AdaptiveWeightedAverage* _avg_old_live; // Statistics for survivor space calculation for young generation AdaptivePaddedAverage* _avg_survived; // Objects that have been directly allocated in the old generation AdaptivePaddedNoZeroDevAverage* _avg_pretenured; // Variable for estimating the major and minor pause times. // These variables represent linear least-squares fits of // the data. // minor pause time vs. old gen size LinearLeastSquareFit* _minor_pause_old_estimator; // minor pause time vs. young gen size LinearLeastSquareFit* _minor_pause_young_estimator; // Variables for estimating the major and minor collection costs // minor collection time vs. young gen size LinearLeastSquareFit* _minor_collection_estimator; // major collection time vs. cms gen size LinearLeastSquareFit* _major_collection_estimator; // These record the most recent collection times. They // are available as an alternative to using the averages // for making ergonomic decisions. double _latest_minor_mutator_interval_seconds; // Allowed difference between major and minor GC times, used // for computing tenuring_threshold const double _threshold_tolerance_percent; const double _gc_pause_goal_sec; // Goal for maximum GC pause // Flag indicating that the adaptive policy is ready to use bool _young_gen_policy_is_ready; // Decrease/increase the young generation for minor pause time int _change_young_gen_for_min_pauses; // Decrease/increase the old generation for major pause time int _change_old_gen_for_maj_pauses; // change old generation for throughput int _change_old_gen_for_throughput; // change young generation for throughput int _change_young_gen_for_throughput; // Flag indicating that the policy would // increase the tenuring threshold because of the total major GC cost // is greater than the total minor GC cost bool _increment_tenuring_threshold_for_gc_cost; // decrease the tenuring threshold because of the the total minor GC // cost is greater than the total major GC cost bool _decrement_tenuring_threshold_for_gc_cost; // decrease due to survivor size limit bool _decrement_tenuring_threshold_for_survivor_limit; // decrease generation sizes for footprint int _decrease_for_footprint; // Set if the ergonomic decisions were made at a full GC. int _decide_at_full_gc; // Changing the generation sizing depends on the data that is // gathered about the effects of changes on the pause times and // throughput. These variable count the number of data points // gathered. The policy may use these counters as a threshold // for reliable data. julong _young_gen_change_for_minor_throughput; julong _old_gen_change_for_major_throughput; static const uint GCWorkersPerJavaThread = 2; // Accessors double gc_pause_goal_sec() const { return _gc_pause_goal_sec; } // The value returned is unitless: it's the proportion of time // spent in a particular collection type. // An interval time will be 0.0 if a collection type hasn't occurred yet. // The 1.4.2 implementation put a floor on the values of major_gc_cost // and minor_gc_cost. This was useful because of the way major_gc_cost // and minor_gc_cost was used in calculating the sizes of the generations. // Do not use a floor in this implementation because any finite value // will put a limit on the throughput that can be achieved and any // throughput goal above that limit will drive the generations sizes // to extremes. double major_gc_cost() const { return MAX2(0.0F, _avg_major_gc_cost->average()); } // The value returned is unitless: it's the proportion of time // spent in a particular collection type. // An interval time will be 0.0 if a collection type hasn't occurred yet. // The 1.4.2 implementation put a floor on the values of major_gc_cost // and minor_gc_cost. This was useful because of the way major_gc_cost // and minor_gc_cost was used in calculating the sizes of the generations. // Do not use a floor in this implementation because any finite value // will put a limit on the throughput that can be achieved and any // throughput goal above that limit will drive the generations sizes // to extremes. double minor_gc_cost() const { return MAX2(0.0F, _avg_minor_gc_cost->average()); } // Because we're dealing with averages, gc_cost() can be // larger than 1.0 if just the sum of the minor cost the // the major cost is used. Worse than that is the // fact that the minor cost and the major cost each // tend toward 1.0 in the extreme of high GC costs. // Limit the value of gc_cost to 1.0 so that the mutator // cost stays non-negative. virtual double gc_cost() const { double result = MIN2(1.0, minor_gc_cost() + major_gc_cost()); assert(result >= 0.0, "Both minor and major costs are non-negative"); return result; } // Elapsed time since the last major collection. virtual double time_since_major_gc() const; // Average interval between major collections to be used // in calculating the decaying major GC cost. An overestimate // of this time would be a conservative estimate because // this time is used to decide if the major GC cost // should be decayed (i.e., if the time since the last // major GC is long compared to the time returned here, // then the major GC cost will be decayed). See the // implementations for the specifics. virtual double major_gc_interval_average_for_decay() const { return _avg_major_interval->average(); } // Return the cost of the GC where the major GC cost // has been decayed based on the time since the last // major collection. double decaying_gc_cost() const; // Decay the major GC cost. Use this only for decisions on // whether to adjust, not to determine by how much to adjust. // This approximation is crude and may not be good enough for the // latter. double decaying_major_gc_cost() const; // Return the mutator cost using the decayed // GC cost. double adjusted_mutator_cost() const { double result = 1.0 - decaying_gc_cost(); assert(result >= 0.0, "adjusted mutator cost calculation is incorrect"); return result; } virtual double mutator_cost() const { double result = 1.0 - gc_cost(); assert(result >= 0.0, "mutator cost calculation is incorrect"); return result; } bool young_gen_policy_is_ready() { return _young_gen_policy_is_ready; } void update_minor_pause_young_estimator(double minor_pause_in_ms); virtual void update_minor_pause_old_estimator(double minor_pause_in_ms) { // This is not meaningful for all policies but needs to be present // to use minor_collection_end() in its current form. } virtual size_t eden_increment(size_t cur_eden); virtual size_t eden_increment(size_t cur_eden, uint percent_change); virtual size_t eden_decrement(size_t cur_eden); virtual size_t promo_increment(size_t cur_eden); virtual size_t promo_increment(size_t cur_eden, uint percent_change); virtual size_t promo_decrement(size_t cur_eden); virtual void clear_generation_free_space_flags(); int change_old_gen_for_throughput() const { return _change_old_gen_for_throughput; } void set_change_old_gen_for_throughput(int v) { _change_old_gen_for_throughput = v; } int change_young_gen_for_throughput() const { return _change_young_gen_for_throughput; } void set_change_young_gen_for_throughput(int v) { _change_young_gen_for_throughput = v; } int change_old_gen_for_maj_pauses() const { return _change_old_gen_for_maj_pauses; } void set_change_old_gen_for_maj_pauses(int v) { _change_old_gen_for_maj_pauses = v; } bool decrement_tenuring_threshold_for_gc_cost() const { return _decrement_tenuring_threshold_for_gc_cost; } void set_decrement_tenuring_threshold_for_gc_cost(bool v) { _decrement_tenuring_threshold_for_gc_cost = v; } bool increment_tenuring_threshold_for_gc_cost() const { return _increment_tenuring_threshold_for_gc_cost; } void set_increment_tenuring_threshold_for_gc_cost(bool v) { _increment_tenuring_threshold_for_gc_cost = v; } bool decrement_tenuring_threshold_for_survivor_limit() const { return _decrement_tenuring_threshold_for_survivor_limit; } void set_decrement_tenuring_threshold_for_survivor_limit(bool v) { _decrement_tenuring_threshold_for_survivor_limit = v; } // Return true if the policy suggested a change. bool tenuring_threshold_change() const; static bool _debug_perturbation; public: AdaptiveSizePolicy(size_t init_eden_size, size_t init_promo_size, size_t init_survivor_size, double gc_pause_goal_sec, uint gc_cost_ratio); // Return number default GC threads to use in the next GC. static uint calc_default_active_workers(uintx total_workers, const uintx min_workers, uintx active_workers, uintx application_workers); // Return number of GC threads to use in the next GC. // This is called sparingly so as not to change the // number of GC workers gratuitously. // For ParNew collections // For PS scavenge and ParOld collections // For G1 evacuation pauses (subject to update) // Other collection phases inherit the number of // GC workers from the calls above. For example, // a CMS parallel remark uses the same number of GC // workers as the most recent ParNew collection. static uint calc_active_workers(uintx total_workers, uintx active_workers, uintx application_workers); // Return number of GC threads to use in the next concurrent GC phase. static uint calc_active_conc_workers(uintx total_workers, uintx active_workers, uintx application_workers); bool is_gc_cms_adaptive_size_policy() { return kind() == _gc_cms_adaptive_size_policy; } bool is_gc_ps_adaptive_size_policy() { return kind() == _gc_ps_adaptive_size_policy; } AdaptivePaddedAverage* avg_minor_pause() const { return _avg_minor_pause; } AdaptiveWeightedAverage* avg_minor_interval() const { return _avg_minor_interval; } AdaptiveWeightedAverage* avg_minor_gc_cost() const { return _avg_minor_gc_cost; } AdaptiveWeightedAverage* avg_major_gc_cost() const { return _avg_major_gc_cost; } AdaptiveWeightedAverage* avg_young_live() const { return _avg_young_live; } AdaptiveWeightedAverage* avg_eden_live() const { return _avg_eden_live; } AdaptiveWeightedAverage* avg_old_live() const { return _avg_old_live; } AdaptivePaddedAverage* avg_survived() const { return _avg_survived; } AdaptivePaddedNoZeroDevAverage* avg_pretenured() { return _avg_pretenured; } // Methods indicating events of interest to the adaptive size policy, // called by GC algorithms. It is the responsibility of users of this // policy to call these methods at the correct times! virtual void minor_collection_begin(); virtual void minor_collection_end(GCCause::Cause gc_cause); virtual LinearLeastSquareFit* minor_pause_old_estimator() const { return _minor_pause_old_estimator; } LinearLeastSquareFit* minor_pause_young_estimator() { return _minor_pause_young_estimator; } LinearLeastSquareFit* minor_collection_estimator() { return _minor_collection_estimator; } LinearLeastSquareFit* major_collection_estimator() { return _major_collection_estimator; } float minor_pause_young_slope() { return _minor_pause_young_estimator->slope(); } float minor_collection_slope() { return _minor_collection_estimator->slope();} float major_collection_slope() { return _major_collection_estimator->slope();} float minor_pause_old_slope() { return _minor_pause_old_estimator->slope(); } void set_eden_size(size_t new_size) { _eden_size = new_size; } void set_survivor_size(size_t new_size) { _survivor_size = new_size; } size_t calculated_eden_size_in_bytes() const { return _eden_size; } size_t calculated_promo_size_in_bytes() const { return _promo_size; } size_t calculated_survivor_size_in_bytes() const { return _survivor_size; } // This is a hint for the heap: we've detected that gc times // are taking longer than GCTimeLimit allows. // Most heaps will choose to throw an OutOfMemoryError when // this occurs but it is up to the heap to request this information // of the policy bool gc_overhead_limit_exceeded() { return _gc_overhead_limit_exceeded; } void set_gc_overhead_limit_exceeded(bool v) { _gc_overhead_limit_exceeded = v; } // Tests conditions indicate the GC overhead limit is being approached. bool gc_overhead_limit_near() { return gc_overhead_limit_count() >= (AdaptiveSizePolicyGCTimeLimitThreshold - 1); } uint gc_overhead_limit_count() { return _gc_overhead_limit_count; } void reset_gc_overhead_limit_count() { _gc_overhead_limit_count = 0; } void inc_gc_overhead_limit_count() { _gc_overhead_limit_count++; } // accessors for flags recording the decisions to resize the // generations to meet the pause goal. int change_young_gen_for_min_pauses() const { return _change_young_gen_for_min_pauses; } void set_change_young_gen_for_min_pauses(int v) { _change_young_gen_for_min_pauses = v; } void set_decrease_for_footprint(int v) { _decrease_for_footprint = v; } int decrease_for_footprint() const { return _decrease_for_footprint; } int decide_at_full_gc() { return _decide_at_full_gc; } void set_decide_at_full_gc(int v) { _decide_at_full_gc = v; } // Check the conditions for an out-of-memory due to excessive GC time. // Set _gc_overhead_limit_exceeded if all the conditions have been met. void check_gc_overhead_limit(size_t young_live, size_t eden_live, size_t max_old_gen_size, size_t max_eden_size, bool is_full_gc, GCCause::Cause gc_cause, SoftRefPolicy* soft_ref_policy); static bool should_update_promo_stats(GCCause::Cause cause) { return ((GCCause::is_user_requested_gc(cause) && UseAdaptiveSizePolicyWithSystemGC) || GCCause::is_tenured_allocation_failure_gc(cause)); } static bool should_update_eden_stats(GCCause::Cause cause) { return ((GCCause::is_user_requested_gc(cause) && UseAdaptiveSizePolicyWithSystemGC) || GCCause::is_allocation_failure_gc(cause)); } // Printing support virtual bool print() const; void print_tenuring_threshold(uint new_tenuring_threshold) const; }; #endif // SHARE_VM_GC_SHARED_ADAPTIVESIZEPOLICY_HPP