/* * Copyright (c) 2001, 2013, 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_IMPLEMENTATION_SHARED_ALLOCATIONSTATS_HPP #define SHARE_VM_GC_IMPLEMENTATION_SHARED_ALLOCATIONSTATS_HPP #include "utilities/macros.hpp" #include "memory/allocation.hpp" #include "utilities/globalDefinitions.hpp" #include "gc_implementation/shared/gcUtil.hpp" class AllocationStats VALUE_OBJ_CLASS_SPEC { // A duration threshold (in ms) used to filter // possibly unreliable samples. static float _threshold; // We measure the demand between the end of the previous sweep and // beginning of this sweep: // Count(end_last_sweep) - Count(start_this_sweep) // + split_births(between) - split_deaths(between) // The above number divided by the time since the end of the // previous sweep gives us a time rate of demand for blocks // of this size. We compute a padded average of this rate as // our current estimate for the time rate of demand for blocks // of this size. Similarly, we keep a padded average for the time // between sweeps. Our current estimate for demand for blocks of // this size is then simply computed as the product of these two // estimates. AdaptivePaddedAverage _demand_rate_estimate; ssize_t _desired; // Demand stimate computed as described above ssize_t _coal_desired; // desired +/- small-percent for tuning coalescing ssize_t _surplus; // count - (desired +/- small-percent), // used to tune splitting in best fit ssize_t _bfr_surp; // surplus at start of current sweep ssize_t _prev_sweep; // count from end of previous sweep ssize_t _before_sweep; // count from before current sweep ssize_t _coal_births; // additional chunks from coalescing ssize_t _coal_deaths; // loss from coalescing ssize_t _split_births; // additional chunks from splitting ssize_t _split_deaths; // loss from splitting size_t _returned_bytes; // number of bytes returned to list. public: void initialize(bool split_birth = false) { AdaptivePaddedAverage* dummy = new (&_demand_rate_estimate) AdaptivePaddedAverage(CMS_FLSWeight, CMS_FLSPadding); _desired = 0; _coal_desired = 0; _surplus = 0; _bfr_surp = 0; _prev_sweep = 0; _before_sweep = 0; _coal_births = 0; _coal_deaths = 0; _split_births = (split_birth ? 1 : 0); _split_deaths = 0; _returned_bytes = 0; } AllocationStats() { initialize(); } // The rate estimate is in blocks per second. void compute_desired(size_t count, float inter_sweep_current, float inter_sweep_estimate, float intra_sweep_estimate) { // If the latest inter-sweep time is below our granularity // of measurement, we may call in here with // inter_sweep_current == 0. However, even for suitably small // but non-zero inter-sweep durations, we may not trust the accuracy // of accumulated data, since it has not been "integrated" // (read "low-pass-filtered") long enough, and would be // vulnerable to noisy glitches. In such cases, we // ignore the current sample and use currently available // historical estimates. assert(prev_sweep() + split_births() + coal_births() // "Total Production Stock" >= split_deaths() + coal_deaths() + (ssize_t)count, // "Current stock + depletion" "Conservation Principle"); if (inter_sweep_current > _threshold) { ssize_t demand = prev_sweep() - (ssize_t)count + split_births() + coal_births() - split_deaths() - coal_deaths(); assert(demand >= 0, err_msg("Demand (" SSIZE_FORMAT ") should be non-negative for " PTR_FORMAT " (size=" SIZE_FORMAT ")", demand, this, count)); // Defensive: adjust for imprecision in event counting if (demand < 0) { demand = 0; } float old_rate = _demand_rate_estimate.padded_average(); float rate = ((float)demand)/inter_sweep_current; _demand_rate_estimate.sample(rate); float new_rate = _demand_rate_estimate.padded_average(); ssize_t old_desired = _desired; float delta_ise = (CMSExtrapolateSweep ? intra_sweep_estimate : 0.0); _desired = (ssize_t)(new_rate * (inter_sweep_estimate + delta_ise)); if (PrintFLSStatistics > 1) { gclog_or_tty->print_cr("demand: %d, old_rate: %f, current_rate: %f, new_rate: %f, old_desired: %d, new_desired: %d", demand, old_rate, rate, new_rate, old_desired, _desired); } } } ssize_t desired() const { return _desired; } void set_desired(ssize_t v) { _desired = v; } ssize_t coal_desired() const { return _coal_desired; } void set_coal_desired(ssize_t v) { _coal_desired = v; } ssize_t surplus() const { return _surplus; } void set_surplus(ssize_t v) { _surplus = v; } void increment_surplus() { _surplus++; } void decrement_surplus() { _surplus--; } ssize_t bfr_surp() const { return _bfr_surp; } void set_bfr_surp(ssize_t v) { _bfr_surp = v; } ssize_t prev_sweep() const { return _prev_sweep; } void set_prev_sweep(ssize_t v) { _prev_sweep = v; } ssize_t before_sweep() const { return _before_sweep; } void set_before_sweep(ssize_t v) { _before_sweep = v; } ssize_t coal_births() const { return _coal_births; } void set_coal_births(ssize_t v) { _coal_births = v; } void increment_coal_births() { _coal_births++; } ssize_t coal_deaths() const { return _coal_deaths; } void set_coal_deaths(ssize_t v) { _coal_deaths = v; } void increment_coal_deaths() { _coal_deaths++; } ssize_t split_births() const { return _split_births; } void set_split_births(ssize_t v) { _split_births = v; } void increment_split_births() { _split_births++; } ssize_t split_deaths() const { return _split_deaths; } void set_split_deaths(ssize_t v) { _split_deaths = v; } void increment_split_deaths() { _split_deaths++; } NOT_PRODUCT( size_t returned_bytes() const { return _returned_bytes; } void set_returned_bytes(size_t v) { _returned_bytes = v; } ) }; #endif // SHARE_VM_GC_IMPLEMENTATION_SHARED_ALLOCATIONSTATS_HPP