src/hotspot/share/gc/g1/g1EvacStats.cpp
author eosterlund
Mon, 26 Feb 2018 09:34:12 +0100
changeset 49164 7e958a8ebcd3
parent 47216 71c04702a3d5
child 50113 caf115bb98ad
permissions -rw-r--r--
8195142: Refactor out card table from CardTableModRefBS to flatten the BarrierSet hierarchy Reviewed-by: stefank, coleenp, kvn, ehelin

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#include "precompiled.hpp"
#include "memory/allocation.inline.hpp"
#include "gc/g1/g1_globals.hpp"
#include "gc/g1/g1EvacStats.hpp"
#include "gc/shared/gcId.hpp"
#include "logging/log.hpp"
#include "trace/tracing.hpp"

void G1EvacStats::log_plab_allocation() {
  PLABStats::log_plab_allocation();
  log_debug(gc, plab)("%s other allocation: "
                      "region end waste: " SIZE_FORMAT "B, "
                      "regions filled: %u, "
                      "direct allocated: " SIZE_FORMAT "B, "
                      "failure used: " SIZE_FORMAT "B, "
                      "failure wasted: " SIZE_FORMAT "B",
                      _description,
                      _region_end_waste * HeapWordSize,
                      _regions_filled,
                      _direct_allocated * HeapWordSize,
                      _failure_used * HeapWordSize,
                      _failure_waste * HeapWordSize);
}

size_t G1EvacStats::compute_desired_plab_sz() {
  // The size of the PLAB caps the amount of space that can be wasted at the
  // end of the collection. In the worst case the last PLAB could be completely
  // empty.
  // This allows us to calculate the new PLAB size to achieve the
  // TargetPLABWastePct given the latest memory usage and that the last buffer
  // will be G1LastPLABAverageOccupancy full.
  //
  // E.g. assume that if in the current GC 100 words were allocated and a
  // TargetPLABWastePct of 10 had been set.
  //
  // So we could waste up to 10 words to meet that percentage. Given that we
  // also assume that that buffer is typically half-full, the new desired PLAB
  // size is set to 20 words.
  //
  // The amount of allocation performed should be independent of the number of
  // threads, so should the maximum waste we can spend in total. So if
  // we used n threads to allocate, each of them can spend maximum waste/n words in
  // a first rough approximation. The number of threads only comes into play later
  // when actually retrieving the actual desired PLAB size.
  //
  // After calculating this optimal PLAB size the algorithm applies the usual
  // exponential decaying average over this value to guess the next PLAB size.
  //
  // We account region end waste fully to PLAB allocation (in the calculation of
  // what we consider as "used_for_waste_calculation" below). This is not
  // completely fair, but is a conservative assumption because PLABs may be sized
  // flexibly while we cannot adjust inline allocations.
  // Allocation during GC will try to minimize region end waste so this impact
  // should be minimal.
  //
  // We need to cover overflow when calculating the amount of space actually used
  // by objects in PLABs when subtracting the region end waste.
  // Region end waste may be higher than actual allocation. This may occur if many
  // threads do not allocate anything but a few rather large objects. In this
  // degenerate case the PLAB size would simply quickly tend to minimum PLAB size,
  // which is an okay reaction.
  size_t const used_for_waste_calculation = used() > _region_end_waste ? used() - _region_end_waste : 0;

  size_t const total_waste_allowed = used_for_waste_calculation * TargetPLABWastePct;
  size_t const cur_plab_sz = (size_t)((double)total_waste_allowed / G1LastPLABAverageOccupancy);
  return cur_plab_sz;
}

G1EvacStats::G1EvacStats(const char* description, size_t desired_plab_sz_, unsigned wt) :
  PLABStats(description, desired_plab_sz_, wt),
  _region_end_waste(0),
  _regions_filled(0),
  _direct_allocated(0),
  _failure_used(0),
  _failure_waste(0) {
}


G1EvacStats::~G1EvacStats() { }