view src/share/vm/memory/cardTableModRefBS.hpp @ 4527:6f817ce50129

8010992: Remove calls to global ::operator new[] and new Summary: disable use of global operator new and new[] which could cause unexpected exception and escape from NMT tracking. Reviewed-by: coleenp, dholmes, zgu Contributed-by: yumin.qi@oracle.com
author minqi
date Fri, 19 Apr 2013 11:08:52 -0700
parents da91efe96a93
children 5a9fa2ba85f0
line wrap: on
line source
/*
 * Copyright (c) 2000, 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_MEMORY_CARDTABLEMODREFBS_HPP
#define SHARE_VM_MEMORY_CARDTABLEMODREFBS_HPP

#include "memory/modRefBarrierSet.hpp"
#include "oops/oop.hpp"
#include "oops/oop.inline2.hpp"

// This kind of "BarrierSet" allows a "CollectedHeap" to detect and
// enumerate ref fields that have been modified (since the last
// enumeration.)

// As it currently stands, this barrier is *imprecise*: when a ref field in
// an object "o" is modified, the card table entry for the card containing
// the head of "o" is dirtied, not necessarily the card containing the
// modified field itself.  For object arrays, however, the barrier *is*
// precise; only the card containing the modified element is dirtied.
// Any MemRegionClosures used to scan dirty cards should take these
// considerations into account.

class Generation;
class OopsInGenClosure;
class DirtyCardToOopClosure;
class ClearNoncleanCardWrapper;

class CardTableModRefBS: public ModRefBarrierSet {
  // Some classes get to look at some private stuff.
  friend class BytecodeInterpreter;
  friend class VMStructs;
  friend class CardTableRS;
  friend class CheckForUnmarkedOops; // Needs access to raw card bytes.
  friend class SharkBuilder;
#ifndef PRODUCT
  // For debugging.
  friend class GuaranteeNotModClosure;
#endif
 protected:

  enum CardValues {
    clean_card                  = -1,
    // The mask contains zeros in places for all other values.
    clean_card_mask             = clean_card - 31,

    dirty_card                  =  0,
    precleaned_card             =  1,
    claimed_card                =  2,
    deferred_card               =  4,
    last_card                   =  8,
    CT_MR_BS_last_reserved      = 16
  };

  // a word's worth (row) of clean card values
  static const intptr_t clean_card_row = (intptr_t)(-1);

  // dirty and precleaned are equivalent wrt younger_refs_iter.
  static bool card_is_dirty_wrt_gen_iter(jbyte cv) {
    return cv == dirty_card || cv == precleaned_card;
  }

  // Returns "true" iff the value "cv" will cause the card containing it
  // to be scanned in the current traversal.  May be overridden by
  // subtypes.
  virtual bool card_will_be_scanned(jbyte cv) {
    return CardTableModRefBS::card_is_dirty_wrt_gen_iter(cv);
  }

  // Returns "true" iff the value "cv" may have represented a dirty card at
  // some point.
  virtual bool card_may_have_been_dirty(jbyte cv) {
    return card_is_dirty_wrt_gen_iter(cv);
  }

  // The declaration order of these const fields is important; see the
  // constructor before changing.
  const MemRegion _whole_heap;       // the region covered by the card table
  const size_t    _guard_index;      // index of very last element in the card
                                     // table; it is set to a guard value
                                     // (last_card) and should never be modified
  const size_t    _last_valid_index; // index of the last valid element
  const size_t    _page_size;        // page size used when mapping _byte_map
  const size_t    _byte_map_size;    // in bytes
  jbyte*          _byte_map;         // the card marking array

  int _cur_covered_regions;
  // The covered regions should be in address order.
  MemRegion* _covered;
  // The committed regions correspond one-to-one to the covered regions.
  // They represent the card-table memory that has been committed to service
  // the corresponding covered region.  It may be that committed region for
  // one covered region corresponds to a larger region because of page-size
  // roundings.  Thus, a committed region for one covered region may
  // actually extend onto the card-table space for the next covered region.
  MemRegion* _committed;

  // The last card is a guard card, and we commit the page for it so
  // we can use the card for verification purposes. We make sure we never
  // uncommit the MemRegion for that page.
  MemRegion _guard_region;

 protected:
  // Initialization utilities; covered_words is the size of the covered region
  // in, um, words.
  inline size_t cards_required(size_t covered_words);
  inline size_t compute_byte_map_size();

  // Finds and return the index of the region, if any, to which the given
  // region would be contiguous.  If none exists, assign a new region and
  // returns its index.  Requires that no more than the maximum number of
  // covered regions defined in the constructor are ever in use.
  int find_covering_region_by_base(HeapWord* base);

  // Same as above, but finds the region containing the given address
  // instead of starting at a given base address.
  int find_covering_region_containing(HeapWord* addr);

  // Resize one of the regions covered by the remembered set.
  void resize_covered_region(MemRegion new_region);

  // Returns the leftmost end of a committed region corresponding to a
  // covered region before covered region "ind", or else "NULL" if "ind" is
  // the first covered region.
  HeapWord* largest_prev_committed_end(int ind) const;

  // Returns the part of the region mr that doesn't intersect with
  // any committed region other than self.  Used to prevent uncommitting
  // regions that are also committed by other regions.  Also protects
  // against uncommitting the guard region.
  MemRegion committed_unique_to_self(int self, MemRegion mr) const;

  // Mapping from address to card marking array entry
  jbyte* byte_for(const void* p) const {
    assert(_whole_heap.contains(p),
           err_msg("Attempt to access p = "PTR_FORMAT" out of bounds of "
                   " card marking array's _whole_heap = ["PTR_FORMAT","PTR_FORMAT")",
                   p, _whole_heap.start(), _whole_heap.end()));
    jbyte* result = &byte_map_base[uintptr_t(p) >> card_shift];
    assert(result >= _byte_map && result < _byte_map + _byte_map_size,
           "out of bounds accessor for card marking array");
    return result;
  }

  // The card table byte one after the card marking array
  // entry for argument address. Typically used for higher bounds
  // for loops iterating through the card table.
  jbyte* byte_after(const void* p) const {
    return byte_for(p) + 1;
  }

  // Iterate over the portion of the card-table which covers the given
  // region mr in the given space and apply cl to any dirty sub-regions
  // of mr. Dirty cards are _not_ cleared by the iterator method itself,
  // but closures may arrange to do so on their own should they so wish.
  void non_clean_card_iterate_serial(MemRegion mr, MemRegionClosure* cl);

  // A variant of the above that will operate in a parallel mode if
  // worker threads are available, and clear the dirty cards as it
  // processes them.
  // XXX ??? MemRegionClosure above vs OopsInGenClosure below XXX
  // XXX some new_dcto_cl's take OopClosure's, plus as above there are
  // some MemRegionClosures. Clean this up everywhere. XXX
  void non_clean_card_iterate_possibly_parallel(Space* sp, MemRegion mr,
                                                OopsInGenClosure* cl, CardTableRS* ct);

 private:
  // Work method used to implement non_clean_card_iterate_possibly_parallel()
  // above in the parallel case.
  void non_clean_card_iterate_parallel_work(Space* sp, MemRegion mr,
                                            OopsInGenClosure* cl, CardTableRS* ct,
                                            int n_threads);

 protected:
  // Dirty the bytes corresponding to "mr" (not all of which must be
  // covered.)
  void dirty_MemRegion(MemRegion mr);

  // Clear (to clean_card) the bytes entirely contained within "mr" (not
  // all of which must be covered.)
  void clear_MemRegion(MemRegion mr);

  // *** Support for parallel card scanning.

  // This is an array, one element per covered region of the card table.
  // Each entry is itself an array, with one element per chunk in the
  // covered region.  Each entry of these arrays is the lowest non-clean
  // card of the corresponding chunk containing part of an object from the
  // previous chunk, or else NULL.
  typedef jbyte*  CardPtr;
  typedef CardPtr* CardArr;
  CardArr* _lowest_non_clean;
  size_t*  _lowest_non_clean_chunk_size;
  uintptr_t* _lowest_non_clean_base_chunk_index;
  int* _last_LNC_resizing_collection;

  // Initializes "lowest_non_clean" to point to the array for the region
  // covering "sp", and "lowest_non_clean_base_chunk_index" to the chunk
  // index of the corresponding to the first element of that array.
  // Ensures that these arrays are of sufficient size, allocating if necessary.
  // May be called by several threads concurrently.
  void get_LNC_array_for_space(Space* sp,
                               jbyte**& lowest_non_clean,
                               uintptr_t& lowest_non_clean_base_chunk_index,
                               size_t& lowest_non_clean_chunk_size);

  // Returns the number of chunks necessary to cover "mr".
  size_t chunks_to_cover(MemRegion mr) {
    return (size_t)(addr_to_chunk_index(mr.last()) -
                    addr_to_chunk_index(mr.start()) + 1);
  }

  // Returns the index of the chunk in a stride which
  // covers the given address.
  uintptr_t addr_to_chunk_index(const void* addr) {
    uintptr_t card = (uintptr_t) byte_for(addr);
    return card / ParGCCardsPerStrideChunk;
  }

  // Apply cl, which must either itself apply dcto_cl or be dcto_cl,
  // to the cards in the stride (of n_strides) within the given space.
  void process_stride(Space* sp,
                      MemRegion used,
                      jint stride, int n_strides,
                      OopsInGenClosure* cl,
                      CardTableRS* ct,
                      jbyte** lowest_non_clean,
                      uintptr_t lowest_non_clean_base_chunk_index,
                      size_t lowest_non_clean_chunk_size);

  // Makes sure that chunk boundaries are handled appropriately, by
  // adjusting the min_done of dcto_cl, and by using a special card-table
  // value to indicate how min_done should be set.
  void process_chunk_boundaries(Space* sp,
                                DirtyCardToOopClosure* dcto_cl,
                                MemRegion chunk_mr,
                                MemRegion used,
                                jbyte** lowest_non_clean,
                                uintptr_t lowest_non_clean_base_chunk_index,
                                size_t    lowest_non_clean_chunk_size);

public:
  // Constants
  enum SomePublicConstants {
    card_shift                  = 9,
    card_size                   = 1 << card_shift,
    card_size_in_words          = card_size / sizeof(HeapWord)
  };

  static int clean_card_val()      { return clean_card; }
  static int clean_card_mask_val() { return clean_card_mask; }
  static int dirty_card_val()      { return dirty_card; }
  static int claimed_card_val()    { return claimed_card; }
  static int precleaned_card_val() { return precleaned_card; }
  static int deferred_card_val()   { return deferred_card; }

  // For RTTI simulation.
  bool is_a(BarrierSet::Name bsn) {
    return bsn == BarrierSet::CardTableModRef || ModRefBarrierSet::is_a(bsn);
  }

  CardTableModRefBS(MemRegion whole_heap, int max_covered_regions);
  ~CardTableModRefBS();

  // *** Barrier set functions.

  bool has_write_ref_pre_barrier() { return false; }

  // Record a reference update. Note that these versions are precise!
  // The scanning code has to handle the fact that the write barrier may be
  // either precise or imprecise. We make non-virtual inline variants of
  // these functions here for performance.
protected:
  void write_ref_field_work(oop obj, size_t offset, oop newVal);
  virtual void write_ref_field_work(void* field, oop newVal);
public:

  bool has_write_ref_array_opt() { return true; }
  bool has_write_region_opt() { return true; }

  inline void inline_write_region(MemRegion mr) {
    dirty_MemRegion(mr);
  }
protected:
  void write_region_work(MemRegion mr) {
    inline_write_region(mr);
  }
public:

  inline void inline_write_ref_array(MemRegion mr) {
    dirty_MemRegion(mr);
  }
protected:
  void write_ref_array_work(MemRegion mr) {
    inline_write_ref_array(mr);
  }
public:

  bool is_aligned(HeapWord* addr) {
    return is_card_aligned(addr);
  }

  // *** Card-table-barrier-specific things.

  template <class T> inline void inline_write_ref_field_pre(T* field, oop newVal) {}

  template <class T> inline void inline_write_ref_field(T* field, oop newVal) {
    jbyte* byte = byte_for((void*)field);
    *byte = dirty_card;
  }

  // These are used by G1, when it uses the card table as a temporary data
  // structure for card claiming.
  bool is_card_dirty(size_t card_index) {
    return _byte_map[card_index] == dirty_card_val();
  }

  void mark_card_dirty(size_t card_index) {
    _byte_map[card_index] = dirty_card_val();
  }

  bool is_card_claimed(size_t card_index) {
    jbyte val = _byte_map[card_index];
    return (val & (clean_card_mask_val() | claimed_card_val())) == claimed_card_val();
  }

  void set_card_claimed(size_t card_index) {
      jbyte val = _byte_map[card_index];
      if (val == clean_card_val()) {
        val = (jbyte)claimed_card_val();
      } else {
        val |= (jbyte)claimed_card_val();
      }
      _byte_map[card_index] = val;
  }

  bool claim_card(size_t card_index);

  bool is_card_clean(size_t card_index) {
    return _byte_map[card_index] == clean_card_val();
  }

  bool is_card_deferred(size_t card_index) {
    jbyte val = _byte_map[card_index];
    return (val & (clean_card_mask_val() | deferred_card_val())) == deferred_card_val();
  }

  bool mark_card_deferred(size_t card_index);

  // Card marking array base (adjusted for heap low boundary)
  // This would be the 0th element of _byte_map, if the heap started at 0x0.
  // But since the heap starts at some higher address, this points to somewhere
  // before the beginning of the actual _byte_map.
  jbyte* byte_map_base;

  // Return true if "p" is at the start of a card.
  bool is_card_aligned(HeapWord* p) {
    jbyte* pcard = byte_for(p);
    return (addr_for(pcard) == p);
  }

  HeapWord* align_to_card_boundary(HeapWord* p) {
    jbyte* pcard = byte_for(p + card_size_in_words - 1);
    return addr_for(pcard);
  }

  // The kinds of precision a CardTableModRefBS may offer.
  enum PrecisionStyle {
    Precise,
    ObjHeadPreciseArray
  };

  // Tells what style of precision this card table offers.
  PrecisionStyle precision() {
    return ObjHeadPreciseArray; // Only one supported for now.
  }

  // ModRefBS functions.
  virtual void invalidate(MemRegion mr, bool whole_heap = false);
  void clear(MemRegion mr);
  void dirty(MemRegion mr);

  // *** Card-table-RemSet-specific things.

  // Invoke "cl.do_MemRegion" on a set of MemRegions that collectively
  // includes all the modified cards (expressing each card as a
  // MemRegion).  Thus, several modified cards may be lumped into one
  // region.  The regions are non-overlapping, and are visited in
  // *decreasing* address order.  (This order aids with imprecise card
  // marking, where a dirty card may cause scanning, and summarization
  // marking, of objects that extend onto subsequent cards.)
  void mod_card_iterate(MemRegionClosure* cl) {
    non_clean_card_iterate_serial(_whole_heap, cl);
  }

  // Like the "mod_cards_iterate" above, except only invokes the closure
  // for cards within the MemRegion "mr" (which is required to be
  // card-aligned and sized.)
  void mod_card_iterate(MemRegion mr, MemRegionClosure* cl) {
    non_clean_card_iterate_serial(mr, cl);
  }

  static uintx ct_max_alignment_constraint();

  // Apply closure "cl" to the dirty cards containing some part of
  // MemRegion "mr".
  void dirty_card_iterate(MemRegion mr, MemRegionClosure* cl);

  // Return the MemRegion corresponding to the first maximal run
  // of dirty cards lying completely within MemRegion mr.
  // If reset is "true", then sets those card table entries to the given
  // value.
  MemRegion dirty_card_range_after_reset(MemRegion mr, bool reset,
                                         int reset_val);

  // Provide read-only access to the card table array.
  const jbyte* byte_for_const(const void* p) const {
    return byte_for(p);
  }
  const jbyte* byte_after_const(const void* p) const {
    return byte_after(p);
  }

  // Mapping from card marking array entry to address of first word
  HeapWord* addr_for(const jbyte* p) const {
    assert(p >= _byte_map && p < _byte_map + _byte_map_size,
           "out of bounds access to card marking array");
    size_t delta = pointer_delta(p, byte_map_base, sizeof(jbyte));
    HeapWord* result = (HeapWord*) (delta << card_shift);
    assert(_whole_heap.contains(result),
           err_msg("Returning result = "PTR_FORMAT" out of bounds of "
                   " card marking array's _whole_heap = ["PTR_FORMAT","PTR_FORMAT")",
                   result, _whole_heap.start(), _whole_heap.end()));
    return result;
  }

  // Mapping from address to card marking array index.
  size_t index_for(void* p) {
    assert(_whole_heap.contains(p),
           err_msg("Attempt to access p = "PTR_FORMAT" out of bounds of "
                   " card marking array's _whole_heap = ["PTR_FORMAT","PTR_FORMAT")",
                   p, _whole_heap.start(), _whole_heap.end()));
    return byte_for(p) - _byte_map;
  }

  const jbyte* byte_for_index(const size_t card_index) const {
    return _byte_map + card_index;
  }

  // Print a description of the memory for the barrier set
  virtual void print_on(outputStream* st) const;

  void verify();
  void verify_guard();

  // val_equals -> it will check that all cards covered by mr equal val
  // !val_equals -> it will check that all cards covered by mr do not equal val
  void verify_region(MemRegion mr, jbyte val, bool val_equals) PRODUCT_RETURN;
  void verify_not_dirty_region(MemRegion mr) PRODUCT_RETURN;
  void verify_dirty_region(MemRegion mr) PRODUCT_RETURN;

  static size_t par_chunk_heapword_alignment() {
    return ParGCCardsPerStrideChunk * card_size_in_words;
  }

};

class CardTableRS;

// A specialization for the CardTableRS gen rem set.
class CardTableModRefBSForCTRS: public CardTableModRefBS {
  CardTableRS* _rs;
protected:
  bool card_will_be_scanned(jbyte cv);
  bool card_may_have_been_dirty(jbyte cv);
public:
  CardTableModRefBSForCTRS(MemRegion whole_heap,
                           int max_covered_regions) :
    CardTableModRefBS(whole_heap, max_covered_regions) {}

  void set_CTRS(CardTableRS* rs) { _rs = rs; }
};


#endif // SHARE_VM_MEMORY_CARDTABLEMODREFBS_HPP