gecko/xpcom/glue/pldhash.h

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

#ifndef pldhash_h___
#define pldhash_h___
/*
 * Double hashing, a la Knuth 6.
 */
#include "mozilla/fallible.h"
#include "mozilla/MemoryReporting.h"
#include "mozilla/Types.h"
#include "nscore.h"

#if defined(__GNUC__) && defined(__i386__)
#define PL_DHASH_FASTCALL __attribute__ ((regparm (3),stdcall))
#elif defined(XP_WIN)
#define PL_DHASH_FASTCALL __fastcall
#else
#define PL_DHASH_FASTCALL
#endif

/*
 * Table capacity limit; do not exceed.  The max capacity used to be 1<<23 but
 * that occasionally that wasn't enough.  Making it much bigger than 1<<26
 * probably isn't worthwhile -- tables that big are kind of ridiculous.  Also,
 * the growth operation will (deliberately) fail if |capacity * entrySize|
 * overflows a uint32_t, and entrySize is always at least 8 bytes.
 */
#define PL_DHASH_MAX_CAPACITY           ((uint32_t)1 << 26)

#define PL_DHASH_MIN_CAPACITY           16

/*
 * Making this half of the max capacity ensures it'll fit. Nobody should need
 * an initial length anywhere nearly this large, anyway.
 */
#define PL_DHASH_MAX_INITIAL_LENGTH     (PL_DHASH_MAX_CAPACITY / 2)

/* This gives a default initial capacity of 16. */
#define PL_DHASH_DEFAULT_INITIAL_LENGTH 8

/*
 * Multiplicative hash uses an unsigned 32 bit integer and the golden ratio,
 * expressed as a fixed-point 32-bit fraction.
 */
#define PL_DHASH_BITS           32
#define PL_DHASH_GOLDEN_RATIO   0x9E3779B9U

/* Primitive and forward-struct typedefs. */
typedef uint32_t                PLDHashNumber;
typedef struct PLDHashEntryHdr  PLDHashEntryHdr;
typedef struct PLDHashEntryStub PLDHashEntryStub;
typedef struct PLDHashTable     PLDHashTable;
typedef struct PLDHashTableOps  PLDHashTableOps;

/*
 * Table entry header structure.
 *
 * In order to allow in-line allocation of key and value, we do not declare
 * either here.  Instead, the API uses const void *key as a formal parameter.
 * The key need not be stored in the entry; it may be part of the value, but
 * need not be stored at all.
 *
 * Callback types are defined below and grouped into the PLDHashTableOps
 * structure, for single static initialization per hash table sub-type.
 *
 * Each hash table sub-type should nest the PLDHashEntryHdr structure at the
 * front of its particular entry type.  The keyHash member contains the result
 * of multiplying the hash code returned from the hashKey callback (see below)
 * by PL_DHASH_GOLDEN_RATIO, then constraining the result to avoid the magic 0
 * and 1 values.  The stored keyHash value is table size invariant, and it is
 * maintained automatically by PL_DHashTableOperate -- users should never set
 * it, and its only uses should be via the entry macros below.
 *
 * The PL_DHASH_ENTRY_IS_LIVE function tests whether entry is neither free nor
 * removed.  An entry may be either busy or free; if busy, it may be live or
 * removed.  Consumers of this API should not access members of entries that
 * are not live.
 *
 * However, use PL_DHASH_ENTRY_IS_BUSY for faster liveness testing of entries
 * returned by PL_DHashTableOperate, as PL_DHashTableOperate never returns a
 * non-live, busy (i.e., removed) entry pointer to its caller.  See below for
 * more details on PL_DHashTableOperate's calling rules.
 */
struct PLDHashEntryHdr
{
  PLDHashNumber keyHash;  /* every entry must begin like this */
};

MOZ_ALWAYS_INLINE bool
PL_DHASH_ENTRY_IS_FREE(PLDHashEntryHdr* aEntry)
{
  return aEntry->keyHash == 0;
}

MOZ_ALWAYS_INLINE bool
PL_DHASH_ENTRY_IS_BUSY(PLDHashEntryHdr* aEntry)
{
  return !PL_DHASH_ENTRY_IS_FREE(aEntry);
}

MOZ_ALWAYS_INLINE bool
PL_DHASH_ENTRY_IS_LIVE(PLDHashEntryHdr* aEntry)
{
  return aEntry->keyHash >= 2;
}

/*
 * A PLDHashTable is currently 8 words (without the PL_DHASHMETER overhead)
 * on most architectures, and may be allocated on the stack or within another
 * structure or class (see below for the Init and Finish functions to use).
 *
 * To decide whether to use double hashing vs. chaining, we need to develop a
 * trade-off relation, as follows:
 *
 * Let alpha be the load factor, esize the entry size in words, count the
 * entry count, and pow2 the power-of-two table size in entries.
 *
 *   (PLDHashTable overhead)    > (PLHashTable overhead)
 *   (unused table entry space) > (malloc and .next overhead per entry) +
 *                                (buckets overhead)
 *   (1 - alpha) * esize * pow2 > 2 * count + pow2
 *
 * Notice that alpha is by definition (count / pow2):
 *
 *   (1 - alpha) * esize * pow2 > 2 * alpha * pow2 + pow2
 *   (1 - alpha) * esize        > 2 * alpha + 1
 *
 *   esize > (1 + 2 * alpha) / (1 - alpha)
 *
 * This assumes both tables must keep keyHash, key, and value for each entry,
 * where key and value point to separately allocated strings or structures.
 * If key and value can be combined into one pointer, then the trade-off is:
 *
 *   esize > (1 + 3 * alpha) / (1 - alpha)
 *
 * If the entry value can be a subtype of PLDHashEntryHdr, rather than a type
 * that must be allocated separately and referenced by an entry.value pointer
 * member, and provided key's allocation can be fused with its entry's, then
 * k (the words wasted per entry with chaining) is 4.
 *
 * To see these curves, feed gnuplot input like so:
 *
 *   gnuplot> f(x,k) = (1 + k * x) / (1 - x)
 *   gnuplot> plot [0:.75] f(x,2), f(x,3), f(x,4)
 *
 * For k of 2 and a well-loaded table (alpha > .5), esize must be more than 4
 * words for chaining to be more space-efficient than double hashing.
 *
 * Solving for alpha helps us decide when to shrink an underloaded table:
 *
 *   esize                     > (1 + k * alpha) / (1 - alpha)
 *   esize - alpha * esize     > 1 + k * alpha
 *   esize - 1                 > (k + esize) * alpha
 *   (esize - 1) / (k + esize) > alpha
 *
 *   alpha < (esize - 1) / (esize + k)
 *
 * Therefore double hashing should keep alpha >= (esize - 1) / (esize + k),
 * assuming esize is not too large (in which case, chaining should probably be
 * used for any alpha).  For esize=2 and k=3, we want alpha >= .2; for esize=3
 * and k=2, we want alpha >= .4.  For k=4, esize could be 6, and alpha >= .5
 * would still obtain.
 *
 * The current implementation uses a lower bound of 0.25 for alpha when
 * deciding whether to shrink the table (while still respecting
 * PL_DHASH_MIN_CAPACITY).
 *
 * Note a qualitative difference between chaining and double hashing: under
 * chaining, entry addresses are stable across table shrinks and grows.  With
 * double hashing, you can't safely hold an entry pointer and use it after an
 * ADD or REMOVE operation, unless you sample aTable->generation before adding
 * or removing, and compare the sample after, dereferencing the entry pointer
 * only if aTable->generation has not changed.
 *
 * The moral of this story: there is no one-size-fits-all hash table scheme,
 * but for small table entry size, and assuming entry address stability is not
 * required, double hashing wins.
 */
struct PLDHashTable
{
  const PLDHashTableOps* ops;         /* virtual operations, see below */
  void*               data;           /* ops- and instance-specific data */
  int16_t             hashShift;      /* multiplicative hash shift */
  /*
   * |recursionLevel| is only used in debug builds, but is present in opt
   * builds to avoid binary compatibility problems when mixing DEBUG and
   * non-DEBUG components.  (Actually, even if it were removed,
   * sizeof(PLDHashTable) wouldn't change, due to struct padding.)
   */
  uint16_t            recursionLevel; /* used to detect unsafe re-entry */
  uint32_t            entrySize;      /* number of bytes in an entry */
  uint32_t            entryCount;     /* number of entries in table */
  uint32_t            removedCount;   /* removed entry sentinels in table */
  uint32_t            generation;     /* entry storage generation number */
  char*               entryStore;     /* entry storage */
#ifdef PL_DHASHMETER
  struct PLDHashStats
  {
    uint32_t        searches;       /* total number of table searches */
    uint32_t        steps;          /* hash chain links traversed */
    uint32_t        hits;           /* searches that found key */
    uint32_t        misses;         /* searches that didn't find key */
    uint32_t        lookups;        /* number of PL_DHASH_LOOKUPs */
    uint32_t        addMisses;      /* adds that miss, and do work */
    uint32_t        addOverRemoved; /* adds that recycled a removed entry */
    uint32_t        addHits;        /* adds that hit an existing entry */
    uint32_t        addFailures;    /* out-of-memory during add growth */
    uint32_t        removeHits;     /* removes that hit, and do work */
    uint32_t        removeMisses;   /* useless removes that miss */
    uint32_t        removeFrees;    /* removes that freed entry directly */
    uint32_t        removeEnums;    /* removes done by Enumerate */
    uint32_t        grows;          /* table expansions */
    uint32_t        shrinks;        /* table contractions */
    uint32_t        compresses;     /* table compressions */
    uint32_t        enumShrinks;    /* contractions after Enumerate */
  } stats;
#endif
};

/*
 * Size in entries (gross, not net of free and removed sentinels) for table.
 * We store hashShift rather than sizeLog2 to optimize the collision-free case
 * in SearchTable.
 */
#define PL_DHASH_TABLE_CAPACITY(table) \
    ((uint32_t)1 << (PL_DHASH_BITS - (table)->hashShift))

/*
 * Table space at entryStore is allocated and freed using these callbacks.
 * The allocator should return null on error only (not if called with aNBytes
 * equal to 0; but note that pldhash.c code will never call with 0 aNBytes).
 */
typedef void* (*PLDHashAllocTable)(PLDHashTable* aTable, uint32_t aNBytes);

typedef void (*PLDHashFreeTable)(PLDHashTable* aTable, void* aPtr);

/*
 * Compute the hash code for a given key to be looked up, added, or removed
 * from aTable.  A hash code may have any PLDHashNumber value.
 */
typedef PLDHashNumber (*PLDHashHashKey)(PLDHashTable* aTable,
                                        const void* aKey);

/*
 * Compare the key identifying aEntry in aTable with the provided key parameter.
 * Return true if keys match, false otherwise.
 */
typedef bool (*PLDHashMatchEntry)(PLDHashTable* aTable,
                                  const PLDHashEntryHdr* aEntry,
                                  const void* aKey);

/*
 * Copy the data starting at aFrom to the new entry storage at aTo. Do not add
 * reference counts for any strong references in the entry, however, as this
 * is a "move" operation: the old entry storage at from will be freed without
 * any reference-decrementing callback shortly.
 */
typedef void (*PLDHashMoveEntry)(PLDHashTable* aTable,
                                 const PLDHashEntryHdr* aFrom,
                                 PLDHashEntryHdr* aTo);

/*
 * Clear the entry and drop any strong references it holds.  This callback is
 * invoked during a PL_DHASH_REMOVE operation (see below for operation codes),
 * but only if the given key is found in the table.
 */
typedef void (*PLDHashClearEntry)(PLDHashTable* aTable,
                                  PLDHashEntryHdr* aEntry);

/*
 * Called when a table (whether allocated dynamically by itself, or nested in
 * a larger structure, or allocated on the stack) is finished.  This callback
 * allows aTable->ops-specific code to finalize aTable->data.
 */
typedef void (*PLDHashFinalize)(PLDHashTable* aTable);

/*
 * Initialize a new entry, apart from keyHash.  This function is called when
 * PL_DHashTableOperate's PL_DHASH_ADD case finds no existing entry for the
 * given key, and must add a new one.  At that point, aEntry->keyHash is not
 * set yet, to avoid claiming the last free entry in a severely overloaded
 * table.
 */
typedef bool (*PLDHashInitEntry)(PLDHashTable* aTable, PLDHashEntryHdr* aEntry,
                                 const void* aKey);

/*
 * Finally, the "vtable" structure for PLDHashTable.  The first eight hooks
 * must be provided by implementations; they're called unconditionally by the
 * generic pldhash.c code.  Hooks after these may be null.
 *
 * Summary of allocation-related hook usage with C++ placement new emphasis:
 *  allocTable          Allocate raw bytes with malloc, no ctors run.
 *  freeTable           Free raw bytes with free, no dtors run.
 *  initEntry           Call placement new using default key-based ctor.
 *                      Return true on success, false on error.
 *  moveEntry           Call placement new using copy ctor, run dtor on old
 *                      entry storage.
 *  clearEntry          Run dtor on entry.
 *  finalize            Stub unless aTable->data was initialized and needs to
 *                      be finalized.
 *
 * Note the reason why initEntry is optional: the default hooks (stubs) clear
 * entry storage:  On successful PL_DHashTableOperate(tbl, key, PL_DHASH_ADD),
 * the returned entry pointer addresses an entry struct whose keyHash member
 * has been set non-zero, but all other entry members are still clear (null).
 * PL_DHASH_ADD callers can test such members to see whether the entry was
 * newly created by the PL_DHASH_ADD call that just succeeded.  If placement
 * new or similar initialization is required, define an initEntry hook.  Of
 * course, the clearEntry hook must zero or null appropriately.
 *
 * XXX assumes 0 is null for pointer types.
 */
struct PLDHashTableOps
{
  /* Mandatory hooks.  All implementations must provide these. */
  PLDHashAllocTable   allocTable;
  PLDHashFreeTable    freeTable;
  PLDHashHashKey      hashKey;
  PLDHashMatchEntry   matchEntry;
  PLDHashMoveEntry    moveEntry;
  PLDHashClearEntry   clearEntry;
  PLDHashFinalize     finalize;

  /* Optional hooks start here.  If null, these are not called. */
  PLDHashInitEntry    initEntry;
};

/*
 * Default implementations for the above ops.
 */
NS_COM_GLUE void* PL_DHashAllocTable(PLDHashTable* aTable, uint32_t aNBytes);

NS_COM_GLUE void PL_DHashFreeTable(PLDHashTable* aTable, void* aPtr);

NS_COM_GLUE PLDHashNumber PL_DHashStringKey(PLDHashTable* aTable,
                                            const void* aKey);

/* A minimal entry contains a keyHash header and a void key pointer. */
struct PLDHashEntryStub
{
  PLDHashEntryHdr hdr;
  const void*     key;
};

NS_COM_GLUE PLDHashNumber PL_DHashVoidPtrKeyStub(PLDHashTable* aTable,
                                                 const void* aKey);

NS_COM_GLUE bool PL_DHashMatchEntryStub(PLDHashTable* aTable,
                                        const PLDHashEntryHdr* aEntry,
                                        const void* aKey);

NS_COM_GLUE bool PL_DHashMatchStringKey(PLDHashTable* aTable,
                                        const PLDHashEntryHdr* aEntry,
                                        const void* aKey);

NS_COM_GLUE void
PL_DHashMoveEntryStub(PLDHashTable* aTable,
                      const PLDHashEntryHdr* aFrom,
                      PLDHashEntryHdr* aTo);

NS_COM_GLUE void PL_DHashClearEntryStub(PLDHashTable* aTable,
                                        PLDHashEntryHdr* aEntry);

NS_COM_GLUE void PL_DHashFreeStringKey(PLDHashTable* aTable,
                                       PLDHashEntryHdr* aEntry);

NS_COM_GLUE void PL_DHashFinalizeStub(PLDHashTable* aTable);

/*
 * If you use PLDHashEntryStub or a subclass of it as your entry struct, and
 * if your entries move via memcpy and clear via memset(0), you can use these
 * stub operations.
 */
NS_COM_GLUE const PLDHashTableOps* PL_DHashGetStubOps(void);

/*
 * Dynamically allocate a new PLDHashTable using malloc, initialize it using
 * PL_DHashTableInit, and return its address.  Return null on malloc failure.
 * Note that the entry storage at aTable->entryStore will be allocated using
 * the aOps->allocTable callback.
 */
NS_COM_GLUE PLDHashTable* PL_NewDHashTable(
  const PLDHashTableOps* aOps, void* aData, uint32_t aEntrySize,
  uint32_t aLength = PL_DHASH_DEFAULT_INITIAL_LENGTH);

/*
 * Finalize aTable's data, free its entry storage (via aTable->ops->freeTable),
 * and return the memory starting at aTable to the malloc heap.
 */
NS_COM_GLUE void PL_DHashTableDestroy(PLDHashTable* aTable);

/*
 * Initialize aTable with aOps, aData, aEntrySize, and aCapacity. The table's
 * initial capacity will be chosen such that |aLength| elements can be inserted
 * without rehashing. If |aLength| is a power-of-two, this capacity will be
 * |2*length|.
 *
 * This function will crash if it can't allocate enough memory, or if
 * |aEntrySize| and/or |aLength| are too large.
 */
NS_COM_GLUE void PL_DHashTableInit(
  PLDHashTable* aTable, const PLDHashTableOps* aOps, void* aData,
  uint32_t aEntrySize, uint32_t aLength = PL_DHASH_DEFAULT_INITIAL_LENGTH);

/*
 * Initialize aTable. This is the same as PL_DHashTableInit, except that it
 * returns a boolean indicating success, rather than crashing on failure.
 */
MOZ_WARN_UNUSED_RESULT NS_COM_GLUE bool PL_DHashTableInit(
  PLDHashTable* aTable, const PLDHashTableOps* aOps, void* aData,
  uint32_t aEntrySize, const mozilla::fallible_t&,
  uint32_t aLength = PL_DHASH_DEFAULT_INITIAL_LENGTH);

/*
 * Finalize aTable's data, free its entry storage using aTable->ops->freeTable,
 * and leave its members unchanged from their last live values (which leaves
 * pointers dangling).  If you want to burn cycles clearing aTable, it's up to
 * your code to call memset.
 */
NS_COM_GLUE void PL_DHashTableFinish(PLDHashTable* aTable);

/*
 * To consolidate keyHash computation and table grow/shrink code, we use a
 * single entry point for lookup, add, and remove operations.  The operation
 * codes are declared here, along with codes returned by PLDHashEnumerator
 * functions, which control PL_DHashTableEnumerate's behavior.
 */
typedef enum PLDHashOperator
{
  PL_DHASH_LOOKUP = 0,        /* lookup entry */
  PL_DHASH_ADD = 1,           /* add entry */
  PL_DHASH_REMOVE = 2,        /* remove entry, or enumerator says remove */
  PL_DHASH_NEXT = 0,          /* enumerator says continue */
  PL_DHASH_STOP = 1           /* enumerator says stop */
} PLDHashOperator;

/*
 * To lookup a key in table, call:
 *
 *  entry = PL_DHashTableOperate(table, key, PL_DHASH_LOOKUP);
 *
 * If PL_DHASH_ENTRY_IS_BUSY(entry) is true, key was found and it identifies
 * entry.  If PL_DHASH_ENTRY_IS_FREE(entry) is true, key was not found.
 *
 * To add an entry identified by key to table, call:
 *
 *  entry = PL_DHashTableOperate(table, key, PL_DHASH_ADD);
 *
 * If entry is null upon return, then either the table is severely overloaded,
 * and memory can't be allocated for entry storage via aTable->ops->allocTable;
 * Or if aTable->ops->initEntry is non-null, the aTable->ops->initEntry op may
 * have returned false.
 *
 * Otherwise, aEntry->keyHash has been set so that PL_DHASH_ENTRY_IS_BUSY(entry)
 * is true, and it is up to the caller to initialize the key and value parts
 * of the entry sub-type, if they have not been set already (i.e. if entry was
 * not already in the table, and if the optional initEntry hook was not used).
 *
 * To remove an entry identified by key from table, call:
 *
 *  (void) PL_DHashTableOperate(table, key, PL_DHASH_REMOVE);
 *
 * If key's entry is found, it is cleared (via table->ops->clearEntry) and
 * the entry is marked so that PL_DHASH_ENTRY_IS_FREE(entry).  This operation
 * returns null unconditionally; you should ignore its return value.
 */
NS_COM_GLUE PLDHashEntryHdr* PL_DHASH_FASTCALL
PL_DHashTableOperate(PLDHashTable* aTable, const void* aKey,
                     PLDHashOperator aOp);

/*
 * Remove an entry already accessed via LOOKUP or ADD.
 *
 * NB: this is a "raw" or low-level routine, intended to be used only where
 * the inefficiency of a full PL_DHashTableOperate (which rehashes in order
 * to find the entry given its key) is not tolerable.  This function does not
 * shrink the table if it is underloaded.  It does not update stats #ifdef
 * PL_DHASHMETER, either.
 */
NS_COM_GLUE void PL_DHashTableRawRemove(PLDHashTable* aTable,
                                        PLDHashEntryHdr* aEntry);

/*
 * Enumerate entries in table using etor:
 *
 *   count = PL_DHashTableEnumerate(table, etor, arg);
 *
 * PL_DHashTableEnumerate calls etor like so:
 *
 *   op = etor(table, entry, number, arg);
 *
 * where number is a zero-based ordinal assigned to live entries according to
 * their order in aTable->entryStore.
 *
 * The return value, op, is treated as a set of flags.  If op is PL_DHASH_NEXT,
 * then continue enumerating.  If op contains PL_DHASH_REMOVE, then clear (via
 * aTable->ops->clearEntry) and free entry.  Then we check whether op contains
 * PL_DHASH_STOP; if so, stop enumerating and return the number of live entries
 * that were enumerated so far.  Return the total number of live entries when
 * enumeration completes normally.
 *
 * If etor calls PL_DHashTableOperate on table with op != PL_DHASH_LOOKUP, it
 * must return PL_DHASH_STOP; otherwise undefined behavior results.
 *
 * If any enumerator returns PL_DHASH_REMOVE, aTable->entryStore may be shrunk
 * or compressed after enumeration, but before PL_DHashTableEnumerate returns.
 * Such an enumerator therefore can't safely set aside entry pointers, but an
 * enumerator that never returns PL_DHASH_REMOVE can set pointers to entries
 * aside, e.g., to avoid copying live entries into an array of the entry type.
 * Copying entry pointers is cheaper, and safe so long as the caller of such a
 * "stable" Enumerate doesn't use the set-aside pointers after any call either
 * to PL_DHashTableOperate, or to an "unstable" form of Enumerate, which might
 * grow or shrink entryStore.
 *
 * If your enumerator wants to remove certain entries, but set aside pointers
 * to other entries that it retains, it can use PL_DHashTableRawRemove on the
 * entries to be removed, returning PL_DHASH_NEXT to skip them.  Likewise, if
 * you want to remove entries, but for some reason you do not want entryStore
 * to be shrunk or compressed, you can call PL_DHashTableRawRemove safely on
 * the entry being enumerated, rather than returning PL_DHASH_REMOVE.
 */
typedef PLDHashOperator (*PLDHashEnumerator)(PLDHashTable* aTable,
                                             PLDHashEntryHdr* aHdr,
                                             uint32_t aNumber, void* aArg);

NS_COM_GLUE uint32_t
PL_DHashTableEnumerate(PLDHashTable* aTable, PLDHashEnumerator aEtor,
                       void* aArg);

typedef size_t (*PLDHashSizeOfEntryExcludingThisFun)(
  PLDHashEntryHdr* aHdr, mozilla::MallocSizeOf aMallocSizeOf, void* aArg);

/**
 * Measure the size of the table's entry storage, and if
 * |aSizeOfEntryExcludingThis| is non-nullptr, measure the size of things
 * pointed to by entries.  Doesn't measure |ops| because it's often shared
 * between tables, nor |data| because it's opaque.
 */
NS_COM_GLUE size_t PL_DHashTableSizeOfExcludingThis(
  const PLDHashTable* aTable,
  PLDHashSizeOfEntryExcludingThisFun aSizeOfEntryExcludingThis,
  mozilla::MallocSizeOf aMallocSizeOf, void* aArg = nullptr);

/**
 * Like PL_DHashTableSizeOfExcludingThis, but includes sizeof(*this).
 */
NS_COM_GLUE size_t PL_DHashTableSizeOfIncludingThis(
  const PLDHashTable* aTable,
  PLDHashSizeOfEntryExcludingThisFun aSizeOfEntryExcludingThis,
  mozilla::MallocSizeOf aMallocSizeOf, void* aArg = nullptr);

#ifdef DEBUG
/**
 * Mark a table as immutable for the remainder of its lifetime.  This
 * changes the implementation from ASSERTing one set of invariants to
 * ASSERTing a different set.
 *
 * When a table is NOT marked as immutable, the table implementation
 * asserts that the table is not mutated from its own callbacks.  It
 * assumes the caller protects the table from being accessed on multiple
 * threads simultaneously.
 *
 * When the table is marked as immutable, the re-entry assertions will
 * no longer trigger erroneously due to multi-threaded access.  Instead,
 * mutations will cause assertions.
 */
NS_COM_GLUE void PL_DHashMarkTableImmutable(PLDHashTable* aTable);
#endif

#ifdef PL_DHASHMETER
#include <stdio.h>

NS_COM_GLUE void PL_DHashTableDumpMeter(PLDHashTable* aTable,
                                        PLDHashEnumerator aDump, FILE* aFp);
#endif

#endif /* pldhash_h___ */