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diff --git a/src/hash.c b/src/hash.c
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+/* Hash tables.
+   Copyright (C) 2000-2011, 2015, 2018-2020 Free Software Foundation,
+   Inc.
+
+This file is part of GNU Wget.
+
+GNU Wget is free software; you can redistribute it and/or modify
+it under the terms of the GNU General Public License as published by
+the Free Software Foundation; either version 3 of the License, or (at
+your option) any later version.
+
+GNU Wget 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 for more details.
+
+You should have received a copy of the GNU General Public License
+along with Wget.  If not, see <http://www.gnu.org/licenses/>.
+
+Additional permission under GNU GPL version 3 section 7
+
+If you modify this program, or any covered work, by linking or
+combining it with the OpenSSL project's OpenSSL library (or a
+modified version of that library), containing parts covered by the
+terms of the OpenSSL or SSLeay licenses, the Free Software Foundation
+grants you additional permission to convey the resulting work.
+Corresponding Source for a non-source form of such a combination
+shall include the source code for the parts of OpenSSL used as well
+as that of the covered work.  */
+
+/* With -DSTANDALONE, this file can be compiled outside Wget source
+   tree.  To test, also use -DTEST.  */
+
+#ifndef STANDALONE
+# include "wget.h"
+#endif
+
+#include <stdio.h>
+#include <stdlib.h>
+#include <assert.h>
+#include <string.h>
+#include <limits.h>
+
+#ifndef STANDALONE
+/* Get Wget's utility headers. */
+# include "utils.h"
+#else
+/* Make do without them. */
+# define xnew(type) (xmalloc (sizeof (type)))
+# define xnew0(type) (xcalloc (1, sizeof (type)))
+# define xnew_array(type, len) (xmalloc ((len) * sizeof (type)))
+# define xfree(p) do { free ((void *) (p)); p = NULL; } while (0)
+
+# ifndef countof
+#  define countof(x) (sizeof (x) / sizeof ((x)[0]))
+# endif
+# include <ctype.h>
+# define c_tolower(x) tolower ((unsigned char) (x))
+# include <stdint.h>
+#endif
+
+#include "hash.h"
+
+/* INTERFACE:
+
+   Hash tables are a technique used to implement mapping between
+   objects with near-constant-time access and storage.  The table
+   associates keys to values, and a value can be very quickly
+   retrieved by providing the key.  Fast lookup tables are typically
+   implemented as hash tables.
+
+   The entry points are
+     hash_table_new       -- creates the table.
+     hash_table_destroy   -- destroys the table.
+     hash_table_put       -- establishes or updates key->value mapping.
+     hash_table_get       -- retrieves value of key.
+     hash_table_get_pair  -- get key/value pair for key.
+     hash_table_contains  -- test whether the table contains key.
+     hash_table_remove    -- remove key->value mapping for given key.
+     hash_table_for_each  -- call function for each table entry.
+     hash_table_iterate   -- iterate over entries in hash table.
+     hash_table_iter_next -- return next element during iteration.
+     hash_table_clear     -- clear hash table contents.
+     hash_table_count     -- return the number of entries in the table.
+
+   The hash table grows internally as new entries are added and is not
+   limited in size, except by available memory.  The table doubles
+   with each resize, which ensures that the amortized time per
+   operation remains constant.
+
+   If not instructed otherwise, tables created by hash_table_new
+   consider the keys to be equal if their pointer values are the same.
+   You can use make_string_hash_table to create tables whose keys are
+   considered equal if their string contents are the same.  In the
+   general case, the criterion of equality used to compare keys is
+   specified at table creation time with two callback functions,
+   "hash" and "test".  The hash function transforms the key into an
+   arbitrary number that must be the same for two equal keys.  The
+   test function accepts two keys and returns non-zero if they are to
+   be considered equal.
+
+   Note that neither keys nor values are copied when inserted into the
+   hash table, so they must exist for the lifetime of the table.  This
+   means that e.g. the use of static strings is OK, but objects with a
+   shorter life-time probably need to be copied (with strdup() or the
+   like in the case of strings) before being inserted.  */
+
+/* IMPLEMENTATION:
+
+   The hash table is implemented as an open-addressed table with
+   linear probing collision resolution.
+
+   The above means that all the cells (each cell containing a key and
+   a value pointer) are stored in a contiguous array.  Array position
+   of each cell is determined by the hash value of its key and the
+   size of the table: location := hash(key) % size.  If two different
+   keys end up on the same position (collide), the one that came
+   second is stored in the first unoccupied cell that follows it.
+   This collision resolution technique is called "linear probing".
+
+   There are more advanced collision resolution methods (quadratic
+   probing, double hashing), but we don't use them because they incur
+   more non-sequential access to the array, which results in worse CPU
+   cache behavior.  Linear probing works well as long as the
+   count/size ratio (fullness) is kept below 75%.  We make sure to
+   grow and rehash the table whenever this threshold is exceeded.
+
+   Collisions complicate deletion because simply clearing a cell
+   followed by previously collided entries would cause those neighbors
+   to not be picked up by find_cell later.  One solution is to leave a
+   "tombstone" marker instead of clearing the cell, and another is to
+   recalculate the positions of adjacent cells.  We take the latter
+   approach because it results in less bookkeeping garbage and faster
+   retrieval at the (slight) expense of deletion.  */
+
+/* Maximum allowed fullness: when hash table's fullness exceeds this
+   value, the table is resized.  */
+#define HASH_MAX_FULLNESS 0.75
+
+/* The hash table size is multiplied by this factor (and then rounded
+   to the next prime) with each resize.  This guarantees infrequent
+   resizes.  */
+#define HASH_RESIZE_FACTOR 2
+
+struct cell {
+  void *key;
+  void *value;
+};
+
+typedef unsigned long (*hashfun_t) (const void *);
+typedef int (*testfun_t) (const void *, const void *);
+
+struct hash_table {
+  hashfun_t hash_function;
+  testfun_t test_function;
+
+  struct cell *cells;           /* contiguous array of cells. */
+  int size;                     /* size of the array. */
+
+  int count;                    /* number of occupied entries. */
+  int resize_threshold;         /* after size exceeds this number of
+                                   entries, resize the table.  */
+  int prime_offset;             /* the offset of the current prime in
+                                   the prime table. */
+};
+
+/* We use the all-bits-set constant (INVALID_PTR) marker to mean that
+   a cell is empty.  It is unaligned and therefore illegal as a
+   pointer.  INVALID_PTR_CHAR (0xff) is the single-character constant
+   used to initialize the entire cells array as empty.
+
+   The all-bits-set value is a better choice than NULL because it
+   allows the use of NULL/0 keys.  Since the keys are either integers
+   or pointers, the only key that cannot be used is the integer value
+   -1.  This is acceptable because it still allows the use of
+   nonnegative integer keys.  */
+
+#define INVALID_PTR ((void *) ~(uintptr_t) 0)
+#ifndef UCHAR_MAX
+# define UCHAR_MAX 0xff
+#endif
+#define INVALID_PTR_CHAR UCHAR_MAX
+
+/* Whether the cell C is occupied (non-empty). */
+#define CELL_OCCUPIED(c) ((c)->key != INVALID_PTR)
+
+/* Clear the cell C, i.e. mark it as empty (unoccupied). */
+#define CLEAR_CELL(c) ((c)->key = INVALID_PTR)
+
+/* "Next" cell is the cell following C, but wrapping back to CELLS
+   when C would reach CELLS+SIZE.  */
+#define NEXT_CELL(c, cells, size) (c != cells + (size - 1) ? c + 1 : cells)
+
+/* Loop over occupied cells starting at C, terminating the loop when
+   an empty cell is encountered.  */
+#define FOREACH_OCCUPIED_ADJACENT(c, cells, size)                               \
+  for (; CELL_OCCUPIED (c); c = NEXT_CELL (c, cells, size))
+
+/* Return the position of KEY in hash table SIZE large, hash function
+   being HASHFUN.  */
+#define HASH_POSITION(key, hashfun, size) ((hashfun) (key) % size)
+
+/* Find a prime near, but greater than or equal to SIZE.  The primes
+   are looked up from a table with a selection of primes convenient
+   for this purpose.
+
+   PRIME_OFFSET is a minor optimization: it specifies start position
+   for the search for the large enough prime.  The final offset is
+   stored in the same variable.  That way the list of primes does not
+   have to be scanned from the beginning each time around.  */
+
+static int
+prime_size (int size, int *prime_offset)
+{
+  static const int primes[] = {
+    13, 19, 29, 41, 59, 79, 107, 149, 197, 263, 347, 457, 599, 787, 1031,
+    1361, 1777, 2333, 3037, 3967, 5167, 6719, 8737, 11369, 14783,
+    19219, 24989, 32491, 42257, 54941, 71429, 92861, 120721, 156941,
+    204047, 265271, 344857, 448321, 582821, 757693, 985003, 1280519,
+    1664681, 2164111, 2813353, 3657361, 4754591, 6180989, 8035301,
+    10445899, 13579681, 17653589, 22949669, 29834603, 38784989,
+    50420551, 65546729, 85210757, 110774011, 144006217, 187208107,
+    243370577, 316381771, 411296309, 534685237, 695090819, 903618083,
+    1174703521, 1527114613, 1837299131, 2147483647
+  };
+  size_t i;
+
+  for (i = *prime_offset; i < countof (primes); i++)
+    if (primes[i] >= size)
+      {
+        /* Set the offset to the next prime.  That is safe because,
+           next time we are called, it will be with a larger SIZE,
+           which means we could never return the same prime anyway.
+           (If that is not the case, the caller can simply reset
+           *prime_offset.)  */
+        *prime_offset = i + 1;
+        return primes[i];
+      }
+
+  abort ();
+}
+
+static int cmp_pointer (const void *, const void *);
+
+/* Create a hash table with hash function HASH_FUNCTION and test
+   function TEST_FUNCTION.  The table is empty (its count is 0), but
+   pre-allocated to store at least ITEMS items.
+
+   ITEMS is the number of items that the table can accept without
+   needing to resize.  It is useful when creating a table that is to
+   be immediately filled with a known number of items.  In that case,
+   the regrows are a waste of time, and specifying ITEMS correctly
+   will avoid them altogether.
+
+   Note that hash tables grow dynamically regardless of ITEMS.  The
+   only use of ITEMS is to preallocate the table and avoid unnecessary
+   dynamic regrows.  Don't bother making ITEMS prime because it's not
+   used as size unchanged.  To start with a small table that grows as
+   needed, simply specify zero ITEMS.
+
+   If hash and test callbacks are not specified, identity mapping is
+   assumed, i.e. pointer values are used for key comparison.  (Common
+   Lisp calls such tables EQ hash tables, and Java calls them
+   IdentityHashMaps.)  If your keys require different comparison,
+   specify hash and test functions.  For easy use of C strings as hash
+   keys, you can use the convenience functions make_string_hash_table
+   and make_nocase_string_hash_table.  */
+
+struct hash_table *
+hash_table_new (int items,
+                unsigned long (*hash_function) (const void *),
+                int (*test_function) (const void *, const void *))
+{
+  int size;
+  struct hash_table *ht = xnew (struct hash_table);
+
+  ht->hash_function = hash_function ? hash_function : hash_pointer;
+  ht->test_function = test_function ? test_function : cmp_pointer;
+
+  /* If the size of struct hash_table ever becomes a concern, this
+     field can go.  (Wget doesn't create many hashes.)  */
+  ht->prime_offset = 0;
+
+  /* Calculate the size that ensures that the table will store at
+     least ITEMS keys without the need to resize.  */
+  size = (int) (1 + items / HASH_MAX_FULLNESS);
+  size = prime_size (size, &ht->prime_offset);
+  ht->size = size;
+  ht->resize_threshold = (int) (size * HASH_MAX_FULLNESS);
+  /*assert (ht->resize_threshold >= items);*/
+
+  ht->cells = xnew_array (struct cell, ht->size);
+
+  /* Mark cells as empty.  We use 0xff rather than 0 to mark empty
+     keys because it allows us to use NULL/0 as keys.  */
+  memset (ht->cells, INVALID_PTR_CHAR, size * sizeof (struct cell));
+
+  ht->count = 0;
+
+  return ht;
+}
+
+/* Free the data associated with hash table HT. */
+
+void
+hash_table_destroy (struct hash_table *ht)
+{
+  xfree (ht->cells);
+  xfree (ht);
+}
+
+/* The heart of most functions in this file -- find the cell whose
+   KEY is equal to key, using linear probing.  Returns the cell
+   that matches KEY, or the first empty cell if none matches.  */
+
+static inline struct cell *
+find_cell (const struct hash_table *ht, const void *key)
+{
+  struct cell *cells = ht->cells;
+  int size = ht->size;
+  struct cell *c = cells + HASH_POSITION (key, ht->hash_function, size);
+  testfun_t equals = ht->test_function;
+
+  FOREACH_OCCUPIED_ADJACENT (c, cells, size)
+    if (equals (key, c->key))
+      break;
+  return c;
+}
+
+/* Get the value that corresponds to the key KEY in the hash table HT.
+   If no value is found, return NULL.  Note that NULL is a legal value
+   for value; if you are storing NULLs in your hash table, you can use
+   hash_table_contains to be sure that a (possibly NULL) value exists
+   in the table.  Or, you can use hash_table_get_pair instead of this
+   function.  */
+
+void *
+hash_table_get (const struct hash_table *ht, const void *key)
+{
+  struct cell *c = find_cell (ht, key);
+  if (CELL_OCCUPIED (c))
+    return c->value;
+  else
+    return NULL;
+}
+
+/* Like hash_table_get, but writes out the pointers to both key and
+   value.  Returns non-zero on success.  */
+
+int
+hash_table_get_pair (const struct hash_table *ht, const void *lookup_key,
+                     void *orig_key, void *value)
+{
+  struct cell *c = find_cell (ht, lookup_key);
+  if (CELL_OCCUPIED (c))
+    {
+      if (orig_key)
+        *(void **)orig_key = c->key;
+      if (value)
+        *(void **)value = c->value;
+      return 1;
+    }
+  else
+    return 0;
+}
+
+/* Return 1 if HT contains KEY, 0 otherwise. */
+
+int
+hash_table_contains (const struct hash_table *ht, const void *key)
+{
+  struct cell *c = find_cell (ht, key);
+  return CELL_OCCUPIED (c);
+}
+
+/* Grow hash table HT as necessary, and rehash all the key-value
+   mappings.  */
+
+static void
+grow_hash_table (struct hash_table *ht)
+{
+  hashfun_t hasher = ht->hash_function;
+  struct cell *old_cells = ht->cells;
+  struct cell *old_end   = ht->cells + ht->size;
+  struct cell *c, *cells;
+  int newsize;
+
+  newsize = prime_size (ht->size * HASH_RESIZE_FACTOR, &ht->prime_offset);
+#if 0
+  printf ("growing from %d to %d; fullness %.2f%% to %.2f%%\n",
+          ht->size, newsize,
+          100.0 * ht->count / ht->size,
+          100.0 * ht->count / newsize);
+#endif
+
+  ht->size = newsize;
+  ht->resize_threshold = (int) (newsize * HASH_MAX_FULLNESS);
+
+  cells = xnew_array (struct cell, newsize);
+  memset (cells, INVALID_PTR_CHAR, newsize * sizeof (struct cell));
+  ht->cells = cells;
+
+  for (c = old_cells; c < old_end; c++)
+    if (CELL_OCCUPIED (c))
+      {
+        struct cell *new_c;
+        /* We don't need to test for uniqueness of keys because they
+           come from the hash table and are therefore known to be
+           unique.  */
+        new_c = cells + HASH_POSITION (c->key, hasher, newsize);
+        FOREACH_OCCUPIED_ADJACENT (new_c, cells, newsize)
+          ;
+        *new_c = *c;
+      }
+
+  xfree (old_cells);
+}
+
+/* Put VALUE in the hash table HT under the key KEY.  This regrows the
+   table if necessary.  */
+
+void
+hash_table_put (struct hash_table *ht, const void *key, const void *value)
+{
+  struct cell *c = find_cell (ht, key);
+  if (CELL_OCCUPIED (c))
+    {
+      /* update existing item */
+      c->key   = (void *)key; /* const? */
+      c->value = (void *)value;
+      return;
+    }
+
+  /* If adding the item would make the table exceed max. fullness,
+     grow the table first.  */
+  if (ht->count >= ht->resize_threshold)
+    {
+      grow_hash_table (ht);
+      c = find_cell (ht, key);
+    }
+
+  /* add new item */
+  ++ht->count;
+  c->key   = (void *)key;       /* const? */
+  c->value = (void *)value;
+}
+
+/* Remove KEY->value mapping from HT.  Return 0 if there was no such
+   entry; return 1 if an entry was removed.  */
+
+int
+hash_table_remove (struct hash_table *ht, const void *key)
+{
+  struct cell *c = find_cell (ht, key);
+  if (!CELL_OCCUPIED (c))
+    return 0;
+  else
+    {
+      int size = ht->size;
+      struct cell *cells = ht->cells;
+      hashfun_t hasher = ht->hash_function;
+
+      CLEAR_CELL (c);
+      --ht->count;
+
+      /* Rehash all the entries following C.  The alternative
+         approach is to mark the entry as deleted, i.e. create a
+         "tombstone".  That speeds up removal, but leaves a lot of
+         garbage and slows down hash_table_get and hash_table_put.  */
+
+      c = NEXT_CELL (c, cells, size);
+      FOREACH_OCCUPIED_ADJACENT (c, cells, size)
+        {
+          const void *key2 = c->key;
+          struct cell *c_new;
+
+          /* Find the new location for the key. */
+          c_new = cells + HASH_POSITION (key2, hasher, size);
+          FOREACH_OCCUPIED_ADJACENT (c_new, cells, size)
+            if (key2 == c_new->key)
+              /* The cell C (key2) is already where we want it (in
+                 C_NEW's "chain" of keys.)  */
+              goto next_rehash;
+
+          *c_new = *c;
+          CLEAR_CELL (c);
+
+        next_rehash:
+          ;
+        }
+      return 1;
+    }
+}
+
+/* Clear HT of all entries.  After calling this function, the count
+   and the fullness of the hash table will be zero.  The size will
+   remain unchanged.  */
+
+void
+hash_table_clear (struct hash_table *ht)
+{
+  memset (ht->cells, INVALID_PTR_CHAR, ht->size * sizeof (struct cell));
+  ht->count = 0;
+}
+
+/* Call FN for each entry in HT.  FN is called with three arguments:
+   the key, the value, and ARG.  When FN returns a non-zero value, the
+   mapping stops.
+
+   It is undefined what happens if you add or remove entries in the
+   hash table while hash_table_for_each is running.  The exception is
+   the entry you're currently mapping over; you may call
+   hash_table_put or hash_table_remove on that entry's key.  That is
+   also the reason why this function cannot be implemented in terms of
+   hash_table_iterate.  */
+
+void
+hash_table_for_each (struct hash_table *ht,
+                     int (*fn) (void *, void *, void *), void *arg)
+{
+  struct cell *c = ht->cells;
+  struct cell *end = ht->cells + ht->size;
+
+  for (; c < end; c++)
+    if (CELL_OCCUPIED (c))
+      {
+        void *key;
+      repeat:
+        key = c->key;
+        if (fn (key, c->value, arg))
+          return;
+        /* hash_table_remove might have moved the adjacent cells. */
+        if (c->key != key && CELL_OCCUPIED (c))
+          goto repeat;
+      }
+}
+
+/* Initiate iteration over HT.  Entries are obtained with
+   hash_table_iter_next, a typical iteration loop looking like this:
+
+       hash_table_iterator iter;
+       for (hash_table_iterate (ht, &iter); hash_table_iter_next (&iter); )
+         ... do something with iter.key and iter.value ...
+
+   The iterator does not need to be deallocated after use.  The hash
+   table must not be modified while being iterated over.  */
+
+void
+hash_table_iterate (struct hash_table *ht, hash_table_iterator *iter)
+{
+  iter->pos = ht->cells;
+  iter->end = ht->cells + ht->size;
+}
+
+/* Get the next hash table entry.  ITER is an iterator object
+   initialized using hash_table_iterate.  While there are more
+   entries, the key and value pointers are stored to ITER->key and
+   ITER->value respectively and 1 is returned.  When there are no more
+   entries, 0 is returned.
+
+   If the hash table is modified between calls to this function, the
+   result is undefined.  */
+
+int
+hash_table_iter_next (hash_table_iterator *iter)
+{
+  struct cell *c = iter->pos;
+  struct cell *end = iter->end;
+  for (; c < end; c++)
+    if (CELL_OCCUPIED (c))
+      {
+        iter->key = c->key;
+        iter->value = c->value;
+        iter->pos = c + 1;
+        return 1;
+      }
+  return 0;
+}
+
+/* Return the number of elements in the hash table.  This is not the
+   same as the physical size of the hash table, which is always
+   greater than the number of elements.  */
+
+int
+hash_table_count (const struct hash_table *ht)
+{
+  return ht->count;
+}
+
+/* Functions from this point onward are meant for convenience and
+   don't strictly belong to this file.  However, this is as good a
+   place for them as any.  */
+
+/* Guidelines for creating custom hash and test functions:
+
+   - The test function returns non-zero for keys that are considered
+     "equal", zero otherwise.
+
+   - The hash function returns a number that represents the
+     "distinctness" of the object.  In more precise terms, it means
+     that for any two objects that test "equal" under the test
+     function, the hash function MUST produce the same result.
+
+     This does not mean that all different objects must produce
+     different values (that would be "perfect" hashing), only that
+     non-distinct objects must produce the same values!  For instance,
+     a hash function that returns 0 for any given object is a
+     perfectly valid (albeit extremely bad) hash function.  A hash
+     function that hashes a string by adding up all its characters is
+     another example of a valid (but still quite bad) hash function.
+
+     It is not hard to make hash and test functions agree about
+     equality.  For example, if the test function compares strings
+     case-insensitively, the hash function can lower-case the
+     characters when calculating the hash value.  That ensures that
+     two strings differing only in case will hash the same.
+
+   - To prevent performance degradation, choose a hash function with
+     as good "spreading" as possible.  A good hash function will use
+     all the bits of the input when calculating the hash, and will
+     react to even small changes in input with a completely different
+     output.  But don't make the hash function itself overly slow,
+     because you'll be incurring a non-negligible overhead to all hash
+     table operations.  */
+
+/*
+ * Support for hash tables whose keys are strings.
+ *
+ */
+
+/* Base 31 hash function.  Taken from Gnome's glib, modified to use
+   standard C types.
+
+   We used to use the popular hash function from the Dragon Book, but
+   this one seems to perform much better, both by being faster and by
+   generating less collisions.  */
+
+#ifdef __clang__
+__attribute__((no_sanitize("integer")))
+#endif
+static unsigned long
+hash_string (const void *key)
+{
+  const char *p = key;
+  unsigned int h = *p;
+
+  if (h)
+    for (p += 1; *p != '\0'; p++)
+      h = (h << 5) - h + *p;
+
+  return h;
+}
+
+/* Frontend for strcmp usable for hash tables. */
+
+static int
+cmp_string (const void *s1, const void *s2)
+{
+  return !strcmp ((const char *)s1, (const char *)s2);
+}
+
+/* Return a hash table of preallocated to store at least ITEMS items
+   suitable to use strings as keys.  */
+
+struct hash_table *
+make_string_hash_table (int items)
+{
+  return hash_table_new (items, hash_string, cmp_string);
+}
+
+/*
+ * Support for hash tables whose keys are strings, but which are
+ * compared case-insensitively.
+ *
+ */
+
+/* Like hash_string, but produce the same hash regardless of the case. */
+
+#ifdef __clang__
+__attribute__((no_sanitize("integer")))
+#endif
+static unsigned long
+hash_string_nocase (const void *key)
+{
+  const char *p = key;
+  unsigned int h = c_tolower (*p);
+
+  if (h)
+    for (p += 1; *p != '\0'; p++)
+      h = (h << 5) - h + c_tolower (*p);
+
+  return h;
+}
+
+/* Like string_cmp, but doing case-insensitive comparison. */
+
+static int
+string_cmp_nocase (const void *s1, const void *s2)
+{
+  return !strcasecmp ((const char *)s1, (const char *)s2);
+}
+
+/* Like make_string_hash_table, but uses string_hash_nocase and
+   string_cmp_nocase.  */
+
+struct hash_table *
+make_nocase_string_hash_table (int items)
+{
+  return hash_table_new (items, hash_string_nocase, string_cmp_nocase);
+}
+
+/* Hashing of numeric values, such as pointers and integers.
+
+   This implementation is the Robert Jenkins' 32 bit Mix Function,
+   with a simple adaptation for 64-bit values.  According to Jenkins
+   it should offer excellent spreading of values.  Unlike the popular
+   Knuth's multiplication hash, this function doesn't need to know the
+   hash table size to work.  */
+
+#ifdef __clang__
+__attribute__((no_sanitize("integer")))
+#endif
+unsigned long
+hash_pointer (const void *ptr)
+{
+  uintptr_t key = (uintptr_t) ptr;
+  key += (key << 12);
+  key ^= (key >> 22);
+  key += (key << 4);
+  key ^= (key >> 9);
+  key += (key << 10);
+  key ^= (key >> 2);
+  key += (key << 7);
+  key ^= (key >> 12);
+#if SIZEOF_VOID_P > 4
+  key += (key << 44);
+  key ^= (key >> 54);
+  key += (key << 36);
+  key ^= (key >> 41);
+  key += (key << 42);
+  key ^= (key >> 34);
+  key += (key << 39);
+  key ^= (key >> 44);
+#endif
+  return (unsigned long) key;
+}
+
+static int
+cmp_pointer (const void *ptr1, const void *ptr2)
+{
+  return ptr1 == ptr2;
+}
+
+#ifdef TEST
+
+#include <stdio.h>
+#include <string.h>
+
+void
+print_hash (struct hash_table *sht)
+{
+  hash_table_iterator iter;
+  int count = 0;
+
+  for (hash_table_iterate (sht, &iter); hash_table_iter_next (&iter);
+       ++count)
+    printf ("%s: %s\n", iter.key, iter.value);
+  assert (count == sht->count);
+}
+
+int
+main (void)
+{
+  struct hash_table *ht = make_string_hash_table (0);
+  char line[80];
+
+#ifdef ENABLE_NLS
+  /* Set the current locale.  */
+  setlocale (LC_ALL, "");
+  /* Set the text message domain.  */
+  bindtextdomain ("wget", LOCALEDIR);
+  textdomain ("wget");
+#endif /* ENABLE_NLS */
+
+  while ((fgets (line, sizeof (line), stdin)))
+    {
+      int len = strlen (line);
+      if (len <= 1)
+        continue;
+      line[--len] = '\0';
+      if (!hash_table_contains (ht, line))
+        hash_table_put (ht, strdup (line), "here I am!");
+#if 1
+      if (len % 5 == 0)
+        {
+          char *line_copy;
+          if (hash_table_get_pair (ht, line, &line_copy, NULL))
+            {
+              hash_table_remove (ht, line);
+              xfree (line_copy);
+            }
+        }
+#endif
+    }
+#if 0
+  print_hash (ht);
+#endif
+#if 1
+  printf ("%d %d\n", ht->count, ht->size);
+#endif
+  return 0;
+}
+#endif /* TEST */