2 @c This is part of the GNU Emacs Lisp Reference Manual.
3 @c Copyright (C) 1999, 2001, 2002, 2003, 2004, 2005,
4 @c 2006, 2007, 2008 Free Software Foundation, Inc.
5 @c See the file elisp.texi for copying conditions.
6 @setfilename ../info/hash
7 @node Hash Tables, Symbols, Sequences Arrays Vectors, Top
12 A hash table is a very fast kind of lookup table, somewhat like an
13 alist (@pxref{Association Lists}) in that it maps keys to
14 corresponding values. It differs from an alist in these ways:
18 Lookup in a hash table is extremely fast for large tables---in fact, the
19 time required is essentially @emph{independent} of how many elements are
20 stored in the table. For smaller tables (a few tens of elements)
21 alists may still be faster because hash tables have a more-or-less
25 The correspondences in a hash table are in no particular order.
28 There is no way to share structure between two hash tables,
29 the way two alists can share a common tail.
32 Emacs Lisp provides a general-purpose hash table data type, along
33 with a series of functions for operating on them. Hash tables have no
34 read syntax, and print in hash notation, like this:
38 @result{} #<hash-table 'eql nil 0/65 0x83af980>
42 (The term ``hash notation'' refers to the initial @samp{#}
43 character---@pxref{Printed Representation}---and has nothing to do with
44 the term ``hash table.'')
46 Obarrays are also a kind of hash table, but they are a different type
47 of object and are used only for recording interned symbols
48 (@pxref{Creating Symbols}).
51 * Creating Hash:: Functions to create hash tables.
52 * Hash Access:: Reading and writing the hash table contents.
53 * Defining Hash:: Defining new comparison methods
54 * Other Hash:: Miscellaneous.
58 @section Creating Hash Tables
59 @cindex creating hash tables
61 The principal function for creating a hash table is
62 @code{make-hash-table}.
64 @defun make-hash-table &rest keyword-args
65 This function creates a new hash table according to the specified
66 arguments. The arguments should consist of alternating keywords
67 (particular symbols recognized specially) and values corresponding to
70 Several keywords make sense in @code{make-hash-table}, but the only two
71 that you really need to know about are @code{:test} and @code{:weakness}.
74 @item :test @var{test}
75 This specifies the method of key lookup for this hash table. The
76 default is @code{eql}; @code{eq} and @code{equal} are other
81 Keys which are numbers are ``the same'' if they are @code{equal}, that
82 is, if they are equal in value and either both are integers or both
83 are floating point numbers; otherwise, two distinct objects are never
87 Any two distinct Lisp objects are ``different'' as keys.
90 Two Lisp objects are ``the same,'' as keys, if they are equal
91 according to @code{equal}.
94 You can use @code{define-hash-table-test} (@pxref{Defining Hash}) to
95 define additional possibilities for @var{test}.
97 @item :weakness @var{weak}
98 The weakness of a hash table specifies whether the presence of a key or
99 value in the hash table preserves it from garbage collection.
101 The value, @var{weak}, must be one of @code{nil}, @code{key},
102 @code{value}, @code{key-or-value}, @code{key-and-value}, or @code{t}
103 which is an alias for @code{key-and-value}. If @var{weak} is @code{key}
104 then the hash table does not prevent its keys from being collected as
105 garbage (if they are not referenced anywhere else); if a particular key
106 does get collected, the corresponding association is removed from the
109 If @var{weak} is @code{value}, then the hash table does not prevent
110 values from being collected as garbage (if they are not referenced
111 anywhere else); if a particular value does get collected, the
112 corresponding association is removed from the hash table.
114 If @var{weak} is @code{key-and-value} or @code{t}, both the key and
115 the value must be live in order to preserve the association. Thus,
116 the hash table does not protect either keys or values from garbage
117 collection; if either one is collected as garbage, that removes the
120 If @var{weak} is @code{key-or-value}, either the key or
121 the value can preserve the association. Thus, associations are
122 removed from the hash table when both their key and value would be
123 collected as garbage (if not for references from weak hash tables).
125 The default for @var{weak} is @code{nil}, so that all keys and values
126 referenced in the hash table are preserved from garbage collection.
128 @item :size @var{size}
129 This specifies a hint for how many associations you plan to store in the
130 hash table. If you know the approximate number, you can make things a
131 little more efficient by specifying it this way. If you specify too
132 small a size, the hash table will grow automatically when necessary, but
133 doing that takes some extra time.
135 The default size is 65.
137 @item :rehash-size @var{rehash-size}
138 When you add an association to a hash table and the table is ``full,''
139 it grows automatically. This value specifies how to make the hash table
140 larger, at that time.
142 If @var{rehash-size} is an integer, it should be positive, and the hash
143 table grows by adding that much to the nominal size. If
144 @var{rehash-size} is a floating point number, it had better be greater
145 than 1, and the hash table grows by multiplying the old size by that
148 The default value is 1.5.
150 @item :rehash-threshold @var{threshold}
151 This specifies the criterion for when the hash table is ``full'' (so
152 it should be made larger). The value, @var{threshold}, should be a
153 positive floating point number, no greater than 1. The hash table is
154 ``full'' whenever the actual number of entries exceeds this fraction
155 of the nominal size. The default for @var{threshold} is 0.8.
159 @defun makehash &optional test
160 This is equivalent to @code{make-hash-table}, but with a different style
161 argument list. The argument @var{test} specifies the method
164 This function is obsolete. Use @code{make-hash-table} instead.
168 @section Hash Table Access
170 This section describes the functions for accessing and storing
171 associations in a hash table. In general, any Lisp object can be used
172 as a hash key, unless the comparison method imposes limits. Any Lisp
173 object can also be used as the value.
175 @defun gethash key table &optional default
176 This function looks up @var{key} in @var{table}, and returns its
177 associated @var{value}---or @var{default}, if @var{key} has no
178 association in @var{table}.
181 @defun puthash key value table
182 This function enters an association for @var{key} in @var{table}, with
183 value @var{value}. If @var{key} already has an association in
184 @var{table}, @var{value} replaces the old associated value.
187 @defun remhash key table
188 This function removes the association for @var{key} from @var{table}, if
189 there is one. If @var{key} has no association, @code{remhash} does
192 @b{Common Lisp note:} In Common Lisp, @code{remhash} returns
193 non-@code{nil} if it actually removed an association and @code{nil}
194 otherwise. In Emacs Lisp, @code{remhash} always returns @code{nil}.
198 This function removes all the associations from hash table @var{table},
199 so that it becomes empty. This is also called @dfn{clearing} the hash
202 @b{Common Lisp note:} In Common Lisp, @code{clrhash} returns the empty
203 @var{table}. In Emacs Lisp, it returns @code{nil}.
206 @defun maphash function table
207 @anchor{Definition of maphash}
208 This function calls @var{function} once for each of the associations in
209 @var{table}. The function @var{function} should accept two
210 arguments---a @var{key} listed in @var{table}, and its associated
211 @var{value}. @code{maphash} returns @code{nil}.
215 @section Defining Hash Comparisons
217 @cindex define hash comparisons
219 You can define new methods of key lookup by means of
220 @code{define-hash-table-test}. In order to use this feature, you need
221 to understand how hash tables work, and what a @dfn{hash code} means.
223 You can think of a hash table conceptually as a large array of many
224 slots, each capable of holding one association. To look up a key,
225 @code{gethash} first computes an integer, the hash code, from the key.
226 It reduces this integer modulo the length of the array, to produce an
227 index in the array. Then it looks in that slot, and if necessary in
228 other nearby slots, to see if it has found the key being sought.
230 Thus, to define a new method of key lookup, you need to specify both a
231 function to compute the hash code from a key, and a function to compare
234 @defun define-hash-table-test name test-fn hash-fn
235 This function defines a new hash table test, named @var{name}.
237 After defining @var{name} in this way, you can use it as the @var{test}
238 argument in @code{make-hash-table}. When you do that, the hash table
239 will use @var{test-fn} to compare key values, and @var{hash-fn} to compute
240 a ``hash code'' from a key value.
242 The function @var{test-fn} should accept two arguments, two keys, and
243 return non-@code{nil} if they are considered ``the same.''
245 The function @var{hash-fn} should accept one argument, a key, and return
246 an integer that is the ``hash code'' of that key. For good results, the
247 function should use the whole range of integer values for hash codes,
248 including negative integers.
250 The specified functions are stored in the property list of @var{name}
251 under the property @code{hash-table-test}; the property value's form is
252 @code{(@var{test-fn} @var{hash-fn})}.
256 This function returns a hash code for Lisp object @var{obj}.
257 This is an integer which reflects the contents of @var{obj}
258 and the other Lisp objects it points to.
260 If two objects @var{obj1} and @var{obj2} are equal, then @code{(sxhash
261 @var{obj1})} and @code{(sxhash @var{obj2})} are the same integer.
263 If the two objects are not equal, the values returned by @code{sxhash}
264 are usually different, but not always; once in a rare while, by luck,
265 you will encounter two distinct-looking objects that give the same
266 result from @code{sxhash}.
269 This example creates a hash table whose keys are strings that are
270 compared case-insensitively.
273 (defun case-fold-string= (a b)
274 (compare-strings a nil nil b nil nil t))
275 (defun case-fold-string-hash (a)
278 (define-hash-table-test 'case-fold
279 'case-fold-string= 'case-fold-string-hash)
281 (make-hash-table :test 'case-fold)
284 Here is how you could define a hash table test equivalent to the
285 predefined test value @code{equal}. The keys can be any Lisp object,
286 and equal-looking objects are considered the same key.
289 (define-hash-table-test 'contents-hash 'equal 'sxhash)
291 (make-hash-table :test 'contents-hash)
295 @section Other Hash Table Functions
297 Here are some other functions for working with hash tables.
299 @defun hash-table-p table
300 This returns non-@code{nil} if @var{table} is a hash table object.
303 @defun copy-hash-table table
304 This function creates and returns a copy of @var{table}. Only the table
305 itself is copied---the keys and values are shared.
308 @defun hash-table-count table
309 This function returns the actual number of entries in @var{table}.
312 @defun hash-table-test table
313 This returns the @var{test} value that was given when @var{table} was
314 created, to specify how to hash and compare keys. See
315 @code{make-hash-table} (@pxref{Creating Hash}).
318 @defun hash-table-weakness table
319 This function returns the @var{weak} value that was specified for hash
323 @defun hash-table-rehash-size table
324 This returns the rehash size of @var{table}.
327 @defun hash-table-rehash-threshold table
328 This returns the rehash threshold of @var{table}.
331 @defun hash-table-size table
332 This returns the current nominal size of @var{table}.
336 arch-tag: 3b5107f9-d2f0-47d5-ad61-3498496bea0e