2007-09-06 04:25:08 +00:00
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@c -*-texinfo-*-
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@c This is part of the GNU Emacs Lisp Reference Manual.
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2011-01-25 04:08:28 +00:00
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@c Copyright (C) 1999, 2001-2011 Free Software Foundation, Inc.
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2007-09-06 04:25:08 +00:00
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@c See the file elisp.texi for copying conditions.
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@setfilename ../../info/hash
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@node Hash Tables, Symbols, Sequences Arrays Vectors, Top
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@chapter Hash Tables
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@cindex hash tables
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@cindex lookup tables
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A hash table is a very fast kind of lookup table, somewhat like an
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alist (@pxref{Association Lists}) in that it maps keys to
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corresponding values. It differs from an alist in these ways:
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@itemize @bullet
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@item
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Lookup in a hash table is extremely fast for large tables---in fact, the
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time required is essentially @emph{independent} of how many elements are
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stored in the table. For smaller tables (a few tens of elements)
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alists may still be faster because hash tables have a more-or-less
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constant overhead.
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@item
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The correspondences in a hash table are in no particular order.
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@item
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There is no way to share structure between two hash tables,
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the way two alists can share a common tail.
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@end itemize
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Emacs Lisp provides a general-purpose hash table data type, along
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with a series of functions for operating on them. Hash tables have a
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special printed representation, which consists of @samp{#s} followed
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by a list specifying the hash table properties and contents.
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@xref{Creating Hash}. (Note that the term ``hash notation'', which
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refers to the initial @samp{#} character used in the printed
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representations of objects with no read representation, has nothing to
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do with the term ``hash table''. @xref{Printed Representation}.)
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Obarrays are also a kind of hash table, but they are a different type
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of object and are used only for recording interned symbols
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(@pxref{Creating Symbols}).
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@menu
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* Creating Hash:: Functions to create hash tables.
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* Hash Access:: Reading and writing the hash table contents.
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* Defining Hash:: Defining new comparison methods.
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* Other Hash:: Miscellaneous.
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@end menu
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@node Creating Hash
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@section Creating Hash Tables
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@cindex creating hash tables
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The principal function for creating a hash table is
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@code{make-hash-table}.
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@defun make-hash-table &rest keyword-args
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This function creates a new hash table according to the specified
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arguments. The arguments should consist of alternating keywords
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(particular symbols recognized specially) and values corresponding to
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them.
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Several keywords make sense in @code{make-hash-table}, but the only two
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that you really need to know about are @code{:test} and @code{:weakness}.
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@table @code
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@item :test @var{test}
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This specifies the method of key lookup for this hash table. The
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default is @code{eql}; @code{eq} and @code{equal} are other
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alternatives:
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@table @code
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@item eql
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Keys which are numbers are ``the same'' if they are @code{equal}, that
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is, if they are equal in value and either both are integers or both
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are floating point numbers; otherwise, two distinct objects are never
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``the same.''
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@item eq
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Any two distinct Lisp objects are ``different'' as keys.
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@item equal
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Two Lisp objects are ``the same,'' as keys, if they are equal
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according to @code{equal}.
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@end table
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You can use @code{define-hash-table-test} (@pxref{Defining Hash}) to
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define additional possibilities for @var{test}.
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@item :weakness @var{weak}
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The weakness of a hash table specifies whether the presence of a key or
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value in the hash table preserves it from garbage collection.
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The value, @var{weak}, must be one of @code{nil}, @code{key},
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@code{value}, @code{key-or-value}, @code{key-and-value}, or @code{t}
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which is an alias for @code{key-and-value}. If @var{weak} is @code{key}
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then the hash table does not prevent its keys from being collected as
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garbage (if they are not referenced anywhere else); if a particular key
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does get collected, the corresponding association is removed from the
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hash table.
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If @var{weak} is @code{value}, then the hash table does not prevent
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values from being collected as garbage (if they are not referenced
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anywhere else); if a particular value does get collected, the
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corresponding association is removed from the hash table.
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If @var{weak} is @code{key-and-value} or @code{t}, both the key and
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the value must be live in order to preserve the association. Thus,
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the hash table does not protect either keys or values from garbage
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collection; if either one is collected as garbage, that removes the
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association.
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If @var{weak} is @code{key-or-value}, either the key or
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the value can preserve the association. Thus, associations are
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removed from the hash table when both their key and value would be
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collected as garbage (if not for references from weak hash tables).
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The default for @var{weak} is @code{nil}, so that all keys and values
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referenced in the hash table are preserved from garbage collection.
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@item :size @var{size}
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This specifies a hint for how many associations you plan to store in the
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hash table. If you know the approximate number, you can make things a
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little more efficient by specifying it this way. If you specify too
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small a size, the hash table will grow automatically when necessary, but
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doing that takes some extra time.
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The default size is 65.
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@item :rehash-size @var{rehash-size}
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When you add an association to a hash table and the table is ``full,''
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it grows automatically. This value specifies how to make the hash table
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larger, at that time.
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If @var{rehash-size} is an integer, it should be positive, and the hash
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table grows by adding that much to the nominal size. If
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@var{rehash-size} is a floating point number, it had better be greater
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than 1, and the hash table grows by multiplying the old size by that
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number.
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The default value is 1.5.
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@item :rehash-threshold @var{threshold}
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This specifies the criterion for when the hash table is ``full'' (so
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it should be made larger). The value, @var{threshold}, should be a
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positive floating point number, no greater than 1. The hash table is
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``full'' whenever the actual number of entries exceeds this fraction
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of the nominal size. The default for @var{threshold} is 0.8.
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@end table
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@end defun
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@defun makehash &optional test
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This is equivalent to @code{make-hash-table}, but with a different style
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argument list. The argument @var{test} specifies the method
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of key lookup.
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This function is obsolete. Use @code{make-hash-table} instead.
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@end defun
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2009-12-25 20:04:07 +00:00
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You can also create a new hash table using the printed representation
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for hash tables. The Lisp reader can read this printed
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representation, provided each element in the specified hash table has
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a valid read syntax (@pxref{Printed Representation}). For instance,
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the following specifies a new hash table containing the keys
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@code{key1} and @code{key2} (both symbols) associated with @code{val1}
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(a symbol) and @code{300} (a number) respectively.
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@example
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#s(hash-table size 30 data (key1 val1 key2 300))
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@end example
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@noindent
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The printed representation for a hash table consists of @samp{#s}
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followed by a list beginning with @samp{hash-table}. The rest of the
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list should consist of zero or more property-value pairs specifying
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the hash table's properties and initial contents. The properties and
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values are read literally. Valid property names are @code{size},
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@code{test}, @code{weakness}, @code{rehash-size},
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@code{rehash-threshold}, and @code{data}. The @code{data} property
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should be a list of key-value pairs for the initial contents; the
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other properties have the same meanings as the matching
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@code{make-hash-table} keywords (@code{:size}, @code{:test}, etc.),
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described above.
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Note that you cannot specify a hash table whose initial contents
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include objects that have no read syntax, such as buffers and frames.
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Such objects may be added to the hash table after it is created.
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2007-09-06 04:25:08 +00:00
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@node Hash Access
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@section Hash Table Access
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This section describes the functions for accessing and storing
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associations in a hash table. In general, any Lisp object can be used
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as a hash key, unless the comparison method imposes limits. Any Lisp
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object can also be used as the value.
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@defun gethash key table &optional default
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This function looks up @var{key} in @var{table}, and returns its
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associated @var{value}---or @var{default}, if @var{key} has no
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association in @var{table}.
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@end defun
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@defun puthash key value table
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This function enters an association for @var{key} in @var{table}, with
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value @var{value}. If @var{key} already has an association in
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@var{table}, @var{value} replaces the old associated value.
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@end defun
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@defun remhash key table
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This function removes the association for @var{key} from @var{table}, if
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there is one. If @var{key} has no association, @code{remhash} does
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nothing.
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@b{Common Lisp note:} In Common Lisp, @code{remhash} returns
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non-@code{nil} if it actually removed an association and @code{nil}
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otherwise. In Emacs Lisp, @code{remhash} always returns @code{nil}.
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@end defun
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@defun clrhash table
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This function removes all the associations from hash table @var{table},
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so that it becomes empty. This is also called @dfn{clearing} the hash
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table.
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@b{Common Lisp note:} In Common Lisp, @code{clrhash} returns the empty
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@var{table}. In Emacs Lisp, it returns @code{nil}.
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@end defun
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@defun maphash function table
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@anchor{Definition of maphash}
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This function calls @var{function} once for each of the associations in
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@var{table}. The function @var{function} should accept two
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arguments---a @var{key} listed in @var{table}, and its associated
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@var{value}. @code{maphash} returns @code{nil}.
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@end defun
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@node Defining Hash
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@section Defining Hash Comparisons
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@cindex hash code
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@cindex define hash comparisons
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You can define new methods of key lookup by means of
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@code{define-hash-table-test}. In order to use this feature, you need
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to understand how hash tables work, and what a @dfn{hash code} means.
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You can think of a hash table conceptually as a large array of many
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slots, each capable of holding one association. To look up a key,
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@code{gethash} first computes an integer, the hash code, from the key.
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It reduces this integer modulo the length of the array, to produce an
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index in the array. Then it looks in that slot, and if necessary in
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other nearby slots, to see if it has found the key being sought.
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Thus, to define a new method of key lookup, you need to specify both a
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function to compute the hash code from a key, and a function to compare
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two keys directly.
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@defun define-hash-table-test name test-fn hash-fn
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This function defines a new hash table test, named @var{name}.
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After defining @var{name} in this way, you can use it as the @var{test}
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argument in @code{make-hash-table}. When you do that, the hash table
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will use @var{test-fn} to compare key values, and @var{hash-fn} to compute
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a ``hash code'' from a key value.
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The function @var{test-fn} should accept two arguments, two keys, and
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return non-@code{nil} if they are considered ``the same.''
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The function @var{hash-fn} should accept one argument, a key, and return
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an integer that is the ``hash code'' of that key. For good results, the
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function should use the whole range of integer values for hash codes,
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including negative integers.
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The specified functions are stored in the property list of @var{name}
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under the property @code{hash-table-test}; the property value's form is
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@code{(@var{test-fn} @var{hash-fn})}.
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@end defun
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@defun sxhash obj
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This function returns a hash code for Lisp object @var{obj}.
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This is an integer which reflects the contents of @var{obj}
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and the other Lisp objects it points to.
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If two objects @var{obj1} and @var{obj2} are equal, then @code{(sxhash
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@var{obj1})} and @code{(sxhash @var{obj2})} are the same integer.
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If the two objects are not equal, the values returned by @code{sxhash}
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are usually different, but not always; once in a rare while, by luck,
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you will encounter two distinct-looking objects that give the same
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result from @code{sxhash}.
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@end defun
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This example creates a hash table whose keys are strings that are
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compared case-insensitively.
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@example
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(defun case-fold-string= (a b)
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(compare-strings a nil nil b nil nil t))
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(defun case-fold-string-hash (a)
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(sxhash (upcase a)))
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(define-hash-table-test 'case-fold
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'case-fold-string= 'case-fold-string-hash)
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(make-hash-table :test 'case-fold)
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@end example
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Here is how you could define a hash table test equivalent to the
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predefined test value @code{equal}. The keys can be any Lisp object,
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and equal-looking objects are considered the same key.
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@example
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(define-hash-table-test 'contents-hash 'equal 'sxhash)
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(make-hash-table :test 'contents-hash)
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@end example
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@node Other Hash
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@section Other Hash Table Functions
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Here are some other functions for working with hash tables.
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@defun hash-table-p table
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This returns non-@code{nil} if @var{table} is a hash table object.
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@end defun
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@defun copy-hash-table table
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This function creates and returns a copy of @var{table}. Only the table
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itself is copied---the keys and values are shared.
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@end defun
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@defun hash-table-count table
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This function returns the actual number of entries in @var{table}.
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@end defun
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@defun hash-table-test table
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This returns the @var{test} value that was given when @var{table} was
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created, to specify how to hash and compare keys. See
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@code{make-hash-table} (@pxref{Creating Hash}).
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@end defun
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@defun hash-table-weakness table
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This function returns the @var{weak} value that was specified for hash
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table @var{table}.
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@end defun
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@defun hash-table-rehash-size table
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This returns the rehash size of @var{table}.
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@end defun
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@defun hash-table-rehash-threshold table
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This returns the rehash threshold of @var{table}.
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@end defun
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@defun hash-table-size table
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This returns the current nominal size of @var{table}.
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@end defun
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