@c -*-texinfo-*- @c This is part of the GNU Guile Reference Manual. @c Copyright (C) 1996, 1997, 2000, 2001, 2002, 2003, 2004 @c Free Software Foundation, Inc. @c See the file guile.texi for copying conditions. @page @node Compound Data Types @section Compound Data Types This chapter describes Guile's compound data types. By @dfn{compound} we mean that the primary purpose of these data types is to act as containers for other kinds of data (including other compound objects). For instance, a (non-uniform) vector with length 5 is a container that can hold five arbitrary Scheme objects. The various kinds of container object differ from each other in how their memory is allocated, how they are indexed, and how particular values can be looked up within them. @menu * Pairs:: Scheme's basic building block. * Lists:: Special list functions supported by Guile. * Vectors:: One-dimensional arrays of Scheme objects. * Uniform Numeric Vectors:: Vectors with elements of a single numeric type. * Bit Vectors:: Vectors of bits. * Generalized Vectors:: Treating all vector-like things uniformly. * Arrays:: Matrices, etc. * Records:: * Structures:: * Dictionary Types:: About dictionary types in general. * Association Lists:: List-based dictionaries. * Hash Tables:: Table-based dictionaries. @end menu @node Pairs @subsection Pairs @tpindex Pairs Pairs are used to combine two Scheme objects into one compound object. Hence the name: A pair stores a pair of objects. The data type @dfn{pair} is extremely important in Scheme, just like in any other Lisp dialect. The reason is that pairs are not only used to make two values available as one object, but that pairs are used for constructing lists of values. Because lists are so important in Scheme, they are described in a section of their own (@pxref{Lists}). Pairs can literally get entered in source code or at the REPL, in the so-called @dfn{dotted list} syntax. This syntax consists of an opening parentheses, the first element of the pair, a dot, the second element and a closing parentheses. The following example shows how a pair consisting of the two numbers 1 and 2, and a pair containing the symbols @code{foo} and @code{bar} can be entered. It is very important to write the whitespace before and after the dot, because otherwise the Scheme parser would not be able to figure out where to split the tokens. @lisp (1 . 2) (foo . bar) @end lisp But beware, if you want to try out these examples, you have to @dfn{quote} the expressions. More information about quotation is available in the section (REFFIXME). The correct way to try these examples is as follows. @lisp '(1 . 2) @result{} (1 . 2) '(foo . bar) @result{} (foo . bar) @end lisp A new pair is made by calling the procedure @code{cons} with two arguments. Then the argument values are stored into a newly allocated pair, and the pair is returned. The name @code{cons} stands for "construct". Use the procedure @code{pair?} to test whether a given Scheme object is a pair or not. @rnindex cons @deffn {Scheme Procedure} cons x y @deffnx {C Function} scm_cons (x, y) Return a newly allocated pair whose car is @var{x} and whose cdr is @var{y}. The pair is guaranteed to be different (in the sense of @code{eq?}) from every previously existing object. @end deffn @rnindex pair? @deffn {Scheme Procedure} pair? x @deffnx {C Function} scm_pair_p (x) Return @code{#t} if @var{x} is a pair; otherwise return @code{#f}. @end deffn @deftypefn {C Function} int scm_is_pair (SCM x) Return 1 when @var{x} is a pair; otherwise return 0. @end deftypefn The two parts of a pair are traditionally called @dfn{car} and @dfn{cdr}. They can be retrieved with procedures of the same name (@code{car} and @code{cdr}), and can be modified with the procedures @code{set-car!} and @code{set-cdr!}. Since a very common operation in Scheme programs is to access the car of a pair, or the car of the cdr of a pair, etc., the procedures called @code{caar}, @code{cadr} and so on are also predefined. @rnindex car @rnindex cdr @deffn {Scheme Procedure} car pair @deffnx {Scheme Procedure} cdr pair @deffnx {C Function} scm_car (pair) @deffnx {C Function} scm_cdr (pair) Return the car or the cdr of @var{pair}, respectively. @end deffn @deffn {Scheme Procedure} cddr pair @deffnx {Scheme Procedure} cdar pair @deffnx {Scheme Procedure} cadr pair @deffnx {Scheme Procedure} caar pair @deffnx {Scheme Procedure} cdddr pair @deffnx {Scheme Procedure} cddar pair @deffnx {Scheme Procedure} cdadr pair @deffnx {Scheme Procedure} cdaar pair @deffnx {Scheme Procedure} caddr pair @deffnx {Scheme Procedure} cadar pair @deffnx {Scheme Procedure} caadr pair @deffnx {Scheme Procedure} caaar pair @deffnx {Scheme Procedure} cddddr pair @deffnx {Scheme Procedure} cdddar pair @deffnx {Scheme Procedure} cddadr pair @deffnx {Scheme Procedure} cddaar pair @deffnx {Scheme Procedure} cdaddr pair @deffnx {Scheme Procedure} cdadar pair @deffnx {Scheme Procedure} cdaadr pair @deffnx {Scheme Procedure} cdaaar pair @deffnx {Scheme Procedure} cadddr pair @deffnx {Scheme Procedure} caddar pair @deffnx {Scheme Procedure} cadadr pair @deffnx {Scheme Procedure} cadaar pair @deffnx {Scheme Procedure} caaddr pair @deffnx {Scheme Procedure} caadar pair @deffnx {Scheme Procedure} caaadr pair @deffnx {Scheme Procedure} caaaar pair @deffnx {C Function} scm_cddr (pair) @deffnx {C Function} scm_cdar (pair) @deffnx {C Function} scm_cadr (pair) @deffnx {C Function} scm_caar (pair) @deffnx {C Function} scm_cdddr (pair) @deffnx {C Function} scm_cddar (pair) @deffnx {C Function} scm_cdadr (pair) @deffnx {C Function} scm_cdaar (pair) @deffnx {C Function} scm_caddr (pair) @deffnx {C Function} scm_cadar (pair) @deffnx {C Function} scm_caadr (pair) @deffnx {C Function} scm_caaar (pair) @deffnx {C Function} scm_cddddr (pair) @deffnx {C Function} scm_cdddar (pair) @deffnx {C Function} scm_cddadr (pair) @deffnx {C Function} scm_cddaar (pair) @deffnx {C Function} scm_cdaddr (pair) @deffnx {C Function} scm_cdadar (pair) @deffnx {C Function} scm_cdaadr (pair) @deffnx {C Function} scm_cdaaar (pair) @deffnx {C Function} scm_cadddr (pair) @deffnx {C Function} scm_caddar (pair) @deffnx {C Function} scm_cadadr (pair) @deffnx {C Function} scm_cadaar (pair) @deffnx {C Function} scm_caaddr (pair) @deffnx {C Function} scm_caadar (pair) @deffnx {C Function} scm_caaadr (pair) @deffnx {C Function} scm_caaaar (pair) These procedures are compositions of @code{car} and @code{cdr}, where for example @code{caddr} could be defined by @lisp (define caddr (lambda (x) (car (cdr (cdr x))))) @end lisp @end deffn @rnindex set-car! @deffn {Scheme Procedure} set-car! pair value @deffnx {C Function} scm_set_car_x (pair, value) Stores @var{value} in the car field of @var{pair}. The value returned by @code{set-car!} is unspecified. @end deffn @rnindex set-cdr! @deffn {Scheme Procedure} set-cdr! pair value @deffnx {C Function} scm_set_cdr_x (pair, value) Stores @var{value} in the cdr field of @var{pair}. The value returned by @code{set-cdr!} is unspecified. @end deffn @node Lists @subsection Lists @tpindex Lists A very important data type in Scheme---as well as in all other Lisp dialects---is the data type @dfn{list}.@footnote{Strictly speaking, Scheme does not have a real datatype @dfn{list}. Lists are made up of @dfn{chained pairs}, and only exist by definition---a list is a chain of pairs which looks like a list.} This is the short definition of what a list is: @itemize @bullet @item Either the empty list @code{()}, @item or a pair which has a list in its cdr. @end itemize @c FIXME::martin: Describe the pair chaining in more detail. @c FIXME::martin: What is a proper, what an improper list? @c What is a circular list? @c FIXME::martin: Maybe steal some graphics from the Elisp reference @c manual? @menu * List Syntax:: Writing literal lists. * List Predicates:: Testing lists. * List Constructors:: Creating new lists. * List Selection:: Selecting from lists, getting their length. * Append/Reverse:: Appending and reversing lists. * List Modification:: Modifying existing lists. * List Searching:: Searching for list elements * List Mapping:: Applying procedures to lists. @end menu @node List Syntax @subsubsection List Read Syntax The syntax for lists is an opening parentheses, then all the elements of the list (separated by whitespace) and finally a closing parentheses.@footnote{Note that there is no separation character between the list elements, like a comma or a semicolon.}. @lisp (1 2 3) ; @r{a list of the numbers 1, 2 and 3} ("foo" bar 3.1415) ; @r{a string, a symbol and a real number} () ; @r{the empty list} @end lisp The last example needs a bit more explanation. A list with no elements, called the @dfn{empty list}, is special in some ways. It is used for terminating lists by storing it into the cdr of the last pair that makes up a list. An example will clear that up: @lisp (car '(1)) @result{} 1 (cdr '(1)) @result{} () @end lisp This example also shows that lists have to be quoted (REFFIXME) when written, because they would otherwise be mistakingly taken as procedure applications (@pxref{Simple Invocation}). @node List Predicates @subsubsection List Predicates Often it is useful to test whether a given Scheme object is a list or not. List-processing procedures could use this information to test whether their input is valid, or they could do different things depending on the datatype of their arguments. @rnindex list? @deffn {Scheme Procedure} list? x @deffnx {C Function} scm_list_p (x) Return @code{#t} iff @var{x} is a proper list, else @code{#f}. @end deffn The predicate @code{null?} is often used in list-processing code to tell whether a given list has run out of elements. That is, a loop somehow deals with the elements of a list until the list satisfies @code{null?}. Then, the algorithm terminates. @rnindex null? @deffn {Scheme Procedure} null? x @deffnx {C Function} scm_null_p (x) Return @code{#t} iff @var{x} is the empty list, else @code{#f}. @end deffn @deftypefn {C Function} int scm_is_null (SCM x) Return 1 when @var{x} is the empty list; otherwise return 0. @end deftypefn @node List Constructors @subsubsection List Constructors This section describes the procedures for constructing new lists. @code{list} simply returns a list where the elements are the arguments, @code{cons*} is similar, but the last argument is stored in the cdr of the last pair of the list. @c C Function scm_list(rest) used to be documented here, but it's a @c no-op since it does nothing but return the list the caller must @c have already created. @c @deffn {Scheme Procedure} list elem1 @dots{} elemN @deffnx {C Function} scm_list_1 (elem1) @deffnx {C Function} scm_list_2 (elem1, elem2) @deffnx {C Function} scm_list_3 (elem1, elem2, elem3) @deffnx {C Function} scm_list_4 (elem1, elem2, elem3, elem4) @deffnx {C Function} scm_list_5 (elem1, elem2, elem3, elem4, elem5) @deffnx {C Function} scm_list_n (elem1, @dots{}, elemN, @nicode{SCM_UNDEFINED}) @rnindex list Return a new list containing elements @var{elem1} to @var{elemN}. @code{scm_list_n} takes a variable number of arguments, terminated by the special @code{SCM_UNDEFINED}. That final @code{SCM_UNDEFINED} is not included in the list. None of @var{elem1} to @var{elemN} can themselves be @code{SCM_UNDEFINED}, or @code{scm_list_n} will terminate at that point. @end deffn @c C Function scm_cons_star(arg1,rest) used to be documented here, @c but it's not really a useful interface, since it expects the @c caller to have already consed up all but the first argument @c already. @c @deffn {Scheme Procedure} cons* arg1 arg2 @dots{} Like @code{list}, but the last arg provides the tail of the constructed list, returning @code{(cons @var{arg1} (cons @var{arg2} (cons @dots{} @var{argn})))}. Requires at least one argument. If given one argument, that argument is returned as result. This function is called @code{list*} in some other Schemes and in Common LISP. @end deffn @deffn {Scheme Procedure} list-copy lst @deffnx {C Function} scm_list_copy (lst) Return a (newly-created) copy of @var{lst}. @end deffn @deffn {Scheme Procedure} make-list n [init] Create a list containing of @var{n} elements, where each element is initialized to @var{init}. @var{init} defaults to the empty list @code{()} if not given. @end deffn Note that @code{list-copy} only makes a copy of the pairs which make up the spine of the lists. The list elements are not copied, which means that modifying the elements of the new list also modifies the elements of the old list. On the other hand, applying procedures like @code{set-cdr!} or @code{delv!} to the new list will not alter the old list. If you also need to copy the list elements (making a deep copy), use the procedure @code{copy-tree} (@pxref{Copying}). @node List Selection @subsubsection List Selection These procedures are used to get some information about a list, or to retrieve one or more elements of a list. @rnindex length @deffn {Scheme Procedure} length lst @deffnx {C Function} scm_length (lst) Return the number of elements in list @var{lst}. @end deffn @deffn {Scheme Procedure} last-pair lst @deffnx {C Function} scm_last_pair (lst) Return the last pair in @var{lst}, signalling an error if @var{lst} is circular. @end deffn @rnindex list-ref @deffn {Scheme Procedure} list-ref list k @deffnx {C Function} scm_list_ref (list, k) Return the @var{k}th element from @var{list}. @end deffn @rnindex list-tail @deffn {Scheme Procedure} list-tail lst k @deffnx {Scheme Procedure} list-cdr-ref lst k @deffnx {C Function} scm_list_tail (lst, k) Return the "tail" of @var{lst} beginning with its @var{k}th element. The first element of the list is considered to be element 0. @code{list-tail} and @code{list-cdr-ref} are identical. It may help to think of @code{list-cdr-ref} as accessing the @var{k}th cdr of the list, or returning the results of cdring @var{k} times down @var{lst}. @end deffn @deffn {Scheme Procedure} list-head lst k @deffnx {C Function} scm_list_head (lst, k) Copy the first @var{k} elements from @var{lst} into a new list, and return it. @end deffn @node Append/Reverse @subsubsection Append and Reverse @code{append} and @code{append!} are used to concatenate two or more lists in order to form a new list. @code{reverse} and @code{reverse!} return lists with the same elements as their arguments, but in reverse order. The procedure variants with an @code{!} directly modify the pairs which form the list, whereas the other procedures create new pairs. This is why you should be careful when using the side-effecting variants. @rnindex append @deffn {Scheme Procedure} append lst1 @dots{} lstN @deffnx {Scheme Procedure} append! lst1 @dots{} lstN @deffnx {C Function} scm_append (lstlst) @deffnx {C Function} scm_append_x (lstlst) Return a list comprising all the elements of lists @var{lst1} to @var{lstN}. @lisp (append '(x) '(y)) @result{} (x y) (append '(a) '(b c d)) @result{} (a b c d) (append '(a (b)) '((c))) @result{} (a (b) (c)) @end lisp The last argument @var{lstN} may actually be any object; an improper list results if the last argument is not a proper list. @lisp (append '(a b) '(c . d)) @result{} (a b c . d) (append '() 'a) @result{} a @end lisp @code{append} doesn't modify the given lists, but the return may share structure with the final @var{lstN}. @code{append!} modifies the given lists to form its return. For @code{scm_append} and @code{scm_append_x}, @var{lstlst} is a list of the list operands @var{lst1} @dots{} @var{lstN}. That @var{lstlst} itself is not modified or used in the return. @end deffn @rnindex reverse @deffn {Scheme Procedure} reverse lst @deffnx {Scheme Procedure} reverse! lst [newtail] @deffnx {C Function} scm_reverse (lst) @deffnx {C Function} scm_reverse_x (lst, newtail) Return a list comprising the elements of @var{lst}, in reverse order. @code{reverse} constructs a new list, @code{reverse!} modifies @var{lst} in constructing its return. For @code{reverse!}, the optional @var{newtail} is appended to to the result. @var{newtail} isn't reversed, it simply becomes the list tail. For @code{scm_reverse_x}, the @var{newtail} parameter is mandatory, but can be @code{SCM_EOL} if no further tail is required. @end deffn @node List Modification @subsubsection List Modification The following procedures modify an existing list, either by changing elements of the list, or by changing the list structure itself. @deffn {Scheme Procedure} list-set! list k val @deffnx {C Function} scm_list_set_x (list, k, val) Set the @var{k}th element of @var{list} to @var{val}. @end deffn @deffn {Scheme Procedure} list-cdr-set! list k val @deffnx {C Function} scm_list_cdr_set_x (list, k, val) Set the @var{k}th cdr of @var{list} to @var{val}. @end deffn @deffn {Scheme Procedure} delq item lst @deffnx {C Function} scm_delq (item, lst) Return a newly-created copy of @var{lst} with elements @code{eq?} to @var{item} removed. This procedure mirrors @code{memq}: @code{delq} compares elements of @var{lst} against @var{item} with @code{eq?}. @end deffn @deffn {Scheme Procedure} delv item lst @deffnx {C Function} scm_delv (item, lst) Return a newly-created copy of @var{lst} with elements @code{eqv?} to @var{item} removed. This procedure mirrors @code{memv}: @code{delv} compares elements of @var{lst} against @var{item} with @code{eqv?}. @end deffn @deffn {Scheme Procedure} delete item lst @deffnx {C Function} scm_delete (item, lst) Return a newly-created copy of @var{lst} with elements @code{equal?} to @var{item} removed. This procedure mirrors @code{member}: @code{delete} compares elements of @var{lst} against @var{item} with @code{equal?}. @end deffn @deffn {Scheme Procedure} delq! item lst @deffnx {Scheme Procedure} delv! item lst @deffnx {Scheme Procedure} delete! item lst @deffnx {C Function} scm_delq_x (item, lst) @deffnx {C Function} scm_delv_x (item, lst) @deffnx {C Function} scm_delete_x (item, lst) These procedures are destructive versions of @code{delq}, @code{delv} and @code{delete}: they modify the pointers in the existing @var{lst} rather than creating a new list. Caveat evaluator: Like other destructive list functions, these functions cannot modify the binding of @var{lst}, and so cannot be used to delete the first element of @var{lst} destructively. @end deffn @deffn {Scheme Procedure} delq1! item lst @deffnx {C Function} scm_delq1_x (item, lst) Like @code{delq!}, but only deletes the first occurrence of @var{item} from @var{lst}. Tests for equality using @code{eq?}. See also @code{delv1!} and @code{delete1!}. @end deffn @deffn {Scheme Procedure} delv1! item lst @deffnx {C Function} scm_delv1_x (item, lst) Like @code{delv!}, but only deletes the first occurrence of @var{item} from @var{lst}. Tests for equality using @code{eqv?}. See also @code{delq1!} and @code{delete1!}. @end deffn @deffn {Scheme Procedure} delete1! item lst @deffnx {C Function} scm_delete1_x (item, lst) Like @code{delete!}, but only deletes the first occurrence of @var{item} from @var{lst}. Tests for equality using @code{equal?}. See also @code{delq1!} and @code{delv1!}. @end deffn @deffn {Scheme Procedure} filter pred lst @deffnx {Scheme Procedure} filter! pred lst Return a list containing all elements from @var{lst} which satisfy the predicate @var{pred}. The elements in the result list have the same order as in @var{lst}. The order in which @var{pred} is applied to the list elements is not specified. @code{filter!} is allowed, but not required to modify the structure of @end deffn @node List Searching @subsubsection List Searching The following procedures search lists for particular elements. They use different comparison predicates for comparing list elements with the object to be searched. When they fail, they return @code{#f}, otherwise they return the sublist whose car is equal to the search object, where equality depends on the equality predicate used. @rnindex memq @deffn {Scheme Procedure} memq x lst @deffnx {C Function} scm_memq (x, lst) Return the first sublist of @var{lst} whose car is @code{eq?} to @var{x} where the sublists of @var{lst} are the non-empty lists returned by @code{(list-tail @var{lst} @var{k})} for @var{k} less than the length of @var{lst}. If @var{x} does not occur in @var{lst}, then @code{#f} (not the empty list) is returned. @end deffn @rnindex memv @deffn {Scheme Procedure} memv x lst @deffnx {C Function} scm_memv (x, lst) Return the first sublist of @var{lst} whose car is @code{eqv?} to @var{x} where the sublists of @var{lst} are the non-empty lists returned by @code{(list-tail @var{lst} @var{k})} for @var{k} less than the length of @var{lst}. If @var{x} does not occur in @var{lst}, then @code{#f} (not the empty list) is returned. @end deffn @rnindex member @deffn {Scheme Procedure} member x lst @deffnx {C Function} scm_member (x, lst) Return the first sublist of @var{lst} whose car is @code{equal?} to @var{x} where the sublists of @var{lst} are the non-empty lists returned by @code{(list-tail @var{lst} @var{k})} for @var{k} less than the length of @var{lst}. If @var{x} does not occur in @var{lst}, then @code{#f} (not the empty list) is returned. @end deffn @node List Mapping @subsubsection List Mapping List processing is very convenient in Scheme because the process of iterating over the elements of a list can be highly abstracted. The procedures in this section are the most basic iterating procedures for lists. They take a procedure and one or more lists as arguments, and apply the procedure to each element of the list. They differ in their return value. @rnindex map @c begin (texi-doc-string "guile" "map") @deffn {Scheme Procedure} map proc arg1 arg2 @dots{} @deffnx {Scheme Procedure} map-in-order proc arg1 arg2 @dots{} @deffnx {C Function} scm_map (proc, arg1, args) Apply @var{proc} to each element of the list @var{arg1} (if only two arguments are given), or to the corresponding elements of the argument lists (if more than two arguments are given). The result(s) of the procedure applications are saved and returned in a list. For @code{map}, the order of procedure applications is not specified, @code{map-in-order} applies the procedure from left to right to the list elements. @end deffn @rnindex for-each @c begin (texi-doc-string "guile" "for-each") @deffn {Scheme Procedure} for-each proc arg1 arg2 @dots{} Like @code{map}, but the procedure is always applied from left to right, and the result(s) of the procedure applications are thrown away. The return value is not specified. @end deffn @node Vectors @subsection Vectors @tpindex Vectors Vectors are sequences of Scheme objects. Unlike lists, the length of a vector, once the vector is created, cannot be changed. The advantage of vectors over lists is that the time required to access one element of a vector given its @dfn{position} (synonymous with @dfn{index}), a zero-origin number, is constant, whereas lists have an access time linear to the position of the accessed element in the list. Vectors can contain any kind of Scheme object; it is even possible to have different types of objects in the same vector. For vectors containing vectors, you may wish to use arrays, instead. Note, too, that vectors are the special case of one dimensional non-uniform arrays and that most array procedures operate happily on vectors (@pxref{Arrays}). @menu * Vector Syntax:: Read syntax for vectors. * Vector Creation:: Dynamic vector creation and validation. * Vector Accessors:: Accessing and modifying vector contents. * Vector Accessing from C:: Ways to work with vectors from C. @end menu @node Vector Syntax @subsubsection Read Syntax for Vectors Vectors can literally be entered in source code, just like strings, characters or some of the other data types. The read syntax for vectors is as follows: A sharp sign (@code{#}), followed by an opening parentheses, all elements of the vector in their respective read syntax, and finally a closing parentheses. The following are examples of the read syntax for vectors; where the first vector only contains numbers and the second three different object types: a string, a symbol and a number in hexadecimal notation. @lisp #(1 2 3) #("Hello" foo #xdeadbeef) @end lisp Like lists, vectors have to be quoted: @lisp '#(a b c) @result{} #(a b c) @end lisp @node Vector Creation @subsubsection Dynamic Vector Creation and Validation Instead of creating a vector implicitly by using the read syntax just described, you can create a vector dynamically by calling one of the @code{vector} and @code{list->vector} primitives with the list of Scheme values that you want to place into a vector. The size of the vector thus created is determined implicitly by the number of arguments given. @rnindex vector @rnindex list->vector @deffn {Scheme Procedure} vector . l @deffnx {Scheme Procedure} list->vector l @deffnx {C Function} scm_vector (l) Return a newly allocated vector composed of the given arguments. Analogous to @code{list}. @lisp (vector 'a 'b 'c) @result{} #(a b c) @end lisp @end deffn The inverse operation is @code{vector->list}: @rnindex vector->list @deffn {Scheme Procedure} vector->list v @deffnx {C Function} scm_vector_to_list (v) Return a newly allocated list composed of the elements of @var{v}. @lisp (vector->list '#(dah dah didah)) @result{} (dah dah didah) (list->vector '(dididit dah)) @result{} #(dididit dah) @end lisp @end deffn To allocate a vector with an explicitly specified size, use @code{make-vector}. With this primitive you can also specify an initial value for the vector elements (the same value for all elements, that is): @rnindex make-vector @deffn {Scheme Procedure} make-vector len [fill] @deffnx {C Function} scm_make_vector (len, fill) Return a newly allocated vector of @var{len} elements. If a second argument is given, then each position is initialized to @var{fill}. Otherwise the initial contents of each position is unspecified. @end deffn @deftypefn {C Function} SCM scm_c_make_vector (size_t k, SCM fill) Like @code{scm_make_vector}, but the length is given as a @code{size_t}. @end deftypefn To check whether an arbitrary Scheme value @emph{is} a vector, use the @code{vector?} primitive: @rnindex vector? @deffn {Scheme Procedure} vector? obj @deffnx {C Function} scm_vector_p (obj) Return @code{#t} if @var{obj} is a vector, otherwise return @code{#f}. @end deffn @deftypefn {C Function} int scm_is_vector (SCM obj) Return non-zero when @var{obj} is a vector, otherwise return @code{zero}. @end deftypefn @node Vector Accessors @subsubsection Accessing and Modifying Vector Contents @code{vector-length} and @code{vector-ref} return information about a given vector, respectively its size and the elements that are contained in the vector. @rnindex vector-length @deffn {Scheme Procedure} vector-length vector @deffnx {C Function} scm_vector_length vector Return the number of elements in @var{vector} as an exact integer. @end deffn @deftypefn {C Function} size_t scm_c_vector_length (SCM v) Return the number of elements in @var{vector} as a @code{size_t}. @end deftypefn @rnindex vector-ref @deffn {Scheme Procedure} vector-ref vector k @deffnx {C Function} scm_vector_ref vector k Return the contents of position @var{k} of @var{vector}. @var{k} must be a valid index of @var{vector}. @lisp (vector-ref '#(1 1 2 3 5 8 13 21) 5) @result{} 8 (vector-ref '#(1 1 2 3 5 8 13 21) (let ((i (round (* 2 (acos -1))))) (if (inexact? i) (inexact->exact i) i))) @result{} 13 @end lisp @end deffn @deftypefn {C Function} SCM scm_c_vector_ref (SCM v, size_t k) Return the contents of position @var{k} (a @code{size_t}) of @var{vector}. @end deftypefn A vector created by one of the dynamic vector constructor procedures (@pxref{Vector Creation}) can be modified using the following procedures. @emph{NOTE:} According to R5RS, it is an error to use any of these procedures on a literally read vector, because such vectors should be considered as constants. Currently, however, Guile does not detect this error. @rnindex vector-set! @deffn {Scheme Procedure} vector-set! vector k obj @deffnx {C Function} scm_vector_set_x vector k obj Store @var{obj} in position @var{k} of @var{vector}. @var{k} must be a valid index of @var{vector}. The value returned by @samp{vector-set!} is unspecified. @lisp (let ((vec (vector 0 '(2 2 2 2) "Anna"))) (vector-set! vec 1 '("Sue" "Sue")) vec) @result{} #(0 ("Sue" "Sue") "Anna") @end lisp @end deffn @deftypefn {C Function} void scm_c_vector_set_x (SCM v, size_t k, SCM obj) Store @var{obj} in position @var{k} (a @code{size_t}) of @var{v}. @end deftypefn @rnindex vector-fill! @deffn {Scheme Procedure} vector-fill! v fill @deffnx {C Function} scm_vector_fill_x (v, fill) Store @var{fill} in every position of @var{vector}. The value returned by @code{vector-fill!} is unspecified. @end deffn @deffn {Scheme Procedure} vector-move-left! vec1 start1 end1 vec2 start2 @deffnx {C Function} scm_vector_move_left_x (vec1, start1, end1, vec2, start2) Copy elements from @var{vec1}, positions @var{start1} to @var{end1}, to @var{vec2} starting at position @var{start2}. @var{start1} and @var{start2} are inclusive indices; @var{end1} is exclusive. @code{vector-move-left!} copies elements in leftmost order. Therefore, in the case where @var{vec1} and @var{vec2} refer to the same vector, @code{vector-move-left!} is usually appropriate when @var{start1} is greater than @var{start2}. @end deffn @deffn {Scheme Procedure} vector-move-right! vec1 start1 end1 vec2 start2 @deffnx {C Function} scm_vector_move_right_x (vec1, start1, end1, vec2, start2) Copy elements from @var{vec1}, positions @var{start1} to @var{end1}, to @var{vec2} starting at position @var{start2}. @var{start1} and @var{start2} are inclusive indices; @var{end1} is exclusive. @code{vector-move-right!} copies elements in rightmost order. Therefore, in the case where @var{vec1} and @var{vec2} refer to the same vector, @code{vector-move-right!} is usually appropriate when @var{start1} is less than @var{start2}. @end deffn @node Vector Accessing from C @subsubsection Vector Accessing from C A vector can be read and modified from C with the functions @code{scm_c_vector_ref} and @code{scm_c_vector_set_x}, for example. In addition to these functions, there are two more ways to access vectors from C that might be more efficient in certain situations: you can restrict yourself to @dfn{simple vectors} and then use the very fast @emph{simple vector macros}; or you can use the very general framework for accessing all kinds of arrays (@pxref{Accessing Arrays from C}), which is more verbose, but can deal efficiently with all kinds of vectors (and arrays). For vectors, you can use the @code{scm_vector_elements} and @code{scm_vector_writable_elements} functions as shortcuts. @deftypefn {C Function} int scm_is_simple_vector (SCM obj) Return non-zero if @var{obj} is a simple vector, else return zero. A simple vector is a vector that can be used with the @code{SCM_SIMPLE_*} macros below. The following functions are guaranteed to return simple vectors: @code{scm_make_vector}, @code{scm_c_make_vector}, @code{scm_vector}, @code{scm_list_to_vector}. @end deftypefn @deftypefn {C Macro} size_t SCM_SIMPLE_VECTOR_LENGTH (SCM vec) Evaluates to the length of the simple vector @var{vec}. No type checking is done. @end deftypefn @deftypefn {C Macro} SCM SCM_SIMPLE_VECTOR_REF (SCM vec, size_t idx) Evaluates to the element at position @var{idx} in the simple vector @var{vec}. No type or range checking is done. @end deftypefn @deftypefn {C Macro} void SCM_SIMPLE_VECTOR_SET_X (SCM vec, size_t idx, SCM val) Sets the element at position @var{idx} in the simple vector @var{vec} to @var{val}. No type or range checking is done. @end deftypefn @deftypefn {C Function} {const SCM *} scm_vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) Acquire a handle for the vector @var{vec} and return a pointer to the elements of it. This pointer can only be used to read the elements of @var{vec}. When @var{vec} is not a vector, an error is signaled. The handle mustr eventually be released with @code{scm_array_handle_release}. The variables pointed to by @var{lenp} and @var{incp} are filled with the number of elements of the vector and the increment between elements, respectively. Note that the increment can well be negative. The following example shows the typical way to use this function. It creates a list of all elements of @code{vec} (in reverse order). @example scm_t_array_handle handle; size_t i, len; ssize_t inc; const SCM *elt; SCM list; elt = scm_vector_elements (vec, &handle, &len, &inc); list = SCM_EOL; for (i = 0; i < len; i++, elt += inc) list = scm_cons (*elt, list); scm_array_handle_release (&handle); @end example @end deftypefn @deftypefn {C Function} {SCM *} scm_vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) Like @code{scm_vector_elements} but the pointer can be used to modify the vector. The following example shows the typical way to use this function. It fills a vector with @code{#t}. @example scm_t_array_handle handle; size_t i, len; ssize_t inc; SCM *elt; elt = scm_vector_elements (vec, &handle, &len, &inc); for (i = 0; i < len; i++, elt += inc) *elt = SCM_BOOL_T; scm_array_handle_release (&handle); @end example @end deftypefn @node Uniform Numeric Vectors @subsection Uniform Numeric Vectors A uniform numeric vector is a vector whose elements are all of a single numeric type. Guile offers uniform numeric vectors for signed and unsigned 8-bit, 16-bit, 32-bit, and 64-bit integers, two sizes of floating point values, and complex floating-point numbers of these two sizes. Strings could be regarded as uniform vectors of characters, @xref{Strings}. Likewise, bit vectors could be regarded as uniform vectors of bits, @xref{Bit Vectors}. Both are sufficiently different from uniform numeric vectors that the procedures described here do not apply to these two data types. However, both strings and bit vectors are generalized vectors, @xref{Generalized Vectors}, and arrays, @xref{Arrays}. Uniform numeric vectors are the special case of one dimensional uniform numeric arrays. Uniform numeric vectors can be useful since they consume less memory than the non-uniform, general vectors. Also, since the types they can store correspond directly to C types, it is easier to work with them efficiently on a low level. Consider image processing as an example, where you want to apply a filter to some image. While you could store the pixels of an image in a general vector and write a general convolution function, things are much more efficient with uniform vectors: the convolution function knows that all pixels are unsigned 8-bit values (say), and can use a very tight inner loop. That is, when it is written in C. Functions for efficiently working with uniform numeric vectors from C are listed at the end of this section. Procedures similar to the vector procedures (@pxref{Vectors}) are provided for handling these uniform vectors, but they are distinct datatypes and the two cannot be inter-mixed. If you want to work primarily with uniform numeric vectors, but want to offer support for general vectors as a convenience, you can use one of the @code{scm_any_to_*} functions. They will coerce lists and vectors to the given type of uniform vector. Alternatively, you can write two versions of your code: one that is fast and works only with uniform numeric vectors, and one that works with any kind of vector but is slower. One set of the procedures listed below is a generic one: it works with all types of uniform numeric vectors. In addition to that, there is a set of procedures for each type that only works with that type. Unless you really need to the generality of the first set, it is best to use the more specific functions. They might not be that much faster, but their use can serve as a kind of declaration and makes it easier to optimize later on. The generic set of procedures uses @code{uniform} in its names, the specific ones use the tag from the following table. @table @nicode @item u8 unsigned 8-bit integers @item s8 signed 8-bit integers @item u16 unsigned 16-bit integers @item s16 signed 16-bit integers @item u32 unsigned 32-bit integers @item s32 signed 32-bit integers @item u64 unsigned 64-bit integers @item s64 signed 64-bit integers @item f32 the C type @code{float} @item f64 the C type @code{double} @item c32 complex numbers in rectangular form with the real and imaginary part being a @code{float} @item c64 complex numbers in rectangular form with the real and imaginary part being a @code{double} @end table The external representation (ie.@: read syntax) for these vectors is similar to normal Scheme vectors, but with an additional tag from the tabel above indiciating the vector's type. For example, @lisp #u16(1 2 3) #f64(3.1415 2.71) @end lisp Note that the read syntax for floating-point here conflicts with @code{#f} for false. In Standard Scheme one can write @code{(1 #f3)} for a three element list @code{(1 #f 3)}, but for Guile @code{(1 #f3)} is invalid. @code{(1 #f 3)} is almost certainly what one should write anyway to make the intention clear, so this is rarely a problem. @deffn {Scheme Procedure} uniform-vector? obj @deffnx {Scheme Procedure} u8vector? obj @deffnx {Scheme Procedure} s8vector? obj @deffnx {Scheme Procedure} u16vector? obj @deffnx {Scheme Procedure} s16vector? obj @deffnx {Scheme Procedure} u32vector? obj @deffnx {Scheme Procedure} s32vector? obj @deffnx {Scheme Procedure} u64vector? obj @deffnx {Scheme Procedure} s64vector? obj @deffnx {Scheme Procedure} f32vector? obj @deffnx {Scheme Procedure} f64vector? obj @deffnx {Scheme Procedure} c32vector? obj @deffnx {Scheme Procedure} c64vector? obj @deffnx {C Function} scm_uniform_vector_p obj @deffnx {C Function} scm_u8vector_p obj @deffnx {C Function} scm_s8vector_p obj @deffnx {C Function} scm_u16vector_p obj @deffnx {C Function} scm_s16vector_p obj @deffnx {C Function} scm_u32vector_p obj @deffnx {C Function} scm_s32vector_p obj @deffnx {C Function} scm_u64vector_p obj @deffnx {C Function} scm_s64vector_p obj @deffnx {C Function} scm_f32vector_p obj @deffnx {C Function} scm_f64vector_p obj @deffnx {C Function} scm_c32vector_p obj @deffnx {C Function} scm_c64vector_p obj Return @code{#t} if @var{obj} is a homogeneous numeric vector of the indicated type. @end deffn @deffn {Scheme Procedure} make-u8vector n [value] @deffnx {Scheme Procedure} make-s8vector n [value] @deffnx {Scheme Procedure} make-u16vector n [value] @deffnx {Scheme Procedure} make-s16vector n [value] @deffnx {Scheme Procedure} make-u32vector n [value] @deffnx {Scheme Procedure} make-s32vector n [value] @deffnx {Scheme Procedure} make-u64vector n [value] @deffnx {Scheme Procedure} make-s64vector n [value] @deffnx {Scheme Procedure} make-f32vector n [value] @deffnx {Scheme Procedure} make-f64vector n [value] @deffnx {Scheme Procedure} make-c32vector n [value] @deffnx {Scheme Procedure} make-c64vector n [value] @deffnx {C Function} scm_make_u8vector n [value] @deffnx {C Function} scm_make_s8vector n [value] @deffnx {C Function} scm_make_u16vector n [value] @deffnx {C Function} scm_make_s16vector n [value] @deffnx {C Function} scm_make_u32vector n [value] @deffnx {C Function} scm_make_s32vector n [value] @deffnx {C Function} scm_make_u64vector n [value] @deffnx {C Function} scm_make_s64vector n [value] @deffnx {C Function} scm_make_f32vector n [value] @deffnx {C Function} scm_make_f64vector n [value] @deffnx {C Function} scm_make_c32vector n [value] @deffnx {C Function} scm_make_c64vector n [value] Return a newly allocated homogeneous numeric vector holding @var{n} elements of the indicated type. If @var{value} is given, the vector is initialized with that value, otherwise the contents are unspecified. @end deffn @deffn {Scheme Procedure} u8vector value @dots{} @deffnx {Scheme Procedure} s8vector value @dots{} @deffnx {Scheme Procedure} u16vector value @dots{} @deffnx {Scheme Procedure} s16vector value @dots{} @deffnx {Scheme Procedure} u32vector value @dots{} @deffnx {Scheme Procedure} s32vector value @dots{} @deffnx {Scheme Procedure} u64vector value @dots{} @deffnx {Scheme Procedure} s64vector value @dots{} @deffnx {Scheme Procedure} f32vector value @dots{} @deffnx {Scheme Procedure} f64vector value @dots{} @deffnx {Scheme Procedure} c32vector value @dots{} @deffnx {Scheme Procedure} c64vector value @dots{} @deffnx {C Function} scm_u8vector values @deffnx {C Function} scm_s8vector values @deffnx {C Function} scm_u16vector values @deffnx {C Function} scm_s16vector values @deffnx {C Function} scm_u32vector values @deffnx {C Function} scm_s32vector values @deffnx {C Function} scm_u64vector values @deffnx {C Function} scm_s64vector values @deffnx {C Function} scm_f32vector values @deffnx {C Function} scm_f64vector values @deffnx {C Function} scm_c32vector values @deffnx {C Function} scm_c64vector values Return a newly allocated homogeneous numeric vector of the indicated type, holding the given parameter @var{value}s. The vector length is the number of parameters given. @end deffn @deffn {Scheme Procedure} uniform-vector-length vec @deffnx {Scheme Procedure} u8vector-length vec @deffnx {Scheme Procedure} s8vector-length vec @deffnx {Scheme Procedure} u16vector-length vec @deffnx {Scheme Procedure} s16vector-length vec @deffnx {Scheme Procedure} u32vector-length vec @deffnx {Scheme Procedure} s32vector-length vec @deffnx {Scheme Procedure} u64vector-length vec @deffnx {Scheme Procedure} s64vector-length vec @deffnx {Scheme Procedure} f32vector-length vec @deffnx {Scheme Procedure} f64vector-length vec @deffnx {Scheme Procedure} c32vector-length vec @deffnx {Scheme Procedure} c64vector-length vec @deffnx {C Function} scm_uniform_vector_length vec @deffnx {C Function} scm_u8vector_length vec @deffnx {C Function} scm_s8vector_length vec @deffnx {C Function} scm_u16vector_length vec @deffnx {C Function} scm_s16vector_length vec @deffnx {C Function} scm_u32vector_length vec @deffnx {C Function} scm_s32vector_length vec @deffnx {C Function} scm_u64vector_length vec @deffnx {C Function} scm_s64vector_length vec @deffnx {C Function} scm_f32vector_length vec @deffnx {C Function} scm_f64vector_length vec @deffnx {C Function} scm_c32vector_length vec @deffnx {C Function} scm_c64vector_length vec Return the number of elements in @var{vec}. @end deffn @deffn {Scheme Procedure} uniform-vector-ref vec i @deffnx {Scheme Procedure} u8vector-ref vec i @deffnx {Scheme Procedure} s8vector-ref vec i @deffnx {Scheme Procedure} u16vector-ref vec i @deffnx {Scheme Procedure} s16vector-ref vec i @deffnx {Scheme Procedure} u32vector-ref vec i @deffnx {Scheme Procedure} s32vector-ref vec i @deffnx {Scheme Procedure} u64vector-ref vec i @deffnx {Scheme Procedure} s64vector-ref vec i @deffnx {Scheme Procedure} f32vector-ref vec i @deffnx {Scheme Procedure} f64vector-ref vec i @deffnx {Scheme Procedure} c32vector-ref vec i @deffnx {Scheme Procedure} c64vector-ref vec i @deffnx {C Function} scm_uniform_vector_ref vec i @deffnx {C Function} scm_u8vector_ref vec i @deffnx {C Function} scm_s8vector_ref vec i @deffnx {C Function} scm_u16vector_ref vec i @deffnx {C Function} scm_s16vector_ref vec i @deffnx {C Function} scm_u32vector_ref vec i @deffnx {C Function} scm_s32vector_ref vec i @deffnx {C Function} scm_u64vector_ref vec i @deffnx {C Function} scm_s64vector_ref vec i @deffnx {C Function} scm_f32vector_ref vec i @deffnx {C Function} scm_f64vector_ref vec i @deffnx {C Function} scm_c32vector_ref vec i @deffnx {C Function} scm_c64vector_ref vec i Return the element at index @var{i} in @var{vec}. The first element in @var{vec} is index 0. @end deffn @deffn {Scheme Procedure} uniform-vector-set! vec i value @deffnx {Scheme Procedure} u8vector-set! vec i value @deffnx {Scheme Procedure} s8vector-set! vec i value @deffnx {Scheme Procedure} u16vector-set! vec i value @deffnx {Scheme Procedure} s16vector-set! vec i value @deffnx {Scheme Procedure} u32vector-set! vec i value @deffnx {Scheme Procedure} s32vector-set! vec i value @deffnx {Scheme Procedure} u64vector-set! vec i value @deffnx {Scheme Procedure} s64vector-set! vec i value @deffnx {Scheme Procedure} f32vector-set! vec i value @deffnx {Scheme Procedure} f64vector-set! vec i value @deffnx {Scheme Procedure} c32vector-set! vec i value @deffnx {Scheme Procedure} c64vector-set! vec i value @deffnx {C Function} scm_uniform_vector_set_x vec i value @deffnx {C Function} scm_u8vector_set_x vec i value @deffnx {C Function} scm_s8vector_set_x vec i value @deffnx {C Function} scm_u16vector_set_x vec i value @deffnx {C Function} scm_s16vector_set_x vec i value @deffnx {C Function} scm_u32vector_set_x vec i value @deffnx {C Function} scm_s32vector_set_x vec i value @deffnx {C Function} scm_u64vector_set_x vec i value @deffnx {C Function} scm_s64vector_set_x vec i value @deffnx {C Function} scm_f32vector_set_x vec i value @deffnx {C Function} scm_f64vector_set_x vec i value @deffnx {C Function} scm_c32vector_set_x vec i value @deffnx {C Function} scm_c64vector_set_x vec i value Set the element at index @var{i} in @var{vec} to @var{value}. The first element in @var{vec} is index 0. The return value is unspecified. @end deffn @deffn {Scheme Procedure} uniform-vector->list vec @deffnx {Scheme Procedure} u8vector->list vec @deffnx {Scheme Procedure} s8vector->list vec @deffnx {Scheme Procedure} u16vector->list vec @deffnx {Scheme Procedure} s16vector->list vec @deffnx {Scheme Procedure} u32vector->list vec @deffnx {Scheme Procedure} s32vector->list vec @deffnx {Scheme Procedure} u64vector->list vec @deffnx {Scheme Procedure} s64vector->list vec @deffnx {Scheme Procedure} f32vector->list vec @deffnx {Scheme Procedure} f64vector->list vec @deffnx {Scheme Procedure} c32vector->list vec @deffnx {Scheme Procedure} c64vector->list vec @deffnx {C Function} scm_uniform_vector_to_list vec @deffnx {C Function} scm_u8vector_to_list vec @deffnx {C Function} scm_s8vector_to_list vec @deffnx {C Function} scm_u16vector_to_list vec @deffnx {C Function} scm_s16vector_to_list vec @deffnx {C Function} scm_u32vector_to_list vec @deffnx {C Function} scm_s32vector_to_list vec @deffnx {C Function} scm_u64vector_to_list vec @deffnx {C Function} scm_s64vector_to_list vec @deffnx {C Function} scm_f32vector_to_list vec @deffnx {C Function} scm_f64vector_to_list vec @deffnx {C Function} scm_c32vector_to_list vec @deffnx {C Function} scm_c64vector_to_list vec Return a newly allocated list holding all elements of @var{vec}. @end deffn @deffn {Scheme Procedure} list->u8vector lst @deffnx {Scheme Procedure} list->s8vector lst @deffnx {Scheme Procedure} list->u16vector lst @deffnx {Scheme Procedure} list->s16vector lst @deffnx {Scheme Procedure} list->u32vector lst @deffnx {Scheme Procedure} list->s32vector lst @deffnx {Scheme Procedure} list->u64vector lst @deffnx {Scheme Procedure} list->s64vector lst @deffnx {Scheme Procedure} list->f32vector lst @deffnx {Scheme Procedure} list->f64vector lst @deffnx {Scheme Procedure} list->c32vector lst @deffnx {Scheme Procedure} list->c64vector lst @deffnx {C Function} scm_list_to_u8vector lst @deffnx {C Function} scm_list_to_s8vector lst @deffnx {C Function} scm_list_to_u16vector lst @deffnx {C Function} scm_list_to_s16vector lst @deffnx {C Function} scm_list_to_u32vector lst @deffnx {C Function} scm_list_to_s32vector lst @deffnx {C Function} scm_list_to_u64vector lst @deffnx {C Function} scm_list_to_s64vector lst @deffnx {C Function} scm_list_to_f32vector lst @deffnx {C Function} scm_list_to_f64vector lst @deffnx {C Function} scm_list_to_c32vector lst @deffnx {C Function} scm_list_to_c64vector lst Return a newly allocated homogeneous numeric vector of the indicated type, initialized with the elements of the list @var{lst}. @end deffn @deffn {Scheme Procedure} any->u8vector obj @deffnx {Scheme Procedure} any->s8vector obj @deffnx {Scheme Procedure} any->u16vector obj @deffnx {Scheme Procedure} any->s16vector obj @deffnx {Scheme Procedure} any->u32vector obj @deffnx {Scheme Procedure} any->s32vector obj @deffnx {Scheme Procedure} any->u64vector obj @deffnx {Scheme Procedure} any->s64vector obj @deffnx {Scheme Procedure} any->f32vector obj @deffnx {Scheme Procedure} any->f64vector obj @deffnx {Scheme Procedure} any->c32vector obj @deffnx {Scheme Procedure} any->c64vector obj @deffnx {C Function} scm_any_to_u8vector obj @deffnx {C Function} scm_any_to_s8vector obj @deffnx {C Function} scm_any_to_u16vector obj @deffnx {C Function} scm_any_to_s16vector obj @deffnx {C Function} scm_any_to_u32vector obj @deffnx {C Function} scm_any_to_s32vector obj @deffnx {C Function} scm_any_to_u64vector obj @deffnx {C Function} scm_any_to_s64vector obj @deffnx {C Function} scm_any_to_f32vector obj @deffnx {C Function} scm_any_to_f64vector obj @deffnx {C Function} scm_any_to_c32vector obj @deffnx {C Function} scm_any_to_c64vector obj Return a (maybe newly allocated) uniform numeric vector of the indicated type, initialized with the elements of @var{obj}, which must be a list, a vector, or a uniform vector. When @var{obj} is already a suitable uniform numeric vector, it is returned unchanged. @end deffn @deftypefn {C Function} int scm_is_uniform_vector (SCM uvec) Return non-zero when @var{uvec} is a uniform numeric vector, zero otherwise. @end deftypefn @deftypefn {C Function} SCM scm_take_u8vector (const scm_t_uint8 *data, size_t len) @deftypefnx {C Function} SCM scm_take_s8vector (const scm_t_int8 *data, size_t len) @deftypefnx {C Function} SCM scm_take_u16vector (const scm_t_uint16 *data, size_t len) @deftypefnx {C Function} SCM scm_take_s168vector (const scm_t_int16 *data, size_t len) @deftypefnx {C Function} SCM scm_take_u32vector (const scm_t_uint32 *data, size_t len) @deftypefnx {C Function} SCM scm_take_s328vector (const scm_t_int32 *data, size_t len) @deftypefnx {C Function} SCM scm_take_u64vector (const scm_t_uint64 *data, size_t len) @deftypefnx {C Function} SCM scm_take_s64vector (const scm_t_int64 *data, size_t len) @deftypefnx {C Function} SCM scm_take_f32vector (const float *data, size_t len) @deftypefnx {C Function} SCM scm_take_f64vector (const double *data, size_t len) @deftypefnx {C Function} SCM scm_take_c32vector (const float *data, size_t len) @deftypefnx {C Function} SCM scm_take_c64vector (const double *data, size_t len) Return a new uniform numeric vector of the indicated type and length that uses the memory pointed to by @var{data} to store its elements. This memory will eventually be freed with @code{free}. The argument @var{len} specifies the number of elements in @var{data}, not its size in bytes. The @code{c32} and @code{c64} variants take a pointer to a C array of @code{float}s or @code{double}s. The real parts of the complex numbers are at even indices in that array, the corresponding imaginary parts are at the following odd index. @end deftypefn @deftypefn {C Function} size_t scm_c_uniform_vector_length (SCM uvec) Return the number of elements of @var{uvec} as a @code{size_t}. @end deftypefn @deftypefn {C Function} {const void *} scm_uniform_vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_uint8 *} scm_u8vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_int8 *} scm_s8vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_uint16 *} scm_u16vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_int16 *} scm_s16vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_uint32 *} scm_u32vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_int32 *} scm_s32vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_uint64 *} scm_u64vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const scm_t_int64 *} scm_s64vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const float *} scm_f23vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const double *} scm_f64vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const float *} scm_c32vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {const double *} scm_c64vector_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) Like @code{scm_vector_elements} (which see), but returns a pointer to the elements of a uniform numeric vector of the indicated kind. @end deftypefn @deftypefn {C Function} {void *} scm_uniform_vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_uint8 *} scm_u8vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_int8 *} scm_s8vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_uint16 *} scm_u16vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_int16 *} scm_s16vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_uint32 *} scm_u32vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_int32 *} scm_s32vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_uint64 *} scm_u64vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {scm_t_int64 *} scm_s64vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {float *} scm_f23vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {double *} scm_f64vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {float *} scm_c32vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) @deftypefnx {C Function} {double *} scm_c64vector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *lenp, ssize_t *incp) Like @code{scm_vector_writable_elements} (which see), but returns a pointer to the elements of a uniform numeric vector of the indicated kind. @end deftypefn @node Bit Vectors @subsection Bit Vectors @noindent Bit vectors are zero-origin, one-dimensional arrays of booleans. They are displayed as a sequence of @code{0}s and @code{1}s prefixed by @code{#*}, e.g., @example (make-bitvector 8 #f) @result{} #*00000000 @end example Bit vectors are are also generalized vectors, @xref{Generalized Vectors}, and can thus be used with the array procedures, @xref{Arrays}. Bit vectors are the special case of one dimensional bit arrays. @deffn {Scheme Procedure} bitvector? obj @deffnx {C Function} scm_bitvector_p (obj) Return @code{#t} when @var{obj} is a bitvector, else return @code{#f}. @end deffn @deftypefn {C Function} int scm_is_bitvector (SCM obj) Return @code{1} when @var{obj} is a bitvector, else return @code{0}. @end deftypefn @deffn {Scheme Procedure} make-bitvector len [fill] @deffnx {C Function} scm_make_bitvector (len, fill) Create a new bitvector of length @var{len} and optionally initialize all elements to @var{fill}. @end deffn @deftypefn {C Function} SCM scm_c_make_bitvector (size_t len, SCM fill) Like @code{scm_make_bitvector}, but the length is given as a @code{size_t}. @end deftypefn @deffn {Scheme Procedure} bitvector . bits @deffnx {C Function} scm_bitvector (bits) Create a new bitvector with the arguments as elements. @end deffn @deffn {Scheme Procedure} bitvector-length vec @deffnx {C Function} scm_bitvector_length (vec) Return the length of the bitvector @var{vec}. @end deffn @deftypefn {C Function} size_t scm_c_bitvector_length (SCM vec) Like @code{scm_bitvector_length}, but the length is returned as a @code{size_t}. @end deftypefn @deffn {Scheme Procedure} bitvector-ref vec idx @deffnx {C Function} scm_bitvector_ref (vec, idx) Return the element at index @var{idx} of the bitvector @var{vec}. @end deffn @deftypefn {C Function} SCM scm_c_bitvector_ref (SCM obj, size_t idx) Return the element at index @var{idx} of the bitvector @var{vec}. @end deftypefn @deffn {Scheme Procedure} bitvector-set! vec idx val @deffnx {C Function} scm_bitvector_set_x (vec, idx, val) Set the element at index @var{idx} of the bitvector @var{vec} when @var{val} is true, else clear it. @end deffn @deftypefn {C Function} SCM scm_c_bitvector_set_x (SCM obj, size_t idx, SCM val) Set the element at index @var{idx} of the bitvector @var{vec} when @var{val} is true, else clear it. @end deftypefn @deffn {Scheme Procedure} bitvector-fill! vec val @deffnx {C Function} scm_bitvector_fill_x (vec, val) Set all elements of the bitvector @var{vec} when @var{val} is true, else clear them. @end deffn @deffn {Scheme Procedure} list->bitvector list @deffnx {C Function} scm_list_to_bitvector (list) Return a new bitvector initialized with the elements of @var{list}. @end deffn @deffn {Scheme Procedure} bitvector->list vec @deffnx {C Function} scm_bitvector_to_list (vec) Return a new list initialized with the elements of the bitvector @var{vec}. @end deffn @deffn {Scheme Procedure} bit-count bool bitvector @deffnx {C Function} scm_bit_count (bool, bitvector) Return a count of how many entries in @var{bitvector} are equal to @var{bool}. For example, @example (bit-count #f #*000111000) @result{} 6 @end example @end deffn @deffn {Scheme Procedure} bit-position bool bitvector start @deffnx {C Function} scm_bit_position (bool, bitvector, start) Return the index of the first occurrance of @var{bool} in @var{bitvector}, starting from @var{start}. If there is no @var{bool} entry between @var{start} and the end of @var{bitvector}, then return @code{#f}. For example, @example (bit-position #t #*000101 0) @result{} 3 (bit-position #f #*0001111 3) @result{} #f @end example @end deffn @deffn {Scheme Procedure} bit-invert! bitvector @deffnx {C Function} scm_bit_invert_x (bitvector) Modify @var{bitvector} by replacing each element with its negation. @end deffn @deffn {Scheme Procedure} bit-set*! bitvector uvec bool @deffnx {C Function} scm_bit_set_star_x (bitvector, uvec, bool) Set entries of @var{bitvector} to @var{bool}, with @var{uvec} selecting the entries to change. The return value is unspecified. If @var{uvec} is a bit vector, then those entries where it has @code{#t} are the ones in @var{bitvector} which are set to @var{bool}. @var{uvec} and @var{bitvector} must be the same length. When @var{bool} is @code{#t} it's like @var{uvec} is OR'ed into @var{bitvector}. Or when @var{bool} is @code{#f} it can be seen as an ANDNOT. @example (define bv #*01000010) (bit-set*! bv #*10010001 #t) bv @result{} #*11010011 @end example If @var{uvec} is a uniform vector of unsigned long integers, then they're indexes into @var{bitvector} which are set to @var{bool}. @example (define bv #*01000010) (bit-set*! bv #u(5 2 7) #t) bv @result{} #*01100111 @end example @end deffn @deffn {Scheme Procedure} bit-count* bitvector uvec bool @deffnx {C Function} scm_bit_count_star (bitvector, uvec, bool) Return a count of how many entries in @var{bitvector} are equal to @var{bool}, with @var{uvec} selecting the entries to consider. @var{uvec} is interpreted in the same way as for @code{bit-set*!} above. Namely, if @var{uvec} is a bit vector then entries which have @code{#t} there are considered in @var{bitvector}. Or if @var{uvec} is a uniform vector of unsigned long integers then it's the indexes in @var{bitvector} to consider. For example, @example (bit-count* #*01110111 #*11001101 #t) @result{} 3 (bit-count* #*01110111 #u(7 0 4) #f) @result{} 2 @end example @end deffn @deftypefn {C Function} {const scm_t_uint32 *} scm_bitvector_elements (SCM vec, scm_t_array_handle *handle, size_t *offp, size_t *lenp, ssize_t *incp) Like @code{scm_vector_elements} (which see), but for bitvectors. The variable pointed to by @var{offp} is set to the value returned by @code{scm_array_handle_bit_elements_offset}. See @code{scm_array_handle_bit_elements} for how to use the returned pointer and the offset. @end deftypefn @deftypefn {C Function} {scm_t_uint32 *} scm_bitvector_writable_elements (SCM vec, scm_t_array_handle *handle, size_t *offp, size_t *lenp, ssize_t *incp) Like @code{scm_bitvector_elements}, but the pointer is good for reading and writing. @end deftypefn @node Generalized Vectors @subsection Generalized Vectors Guile has a number of data types that are generally vector-like: strings, uniform numeric vectors, bitvectors, and of course ordinary vectors of arbitrary Scheme values. These types are disjoint: a Scheme value belongs to at most one of the four types listed above. If you want to gloss over this distinction and want to treat all four types with common code, you can use the procedures in this section. They work with the @emph{generalized vector} type, which is the union of the four vector-like types. @deffn {Scheme Procedure} generalized-vector? obj @deffnx {C Function} scm_generalized_vector_p (obj) Return @code{#t} if @var{obj} is a vector, string, bitvector, or uniform numeric vector. @end deffn @deffn {Scheme Procedure} generalized-vector-length v @deffnx {C Function} scm_generalized_vector_length (v) Return the length of the generalized vector @var{v}. @end deffn @deffn {Scheme Procedure} generalized-vector-ref v idx @deffnx {C Function} scm_generalized_vector_ref (v, idx) Return the element at index @var{idx} of the generalized vector @var{v}. @end deffn @deffn {Scheme Procedure} generalized-vector-set! v idx val @deffnx {C Function} scm_generalized_vector_set_x (v, idx, val) Set the element at index @var{idx} of the generalized vector @var{v} to @var{val}. @end deffn @deffn {Scheme Procedure} generalized-vector->list v @deffnx {C Function} scm_generalized_vector_to_list (v) Return a new list whose elements are the elements of the generalized vector @var{v}. @end deffn @deftypefn {C Function} int scm_is_generalized_vector (SCM obj) Return @code{1} if @var{obj} is a vector, string, bitvector, or uniform numeric vector; else return @code{0}. @end deftypefn @deftypefn {C Function} size_t scm_c_generalized_vector_length (SCM v) Return the length of the generalized vector @var{v}. @end deftypefn @deftypefn {C Function} SCM scm_c_generalized_vector_ref (SCM v, size_t idx) Return the element at index @var{idx} of the generalized vector @var{v}. @end deftypefn @deftypefn {C Function} void scm_c_generalized_vector_set_x (SCM v, size_t idx, SCM val) Set the element at index @var{idx} of the generalized vector @var{v} to @var{val}. @end deftypefn @deftypefn {C Function} void scm_generalized_vector_get_handle (SCM v, scm_t_array_handle *handle) Like @code{scm_array_get_handle} but an error is signalled when @var{v} is not of rank one. You can use @code{scm_array_handle_ref} and @code{scm_array_handle_set} to read and write the elements of @var{v}, or you can use functions like @code{scm_array_handle__elements} to deal with specific types of vectors. @end deftypefn @node Arrays @subsection Arrays @tpindex Arrays @dfn{Arrays} are a collection of cells organized into an arbitrary number of dimensions. Each cell can be accessed in constant time by supplying an index for each dimension. In the current implementation, an array uses a generalized vector for the actual storage of its elements. Any kind of generalized vector will do, so you can have arrays of uniform numeric values, arrays of characters, arrays of bits, and of course, arrays of arbitrary Scheme values. For example, arrays with an underlying @code{c64vector} might be nice for digital signal processing, while arrays made from a @code{u8vector} might be used to hold gray-scale images. The number of dimensions of an array is called its @dfn{rank}. Thus, a matrix is an array of rank 2, while a vector has rank 1. When accessing an array element, you have to specify one exact integer for each dimension. These integers are called the @dfn{indices} of the element. An array specifies the allowed range of indices for each dimension via an inclusive lower and upper bound. These bounds can well be negative, but the upper bound must be greater than or equal to the lower bound minus one. When all lower bounds of an array are zero, it is called a @dfn{zero-origin} array. Arrays can be of rank 0, which could be interpreted as a scalar. Thus, a zero-rank array can store exactly one object and the list of indices of this element is the empty list. Arrays contain zero elements when one of their dimensions has a zero length. These empty arrays maintain information about their shape: a matrix with zero columns and 3 rows is different from a matrix with 3 columns and zero rows, which again is different from a vector of length zero. Generalized vectors, such as strings, uniform numeric vectors, bit vectors and ordinary vectors, are the special case of one dimensional arrays. @menu * Array Syntax:: * Array Procedures:: * Shared Arrays:: * Accessing Arrays from C:: @end menu @node Array Syntax @subsubsection Array Syntax An array is displayed as @code{#} followed by its rank, followed by a tag that describes the underlying vector, optionally followed by information about its shape, and finally followed by the cells, organized into dimensions using parentheses. In more words, the array tag is of the form @example #<@@lower><:len><@@lower><:len>... @end example where @code{} is a positive integer in decimal giving the rank of the array. It is omitted when the rank is 1 and the array is non-shared and has zero-origin (see below). For shared arrays and for a non-zero origin, the rank is always printed even when it is 1 to dinstinguish them from ordinary vectors. The @code{} part is the tag for a uniform numeric vector, like @code{u8}, @code{s16}, etc, @code{b} for bitvectors, or @code{a} for strings. It is empty for ordinary vectors. The @code{<@@lower>} part is a @samp{@@} character followed by a signed integer in decimal giving the lower bound of a dimension. There is one @code{<@@lower>} for each dimension. When all lower bounds are zero, all @code{<@@lower>} parts are omitted. The @code{<:len>} part is a @samp{:} character followed by an unsigned integer in decimal giving the length of a dimension. Like for the lower bounds, there is one @code{<:len>} for each dimension, and the @code{<:len>} part always follows the @code{<@@lower>} part for a dimension. Lengths are only then printed when they can't be deduced from the nested lists of elements of the array literal, which can happen when at least one length is zero. As a special case, an array of rank 0 is printed as @code{#0()}, where @code{} is the result of printing the single element of the array. Thus, @table @code @item #(1 2 3) is an ordinary array of rank 1 with lower bound 0 in dimension 0. (I.e., a regular vector.) @item #@@2(1 2 3) is an ordinary array of rank 1 with lower bound 2 in dimension 0. @item #2((1 2 3) (4 5 6)) is a non-uniform array of rank 2; a 3@cross{}3 matrix with index ranges 0..2 and 0..2. @item #u32(0 1 2) is a uniform u8 array of rank 1. @item #2u32@@2@@3((1 2) (2 3)) is a uniform u8 array of rank 2 with index ranges 2..3 and 3..4. @item #2() is a two-dimensional array with index ranges 0..-1 and 0..-1, i.e. both dimensions have length zero. @item #2:0:2() is a two-dimensional array with index ranges 0..-1 and 0..1, i.e. the first dimension has length zero, but the second has length 2. @item #0(12) is a rank-zero array with contents 12. @end table @node Array Procedures @subsubsection Array Procedures When an array is created, the range of each dimension must be specified, e.g., to create a 2@cross{}3 array with a zero-based index: @example (make-array 'ho 2 3) @result{} #2((ho ho ho) (ho ho ho)) @end example The range of each dimension can also be given explicitly, e.g., another way to create the same array: @example (make-array 'ho '(0 1) '(0 2)) @result{} #2((ho ho ho) (ho ho ho)) @end example The following procedures can be used with arrays (or vectors). An argument shown as @var{idx}@dots{} means one parameter for each dimension in the array. A @var{idxlist} argument means a list of such values, one for each dimension. @deffn {Scheme Procedure} array? obj @deffnx {C Function} scm_array_p (obj, unused) Return @code{#t} if the @var{obj} is an array, and @code{#f} if not. The second argument to scm_array_p is there for historical reasons, but it is not used. You should always pass @code{SCM_UNDEFINED} as its value. @end deffn @deffn {Scheme Procedure} typed-array? obj type @deffnx {C Function} scm_typed_array_p (obj, type) Return @code{#t} if the @var{obj} is an array of type @var{type}, and @code{#f} if not. @end deffn @deftypefn {C Function} int scm_is_array (SCM obj) Return @code{1} if the @var{obj} is an array and @code{0} if not. @end deftypefn @deftypefn {C Function} int scm_is_typed_array (SCM obj, SCM type) Return @code{0} if the @var{obj} is an array of type @var{type}, and @code{1} if not. @end deftypefn @deffn {Scheme Procedure} make-array fill bound @dots{} @deffnx {C Function} scm_make_array (fill, bounds) Equivalent to @code{(make-typed-array #t @var{fill} @var{bound} ...)}. @end deffn @deffn {Scheme Procedure} make-typed-array type fill bound @dots{} @deffnx {C Function} scm_make_typed_array (type, fill, bounds) Create and return an array that has as many dimensions as there are @var{bound}s and (maybe) fill it with @var{fill}. The underlaying storage vector is created according to @var{type}, which must be a symbol whose name is the `vectag' of the array as explained above, or @code{#t} for ordinary, non-specialized arrays. For example, using the symbol @code{f64} for @var{type} will create an array that uses a @code{f64vector} for storing its elements, and @code{a} will use a string. When @var{fill} is not the special @emph{unspecified} value, the new array is filled with @var{fill}. Otherwise, the initial contents of the array is unspecified. The special @emph{unspecified} value is stored in the variable @code{*unspecified*} so that for example @code{(make-typed-array 'u32 *unspecified* 4)} creates a uninitialized @code{u32} vector of length 4. Each @var{bound} may be a positive non-zero integer @var{N}, in which case the index for that dimension can range from 0 through @var{N-1}; or an explicit index range specifier in the form @code{(LOWER UPPER)}, where both @var{lower} and @var{upper} are integers, possibly less than zero, and possibly the same number (however, @var{lower} cannot be greater than @var{upper}). @end deffn @deffn {Scheme Procedure} list->array dimspec list Equivalent to @code{(list->typed-array #t @var{dimspec} @var{list})}. @end deffn @deffn {Scheme Procedure} list->typed-array type dimspec list @deffnx {C Function} scm_list_to_typed_array (type, dimspec, list) Return an array of the type indicated by @var{type} with elements the same as those of @var{list}. The argument @var{dimspec} determines the number of dimensions of the array and their lower bounds. When @var{dimspec} is an exact integer, it gives the number of dimensions directly and all lower bounds are zero. When it is a list of exact integers, then each element is the lower index bound of a dimension, and there will be as many dimensions as elements in the list. @end deffn @deffn {Scheme Procedure} array-type array Return the type of @var{array}. This is the `vectag' used for printing @var{array} (or @code{#t} for ordinary arrays) and can be used with @code{make-typed-array} to create an array of the same kind as @var{array}. @end deffn @deffn {Scheme Procedure} array-ref array idx @dots{} Return the element at @code{(idx @dots{})} in @var{array}. @example (define a (make-array 999 '(1 2) '(3 4))) (array-ref a 2 4) @result{} 999 @end example @end deffn @deffn {Scheme Procedure} array-in-bounds? array idx @dots{} @deffnx {C Function} scm_array_in_bounds_p (array, idxlist) Return @code{#t} if the given index would be acceptable to @code{array-ref}. @example (define a (make-array #f '(1 2) '(3 4))) (array-in-bounds? a 2 3) @result{} #f (array-in-bounds? a 0 0) @result{} #f @end example @end deffn @deffn {Scheme Procedure} array-set! array obj idx @dots{} @deffnx {C Function} scm_array_set_x (array, obj, idxlist) Set the element at @code{(idx @dots{})} in @var{array} to @var{obj}. The return value is unspecified. @example (define a (make-array #f '(0 1) '(0 1))) (array-set! a #t 1 1) a @result{} #2((#f #f) (#f #t)) @end example @end deffn @deffn {Scheme Procedure} enclose-array array dim1 @dots{} @deffnx {C Function} scm_enclose_array (array, dimlist) @var{dim1}, @var{dim2} @dots{} should be nonnegative integers less than the rank of @var{array}. @code{enclose-array} returns an array resembling an array of shared arrays. The dimensions of each shared array are the same as the @var{dim}th dimensions of the original array, the dimensions of the outer array are the same as those of the original array that did not match a @var{dim}. An enclosed array is not a general Scheme array. Its elements may not be set using @code{array-set!}. Two references to the same element of an enclosed array will be @code{equal?} but will not in general be @code{eq?}. The value returned by @code{array-prototype} when given an enclosed array is unspecified. For example, @lisp (enclose-array '#3(((a b c) (d e f)) ((1 2 3) (4 5 6))) 1) @result{} # (enclose-array '#3(((a b c) (d e f)) ((1 2 3) (4 5 6))) 1 0) @result{} # @end lisp @end deffn @deffn {Scheme Procedure} array-shape array @deffnx {Scheme Procedure} array-dimensions array @deffnx {C Function} scm_array_dimensions (array) Return a list of the bounds for each dimenson of @var{array}. @code{array-shape} gives @code{(@var{lower} @var{upper})} for each dimension. @code{array-dimensions} instead returns just @math{@var{upper}+1} for dimensions with a 0 lower bound. Both are suitable as input to @code{make-array}. For example, @example (define a (make-array 'foo '(-1 3) 5)) (array-shape a) @result{} ((-1 3) (0 4)) (array-dimensions a) @result{} ((-1 3) 5) @end example @end deffn @deffn {Scheme Procedure} array-rank obj @deffnx {C Function} scm_array_rank (obj) Return the rank of @var{array}. @end deffn @deftypefn {C Function} scm_c_array_rank (SCM array) Return the rank of @var{array} as a @code{size_t}. @end deftypefn @deffn {Scheme Procedure} array->list array @deffnx {C Function} scm_array_to_list (array) Return a list consisting of all the elements, in order, of @var{array}. @end deffn @c FIXME: Describe how the order affects the copying (it matters for @c shared arrays with the same underlying root vector, presumably). @c @deffn {Scheme Procedure} array-copy! src dst @deffnx {Scheme Procedure} array-copy-in-order! src dst @deffnx {C Function} scm_array_copy_x (src, dst) Copy every element from vector or array @var{src} to the corresponding element of @var{dst}. @var{dst} must have the same rank as @var{src}, and be at least as large in each dimension. The return value is unspecified. @end deffn @deffn {Scheme Procedure} array-fill! array fill @deffnx {C Function} scm_array_fill_x (array, fill) Store @var{fill} in every element of @var{array}. The value returned is unspecified. @end deffn @c begin (texi-doc-string "guile" "array-equal?") @deffn {Scheme Procedure} array-equal? array1 array2 @dots{} Return @code{#t} if all arguments are arrays with the same shape, the same type, and have corresponding elements which are either @code{equal?} or @code{array-equal?}. This function differs from @code{equal?} in that a one dimensional shared array may be @var{array-equal?} but not @var{equal?} to a vector or uniform vector. @end deffn @deffn {Scheme Procedure} array-contents array [strict] @deffnx {C Function} scm_array_contents (array, strict) If @var{array} may be @dfn{unrolled} into a one dimensional shared array without changing their order (last subscript changing fastest), then @code{array-contents} returns that shared array, otherwise it returns @code{#f}. All arrays made by @code{make-array} and @code{make-generalized-array} may be unrolled, some arrays made by @code{make-shared-array} may not be. If the optional argument @var{strict} is provided, a shared array will be returned only if its elements are stored internally contiguous in memory. @end deffn @c FIXME: array-map! accepts no source arrays at all, and in that @c case makes calls "(proc)". Is that meant to be a documented @c feature? @c @c FIXME: array-for-each doesn't say what happens if the sources have @c different index ranges. The code currently iterates over the @c indices of the first and expects the others to cover those. That @c at least vaguely matches array-map!, but is is meant to be a @c documented feature? @deffn {Scheme Procedure} array-map! dst proc src1 @dots{} srcN @deffnx {Scheme Procedure} array-map-in-order! dst proc src1 @dots{} srcN @deffnx {C Function} scm_array_map_x (dst, proc, srclist) Set each element of the @var{dst} array to values obtained from calls to @var{proc}. The value returned is unspecified. Each call is @code{(@var{proc} @var{elem1} @dots{} @var{elemN})}, where each @var{elem} is from the corresponding @var{src} array, at the @var{dst} index. @code{array-map-in-order!} makes the calls in row-major order, @code{array-map!} makes them in an unspecified order. The @var{src} arrays must have the same number of dimensions as @var{dst}, and must have a range for each dimension which covers the range in @var{dst}. This ensures all @var{dst} indices are valid in each @var{src}. @end deffn @deffn {Scheme Procedure} array-for-each proc src1 @dots{} srcN @deffnx {C Function} scm_array_for_each (proc, src1, srclist) Apply @var{proc} to each tuple of elements of @var{src1} @dots{} @var{srcN}, in row-major order. The value returned is unspecified. @end deffn @deffn {Scheme Procedure} array-index-map! dst proc @deffnx {C Function} scm_array_index_map_x (dst, proc) Set each element of the @var{dst} array to values returned by calls to @var{proc}. The value returned is unspecified. Each call is @code{(@var{proc} @var{i1} @dots{} @var{iN})}, where @var{i1}@dots{}@var{iN} is the destination index, one parameter for each dimension. The order in which the calls are made is unspecified. For example, to create a @m{4\times4, 4x4} matrix representing a cyclic group, @tex \advance\leftskip by 2\lispnarrowing { $\left(\matrix{% 0 & 1 & 2 & 3 \cr 1 & 2 & 3 & 0 \cr 2 & 3 & 0 & 1 \cr 3 & 0 & 1 & 2 \cr }\right)$} \par @end tex @ifnottex @example / 0 1 2 3 \ | 1 2 3 0 | | 2 3 0 1 | \ 3 0 1 2 / @end example @end ifnottex @example (define a (make-array #f 4 4)) (array-index-map! a (lambda (i j) (modulo (+ i j) 4))) @end example @end deffn @deffn {Scheme Procedure} uniform-array-read! ra [port_or_fd [start [end]]] @deffnx {C Function} scm_uniform_array_read_x (ra, port_or_fd, start, end) Attempt to read all elements of @var{ura}, in lexicographic order, as binary objects from @var{port-or-fdes}. If an end of file is encountered, the objects up to that point are put into @var{ura} (starting at the beginning) and the remainder of the array is unchanged. The optional arguments @var{start} and @var{end} allow a specified region of a vector (or linearized array) to be read, leaving the remainder of the vector unchanged. @code{uniform-array-read!} returns the number of objects read. @var{port-or-fdes} may be omitted, in which case it defaults to the value returned by @code{(current-input-port)}. @end deffn @deffn {Scheme Procedure} uniform-array-write v [port_or_fd [start [end]]] @deffnx {C Function} scm_uniform_array_write (v, port_or_fd, start, end) Writes all elements of @var{ura} as binary objects to @var{port-or-fdes}. The optional arguments @var{start} and @var{end} allow a specified region of a vector (or linearized array) to be written. The number of objects actually written is returned. @var{port-or-fdes} may be omitted, in which case it defaults to the value returned by @code{(current-output-port)}. @end deffn @node Shared Arrays @subsubsection Shared Arrays @deffn {Scheme Procedure} make-shared-array oldarray mapfunc bound @dots{} @deffnx {C Function} scm_make_shared_array (oldarray, mapfunc, boundlist) Return a new array which shares the storage of @var{oldarray}. Changes made through either affect the same underlying storage. The @var{bound@dots{}} arguments are the shape of the new array, the same as @code{make-array} (@pxref{Array Procedures}). @var{mapfunc} translates coordinates from the new array to the @var{oldarray}. It's called as @code{(@var{mapfunc} newidx1 @dots{})} with one parameter for each dimension of the new array, and should return a list of indices for @var{oldarray}, one for each dimension of @var{oldarray}. @var{mapfunc} must be affine linear, meaning that each @var{oldarray} index must be formed by adding integer multiples (possibly negative) of some or all of @var{newidx1} etc, plus a possible integer offset. The multiples and offset must be the same in each call. @sp 1 One good use for a shared array is to restrict the range of some dimensions, so as to apply say @code{array-for-each} or @code{array-fill!} to only part of an array. The plain @code{list} function can be used for @var{mapfunc} in this case, making no changes to the index values. For example, @example (make-shared-array #2((a b c) (d e f) (g h i)) list 3 2) @result{} #2((a b) (d e) (g h)) @end example The new array can have fewer dimensions than @var{oldarray}, for example to take a column from an array. @example (make-shared-array #2((a b c) (d e f) (g h i)) (lambda (i) (list i 2)) '(0 2)) @result{} #1(c f i) @end example A diagonal can be taken by using the single new array index for both row and column in the old array. For example, @example (make-shared-array #2((a b c) (d e f) (g h i)) (lambda (i) (list i i)) '(0 2)) @result{} #1(a e i) @end example Dimensions can be increased by for instance considering portions of a one dimensional array as rows in a two dimensional array. (@code{array-contents} below can do the opposite, flattening an array.) @example (make-shared-array #1(a b c d e f g h i j k l) (lambda (i j) (list (+ (* i 3) j))) 4 3) @result{} #2((a b c) (d e f) (g h i) (j k l)) @end example By negating an index the order that elements appear can be reversed. The following just reverses the column order, @example (make-shared-array #2((a b c) (d e f) (g h i)) (lambda (i j) (list i (- 2 j))) 3 3) @result{} #2((c b a) (f e d) (i h g)) @end example A fixed offset on indexes allows for instance a change from a 0 based to a 1 based array, @example (define x #2((a b c) (d e f) (g h i))) (define y (make-shared-array x (lambda (i j) (list (1- i) (1- j))) '(1 3) '(1 3))) (array-ref x 0 0) @result{} a (array-ref y 1 1) @result{} a @end example A multiple on an index allows every Nth element of an array to be taken. The following is every third element, @example (make-shared-array #1(a b c d e f g h i j k l) (lambda (i) (* i 3)) 4) @result{} #1(a d g j) @end example The above examples can be combined to make weird and wonderful selections from an array, but it's important to note that because @var{mapfunc} must be affine linear, arbitrary permutations are not possible. In the current implementation, @var{mapfunc} is not called for every access to the new array but only on some sample points to establish a base and stride for new array indices in @var{oldarray} data. A few sample points are enough because @var{mapfunc} is linear. @end deffn @deffn {Scheme Procedure} shared-array-increments array @deffnx {C Function} scm_shared_array_increments (array) For each dimension, return the distance between elements in the root vector. @end deffn @deffn {Scheme Procedure} shared-array-offset array @deffnx {C Function} scm_shared_array_offset (array) Return the root vector index of the first element in the array. @end deffn @deffn {Scheme Procedure} shared-array-root array @deffnx {C Function} scm_shared_array_root (array) Return the root vector of a shared array. @end deffn @deffn {Scheme Procedure} transpose-array array dim1 @dots{} @deffnx {C Function} scm_transpose_array (array, dimlist) Return an array sharing contents with @var{array}, but with dimensions arranged in a different order. There must be one @var{dim} argument for each dimension of @var{array}. @var{dim1}, @var{dim2}, @dots{} should be integers between 0 and the rank of the array to be returned. Each integer in that range must appear at least once in the argument list. The values of @var{dim1}, @var{dim2}, @dots{} correspond to dimensions in the array to be returned, and their positions in the argument list to dimensions of @var{array}. Several @var{dim}s may have the same value, in which case the returned array will have smaller rank than @var{array}. @lisp (transpose-array '#2((a b) (c d)) 1 0) @result{} #2((a c) (b d)) (transpose-array '#2((a b) (c d)) 0 0) @result{} #1(a d) (transpose-array '#3(((a b c) (d e f)) ((1 2 3) (4 5 6))) 1 1 0) @result{} #2((a 4) (b 5) (c 6)) @end lisp @end deffn @node Accessing Arrays from C @subsubsection Accessing Arrays from C Arrays, especially uniform numeric arrays, are useful to efficiently represent large amounts of rectangularily organized information, such as matrices, images, or generally blobs of binary data. It is desirable to access these blobs in a C like manner so that they can be handed to external C code such as linear algebra libraries or image processing routines. While pointers to the elements of an array are in use, the array itself must be protected so that the pointer remains valid. Such a protected array is said to be @dfn{reserved}. A reserved array can be read but modifications to it that would cause the pointer to its elements to become invalid are prevented. When you attempt such a modification, an error is signalled. (This is similar to locking the array while it is in use, but without the danger of a deadlock. In a multi-threaded program, you will need additional synchronization to avoid modifying reserved arrays.) You must take care to always unreserve an array after reserving it, also in the presence of non-local exits. To simplify this, reserving and unreserving work like a frame (@pxref{Frames}): a call to @code{scm_array_get_handle} can be thought of as beginning a frame and @code{scm_array_handle_release} as ending it. When a non-local exit happens between these two calls, the array is implicitely unreserved. That is, you need to properly pair reserving and unreserving in your code, but you don't need to worry about non-local exits. These calls and other pairs of calls that establish dynamic contexts need to be properly nested. If you begin a frame prior to reserving an array, you need to unreserve the array before ending the frame. Likewise, when reserving two or more arrays in a certain order, you need to unreserve them in the opposite order. Once you have reserved an array and have retrieved the pointer to its elements, you must figure out the layout of the elements in memory. Guile allows slices to be taken out of arrays without actually making a copy, such as making an alias for the diagonal of a matrix that can be treated as a vector. Arrays that result from such an operation are not stored contiguously in memory and when working with their elements directly, you need to take this into account. The layout of array elements in memory can be defined via a @emph{mapping function} that computes a scalar position from a vector of indices. The scalar position then is the offset of the element with the given indices from the start of the storage block of the array. In Guile, this mapping function is restricted to be @dfn{affine}: all mapping function of Guile arrays can be written as @code{p = b + c[0]*i[0] + c[1]*i[1] + ... + c[n-1]*i[n-1]} where @code{i[k]} is the @nicode{k}th index and @code{n} is the rank of the array. For example, a matrix of size 3x3 would have @code{b == 0}, @code{c[0] == 3} and @code{c[1] == 1}. When you transpose this matrix (with @code{transpose-array}, say), you will get an array whose mapping function has @code{b == 0}, @code{c[0] == 1} and @code{c[1] == 3}. The function @code{scm_array_handle_dims} gives you (indirect) access to the coefficients @code{c[k]}. @c XXX Note that there are no functions for accessing the elements of a character array yet. Once the string implementation of Guile has been changed to use Unicode, we will provide them. @deftp {C Type} scm_t_array_handle This is a structure type that holds all information necessary to manage the reservation of arrays as explained above. Structures of this type must be allocated on the stack and must only be accessed by the functions listed below. @end deftp @deftypefn {C Function} void scm_array_get_handle (SCM array, scm_t_array_handle *handle) Reserve @var{array}, which must be an array, and prepare @var{handle} to be used with the functions below. You must eventually call @code{scm_array_handle_release} on @var{handle}, and do this in a properly nested fashion, as explained above. The structure pointed to by @var{handle} does not need to be initialized before calling this function. @end deftypefn @deftypefn {C Function} void scm_array_handle_release (scm_t_array_handle *handle) End the array reservation represented by @var{handle}. After a call to this function, @var{handle} might be used for another reservation. @end deftypefn @deftypefn {C Function} size_t scm_array_handle_rank (scm_t_array_handle *handle) Return the rank of the array represented by @var{handle}. @end deftypefn @deftp {C Type} scm_t_array_dim This structure type holds information about the layout of one dimension of an array. It includes the following fields: @table @code @item ssize_t lbnd @itemx ssize_t ubnd The lower and upper bounds (both inclusive) of the permissible index range for the given dimension. Both values can be negative, but @var{lbnd} is always less than or equal to @var{ubnd}. @item ssize_t inc The distance from one element of this dimension to the next. Note, too, that this can be negative. @end table @end deftp @deftypefn {C Function} {const scm_t_array_dim *} scm_array_handle_dims (scm_t_array_handle *handle) Return a pointer to a C vector of information about the dimensions of the array represented by @var{handle}. This pointer is valid as long as the array remains reserved. As explained above, the @code{scm_t_array_dim} structures returned by this function can be used calculate the position of an element in the storage block of the array from its indices. This position can then be used as an index into the C array pointer returned by the various @code{scm_array_handle__elements} functions, or with @code{scm_array_handle_ref} and @code{scm_array_handle_set}. Here is how one can compute the position @var{pos} of an element given its indices in the vector @var{indices}: @example ssize_t indices[RANK]; scm_t_array_dim *dims; ssize_t pos; size_t i; pos = 0; for (i = 0; i < RANK; i++) @{ if (indices[i] < dims[i].lbnd || indices[i] > dims[i].ubnd) out_of_range (); pos += (indices[i] - dims[i].lbnd) * dims[i].inc; @} @end example @end deftypefn @deftypefn {C Function} ssize_t scm_array_handle_pos (scm_t_array_handle *handle, SCM indices) Compute the position corresponding to @var{indices}, a list of indices. The position is computed as described above for @code{scm_array_handle_dims}. The number of the indices and their range is checked and an approrpiate error is signalled for invalid indices. @end deftypefn @deftypefn {C Function} SCM scm_array_handle_ref (scm_t_array_handle *handle, ssize_t pos) Return the element at position @var{pos} in the storage block of the array represented by @var{handle}. Any kind of array is acceptable. No range checking is done on @var{pos}. @end deftypefn @deftypefn {C Function} void scm_array_handle_set (scm_t_array_handle *handle, ssize_t pos, SCM val) Set the element at position @var{pos} in the storage block of the array represented by @var{handle} to @var{val}. Any kind of array is acceptable. No range checking is done on @var{pos}. An error is signalled when the array can not store @var{val}. @end deftypefn @deftypefn {C Function} {const SCM *} scm_array_handle_elements (scm_t_array_handle *handle) Return a pointer to the elements of a ordinary array of general Scheme values (i.e., a non-uniform array) for reading. This pointer is valid as long as the array remains reserved. @end deftypefn @deftypefn {C Function} {SCM *} scm_array_handle_writable_elements (scm_t_array_handle *handle) Like @code{scm_array_handle_elements}, but the pointer is good for reading and writing. @end deftypefn @deftypefn {C Function} {const void *} scm_array_handle_uniform_elements (scm_t_array_handle *handle) Return a pointer to the elements of a uniform numeric array for reading. This pointer is valid as long as the array remains reserved. The size of each element is given by @code{scm_array_handle_uniform_element_size}. @end deftypefn @deftypefn {C Function} {void *} scm_array_handle_uniform_writable_elements (scm_t_array_handle *handle) Like @code{scm_array_handle_uniform_elements}, but the pointer is good reading and writing. @end deftypefn @deftypefn {C Function} size_t scm_array_handle_uniform_element_size (scm_t_array_handle *handle) Return the size of one element of the uniform numeric array represented by @var{handle}. @end deftypefn @deftypefn {C Function} {const scm_t_uint8 *} scm_array_handle_u8_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const scm_t_int8 *} scm_array_handle_s8_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const scm_t_uint16 *} scm_array_handle_u16_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const scm_t_int16 *} scm_array_handle_s16_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const scm_t_uint32 *} scm_array_handle_u32_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const scm_t_int32 *} scm_array_handle_s32_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const scm_t_uint64 *} scm_array_handle_u64_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const scm_t_int64 *} scm_array_handle_s64_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const float *} scm_array_handle_f32_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const double *} scm_array_handle_f64_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const float *} scm_array_handle_c32_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {const double *} scm_array_handle_c64_elements (scm_t_array_handle *handle) Return a pointer to the elements of a uniform numeric array of the indicated kind for reading. This pointer is valid as long as the array remains reserved. The pointers for @code{c32} and @code{c64} uniform numeric arrays point to pairs of floating point numbers. The even index holds the real part, the odd index the imaginary part of the complex number. @end deftypefn @deftypefn {C Function} {scm_t_uint8 *} scm_array_handle_u8_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {scm_t_int8 *} scm_array_handle_s8_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {scm_t_uint16 *} scm_array_handle_u16_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {scm_t_int16 *} scm_array_handle_s16_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {scm_t_uint32 *} scm_array_handle_u32_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {scm_t_int32 *} scm_array_handle_s32_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {scm_t_uint64 *} scm_array_handle_u64_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {scm_t_int64 *} scm_array_handle_s64_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {float *} scm_array_handle_f32_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {double *} scm_array_handle_f64_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {float *} scm_array_handle_c32_writable_elements (scm_t_array_handle *handle) @deftypefnx {C Function} {double *} scm_array_handle_c64_writable_elements (scm_t_array_handle *handle) Like @code{scm_array_handle__elements}, but the pointer is good for reading and writing. @end deftypefn @deftypefn {C Function} {const scm_t_uint32 *} scm_array_handle_bit_elements (scm_t_array_handle *handle) Return a pointer to the words that store the bits of the represented array, which must be a bit array. Unlike other arrays, bit arrays have an additional offset that must be figured into index calculations. That offset is returned by @code{scm_array_handle_bit_elements_offset}. To find a certain bit you first need to calculate its position as explained above for @code{scm_array_handle_dims} and then add the offset. This gives the absolute position of the bit, which is always a non-negative integer. Each word of the bit array storage block contains exactly 32 bits, with the least significant bit in that word having the lowest absolute position number. The next word contains the next 32 bits. Thus, the following code can be used to access a bit whose position according to @code{scm_array_handle_dims} is given in @var{pos}: @example SCM bit_array; scm_t_array_handle handle; scm_t_uint32 *bits; ssize_t pos; size_t abs_pos; size_t word_pos, mask; scm_array_get_handle (&bit_array, &handle); bits = scm_array_handle_bit_elements (&handle); pos = ... abs_pos = pos + scm_array_handle_bit_elements_offset (&handle); word_pos = abs_pos / 32; mask = 1L << (abs_pos % 32); if (bits[word_pos] & mask) /* bit is set. */ scm_array_handle_release (&handle); @end example @end deftypefn @deftypefn {C Function} {scm_t_uint32 *} scm_array_handle_bit_writable_elements (scm_t_array_handle *handle) Like @code{scm_array_handle_bit_elements} but the pointer is good for reading and writing. You must take care not to modify bits outside of the allowed index range of the array, even for contiguous arrays. @end deftypefn @node Records @subsection Records A @dfn{record type} is a first class object representing a user-defined data type. A @dfn{record} is an instance of a record type. @deffn {Scheme Procedure} record? obj Return @code{#t} if @var{obj} is a record of any type and @code{#f} otherwise. Note that @code{record?} may be true of any Scheme value; there is no promise that records are disjoint with other Scheme types. @end deffn @deffn {Scheme Procedure} make-record-type type-name field-names Return a @dfn{record-type descriptor}, a value representing a new data type disjoint from all others. The @var{type-name} argument must be a string, but is only used for debugging purposes (such as the printed representation of a record of the new type). The @var{field-names} argument is a list of symbols naming the @dfn{fields} of a record of the new type. It is an error if the list contains any duplicates. It is unspecified how record-type descriptors are represented. @end deffn @deffn {Scheme Procedure} record-constructor rtd [field-names] Return a procedure for constructing new members of the type represented by @var{rtd}. The returned procedure accepts exactly as many arguments as there are symbols in the given list, @var{field-names}; these are used, in order, as the initial values of those fields in a new record, which is returned by the constructor procedure. The values of any fields not named in that list are unspecified. The @var{field-names} argument defaults to the list of field names in the call to @code{make-record-type} that created the type represented by @var{rtd}; if the @var{field-names} argument is provided, it is an error if it contains any duplicates or any symbols not in the default list. @end deffn @deffn {Scheme Procedure} record-predicate rtd Return a procedure for testing membership in the type represented by @var{rtd}. The returned procedure accepts exactly one argument and returns a true value if the argument is a member of the indicated record type; it returns a false value otherwise. @end deffn @deffn {Scheme Procedure} record-accessor rtd field-name Return a procedure for reading the value of a particular field of a member of the type represented by @var{rtd}. The returned procedure accepts exactly one argument which must be a record of the appropriate type; it returns the current value of the field named by the symbol @var{field-name} in that record. The symbol @var{field-name} must be a member of the list of field-names in the call to @code{make-record-type} that created the type represented by @var{rtd}. @end deffn @deffn {Scheme Procedure} record-modifier rtd field-name Return a procedure for writing the value of a particular field of a member of the type represented by @var{rtd}. The returned procedure accepts exactly two arguments: first, a record of the appropriate type, and second, an arbitrary Scheme value; it modifies the field named by the symbol @var{field-name} in that record to contain the given value. The returned value of the modifier procedure is unspecified. The symbol @var{field-name} must be a member of the list of field-names in the call to @code{make-record-type} that created the type represented by @var{rtd}. @end deffn @deffn {Scheme Procedure} record-type-descriptor record Return a record-type descriptor representing the type of the given record. That is, for example, if the returned descriptor were passed to @code{record-predicate}, the resulting predicate would return a true value when passed the given record. Note that it is not necessarily the case that the returned descriptor is the one that was passed to @code{record-constructor} in the call that created the constructor procedure that created the given record. @end deffn @deffn {Scheme Procedure} record-type-name rtd Return the type-name associated with the type represented by rtd. The returned value is @code{eqv?} to the @var{type-name} argument given in the call to @code{make-record-type} that created the type represented by @var{rtd}. @end deffn @deffn {Scheme Procedure} record-type-fields rtd Return a list of the symbols naming the fields in members of the type represented by @var{rtd}. The returned value is @code{equal?} to the field-names argument given in the call to @code{make-record-type} that created the type represented by @var{rtd}. @end deffn @node Structures @subsection Structures @tpindex Structures [FIXME: this is pasted in from Tom Lord's original guile.texi and should be reviewed] A @dfn{structure type} is a first class user-defined data type. A @dfn{structure} is an instance of a structure type. A structure type is itself a structure. Structures are less abstract and more general than traditional records. In fact, in Guile Scheme, records are implemented using structures. @menu * Structure Concepts:: The structure of Structures * Structure Layout:: Defining the layout of structure types * Structure Basics:: make-, -ref and -set! procedures for structs * Vtables:: Accessing type-specific data @end menu @node Structure Concepts @subsubsection Structure Concepts A structure object consists of a handle, structure data, and a vtable. The handle is a Scheme value which points to both the vtable and the structure's data. Structure data is a dynamically allocated region of memory, private to the structure, divided up into typed fields. A vtable is another structure used to hold type-specific data. Multiple structures can share a common vtable. Three concepts are key to understanding structures. @itemize @bullet{} @item @dfn{layout specifications} Layout specifications determine how memory allocated to structures is divided up into fields. Programmers must write a layout specification whenever a new type of structure is defined. @item @dfn{structural accessors} Structure access is by field number. There is only one set of accessors common to all structure objects. @item @dfn{vtables} Vtables, themselves structures, are first class representations of disjoint sub-types of structures in general. In most cases, when a new structure is created, programmers must specify a vtable for the new structure. Each vtable has a field describing the layout of its instances. Vtables can have additional, user-defined fields as well. @end itemize @node Structure Layout @subsubsection Structure Layout When a structure is created, a region of memory is allocated to hold its state. The @dfn{layout} of the structure's type determines how that memory is divided into fields. Each field has a specified type. There are only three types allowed, each corresponding to a one letter code. The allowed types are: @itemize @bullet{} @item 'u' -- unprotected The field holds binary data that is not GC protected. @item 'p' -- protected The field holds a Scheme value and is GC protected. @item 's' -- self The field holds a Scheme value and is GC protected. When a structure is created with this type of field, the field is initialized to refer to the structure's own handle. This kind of field is mainly useful when mixing Scheme and C code in which the C code may need to compute a structure's handle given only the address of its malloc'd data. @end itemize Each field also has an associated access protection. There are only three kinds of protection, each corresponding to a one letter code. The allowed protections are: @itemize @bullet{} @item 'w' -- writable The field can be read and written. @item 'r' -- readable The field can be read, but not written. @item 'o' -- opaque The field can be neither read nor written. This kind of protection is for fields useful only to built-in routines. @end itemize A layout specification is described by stringing together pairs of letters: one to specify a field type and one to specify a field protection. For example, a traditional cons pair type object could be described as: @example ; cons pairs have two writable fields of Scheme data "pwpw" @end example A pair object in which the first field is held constant could be: @example "prpw" @end example Binary fields, (fields of type "u"), hold one @dfn{word} each. The size of a word is a machine dependent value defined to be equal to the value of the C expression: @code{sizeof (long)}. The last field of a structure layout may specify a tail array. A tail array is indicated by capitalizing the field's protection code ('W', 'R' or 'O'). A tail-array field is replaced by a read-only binary data field containing an array size. The array size is determined at the time the structure is created. It is followed by a corresponding number of fields of the type specified for the tail array. For example, a conventional Scheme vector can be described as: @example ; A vector is an arbitrary number of writable fields holding Scheme ; values: "pW" @end example In the above example, field 0 contains the size of the vector and fields beginning at 1 contain the vector elements. A kind of tagged vector (a constant tag followed by conventional vector elements) might be: @example "prpW" @end example Structure layouts are represented by specially interned symbols whose name is a string of type and protection codes. To create a new structure layout, use this procedure: @deffn {Scheme Procedure} make-struct-layout fields @deffnx {C Function} scm_make_struct_layout (fields) Return a new structure layout object. @var{fields} must be a string made up of pairs of characters strung together. The first character of each pair describes a field type, the second a field protection. Allowed types are 'p' for GC-protected Scheme data, 'u' for unprotected binary data, and 's' for a field that points to the structure itself. Allowed protections are 'w' for mutable fields, 'r' for read-only fields, and 'o' for opaque fields. The last field protection specification may be capitalized to indicate that the field is a tail-array. @end deffn @node Structure Basics @subsubsection Structure Basics This section describes the basic procedures for creating and accessing structures. @deffn {Scheme Procedure} make-struct vtable tail_array_size . init @deffnx {C Function} scm_make_struct (vtable, tail_array_size, init) Create a new structure. @var{type} must be a vtable structure (@pxref{Vtables}). @var{tail-elts} must be a non-negative integer. If the layout specification indicated by @var{type} includes a tail-array, this is the number of elements allocated to that array. The @var{init1}, @dots{} are optional arguments describing how successive fields of the structure should be initialized. Only fields with protection 'r' or 'w' can be initialized, except for fields of type 's', which are automatically initialized to point to the new structure itself; fields with protection 'o' can not be initialized by Scheme programs. If fewer optional arguments than initializable fields are supplied, fields of type 'p' get default value #f while fields of type 'u' are initialized to 0. Structs are currently the basic representation for record-like data structures in Guile. The plan is to eventually replace them with a new representation which will at the same time be easier to use and more powerful. For more information, see the documentation for @code{make-vtable-vtable}. @end deffn @deffn {Scheme Procedure} struct? x @deffnx {C Function} scm_struct_p (x) Return @code{#t} iff @var{x} is a structure object, else @code{#f}. @end deffn @deffn {Scheme Procedure} struct-ref handle pos @deffnx {Scheme Procedure} struct-set! struct n value @deffnx {C Function} scm_struct_ref (handle, pos) @deffnx {C Function} scm_struct_set_x (struct, n, value) Access (or modify) the @var{n}th field of @var{struct}. If the field is of type 'p', then it can be set to an arbitrary value. If the field is of type 'u', then it can only be set to a non-negative integer value small enough to fit in one machine word. @end deffn @node Vtables @subsubsection Vtables Vtables are structures that are used to represent structure types. Each vtable contains a layout specification in field @code{vtable-index-layout} -- instances of the type are laid out according to that specification. Vtables contain additional fields which are used only internally to libguile. The variable @code{vtable-offset-user} is bound to a field number. Vtable fields at that position or greater are user definable. @deffn {Scheme Procedure} struct-vtable handle @deffnx {C Function} scm_struct_vtable (handle) Return the vtable structure that describes the type of @var{struct}. @end deffn @deffn {Scheme Procedure} struct-vtable? x @deffnx {C Function} scm_struct_vtable_p (x) Return @code{#t} iff @var{x} is a vtable structure. @end deffn If you have a vtable structure, @code{V}, you can create an instance of the type it describes by using @code{(make-struct V ...)}. But where does @code{V} itself come from? One possibility is that @code{V} is an instance of a user-defined vtable type, @code{V'}, so that @code{V} is created by using @code{(make-struct V' ...)}. Another possibility is that @code{V} is an instance of the type it itself describes. Vtable structures of the second sort are created by this procedure: @deffn {Scheme Procedure} make-vtable-vtable user_fields tail_array_size . init @deffnx {C Function} scm_make_vtable_vtable (user_fields, tail_array_size, init) Return a new, self-describing vtable structure. @var{user-fields} is a string describing user defined fields of the vtable beginning at index @code{vtable-offset-user} (see @code{make-struct-layout}). @var{tail-size} specifies the size of the tail-array (if any) of this vtable. @var{init1}, @dots{} are the optional initializers for the fields of the vtable. Vtables have one initializable system field---the struct printer. This field comes before the user fields in the initializers passed to @code{make-vtable-vtable} and @code{make-struct}, and thus works as a third optional argument to @code{make-vtable-vtable} and a fourth to @code{make-struct} when creating vtables: If the value is a procedure, it will be called instead of the standard printer whenever a struct described by this vtable is printed. The procedure will be called with arguments STRUCT and PORT. The structure of a struct is described by a vtable, so the vtable is in essence the type of the struct. The vtable is itself a struct with a vtable. This could go on forever if it weren't for the vtable-vtables which are self-describing vtables, and thus terminate the chain. There are several potential ways of using structs, but the standard one is to use three kinds of structs, together building up a type sub-system: one vtable-vtable working as the root and one or several "types", each with a set of "instances". (The vtable-vtable should be compared to the class which is the class of itself.) @lisp (define ball-root (make-vtable-vtable "pr" 0)) (define (make-ball-type ball-color) (make-struct ball-root 0 (make-struct-layout "pw") (lambda (ball port) (format port "#" (color ball) (owner ball))) ball-color)) (define (color ball) (struct-ref (struct-vtable ball) vtable-offset-user)) (define (owner ball) (struct-ref ball 0)) (define red (make-ball-type 'red)) (define green (make-ball-type 'green)) (define (make-ball type owner) (make-struct type 0 owner)) (define ball (make-ball green 'Nisse)) ball @result{} # @end lisp @end deffn @deffn {Scheme Procedure} struct-vtable-name vtable @deffnx {C Function} scm_struct_vtable_name (vtable) Return the name of the vtable @var{vtable}. @end deffn @deffn {Scheme Procedure} set-struct-vtable-name! vtable name @deffnx {C Function} scm_set_struct_vtable_name_x (vtable, name) Set the name of the vtable @var{vtable} to @var{name}. @end deffn @deffn {Scheme Procedure} struct-vtable-tag handle @deffnx {C Function} scm_struct_vtable_tag (handle) Return the vtable tag of the structure @var{handle}. @end deffn @node Dictionary Types @subsection Dictionary Types A @dfn{dictionary} object is a data structure used to index information in a user-defined way. In standard Scheme, the main aggregate data types are lists and vectors. Lists are not really indexed at all, and vectors are indexed only by number (e.g. @code{(vector-ref foo 5)}). Often you will find it useful to index your data on some other type; for example, in a library catalog you might want to look up a book by the name of its author. Dictionaries are used to help you organize information in such a way. An @dfn{association list} (or @dfn{alist} for short) is a list of key-value pairs. Each pair represents a single quantity or object; the @code{car} of the pair is a key which is used to identify the object, and the @code{cdr} is the object's value. A @dfn{hash table} also permits you to index objects with arbitrary keys, but in a way that makes looking up any one object extremely fast. A well-designed hash system makes hash table lookups almost as fast as conventional array or vector references. Alists are popular among Lisp programmers because they use only the language's primitive operations (lists, @dfn{car}, @dfn{cdr} and the equality primitives). No changes to the language core are necessary. Therefore, with Scheme's built-in list manipulation facilities, it is very convenient to handle data stored in an association list. Also, alists are highly portable and can be easily implemented on even the most minimal Lisp systems. However, alists are inefficient, especially for storing large quantities of data. Because we want Guile to be useful for large software systems as well as small ones, Guile provides a rich set of tools for using either association lists or hash tables. @node Association Lists @subsection Association Lists @tpindex Association Lists @tpindex Alist @cindex association List @cindex alist @cindex aatabase An association list is a conventional data structure that is often used to implement simple key-value databases. It consists of a list of entries in which each entry is a pair. The @dfn{key} of each entry is the @code{car} of the pair and the @dfn{value} of each entry is the @code{cdr}. @example ASSOCIATION LIST ::= '( (KEY1 . VALUE1) (KEY2 . VALUE2) (KEY3 . VALUE3) @dots{} ) @end example @noindent Association lists are also known, for short, as @dfn{alists}. The structure of an association list is just one example of the infinite number of possible structures that can be built using pairs and lists. As such, the keys and values in an association list can be manipulated using the general list structure procedures @code{cons}, @code{car}, @code{cdr}, @code{set-car!}, @code{set-cdr!} and so on. However, because association lists are so useful, Guile also provides specific procedures for manipulating them. @menu * Alist Key Equality:: * Adding or Setting Alist Entries:: * Retrieving Alist Entries:: * Removing Alist Entries:: * Sloppy Alist Functions:: * Alist Example:: @end menu @node Alist Key Equality @subsubsection Alist Key Equality All of Guile's dedicated association list procedures, apart from @code{acons}, come in three flavours, depending on the level of equality that is required to decide whether an existing key in the association list is the same as the key that the procedure call uses to identify the required entry. @itemize @bullet @item Procedures with @dfn{assq} in their name use @code{eq?} to determine key equality. @item Procedures with @dfn{assv} in their name use @code{eqv?} to determine key equality. @item Procedures with @dfn{assoc} in their name use @code{equal?} to determine key equality. @end itemize @code{acons} is an exception because it is used to build association lists which do not require their entries' keys to be unique. @node Adding or Setting Alist Entries @subsubsection Adding or Setting Alist Entries @code{acons} adds a new entry to an association list and returns the combined association list. The combined alist is formed by consing the new entry onto the head of the alist specified in the @code{acons} procedure call. So the specified alist is not modified, but its contents become shared with the tail of the combined alist that @code{acons} returns. In the most common usage of @code{acons}, a variable holding the original association list is updated with the combined alist: @example (set! address-list (acons name address address-list)) @end example In such cases, it doesn't matter that the old and new values of @code{address-list} share some of their contents, since the old value is usually no longer independently accessible. Note that @code{acons} adds the specified new entry regardless of whether the alist may already contain entries with keys that are, in some sense, the same as that of the new entry. Thus @code{acons} is ideal for building alists where there is no concept of key uniqueness. @example (set! task-list (acons 3 "pay gas bill" '())) task-list @result{} ((3 . "pay gas bill")) (set! task-list (acons 3 "tidy bedroom" task-list)) task-list @result{} ((3 . "tidy bedroom") (3 . "pay gas bill")) @end example @code{assq-set!}, @code{assv-set!} and @code{assoc-set!} are used to add or replace an entry in an association list where there @emph{is} a concept of key uniqueness. If the specified association list already contains an entry whose key is the same as that specified in the procedure call, the existing entry is replaced by the new one. Otherwise, the new entry is consed onto the head of the old association list to create the combined alist. In all cases, these procedures return the combined alist. @code{assq-set!} and friends @emph{may} destructively modify the structure of the old association list in such a way that an existing variable is correctly updated without having to @code{set!} it to the value returned: @example address-list @result{} (("mary" . "34 Elm Road") ("james" . "16 Bow Street")) (assoc-set! address-list "james" "1a London Road") @result{} (("mary" . "34 Elm Road") ("james" . "1a London Road")) address-list @result{} (("mary" . "34 Elm Road") ("james" . "1a London Road")) @end example Or they may not: @example (assoc-set! address-list "bob" "11 Newington Avenue") @result{} (("bob" . "11 Newington Avenue") ("mary" . "34 Elm Road") ("james" . "1a London Road")) address-list @result{} (("mary" . "34 Elm Road") ("james" . "1a London Road")) @end example The only safe way to update an association list variable when adding or replacing an entry like this is to @code{set!} the variable to the returned value: @example (set! address-list (assoc-set! address-list "bob" "11 Newington Avenue")) address-list @result{} (("bob" . "11 Newington Avenue") ("mary" . "34 Elm Road") ("james" . "1a London Road")) @end example Because of this slight inconvenience, you may find it more convenient to use hash tables to store dictionary data. If your application will not be modifying the contents of an alist very often, this may not make much difference to you. If you need to keep the old value of an association list in a form independent from the list that results from modification by @code{acons}, @code{assq-set!}, @code{assv-set!} or @code{assoc-set!}, use @code{list-copy} to copy the old association list before modifying it. @deffn {Scheme Procedure} acons key value alist @deffnx {C Function} scm_acons (key, value, alist) Add a new key-value pair to @var{alist}. A new pair is created whose car is @var{key} and whose cdr is @var{value}, and the pair is consed onto @var{alist}, and the new list is returned. This function is @emph{not} destructive; @var{alist} is not modified. @end deffn @deffn {Scheme Procedure} assq-set! alist key val @deffnx {Scheme Procedure} assv-set! alist key value @deffnx {Scheme Procedure} assoc-set! alist key value @deffnx {C Function} scm_assq_set_x (alist, key, val) @deffnx {C Function} scm_assv_set_x (alist, key, val) @deffnx {C Function} scm_assoc_set_x (alist, key, val) Reassociate @var{key} in @var{alist} with @var{value}: find any existing @var{alist} entry for @var{key} and associate it with the new @var{value}. If @var{alist} does not contain an entry for @var{key}, add a new one. Return the (possibly new) alist. These functions do not attempt to verify the structure of @var{alist}, and so may cause unusual results if passed an object that is not an association list. @end deffn @node Retrieving Alist Entries @subsubsection Retrieving Alist Entries @rnindex assq @rnindex assv @rnindex assoc @code{assq}, @code{assv} and @code{assoc} take an alist and a key as arguments and return the entry for that key if an entry exists, or @code{#f} if there is no entry for that key. Note that, in the cases where an entry exists, these procedures return the complete entry, that is @code{(KEY . VALUE)}, not just the value. @deffn {Scheme Procedure} assq key alist @deffnx {Scheme Procedure} assv key alist @deffnx {Scheme Procedure} assoc key alist @deffnx {C Function} scm_assq (key, alist) @deffnx {C Function} scm_assv (key, alist) @deffnx {C Function} scm_assoc (key, alist) Fetch the entry in @var{alist} that is associated with @var{key}. To decide whether the argument @var{key} matches a particular entry in @var{alist}, @code{assq} compares keys with @code{eq?}, @code{assv} uses @code{eqv?} and @code{assoc} uses @code{equal?}. If @var{key} cannot be found in @var{alist} (according to whichever equality predicate is in use), then return @code{#f}. These functions return the entire alist entry found (i.e. both the key and the value). @end deffn @code{assq-ref}, @code{assv-ref} and @code{assoc-ref}, on the other hand, take an alist and a key and return @emph{just the value} for that key, if an entry exists. If there is no entry for the specified key, these procedures return @code{#f}. This creates an ambiguity: if the return value is @code{#f}, it means either that there is no entry with the specified key, or that there @emph{is} an entry for the specified key, with value @code{#f}. Consequently, @code{assq-ref} and friends should only be used where it is known that an entry exists, or where the ambiguity doesn't matter for some other reason. @deffn {Scheme Procedure} assq-ref alist key @deffnx {Scheme Procedure} assv-ref alist key @deffnx {Scheme Procedure} assoc-ref alist key @deffnx {C Function} scm_assq_ref (alist, key) @deffnx {C Function} scm_assv_ref (alist, key) @deffnx {C Function} scm_assoc_ref (alist, key) Like @code{assq}, @code{assv} and @code{assoc}, except that only the value associated with @var{key} in @var{alist} is returned. These functions are equivalent to @lisp (let ((ent (@var{associator} @var{key} @var{alist}))) (and ent (cdr ent))) @end lisp where @var{associator} is one of @code{assq}, @code{assv} or @code{assoc}. @end deffn @node Removing Alist Entries @subsubsection Removing Alist Entries To remove the element from an association list whose key matches a specified key, use @code{assq-remove!}, @code{assv-remove!} or @code{assoc-remove!} (depending, as usual, on the level of equality required between the key that you specify and the keys in the association list). As with @code{assq-set!} and friends, the specified alist may or may not be modified destructively, and the only safe way to update a variable containing the alist is to @code{set!} it to the value that @code{assq-remove!} and friends return. @example address-list @result{} (("bob" . "11 Newington Avenue") ("mary" . "34 Elm Road") ("james" . "1a London Road")) (set! address-list (assoc-remove! address-list "mary")) address-list @result{} (("bob" . "11 Newington Avenue") ("james" . "1a London Road")) @end example Note that, when @code{assq/v/oc-remove!} is used to modify an association list that has been constructed only using the corresponding @code{assq/v/oc-set!}, there can be at most one matching entry in the alist, so the question of multiple entries being removed in one go does not arise. If @code{assq/v/oc-remove!} is applied to an association list that has been constructed using @code{acons}, or an @code{assq/v/oc-set!} with a different level of equality, or any mixture of these, it removes only the first matching entry from the alist, even if the alist might contain further matching entries. For example: @example (define address-list '()) (set! address-list (assq-set! address-list "mary" "11 Elm Street")) (set! address-list (assq-set! address-list "mary" "57 Pine Drive")) address-list @result{} (("mary" . "57 Pine Drive") ("mary" . "11 Elm Street")) (set! address-list (assoc-remove! address-list "mary")) address-list @result{} (("mary" . "11 Elm Street")) @end example In this example, the two instances of the string "mary" are not the same when compared using @code{eq?}, so the two @code{assq-set!} calls add two distinct entries to @code{address-list}. When compared using @code{equal?}, both "mary"s in @code{address-list} are the same as the "mary" in the @code{assoc-remove!} call, but @code{assoc-remove!} stops after removing the first matching entry that it finds, and so one of the "mary" entries is left in place. @deffn {Scheme Procedure} assq-remove! alist key @deffnx {Scheme Procedure} assv-remove! alist key @deffnx {Scheme Procedure} assoc-remove! alist key @deffnx {C Function} scm_assq_remove_x (alist, key) @deffnx {C Function} scm_assv_remove_x (alist, key) @deffnx {C Function} scm_assoc_remove_x (alist, key) Delete the first entry in @var{alist} associated with @var{key}, and return the resulting alist. @end deffn @node Sloppy Alist Functions @subsubsection Sloppy Alist Functions @code{sloppy-assq}, @code{sloppy-assv} and @code{sloppy-assoc} behave like the corresponding non-@code{sloppy-} procedures, except that they return @code{#f} when the specified association list is not well-formed, where the non-@code{sloppy-} versions would signal an error. Specifically, there are two conditions for which the non-@code{sloppy-} procedures signal an error, which the @code{sloppy-} procedures handle instead by returning @code{#f}. Firstly, if the specified alist as a whole is not a proper list: @example (assoc "mary" '((1 . 2) ("key" . "door") . "open sesame")) @result{} ERROR: In procedure assoc in expression (assoc "mary" (quote #)): ERROR: Wrong type argument in position 2 (expecting association list): ((1 . 2) ("key" . "door") . "open sesame") (sloppy-assoc "mary" '((1 . 2) ("key" . "door") . "open sesame")) @result{} #f @end example @noindent Secondly, if one of the entries in the specified alist is not a pair: @example (assoc 2 '((1 . 1) 2 (3 . 9))) @result{} ERROR: In procedure assoc in expression (assoc 2 (quote #)): ERROR: Wrong type argument in position 2 (expecting association list): ((1 . 1) 2 (3 . 9)) (sloppy-assoc 2 '((1 . 1) 2 (3 . 9))) @result{} #f @end example Unless you are explicitly working with badly formed association lists, it is much safer to use the non-@code{sloppy-} procedures, because they help to highlight coding and data errors that the @code{sloppy-} versions would silently cover up. @deffn {Scheme Procedure} sloppy-assq key alist @deffnx {C Function} scm_sloppy_assq (key, alist) Behaves like @code{assq} but does not do any error checking. Recommended only for use in Guile internals. @end deffn @deffn {Scheme Procedure} sloppy-assv key alist @deffnx {C Function} scm_sloppy_assv (key, alist) Behaves like @code{assv} but does not do any error checking. Recommended only for use in Guile internals. @end deffn @deffn {Scheme Procedure} sloppy-assoc key alist @deffnx {C Function} scm_sloppy_assoc (key, alist) Behaves like @code{assoc} but does not do any error checking. Recommended only for use in Guile internals. @end deffn @node Alist Example @subsubsection Alist Example Here is a longer example of how alists may be used in practice. @lisp (define capitals '(("New York" . "Albany") ("Oregon" . "Salem") ("Florida" . "Miami"))) ;; What's the capital of Oregon? (assoc "Oregon" capitals) @result{} ("Oregon" . "Salem") (assoc-ref capitals "Oregon") @result{} "Salem" ;; We left out South Dakota. (set! capitals (assoc-set! capitals "South Dakota" "Pierre")) capitals @result{} (("South Dakota" . "Pierre") ("New York" . "Albany") ("Oregon" . "Salem") ("Florida" . "Miami")) ;; And we got Florida wrong. (set! capitals (assoc-set! capitals "Florida" "Tallahassee")) capitals @result{} (("South Dakota" . "Pierre") ("New York" . "Albany") ("Oregon" . "Salem") ("Florida" . "Tallahassee")) ;; After Oregon secedes, we can remove it. (set! capitals (assoc-remove! capitals "Oregon")) capitals @result{} (("South Dakota" . "Pierre") ("New York" . "Albany") ("Florida" . "Tallahassee")) @end lisp @node Hash Tables @subsection Hash Tables @tpindex Hash Tables @c FIXME::martin: Review me! Hash tables are dictionaries which offer similar functionality as association lists: They provide a mapping from keys to values. The difference is that association lists need time linear in the size of elements when searching for entries, whereas hash tables can normally search in constant time. The drawback is that hash tables require a little bit more memory, and that you can not use the normal list procedures (@pxref{Lists}) for working with them. @menu * Hash Table Examples:: Demonstration of hash table usage. * Hash Table Reference:: Hash table procedure descriptions. @end menu @node Hash Table Examples @subsubsection Hash Table Examples @c FIXME::martin: Review me! For demonstration purposes, this section gives a few usage examples of some hash table procedures, together with some explanation what they do. First we start by creating a new hash table with 31 slots, and populate it with two key/value pairs. @lisp (define h (make-hash-table 31)) (hashq-create-handle! h 'foo "bar") @result{} (foo . "bar") (hashq-create-handle! h 'braz "zonk") @result{} (braz . "zonk") (hashq-create-handle! h 'frob #f) @result{} (frob . #f) @end lisp You can get the value for a given key with the procedure @code{hashq-ref}, but the problem with this procedure is that you cannot reliably determine whether a key does exists in the table. The reason is that the procedure returns @code{#f} if the key is not in the table, but it will return the same value if the key is in the table and just happens to have the value @code{#f}, as you can see in the following examples. @lisp (hashq-ref h 'foo) @result{} "bar" (hashq-ref h 'frob) @result{} #f (hashq-ref h 'not-there) @result{} #f @end lisp Better is to use the procedure @code{hashq-get-handle}, which makes a distinction between the two cases. Just like @code{assq}, this procedure returns a key/value-pair on success, and @code{#f} if the key is not found. @lisp (hashq-get-handle h 'foo) @result{} (foo . "bar") (hashq-get-handle h 'not-there) @result{} #f @end lisp There is no procedure for calculating the number of key/value-pairs in a hash table, but @code{hash-fold} can be used for doing exactly that. @lisp (hash-fold (lambda (key value seed) (+ 1 seed)) 0 h) @result{} 3 @end lisp @node Hash Table Reference @subsubsection Hash Table Reference @c FIXME: Describe in broad terms what happens for resizing, and what @c the initial size means for this. Like the association list functions, the hash table functions come in several varieties, according to the equality test used for the keys. Plain @code{hash-} functions use @code{equal?}, @code{hashq-} functions use @code{eq?}, @code{hashv-} functions use @code{eqv?}, and the @code{hashx-} functions use an application supplied test. A single @code{make-hash-table} creates a hash table suitable for use with any set of functions, but it's imperative that just one set is then used consistently, or results will be unpredictable. @sp 1 Hash tables are implemented as a vector indexed by a hash value formed from the key, with an association list of key/value pairs for each bucket in case distinct keys hash together. Direct access to the pairs in those lists is provided by the @code{-handle-} functions. When the number of table entries goes above a threshold the vector is increased and the entries rehashed, to prevent the bucket lists becoming too long and slowing down accesses. When the number of entries goes below a threshold the vector is decreased to save space. @sp 1 For the @code{hashx-} ``extended'' routines, an application supplies a @var{hash} function producing an integer index like @code{hashq} etc below, and an @var{assoc} alist search function like @code{assq} etc (@pxref{Retrieving Alist Entries}). Here's an example of such functions implementing case-insensitive hashing of string keys, @example (use-modules (srfi srfi-1) (srfi srfi-13)) (define (my-hash str size) (remainder (string-hash-ci str) size)) (define (my-assoc str alist) (find (lambda (pair) (string-ci=? str (car pair))) alist)) (define my-table (make-hash-table)) (hashx-set! my-hash my-assoc my-table "foo" 123) (hashx-ref my-hash my-assoc my-table "FOO") @result{} 123 @end example In a @code{hashx-} @var{hash} function the aim is to spread keys across the vector, so bucket lists don't become long. But the actual values are arbitrary as long as they're in the range 0 to @math{@var{size}-1}. Helpful functions for forming a hash value, in addition to @code{hashq} etc below, include @code{symbol-hash} (@pxref{Symbol Keys}), @code{string-hash} and @code{string-hash-ci} (@pxref{String Comparison}), and @code{char-set-hash} (@pxref{Character Set Predicates/Comparison}). Note that currently, unfortunately, there's no @code{hashx-remove!} function, which rather limits the usefulness of the @code{hashx-} routines. @sp 1 @deffn {Scheme Procedure} make-hash-table [size] Create a new hash table, with an optional minimum vector @var{size}. When @var{size} is given, the table vector will still grow and shrink automatically, as described above, but with @var{size} as a minimum. If an application knows roughly how many entries the table will hold then it can use @var{size} to avoid rehashing when initial entries are added. @end deffn @deffn {Scheme Procedure} hash-table? obj @deffnx {C Function} scm_hash_table_p (obj) Return @code{#t} if @var{obj} is a hash table. @end deffn @deffn {Scheme Procedure} hash-clear! table @deffnx {C Function} scm_hash_clear_x (table) Remove all items from TABLE (without triggering a resize). @end deffn @deffn {Scheme Procedure} hash-ref table key [dflt] @deffnx {Scheme Procedure} hashq-ref table key [dflt] @deffnx {Scheme Procedure} hashv-ref table key [dflt] @deffnx {Scheme Procedure} hashx-ref hash assoc table key [dflt] @deffnx {C Function} scm_hash_ref (table, key, dflt) @deffnx {C Function} scm_hashq_ref (table, key, dflt) @deffnx {C Function} scm_hashv_ref (table, key, dflt) @deffnx {C Function} scm_hashx_ref (hash, assoc, table, key, dflt) Lookup @var{key} in the given hash @var{table}, and return the associated value. If @var{key} is not found, return @var{dflt}, or @code{#f} if @var{dflt} is not given. @end deffn @deffn {Scheme Procedure} hash-set! table key val @deffnx {Scheme Procedure} hashq-set! table key val @deffnx {Scheme Procedure} hashv-set! table key val @deffnx {Scheme Procedure} hashx-set! hash assoc table key val @deffnx {C Function} scm_hash_set_x (table, key, val) @deffnx {C Function} scm_hashq_set_x (table, key, val) @deffnx {C Function} scm_hashv_set_x (table, key, val) @deffnx {C Function} scm_hashx_set_x (hash, assoc, table, key, val) Associate @var{val} with @var{key} in the given hash @var{table}. If @var{key} is already present then it's associated value is changed. If it's not present then a new entry is created. @end deffn @deffn {Scheme Procedure} hash-remove! table key @deffnx {Scheme Procedure} hashq-remove! table key @deffnx {Scheme Procedure} hashv-remove! table key @deffnx {C Function} scm_hash_remove_x (table, key) @deffnx {C Function} scm_hashq_remove_x (table, key) @deffnx {C Function} scm_hashv_remove_x (table, key) Remove any association for @var{key} in the given hash @var{table}. If @var{key} is not in @var{table} then nothing is done. @end deffn @deffn {Scheme Procedure} hash key size @deffnx {Scheme Procedure} hashq key size @deffnx {Scheme Procedure} hashv key size @deffnx {C Function} scm_hash (key, size) @deffnx {C Function} scm_hashq (key, size) @deffnx {C Function} scm_hashv (key, size) Return a hash value for @var{key}. This is a number in the range @math{0} to @math{@var{size}-1}, which is suitable for use in a hash table of the given @var{size}. Note that @code{hashq} and @code{hashv} may use internal addresses of objects, so if an object is garbage collected and re-created it can have a different hash value, even when the two are notionally @code{eq?}. For instance with symbols, @example (hashq 'something 123) @result{} 19 (gc) (hashq 'something 123) @result{} 62 @end example In normal use this is not a problem, since an object entered into a hash table won't be garbage collected until removed. It's only if hashing calculations are somehow separated from normal references that its lifetime needs to be considered. @end deffn @deffn {Scheme Procedure} hash-get-handle table key @deffnx {Scheme Procedure} hashq-get-handle table key @deffnx {Scheme Procedure} hashv-get-handle table key @deffnx {Scheme Procedure} hashx-get-handle hash assoc table key @deffnx {C Function} scm_hash_get_handle (table, key) @deffnx {C Function} scm_hashq_get_handle (table, key) @deffnx {C Function} scm_hashv_get_handle (table, key) @deffnx {C Function} scm_hashx_get_handle (hash, assoc, table, key) Return the @code{(@var{key} . @var{value})} pair for @var{key} in the given hash @var{table}, or @code{#f} if @var{key} is not in @var{table}. @end deffn @deffn {Scheme Procedure} hash-create-handle! table key init @deffnx {Scheme Procedure} hashq-create-handle! table key init @deffnx {Scheme Procedure} hashv-create-handle! table key init @deffnx {Scheme Procedure} hashx-create-handle! hash assoc table key init @deffnx {C Function} scm_hash_create_handle_x (table, key, init) @deffnx {C Function} scm_hashq_create_handle_x (table, key, init) @deffnx {C Function} scm_hashv_create_handle_x (table, key, init) @deffnx {C Function} scm_hashx_create_handle_x (hash, assoc, table, key, init) Return the @code{(@var{key} . @var{value})} pair for @var{key} in the given hash @var{table}. If @var{key} is not in @var{table} then create an entry for it with @var{init} as the value, and return that pair. @end deffn @deffn {Scheme Procedure} hash-map->list proc table @deffnx {Scheme Procedure} hash-for-each proc table @deffnx {C Function} scm_hash_map_to_list (proc, table) @deffnx {C Function} scm_hash_for_each (proc, table) Apply @var{proc} to the entries in the given hash @var{table}. Each call is @code{(@var{proc} @var{key} @var{value})}. @code{hash-map->list} returns a list of the results from these calls, @code{hash-for-each} discards the results and returns an unspecified value. Calls are made over the table entries in an unspecified order, and for @code{hash-map->list} the order of the values in the returned list is unspecified. Results will be unpredictable if @var{table} is modified while iterating. For example the following returns a new alist comprising all the entries from @code{mytable}, in no particular order. @example (hash-map->list cons mytable) @end example @end deffn @deffn {Scheme Procedure} hash-for-each-handle proc table @deffnx {C Function} scm_hash_for_each_handle (proc, table) Apply @var{proc} to the entries in the given hash @var{table}. Each call is @code{(@var{proc} @var{handle})}, where @var{handle} is a @code{(@var{key} . @var{value})} pair. Return an unspecified value. @code{hash-for-each-handle} differs from @code{hash-for-each} only in the argument list of @var{proc}. @end deffn @deffn {Scheme Procedure} hash-fold proc init table @deffnx {C Function} scm_hash_fold (proc, init, table) Accumulate a result by applying @var{proc} to the elements of the given hash @var{table}. Each call is @code{(@var{proc} @var{key} @var{value} @var{prior-result})}, where @var{key} and @var{value} are from the @var{table} and @var{prior-result} is the return from the previous @var{proc} call. For the first call, @var{prior-result} is the given @var{init} value. Calls are made over the table entries in an unspecified order. Results will be unpredictable if @var{table} is modified while @code{hash-fold} is running. For example, the following returns a count of how many keys in @code{mytable} are strings. @example (hash-fold (lambda (key value prior) (if (string? key) (1+ prior) prior)) 0 mytable) @end example @end deffn @c Local Variables: @c TeX-master: "guile.texi" @c End: