R5RS Scheme has an impoverished set of list-processing utilities, which is a problem for authors of portable code. This SRFI proposes a coherent and comprehensive set of list-processing procedures; it is accompanied by a reference implementation of the spec. The reference implementation is
The set of basic list and pair operations provided by R4RS/R5RS Scheme is far from satisfactory. Because this set is so small and basic, most implementations provide additional utilities, such as a list-filtering function, or a "left fold" operator, and so forth. But, of course, this introduces incompatibilities -- different Scheme implementations provide different sets of procedures.
I have designed a full-featured library of procedures for list processing. While putting this library together, I checked as many Schemes as I could get my hands on. (I have a fair amount of experience with several of these already.) I missed Chez -- no on-line manual that I can find -- but I hit most of the other big, full-featured Schemes. The complete list of list-processing systems I checked is:
As a result, the library I am proposing is fairly rich.
Following this initial design phase, this library went through several months of discussion on the SRFI mailing lists, and was altered in light of the ideas and suggestions put forth during this discussion.
In parallel with designing this API, I have also written a reference implementation. I have placed this source on the Net with an unencumbered, "open" copyright. A few notes about the reference implementation:
error
procedure;
values
and a simple receive
macro for producing
and consuming multiple return values;
:optional
and let-optionals
macros for optional
argument parsing and defaulting;
check-arg
procedure for argument checking.
filter!
avoid unnecessary,
redundant set-cdr!
s which would thrash a generational GC's write barrier
and the store buffers of fast processors. Functions reuse longest common
tails from input parameters to construct their results where
possible. Constant-space iterations are used in preference to recursions;
local recursions are used in preference to consing temporary intermediate
data structures.
This is not to say that the implementation can't be tuned up for a specific Scheme implementation. There are notes in comments addressing ways implementors can tune the reference implementation for performance.
In short, I've written the reference implementation to make it as painless as possible for an implementor -- or a regular programmer -- to adopt this library and get good results with it.
Here is a short list of the procedures provided by the list-lib package. R5RS procedures are shown in bold; extended R5RS procedures, in bold italic.
cons list xcons cons* make-list list-tabulate list-copy circular-list iota
pair? null? proper-list? circular-list? dotted-list? not-pair? null-list? list=
car cdr ... cddadr cddddr list-ref first second third fourth fifth sixth seventh eighth ninth tenth car+cdr take drop take-right drop-right take! drop-right! split-at split-at! last last-pair
length length+ append concatenate reverse append! concatenate! reverse! append-reverse append-reverse! zip unzip1 unzip2 unzip3 unzip4 unzip5 count
map for-each fold unfold pair-fold reduce fold-right unfold-right pair-fold-right reduce-right append-map append-map! map! pair-for-each filter-map map-in-order
filter partition remove filter! partition! remove!
member memq memv find find-tail any every list-index take-while drop-while take-while! span break span! break!
delete delete-duplicates delete! delete-duplicates!
assoc assq assv alist-cons alist-copy alist-delete alist-delete!
lset<= lset= lset-adjoin lset-union lset-union! lset-intersection lset-intersection! lset-difference lset-difference! lset-xor lset-xor! lset-diff+intersection lset-diff+intersection!
set-car! set-cdr!
Four R4RS/R5RS list-processing procedures are extended by this library in backwards-compatible ways:
map for-each
| (Extended to take lists of unequal length) |
member assoc
| (Extended to take an optional comparison procedure.) |
The following R4RS/R5RS list- and pair-processing procedures are also part of list-lib's exports, as defined by the R5RS:
cons pair? null? car cdr ... cdddar cddddr set-car! set-cdr! list append reverse length list-ref memq memv assq assv
The remaining two R4RS/R5RS list-processing procedures are not part of this library:
list-tail
| (renamed drop )
|
list?
| (see proper-list? ,
circular-list? and
dotted-list? )
|
A set of general criteria guided the design of this library.
I don't require "destructive" (what I call "linear update") procedures to alter and recycle cons cells from the argument lists. They are allowed to, but not required to. (And the reference implementations I have written do recycle the argument lists.)
List-filtering procedures such as filter
or delete
do not disorder
lists. Elements appear in the answer list in the same order as they appear in
the argument list. This constrains implementation, but seems like a desirable
feature, since in many uses of lists, order matters. (In particular,
disordering an alist is definitely a bad idea.)
Contrariwise, although the reference implementations of the list-filtering procedures share longest common tails between argument and answer lists, it not is part of the spec.
Because lists are an inherently sequential data structure (unlike, say,
vectors), list-inspection functions such as find
, find-tail
, for-each
, any
and every
commit to a left-to-right traversal order of their argument list.
However, constructor functions, such as
and the mapping
procedures (list-tabulate
append-map
, append-map!
, map!
, pair-for-each
, filter-map
,
map-in-order
), do not specify the dynamic order in which their procedural
argument is applied to its various values.
Predicates return useful true values wherever possible. Thus any
must return
the true value produced by its predicate, and every
returns the final true
value produced by applying its predicate argument to the last element of its
argument list.
Functionality is provided both in pure and linear-update (potentially destructive) forms wherever this makes sense.
No special status accorded Scheme's built-in equality functions.
Any functionality provided in terms of eq?
, eqv?
, equal?
is also
available using a client-provided equality function.
Proper design counts for more than backwards compatibility, but I have tried, ceteris paribus, to be as backwards-compatible as possible with existing list-processing libraries, in order to facilitate porting old code to run as a client of the procedures in this library. Name choices and semantics are, for the most part, in agreement with existing practice in many current Scheme systems. I have indicated some incompatibilities in the following text.
These procedures are not "sequence generic" -- i.e., procedures that operate on either vectors and lists. They are list-specific. I prefer to keep the library simple and focussed.
I have named these procedures without a qualifying initial "list-" lexeme,
which is in keeping with the existing set of list-processing utilities in
Scheme.
I follow the general Scheme convention (vector-length, string-ref) of
placing the type-name before the action when naming procedures -- so
we have list-copy
and pair-for-each
rather than the perhaps
more fluid, but less consistent, copy-list
or for-each-pair
.
I have generally followed a regular and consistent naming scheme, composing procedure names from a set of basic lexemes.
Many procedures in this library have "pure" and "linear update" variants. A
"pure" procedure has no side-effects, and in particular does not alter its
arguments in any way. A "linear update" procedure is allowed -- but not
required -- to side-effect its arguments in order to construct its
result. "Linear update" procedures are typically given names ending with an
exclamation point. So, for example, (append! list1 list2)
is allowed to
construct its result by simply using set-cdr!
to set the cdr of the last pair
of list1 to point to list2, and then returning list1 (unless list1 is the
empty list, in which case it would simply return list2). However, append!
may
also elect to perform a pure append operation -- this is a legal definition
of append!
:
(define append! append)
This is why we do not call these procedures "destructive" -- because they aren't required to be destructive. They are potentially destructive.
What this means is that you may only apply linear-update procedures to values that you know are "dead" -- values that will never be used again in your program. This must be so, since you can't rely on the value passed to a linear-update procedure after that procedure has been called. It might be unchanged; it might be altered.
The "linear" in "linear update" doesn't mean "linear time" or "linear space" or any sort of multiple-of-n kind of meaning. It's a fancy term that type theorists and pure functional programmers use to describe systems where you are only allowed to have exactly one reference to each variable. This provides a guarantee that the value bound to a variable is bound to no other variable. So when you use a variable in a variable reference, you "use it up." Knowing that no one else has a pointer to that value means the a system primitive is free to side-effect its arguments to produce what is, observationally, a pure-functional result.
In the context of this library, "linear update" means you, the programmer, know there are no other live references to the value passed to the procedure -- after passing the value to one of these procedures, the value of the old pointer is indeterminate. Basically, you are licensing the Scheme implementation to alter the data structure if it feels like it -- you have declared you don't care either way.
You get no help from Scheme in checking that the values you claim are "linear" really are. So you better get it right. Or play it safe and use the non-! procedures -- it doesn't do any good to compute quickly if you get the wrong answer.
Why go to all this trouble to define the notion of "linear update" and use it in a procedure spec, instead of the more common notion of a "destructive" operation? First, note that destructive list-processing procedures are almost always used in a linear-update fashion. This is in part required by the special case of operating upon the empty list, which can't be side-effected. This means that destructive operators are not pure side-effects -- they have to return a result. Second, note that code written using linear-update operators can be trivially ported to a pure, functional subset of Scheme by simply providing pure implementations of the linear-update operators. Finally, requiring destructive side-effects ruins opportunities to parallelise these operations -- and the places where one has taken the trouble to spell out destructive operations are usually exactly the code one would want a parallelising compiler to parallelise: the efficiency-critical kernels of the algorithm. Linear-update operations are easily parallelised. Going with a linear-update spec doesn't close off these valuable alternative implementation techniques. This list library is intended as a set of low-level, basic operators, so we don't want to exclude these possible implementations.
The linear-update procedures in this library are
take! drop-right! split-at!
append! concatenate! reverse! append-reverse!
append-map! map!
filter! partition! remove!
take-while! span! break!
delete! alist-delete! delete-duplicates!
lset-adjoin! lset-union! lset-intersection!
lset-difference! lset-xor! lset-diff+intersection!
Scheme does not properly have a list type, just as C does not have a string type. Rather, Scheme has a binary-tuple type, from which one can build binary trees. There is an interpretation of Scheme values that allows one to treat these trees as lists. Further complications ensue from the fact that Scheme allows side-effects to these tuples, raising the possibility of lists of unbounded length, and trees of unbounded depth (that is, circular data structures).
However, there is a simple view of the world of Scheme values that considers every value to be a list of some sort. that is, every value is either
(a b c)
()
(32)
(a b c . d)
(x . y)
42
george
Note that the zero-length dotted lists are simply all the non-null, non-pair values.
This view is captured by the predicates proper-list?
, dotted-list?
, and
circular-list?
. List-lib users should note that dotted lists are not commonly
used, and are considered by many Scheme programmers to be an ugly artifact of
Scheme's lack of a true list type. However, dotted lists do play a noticeable
role in the syntax of Scheme, in the "rest" parameters used by n-ary
lambdas: (lambda (x y . rest) ...)
.
Dotted lists are not fully supported by list-lib. Most procedures are defined only on proper lists -- that is, finite, nil-terminated lists. The procedures that will also handle circular or dotted lists are specifically marked. While this design decision restricts the domain of possible arguments one can pass to these procedures, it has the benefit of allowing the procedures to catch the error cases where programmers inadvertently pass scalar values to a list procedure by accident, e.g., by switching the arguments to a procedure call.
Note that statements of the form "it is an error" merely mean "don't
do that." They are not a guarantee that a conforming implementation will
"catch" such improper use by, for example, raising some kind of exception.
Regrettably, R5RS Scheme requires no firmer guarantee even for basic operators such
as car
and cdr
, so there's little point in requiring these procedures to do
more. Here is the relevant section of the R5RS:
When speaking of an error situation, this report uses the phrase "an error is signalled" to indicate that implementations must detect and report the error. If such wording does not appear in the discussion of an error, then implementations are not required to detect or report the error, though they are encouraged to do so. An error situation that implementations are not required to detect is usually referred to simply as "an error."
For example, it is an error for a procedure to be passed an argument that the procedure is not explicitly specified to handle, even though such domain errors are seldom mentioned in this report. Implementations may extend a procedure's domain of definition to include such arguments.
The following items are not in this library:
They should have their own SRFI specs.
In a Scheme system that has a module or package system, these procedures should be contained in a module named "list-lib". The templates given below obey the following conventions for procedure formals:
list | A proper (finite, nil-terminated) list |
---|---|
clist | A proper or circular list |
flist | A finite (proper or dotted) list |
pair | A pair |
x, y, d, a | Any value |
object, value | Any value |
n, i | A natural number (an integer >= 0) |
proc | A procedure |
pred | A procedure whose return value is treated as a boolean |
= | A boolean procedure taking two arguments |
It is an error to pass a circular or dotted list to a procedure not defined to accept such an argument.
cons
a d -> pair
eqv?
)
from every existing object.
(cons 'a '()) => (a) (cons '(a) '(b c d)) => ((a) b c d) (cons "a" '(b c)) => ("a" b c) (cons 'a 3) => (a . 3) (cons '(a b) 'c) => ((a b) . c)
list
object ... -> list
(list 'a (+ 3 4) 'c) => (a 7 c) (list) => ()
xcons
d a -> pair
(lambda (d a) (cons a d))Of utility only as a value to be conveniently passed to higher-order procedures.
(xcons '(b c) 'a) => (a b c)The name stands for "eXchanged CONS."
cons*
elt1 elt2 ... -> object
list
,
but the last argument provides the tail of the constructed list,
returning
(cons elt1 (cons elt2 (cons ... eltn)))
list*
in Common Lisp and about
half of the Schemes that provide it,
and cons*
in the other half.
(cons* 1 2 3 4) => (1 2 3 . 4) (cons* 1) => 1
make-list
n [fill] -> list
(make-list 4 'c) => (c c c c)
list-tabulate
n init-proc -> list
(init-proc i)
. No guarantee is made about the dynamic
order in which init-proc is applied to these indices.
(list-tabulate 4 values) => (0 1 2 3)
list-copy
flist -> flist
circular-list
elt1 elt2 ... -> list
(circular-list 'z 'q) => (z q z q z q ...)
iota
count [start step] -> list
(start start+step ... start+(count-1)*step)The start and step parameters default to 0 and 1, respectively. This procedure takes its name from the APL primitive.
(iota 5) => (0 1 2 3 4) (iota 5 0 -0.1) => (0 -0.1 -0.2 -0.3 -0.4)
Note: the predicates proper-list?
, circular-list?
, and dotted-list?
partition the entire universe of Scheme values.
proper-list?
x -> boolean
More carefully: The empty list is a proper list. A pair whose cdr is a proper list is also a proper list:
<proper-list> ::= () (Empty proper list) | (cons <x> <proper-list>) (Proper-list pair)Note that this definition rules out circular lists. This function is required to detect this case and return false.
Nil-terminated lists are called "proper" lists by R5RS and Common Lisp. The opposite of proper is improper.
R5RS binds this function to the variable list?
.
(not (proper-list? x)) = (or (dotted-list? x) (circular-list? x))
circular-list?
x -> boolean
Terminology: The opposite of circular is finite.
(not (circular-list? x)) = (or (proper-list? x) (dotted-list? x))
dotted-list?
x -> boolean
(not (dotted-list? x)) = (or (proper-list? x) (circular-list? x))
pair?
object -> boolean
(pair? '(a . b)) => #t (pair? '(a b c)) => #t (pair? '()) => #f (pair? '#(a b)) => #f (pair? 7) => #f (pair? 'a) => #f
null?
object -> boolean
null-list?
list -> boolean
not-pair?
x -> boolean
(lambda (x) (not (pair? x)))Provided as a procedure as it can be useful as the termination condition for list-processing procedures that wish to handle all finite lists, both proper and dotted.
list=
elt= list1 ... -> boolean
(elt= a b)
for a an element of list A,
and b an element of list B.
In the n-ary case,
every listi is compared to
listi+1
(as opposed, for example, to comparing
list1 to every listi,
for i>1).
If there are no list arguments at all,
list=
simply returns true.
It is an error to apply list=
to anything except proper lists.
While
implementations may choose to extend it to circular lists, note that it
cannot reasonably be extended to dotted lists, as it provides no way to
specify an equality procedure for comparing the list terminators.
Note that the dynamic order in which the elt= procedure is
applied to pairs of elements is not specified.
For example, if list=
is applied
to three lists, A, B, and C,
it may first completely compare A to B,
then compare B to C,
or it may compare the first elements of A and B,
then the first elements of B and C,
then the second elements of A and B, and so forth.
The equality procedure must be consistent with eq?
.
That is, it must be the case that
(eq? x y)
=> (elt= x y)
.
eq?
are always list=, as well; implementations may exploit this
fact to "short-cut" the element-by-element comparisons.
(list= eq?) => #t ; Trivial cases (list= eq? '(a)) => #t
car
pair -> value
cdr
pair -> value
(car '(a b c)) => a (cdr '(a b c)) => (b c) (car '((a) b c d)) => (a) (cdr '((a) b c d)) => (b c d) (car '(1 . 2)) => 1 (cdr '(1 . 2)) => 2 (car '()) => *error* (cdr '()) => *error*
caar
pair -> value
cadr
pair -> value
:
cdddar
pair -> value
cddddr
pair -> value
car
and cdr
,
where for example caddr
could be defined by
(define caddr (lambda (x) (car (cdr (cdr x))))).Arbitrary compositions, up to four deep, are provided. There are twenty-eight of these procedures in all.
list-ref
clist i -> value
(drop clist i)
.)
It is an error if i >= n,
where n is the length of clist.
(list-ref '(a b c d) 2) => c
first
pair -> object
second
pair -> object
third
pair -> object
fourth
pair -> object
fifth
pair -> object
sixth
pair -> object
seventh
pair -> object
eighth
pair -> object
ninth
pair -> object
tenth
pair -> object
car
, cadr
, caddr
, ...
(third '(a b c d e)) => c
car+cdr
pair -> [x y]
(lambda (p) (values (car p) (cdr p)))This can, of course, be implemented more efficiently by a compiler.
take
x i -> list
drop
x i -> object
take
returns the first i elements of list x.drop
returns all but the first i elements of list x.
(take '(a b c d e) 2) => (a b) (drop '(a b c d e) 2) => (c d e)x may be any value -- a proper, circular, or dotted list:
(take '(1 2 3 . d) 2) => (1 2) (drop '(1 2 3 . d) 2) => (3 . d) (take '(1 2 3 . d) 3) => (1 2 3) (drop '(1 2 3 . d) 3) => dFor a legal i,
take
and drop
partition the list in a manner which
can be inverted with append
:
(append (take x i) (drop x i)) = x
drop
is exactly equivalent to performing i cdr operations on x;
the returned value shares a common tail with x.
If the argument is a list of non-zero length, take
is guaranteed to
return a freshly-allocated list, even in the case where the entire
list is taken, e.g. (take lis (length lis))
.
take-right
flist i -> object
drop-right
flist i -> list
take-right
returns the last i elements of flist.drop-right
returns all but the last i elements of flist.
(take-right '(a b c d e) 2) => (d e) (drop-right '(a b c d e) 2) => (a b c)The returned list may share a common tail with the argument list.
flist may be any finite list, either proper or dotted:
(take-right '(1 2 3 . d) 2) => (2 3 . d) (drop-right '(1 2 3 . d) 2) => (1) (take-right '(1 2 3 . d) 0) => d (drop-right '(1 2 3 . d) 0) => (1 2 3)For a legal i,
take-right
and drop-right
partition the list in a manner
which can be inverted with append
:
(append (take flist i) (drop flist i)) = flist
take-right
's return value is guaranteed to share a common tail with flist.
If the argument is a list of non-zero length, drop-right
is guaranteed to
return a freshly-allocated list, even in the case where nothing is
dropped, e.g. (drop-right lis 0)
.
take!
x i -> list
drop-right!
flist i -> list
take!
and drop-right!
are "linear-update" variants of take
and
drop-right
: the procedure is allowed, but not required, to alter the
argument list to produce the result.
If x is circular, take!
may return a shorter-than-expected list:
(take! (circular-list 1 3 5) 8) => (1 3) (take! (circular-list 1 3 5) 8) => (1 3 5 1 3 5 1 3)
split-at
x i -> [list object]
split-at!
x i -> [list object]
split-at
splits the list x
at index i, returning a list of the
first i elements, and the remaining tail. It is equivalent
to
(values (take x i) (drop x i))
split-at!
is the linear-update variant. It is allowed, but not
required, to alter the argument list to produce the result.
(split-at '(a b c d e f g h) 3) => (a b c) (d e f g h)
last
pair -> object
last-pair
pair -> pair
last
returns the last element of the non-empty,
finite list pair.
last-pair
returns the last pair in the non-empty,
finite list pair.
(last '(a b c)) => c (last-pair '(a b c)) => (c)
length
list -> integer
length+
clist -> integer or #f
length
and length+
return the length of the argument.
It is an error to pass a value to length
which is not a proper
list (finite and nil-terminated). In particular, this means an
implementation may diverge or signal an error when length
is
applied to a circular list.
length+
, on the other hand, returns #F
when applied to a circular
list.
The length of a proper list is a non-negative integer n such that cdr
applied n times to the list produces the empty list.
append
list1 ... -> list
append!
list1 ... -> list
append
returns a list consisting of the elements
of list1
followed by the elements of the other list parameters.
(append '(x) '(y)) => (x y) (append '(a) '(b c d)) => (a b c d) (append '(a (b)) '((c))) => (a (b) (c))The resulting list is always newly allocated, except that it shares structure with the final listi argument. This last argument may be any value at all; an improper list results if it is not a proper list. All other arguments must be proper lists.
(append '(a b) '(c . d)) => (a b c . d) (append '() 'a) => a (append '(x y)) => (x y) (append) => ()
append!
is the "linear-update" variant of append
-- it is allowed, but not required, to alter cons cells in the argument
lists to construct the result list.
The last argument is never altered; the result
list shares structure with this parameter.
concatenate
list-of-lists -> value
concatenate!
list-of-lists -> value
concatenate
returns
(apply append list-of-lists)or, equivalently,
(reduce-right append '() list-of-lists)
concatenate!
is the linear-update variant, defined in
terms of append!
instead of append
.
Note that some Scheme implementations do not support passing more than a
certain number (e.g., 64) of arguments to an n-ary procedure.
In these implementations, the (apply append ...)
idiom
would fail when applied to long lists,
but concatenate
would continue to function properly.
As with append
and append!
,
the last element of the input list may be any value at all.
reverse
list -> list
reverse!
list -> list
reverse
returns a newly allocated list consisting of
the elements of list in reverse order.
(reverse '(a b c)) => (c b a) (reverse '(a (b c) d (e (f)))) => ((e (f)) d (b c) a)
reverse!
is the linear-update variant of reverse
.
It is permitted, but not required, to alter the argument's cons cells
to produce the reversed list.
append-reverse
rev-head tail -> list
append-reverse!
rev-head tail -> list
append-reverse
returns
(append (reverse rev-head) tail)
.
It is provided because it is a common operation -- a common
list-processing style calls for this exact operation to transfer values
accumulated in reverse order onto the front of another list, and because
the implementation is significantly more efficient than the simple
composition it replaces. (But note that this pattern of iterative
computation followed by a reverse can frequently be rewritten as a
recursion, dispensing with the reverse
and append-reverse
steps, and
shifting temporary, intermediate storage from the heap to the stack,
which is typically a win for reasons of cache locality and eager storage
reclamation.)
append-reverse!
is just the linear-update variant -- it is allowed, but
not required, to alter rev-head's cons cells to construct the result.
zip
clist1 clist2 ... -> list
(lambda lists (apply map list lists))If
zip
is passed n lists, it returns a list as long as the shortest
of these lists, each element of which is an n-element list comprised
of the corresponding elements from the parameter lists.
(zip '(one two three) '(1 2 3) '(odd even odd even odd even odd even)) => ((one 1 odd) (two 2 even) (three 3 odd)) (zip '(1 2 3)) => ((1) (2) (3))At least one of the argument lists must be finite:
(zip '(3 1 4 1) (circular-list #f #t)) => ((3 #f) (1 #t) (4 #f) (1 #t))
unzip1
list -> list
unzip2
list -> [list list]
unzip3
list -> [list list list]
unzip4
list -> [list list list list]
unzip5
list -> [list list list list list]
unzip1
takes a list of lists,
where every list must contain at least one element,
and returns a list containing the initial element of each such list.
That is, it returns (map car lists)
.
unzip2
takes a list of lists, where every list must contain at least
two elements, and returns two values: a list of the first elements,
and a list of the second elements. unzip3
does the same for the first
three elements of the lists, and so forth.
(unzip2 '((1 one) (2 two) (3 three))) => (1 2 3) (one two three)
count
pred clist1 clist2 -> integer
count
is "iterative" in that it is guaranteed
to apply pred to the list elements in a
left-to-right order.
The counting stops when the shortest list expires.
(count even? '(3 1 4 1 5 9 2 5 6)) => 3 (count < '(1 2 4 8) '(2 4 6 8 10 12 14 16)) => 3At least one of the argument lists must be finite:
(count < '(3 1 4 1) (circular-list 1 10)) => 2
fold
kons knil clist1 clist2 ... -> value
First, consider the single list-parameter case. If clist1 = (e1 e2 ... en), then this procedure returns
(kons en ... (kons e2 (kons e1 knil)) ... )
(fold kons knil lis) = (fold kons (kons (car lis) knil) (cdr lis)) (fold kons knil '()) = knilExamples:
(fold + 0 lis) ; Add up the elements of LIS. (fold cons '() lis) ; Reverse LIS. (fold cons tail rev-head) ; See APPEND-REVERSE. ;; How many symbols in LIS? (fold (lambda (x count) (if (symbol? x) (+ count 1) count)) 0 lis) ;; Length of the longest string in LIS: (fold (lambda (s max-len) (max max-len (string-length s))) 0 lis)If n list arguments are provided, then the kons function must take n+1 parameters: one element from each list, and the "seed" or fold state, which is initially knil. The fold operation terminates when the shortest list runs out of values:
(fold cons* '() '(a b c) '(1 2 3 4 5)) => (c 3 b 2 a 1)At least one of the list arguments must be finite.
fold-right
kons knil clist1 clist2 ... -> value
First, consider the single list-parameter case. If clist1 = (e1 e2 ... en)
,
then this procedure returns
(kons e1 (kons e2 ... (kons en knil)))
(fold-right kons knil lis) = (kons (car lis) (fold-right kons knil (cdr lis))) (fold-right kons knil '()) = knilExamples:
(fold-right cons '() lis) ; Copy LIS. ;; Filter the even numbers out of LIS. (fold-right (lambda (x l) (if (even? x) (cons x l) l)) '() lis))If n list arguments are provided, then the kons function must take n+1 parameters: one element from each list, and the "seed" or fold state, which is initially knil. The fold operation terminates when the shortest list runs out of values:
(fold-right cons* '() '(a b c) '(1 2 3 4 5)) => (a 1 b 2 c 3)At least one of the list arguments must be finite.
pair-fold
kons knil clist1 clist2 ... -> value
fold
, but kons is applied to successive sublists of the
lists, rather than successive elements -- that is, kons is applied to the
pairs making up the lists, giving this (tail) recursion:
(pair-fold kons knil lis) = (let ((tail (cdr lis)))
(pair-fold kons (kons lis knil) tail))
(pair-fold kons knil '()
) = knil
For finite lists, the kons function may reliably apply
set-cdr!
to the pairs it is given
without altering the sequence of execution.
Example:
;;; Destructively reverse a list. (pair-fold (lambda (pair tail) (set-cdr! pair tail) pair) '() lis))At least one of the list arguments must be finite.
pair-fold-right
kons knil clist1 clist2 ... -> value
fold-right
that pair-fold
holds with fold
.
Obeys the recursion
(pair-fold-right kons knil lis) =
(kons lis (pair-fold-right kons knil (cdr lis)))
(pair-fold-right kons knil '()
) = knil
Example:
(pair-fold-right cons '() '(a b c)) => ((a b c) (b c) (c))At least one of the list arguments must be finite.
reduce
f ridentity list -> value
reduce
is a variant of fold
.
ridentity should be a "right identity" of the procedure f -- that is, for any value x acceptable to f,
(f x ridentity) = x
reduce
has the following definition:
(fold f (car list) (cdr list))
.
(fold f ridentity list)
.
Note that ridentity is used only in the empty-list case.
You typically use reduce
when applying f is expensive and you'd
like to avoid the extra application incurred when fold
applies
f to the head of list and the identity value,
redundantly producing the same value passed in to f.
For example, if f involves searching a file directory or
performing a database query, this can be significant.
In general, however, fold
is useful in many contexts where reduce
is not
(consider the examples given in the fold
definition -- only one of the
five folds uses a function with a right identity.
The other four may not be performed with reduce
).
Note: MIT Scheme and Haskell flip F's arg order for their reduce
and
fold
functions.
;; Take the max of a list of non-negative integers. (reduce max 0 nums) ; i.e., (apply max 0 nums)
reduce-right
f ridentity list -> value
reduce-right
is the fold-right variant of reduce
.
It obeys the following definition:
(reduce-right f ridentity '()) = ridentity (reduce-right f ridentity '(e1)) = (f e1 ridentity) = e1 (reduce-right f ridentity '(e1 e2 ...)) = (f e1 (reduce f ridentity (e2 ...)))...in other words, we compute
(fold-right f ridentity list)
.
;; Append a bunch of lists together. ;; I.e., (apply append list-of-lists) (reduce-right append '() list-of-lists)
unfold
p f g seed [tail-gen] -> list
unfold
is best described by its basic recursion:
(unfold p f g seed) = (if (p seed) (tail-gen seed) (cons (f seed) (unfold p f g (g seed))))
(lambda (x) '())
In other words, we use g to generate a sequence of seed values
unfold
is the fundamental recursive list constructor,
just as fold-right
is
the fundamental recursive list consumer.
While unfold
may seem a bit abstract
to novice functional programmers, it can be used in a number of ways:
;; List of squares: 1^2 ... 10^2 (unfold (lambda (x) (> x 10)) (lambda (x) (* x x)) (lambda (x) (+ x 1)) 1) (unfold null-list? car cdr lis) ; Copy a proper list. ;; Read current input port into a list of values. (unfold eof-object? values (lambda (x) (read)) (read)) ;; Copy a possibly non-proper list: (unfold not-pair? car cdr lis values) ;; Append HEAD onto TAIL: (unfold null-list? car cdr head (lambda (x) tail))Interested functional programmers may enjoy noting that
fold-right
and unfold
are in some sense inverses.
That is, given operations knull?, kar,
kdr, kons, and knil satisfying
(kons (kar x) (kdr x))
= x
and
(knull? knil)
= #t
(fold-right kons knil (unfold knull? kar kdr x))
= x
(unfold knull? kar kdr (fold-right kons knil x))
= x.
unfold-right
p f g seed [tail] -> list
unfold-right
constructs a list with the following loop:
(let lp ((seed seed) (lis tail)) (if (p seed) lis (lp (g seed) (cons (f seed) lis))))
'()
.
In other words, we use g to generate a sequence of seed values
unfold-right
is the fundamental iterative list constructor,
just as fold
is the
fundamental iterative list consumer.
While unfold-right
may seem a bit abstract
to novice functional programmers, it can be used in a number of ways:
;; List of squares: 1^2 ... 10^2 (unfold-right zero? (lambda (x) (* x x)) (lambda (x) (- x 1)) 10) ;; Reverse a proper list. (unfold-right null-list? car cdr lis) ;; Read current input port into a list of values. (unfold-right eof-object? values (lambda (x) (read)) (read)) ;; (append-reverse rev-head tail) (unfold-right null-list? car cdr rev-head tail)Interested functional programmers may enjoy noting that
fold
and unfold-right
are in some sense inverses.
That is, given operations knull?, kar,
kdr, kons, and knil satisfying
(kons (kar x) (kdr x))
= x
and
(knull? knil)
= #t
(fold kons knil (unfold-right knull? kar kdr x))
= x
(unfold-right knull? kar kdr (fold kons knil x))
= x.
map
proc clist1 clist2 ... -> list
map
applies proc element-wise to the elements
of the lists and returns a list of the results,
in order.
The dynamic order in which proc
is applied to the elements of the lists is unspecified.
(map cadr '((a b) (d e) (g h))) => (b e h) (map (lambda (n) (expt n n)) '(1 2 3 4 5)) => (1 4 27 256 3125) (map + '(1 2 3) '(4 5 6)) => (5 7 9) (let ((count 0)) (map (lambda (ignored) (set! count (+ count 1)) count) '(a b))) => (1 2) or (2 1)This procedure is extended from its R5RS specification to allow the arguments to be of unequal length; it terminates when the shortest list runs out.
At least one of the argument lists must be finite:
(map + '(3 1 4 1) (circular-list 1 0)) => (4 1 5 1)
for-each
proc clist1 clist2 ... -> unspecified
for-each
are like the arguments to
map
, but
for-each
calls proc for its side effects rather
than for its values.
Unlike map
, for-each
is guaranteed to call
proc on the elements of the lists in order from the first
element(s) to the last,
and the value returned by for-each
is unspecified.
(let ((v (make-vector 5))) (for-each (lambda (i) (vector-set! v i (* i i))) '(0 1 2 3 4)) v) => #(0 1 4 9 16)This procedure is extended from its R5RS specification to allow the arguments to be of unequal length; it terminates when the shortest list runs out.
At least one of the argument lists must be finite.
append-map
f clist1 clist2 ... -> value
append-map!
f clist1 clist2 ... -> value
(apply append (map f clist1 clist2 ...))
(apply append! (map f clist1 clist2 ...))
map
function.
However, the results of the applications are appended together to
make the final result. append-map
uses append
to append the results
together; append-map!
uses append!
.
The dynamic order in which the various applications of f are made is not specified.
Example:
(append-map! (lambda (x) (list x (- x))) '(1 3 8)) => (1 -1 3 -3 8 -8)At least one of the list arguments must be finite.
map!
f list1 clist2 ... -> list
map
-- map!
is allowed, but not required, to
alter the cons cells of list1 to construct the result list.
The dynamic order in which the various applications of f are made is not specified. In the n-ary case, clist2, clist3, ... must have at least as many elements as list1.
map-in-order
f clist1 clist2 ... -> list
map
procedure that guarantees to apply f across
the elements of the listi arguments in a left-to-right order. This
is useful for mapping procedures that both have side effects and
return useful values.
At least one of the list arguments must be finite.
pair-for-each
f clist1 clist2 ... -> unspecific
for-each
, but f is applied to successive sublists of the argument
lists. That is, f is applied to the cons cells of the lists, rather
than the lists' elements. These applications occur in left-to-right
order.
The f procedure may reliably apply set-cdr!
to the pairs it is given
without altering the sequence of execution.
(pair-for-each (lambda (pair) (display pair) (newline)) '(a b c)) ==> (a b c) (b c) (c)At least one of the list arguments must be finite.
filter-map
f clist1 clist2 ... -> list
map
, but only true values are saved.
(filter-map (lambda (x) (and (number? x) (* x x))) '(a 1 b 3 c 7)) => (1 9 49)The dynamic order in which the various applications of f are made is not specified.
At least one of the list arguments must be finite.
filter
pred list -> list
(filter even? '(0 7 8 8 43 -4)) => (0 8 8 -4)
partition
pred list -> [list list]
(partition symbol? '(one 2 3 four five 6)) => (one four five) (2 3 6)
remove
pred list -> list
(lambda (pred list) (filter (lambda (x) (not (pred x))) list))The list is not disordered -- elements that appear in the result list occur in the same order as they occur in the argument list. The returned list may share a common tail with the argument list. The dynamic order in which the various applications of pred are made is not specified.
(remove even? '(0 7 8 8 43 -4)) => (7 43)
filter!
pred list -> list
partition!
pred list -> [list list]
remove!
pred list -> list
filter
, partition
and remove
.
These procedures are allowed, but not required, to alter the cons cells
in the argument list to construct the result lists.
The following procedures all search lists for a leftmost element satisfying some criteria. This means they do not always examine the entire list; thus, there is no efficient way for them to reliably detect and signal an error when passed a dotted or circular list. Here are the general rules describing how these procedures work when applied to different kinds of lists:
In brief, SRFI-1 compliant code may not pass a dotted list argument to these procedures.
Here are some examples, using the find
and any
procedures as canonical
representatives:
;; Proper list -- success (find even? '(1 2 3)) => 2 (any even? '(1 2 3)) => #t ;; proper list -- failure (find even? '(1 7 3)) => #f (any even? '(1 7 3)) => #f ;; Failure is error on a dotted list. (find even? '(1 3 . x)) => error (any even? '(1 3 . x)) => error ;; The dotted list contains an element satisfying the search. ;; This case is not specified -- it could be success, an error, ;; or some third possibility. (find even? '(1 2 . x)) => error/undefined (any even? '(1 2 . x)) => error/undefined ; success, error or other. ;; circular list -- success (find even? (circular-list 1 6 3)) => 6 (any even? (circular-list 1 6 3)) => #t ;; circular list -- failure is error. Procedure may diverge. (find even? (circular-list 1 3)) => error (any even? (circular-list 1 3)) => error
find
pred clist -> value
(find even? '(3 1 4 1 5 9)) => 4Note that
find
has an ambiguity in its lookup semantics -- if find
returns #f
, you cannot tell (in general) if it found a #f
element
that satisfied pred, or if it did not find any element at all. In
many situations, this ambiguity cannot arise -- either the list being
searched is known not to contain any #f
elements, or the list is
guaranteed to have an element satisfying pred. However, in cases
where this ambiguity can arise, you should use find-tail
instead of
find
-- find-tail
has no such ambiguity:
(cond ((find-tail pred lis) => (lambda (pair) ...)) ; Handle (CAR PAIR) (else ...)) ; Search failed.
find-tail
pred clist -> pair or false
find-tail
can be viewed as a general-predicate variant of the member
function.
Examples:
(find-tail even? '(3 1 37 -8 -5 0 0)) => (-8 -5 0 0) (find-tail even? '(3 1 37 -5)) => #f ;; MEMBER X LIS: (find-tail (lambda (elt) (equal? x elt)) lis)In the circular-list case, this procedure "rotates" the list.
Find-tail
is essentially drop-while
,
where the sense of the predicate is inverted:
Find-tail
searches until it finds an element satisfying
the predicate; drop-while
searches until it finds an
element that doesn't satisfy the predicate.
take-while
pred clist -> list
take-while!
pred clist -> list
Take-while!
is the linear-update variant. It is allowed, but not
required, to alter the argument list to produce the result.
(take-while even? '(2 18 3 10 22 9)) => (2 18)
drop-while
pred clist -> list
(drop-while even? '(2 18 3 10 22 9)) => (3 10 22 9)The circular-list case may be viewed as "rotating" the list.
span
pred clist -> [list clist]
span!
pred list -> [list list]
break
pred clist -> [list clist]
break!
pred list -> [list list]
Span
splits the list into the longest initial prefix whose
elements all satisfy pred, and the remaining tail.
Break
inverts the sense of the predicate:
the tail commences with the first element of the input list
that satisfies the predicate.
In other words:
span
finds the intial span of elements
satisfying pred,
and break
breaks the list at the first element satisfying
pred.
Span
is equivalent to
(values (take-while pred clist) (drop-while pred clist))
Span!
and break!
are the linear-update variants.
They are allowed, but not required,
to alter the argument list to produce the result.
(span even? '(2 18 3 10 22 9)) => (2 18) (3 10 22 9) (break even? '(3 1 4 1 5 9)) => (3 1) (4 1 5 9)
any
pred clist1 clist2 ... -> value
If there are n list arguments clist1 ... clistn, then pred must be a procedure taking n arguments and returning a boolean result.
any
applies pred to the first elements of the clisti parameters.
If this application returns a true value, any
immediately returns
that value. Otherwise, it iterates, applying pred to the second
elements of the clisti parameters, then the third, and so forth.
The iteration stops when a true value is produced or one of the lists runs
out of values; in
the latter case, any
returns #f
.
The application of pred to the last element of the
lists is a tail call.
Note the difference between find
and any
-- find
returns the element
that satisfied the predicate; any
returns the true value that the
predicate produced.
Like every
, any
's name does not end with a question mark -- this is to
indicate that it does not return a simple boolean (#t
or #f
), but a
general value.
(any integer? '(a 3 b 2.7)) => #t (any integer? '(a 3.1 b 2.7)) => #f (any < '(3 1 4 1 5) '(2 7 1 8 2)) => #t
every
pred clist1 clist2 ... -> value
If there are n list arguments clist1 ... clistn, then pred must be a procedure taking n arguments and returning a boolean result.
every
applies pred to the first elements of the clisti parameters.
If this application returns false, every
immediately returns false.
Otherwise, it iterates, applying pred to the second elements of the
clisti parameters, then the third, and so forth. The iteration stops
when a false value is produced or one of the lists runs out of values.
In the latter case, every
returns
the true value produced by its final application of pred.
The application of pred to the last element of the lists
is a tail call.
If one of the clisti has no elements, every
simply returns #t
.
Like any
, every
's name does not end with a question mark -- this is to
indicate that it does not return a simple boolean (#t
or #f
), but a
general value.
list-index
pred clist1 clist2 ... -> integer or false
If there are n list arguments clist1 ... clistn, then pred must be a function taking n arguments and returning a boolean result.
list-index
applies pred to the first elements of the clisti parameters.
If this application returns true, list-index
immediately returns zero.
Otherwise, it iterates, applying pred to the second elements of the
clisti parameters, then the third, and so forth. When it finds a tuple of
list elements that cause pred to return true, it stops and returns the
zero-based index of that position in the lists.
The iteration stops when one of the lists runs out of values; in this
case, list-index
returns #f
.
(list-index even? '(3 1 4 1 5 9)) => 2 (list-index < '(3 1 4 1 5 9 2 5 6) '(2 7 1 8 2)) => 1 (list-index = '(3 1 4 1 5 9 2 5 6) '(2 7 1 8 2)) => #f
member
x list [=] -> list
memq
x list -> list
memv
x list -> list
(drop list i)
for i less than the length of list.
If x does
not occur in list, then #f
is returned.
memq
uses eq?
to compare x
with the elements of list,
while memv
uses eqv?
, and
member
uses equal?
.
(memq 'a '(a b c)) => (a b c) (memq 'b '(a b c)) => (b c) (memq 'a '(b c d)) => #f (memq (list 'a) '(b (a) c)) => #f (member (list 'a) '(b (a) c)) => ((a) c) (memq 101 '(100 101 102)) => *unspecified* (memv 101 '(100 101 102)) => (101 102)
member
is extended from its
R5RS
definition to allow the client to pass in
an optional equality procedure = used to compare keys.
The comparison procedure is used to compare the elements ei of list to the key x in this way:
(= x ei) ; list is (E1 ... En)
(member 5 list <)
Note that fully general list searching may be performed with
the find-tail
and find
procedures, e.g.
(find-tail even? list) ; Find the first elt with an even key.
delete
x list [=] -> list
delete!
x list [=] -> list
delete
uses the comparison procedure =, which defaults to equal?
, to find
all elements of list that are equal to x, and deletes them from list. The
dynamic order in which the various applications of = are made is not
specified.
The list is not disordered -- elements that appear in the result list occur in the same order as they occur in the argument list. The result may share a common tail with the argument list.
Note that fully general element deletion can be performed with the remove
and remove!
procedures, e.g.:
;; Delete all the even elements from LIS: (remove even? lis)The comparison procedure is used in this way:
(= x ei)
.
That is, x is always the first argument,
and a list element is always the
second argument. The comparison procedure will be used to compare each
element of list exactly once; the order in which it is applied to the
various ei is not specified. Thus, one can reliably remove all the
numbers greater than five from a list with
(delete 5 list <)
delete!
is the linear-update variant of delete
.
It is allowed, but not required, to alter the cons cells in
its argument list to construct the result.
delete-duplicates
list [=] -> list
delete-duplicates!
list [=] -> list
delete-duplicates
removes duplicate elements from the
list argument.
If there are multiple equal elements in the argument list, the result list
only contains the first or leftmost of these elements in the result.
The order of these surviving elements is the same as in the original
list -- delete-duplicates
does not disorder the list (hence it is useful
for "cleaning up" association lists).
The = parameter is used to compare the elements of the list; it defaults
to equal?
. If x comes before y in list, then the comparison is performed
(= x y)
.
The comparison procedure will be used to compare each pair of elements in
list no more than once;
the order in which it is applied to the various pairs is not specified.
Implementations of delete-duplicates
are allowed to share common tails
between argument and result lists -- for example, if the list argument
contains only unique elements, it may simply return exactly
this list.
Be aware that, in general, delete-duplicates
runs in time O(n2) for n-element lists.
Uniquifying long lists can be accomplished in O(n lg n) time by sorting
the list to bring equal elements together, then using a linear-time
algorithm to remove equal elements. Alternatively, one can use algorithms
based on element-marking, with linear-time results.
delete-duplicates!
is the linear-update variant of delete-duplicates
; it
is allowed, but not required, to alter the cons cells in its argument
list to construct the result.
(delete-duplicates '(a b a c a b c z)) => (a b c z) ;; Clean up an alist: (delete-duplicates '((a . 3) (b . 7) (a . 9) (c . 1)) (lambda (x y) (eq? (car x) (car y)))) => ((a . 3) (b . 7) (c . 1))
An "association list" (or "alist") is a list of pairs. The car of each pair contains a key value, and the cdr contains the associated data value. They can be used to construct simple look-up tables in Scheme. Note that association lists are probably inappropriate for performance-critical use on large data; in these cases, hash tables or some other alternative should be employed.
assoc
key alist [=] -> pair or #f
assq
key alist -> pair or #f
assv
key alist -> pair or #f
#f
is returned.
assq
uses eq?
to compare key
with the car fields of the pairs in alist,
while assv
uses eqv?
and assoc
uses equal?
.
(define e '((a 1) (b 2) (c 3))) (assq 'a e) => (a 1) (assq 'b e) => (b 2) (assq 'd e) => #f (assq (list 'a) '(((a)) ((b)) ((c)))) => #f (assoc (list 'a) '(((a)) ((b)) ((c)))) => ((a)) (assq 5 '((2 3) (5 7) (11 13))) => *unspecified* (assv 5 '((2 3) (5 7) (11 13))) => (5 7)
assoc
is extended from its
R5RS
definition to allow the client to pass in
an optional equality procedure = used to compare keys.
The comparison procedure is used to compare the elements ei of list to the key parameter in this way:
(= key (car ei)) ; list is (E1 ... En)
(assoc 5 alist <)
Note that fully general alist searching may be performed with
the find-tail
and find
procedures, e.g.
;; Look up the first association in alist with an even key: (find (lambda (a) (even? (car a))) alist)
alist-cons
key datum alist -> alist
(lambda (key datum alist) (cons (cons key datum) alist))Cons a new alist entry mapping key -> datum onto alist.
alist-copy
alist -> alist
(lambda (a) (map (lambda (elt) (cons (car elt) (cdr elt))) a))
alist-delete
key alist [=] -> alist
alist-delete!
key alist [=] -> alist
alist-delete
deletes all associations from alist with the given key,
using key-comparison procedure =, which defaults to equal?
.
The dynamic order in which the various applications of = are made is not
specified.
Return values may share common tails with the alist argument. The alist is not disordered -- elements that appear in the result alist occur in the same order as they occur in the argument alist.
The comparison procedure is used to compare the element keys ki of alist's
entries to the key parameter in this way:
(= key ki)
.
Thus, one can reliably remove all entries of alist whose key is greater
than five with
(alist-delete 5 alist <)
alist-delete!
is the linear-update variant of alist-delete
.
It is allowed, but not required,
to alter cons cells from the alist parameter to construct the result.
These procedures implement operations on sets represented as lists of elements.
They all take an = argument used to compare elements of lists.
This equality procedure is required to be consistent with eq?
.
That is, it must be the case that
(eq? x y)
=> (= x y)
.
eq?
are
also set-equal by any legal comparison procedure. This allows for
constant-time determination of set operations on eq?
lists.
Be aware that these procedures typically run in time O(n * m) for n- and m-element list arguments. Performance-critical applications operating upon large sets will probably wish to use other data structures and algorithms.
lset<=
= list1 ... -> boolean
(lset<= eq? '(a) '(a b a) '(a b c c)) => #t (lset<= eq?) => #t ; Trivial cases (lset<= eq? '(a)) => #t
lset=
= list1 list2 ... -> boolean
(lset= eq? '(b e a) '(a e b) '(e e b a)) => #t (lset= eq?) => #t ; Trivial cases (lset= eq? '(a)) => #t
lset-adjoin
= list elt1 ... -> list
The list parameter is always a suffix of the result -- even if the list parameter contains repeated elements, these are not reduced.
(lset-adjoin eq? '(a b c d c e) 'a 'e 'i 'o 'u) => (u o i a b c d c e)
lset-union
= list1 ... -> list
The union of lists A and B is constructed as follows:
(= r b)
.
If all comparisons fail,
b is consed onto the front of the result.
eq
? to B,
the operation may immediately terminate.
In the n-ary case, the two-argument list-union operation is simply folded across the argument lists.
(lset-union eq? '(a b c d e) '(a e i o u)) => (u o i a b c d e) ;; Repeated elements in LIST1 are preserved. (lset-union eq? '(a a c) '(x a x)) => (x a a c) ;; Trivial cases (lset-union eq?) => () (lset-union eq? '(a b c)) => (a b c)
lset-intersection
= list1 list2 ... -> list
The intersection of lists A and B
is comprised of every element of A that is =
to some element of B:
(= a b)
,
for a in A, and b in B.
Note this implies that an element which appears in B
and multiple times in list A
will also appear multiple times in the result.
The order in which elements appear in the result is the same as
they appear in list1 --
that is, lset-intersection
essentially filters
list1,
without disarranging element order.
The result may
share a common tail with list1.
In the n-ary case, the two-argument list-intersection operation is simply folded across the argument lists. However, the dynamic order in which the applications of = are made is not specified. The procedure may check an element of list1 for membership in every other list before proceeding to consider the next element of list1, or it may completely intersect list1 and list2 before proceeding to list3, or it may go about its work in some third order.
(lset-intersection eq? '(a b c d e) '(a e i o u)) => (a e) ;; Repeated elements in LIST1 are preserved. (lset-intersection eq? '(a x y a) '(x a x z)) => '(a x a) (lset-intersection eq? '(a b c)) => (a b c) ; Trivial case
lset-difference
= list1 list2 ... -> list
The = procedure's first argument is
always an element of list1;
its second is an element of one of the other listi.
Elements that are repeated multiple times in the
list1 parameter
will occur multiple times in the result.
The order in which elements appear in the result is the same as
they appear in list1 --
that is, lset-difference
essentially
filters list1, without disarranging element order.
The result may share a common tail with list1.
The dynamic order in which the applications of = are made is not
specified.
The procedure may check an element of list1
for membership in every other list before proceeding to consider the
next element of list1,
or it may completely compute the difference of
list1 and list2 before
proceeding to list3,
or it may go about its work in some third order.
(lset-difference eq? '(a b c d e) '(a e i o u)) => (b c d) (lset-difference eq? '(a b c)) => (a b c) ; Trivial case
lset-xor
= list1 ... -> list
More precisely, for two lists A and B, A xor B is a list of
(= a b)
, and
(= b a)
.
(= a b)
=>
(= b a)
.
(= a b)
produces
true for some a in A
and b in B,
both a and b may be removed from
inclusion in the result.
In the n-ary case, the binary-xor operation is simply folded across the lists.
(lset-xor eq? '(a b c d e) '(a e i o u)) => (d c b i o u) ;; Trivial cases. (lset-xor eq?) => () (lset-xor eq? '(a b c d e)) => (a b c d e)
lset-diff+intersection
= list1 list2 ... -> [list list]
(values (lset-difference = list1 list2 ...) (lset-intersection = list1 (lset-union = list2 ...)))but can be implemented more efficiently.
The = procedure's first argument is an element of list1; its second is an element of one of the other listi.
Either of the answer lists may share a common tail with list1. This operation essentially partitions list1.
lset-union!
= list1 ... -> list
lset-intersection!
= list1 list2 ... -> list
lset-difference!
= list1 list2 ... -> list
lset-xor!
= list1 ... -> list
lset-diff+intersection!
= list1 list2 ... -> [list list]
lset-union!
is permitted to recycle cons cells from any
of its list arguments.
These two procedures are the primitive, R5RS side-effect operations on pairs.
set-car!
pair object -> unspecified
set-cdr!
pair object -> unspecified
(define (f) (list 'not-a-constant-list)) (define (g) '(constant-list)) (set-car! (f) 3) => *unspecified* (set-car! (g) 3) => *error*
The design of this library benefited greatly from the feedback provided during the SRFI discussion phase. Among those contributing thoughtful commentary and suggestions, both on the mailing list and by private discussion, were Mike Ashley, Darius Bacon, Alan Bawden, Phil Bewig, Jim Blandy, Dan Bornstein, Per Bothner, Anthony Carrico, Doug Currie, Kent Dybvig, Sergei Egorov, Doug Evans, Marc Feeley, Matthias Felleisen, Will Fitzgerald, Matthew Flatt, Dan Friedman, Lars Thomas Hansen, Brian Harvey, Erik Hilsdale, Wolfgang Hukriede, Richard Kelsey, Donovan Kolbly, Shriram Krishnamurthi, Dave Mason, Jussi Piitulainen, David Pokorny, Duncan Smith, Mike Sperber, Maciej Stachowiak, Harvey J. Stein, John David Stone, and Joerg F. Wittenberger. I am grateful to them for their assistance.
I am also grateful the authors, implementors and documentors of all the systems mentioned in the rationale. Aubrey Jaffer and Kent Pitman should be noted for their work in producing Web-accessible versions of the R5RS and Common Lisp spec, which was a tremendous aid.
This is not to imply that these individuals necessarily endorse the final results, of course.
The Common Lisp "HyperSpec," produced by Kent Pitman, is essentially the ANSI spec for Common Lisp: http://www.harlequin.com/education/books/HyperSpec/.
Certain portions of this document -- the specific, marked segments of text describing the R5RS procedures -- were adapted with permission from the R5RS report.
All other text is copyright (C) Olin Shivers (1998, 1999). All Rights Reserved.
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.