Sanctuary
Sanctuary is a JavaScript functional programming library inspired by
Haskell and PureScript. It's stricter than Ramda, and
provides a similar suite of functions.
Sanctuary promotes programs composed of simple, pure functions. Such
programs are easier to comprehend, test, and maintain – they are
also a pleasure to write.
Sanctuary provides two data types, Maybe and Either, both of
which are compatible with Fantasy Land. Thanks to these data types
even Sanctuary functions which may fail, such as head
, are
composable.
Sanctuary makes it possible to write safe code without null checks.
In JavaScript it's trivial to introduce a possible run-time type error:
words[0].toUpperCase()
If words
is []
we'll get a familiar error at run-time:
TypeError: Cannot read property 'toUpperCase' of undefined
Sanctuary gives us a fighting chance of avoiding such errors. We might
write:
S.map (S.toUpper) (S.head (words))
Sanctuary is designed to work in Node.js and in ES5-compatible browsers.
Folktale
Folktale, like Sanctuary, is a standard library for functional
programming in JavaScript. It is well designed and well documented.
Whereas Sanctuary treats JavaScript as a member of the ML language
family, Folktale embraces JavaScript's object-oriented programming
model. Programming with Folktale resembles programming with Scala.
Ramda
Ramda provides several functions which return problematic values
such as undefined
, Infinity
, or NaN
when applied to unsuitable
inputs. These are known as partial functions. Partial functions
necessitate the use of guards or null checks. In order to safely use
R.head
, for example, one must ensure that the array is non-empty:
if (R.isEmpty (xs)) {
// ...
} else {
return f (R.head (xs));
}
Using the Maybe type renders such guards (and null checks) unnecessary.
Changing functions such as R.head
to return Maybe values was proposed
in ramda/ramda#683, but was considered too much of a stretch for
JavaScript programmers. Sanctuary was released the following month,
in January 2015, as a companion library to Ramda.
In addition to broadening in scope in the years since its release,
Sanctuary's philosophy has diverged from Ramda's in several respects.
Totality
Every Sanctuary function is defined for every value which is a member of
the function's input type. Such functions are known as total functions.
Ramda, on the other hand, contains a number of partial functions.
Information preservation
Certain Sanctuary functions preserve more information than their Ramda
counterparts. Examples:
|> R.tail ([]) |> S.tail ([])
[] Nothing
|> R.tail (['foo']) |> S.tail (['foo'])
[] Just ([])
|> R.replace (/^x/) ('') ('abc') |> S.stripPrefix ('x') ('abc')
'abc' Nothing
|> R.replace (/^x/) ('') ('xabc') |> S.stripPrefix ('x') ('xabc')
'abc' Just ('abc')
Invariants
Sanctuary performs rigorous type checking of inputs and outputs, and
throws a descriptive error if a type error is encountered. This allows bugs
to be caught and fixed early in the development cycle.
Ramda operates on the garbage in, garbage out principle. Functions
are documented to take arguments of particular types, but these invariants
are not enforced. The problem with this approach in a language as
permissive as JavaScript is that there's no guarantee that garbage input
will produce garbage output (ramda/ramda#1413). Ramda performs ad hoc
type checking in some such cases (ramda/ramda#1419).
Sanctuary can be configured to operate in garbage in, garbage out mode.
Ramda cannot be configured to enforce its invariants.
Currying
Sanctuary functions are curried. There is, for example, exactly one way to
apply S.reduce
to S.add
, 0
, and xs
:
S.reduce (S.add) (0) (xs)
Ramda functions are also curried, but in a complex manner. There are four
ways to apply R.reduce
to R.add
, 0
, and xs
:
R.reduce (R.add) (0) (xs)
R.reduce (R.add) (0, xs)
R.reduce (R.add, 0) (xs)
R.reduce (R.add, 0, xs)
Ramda supports all these forms because curried functions enable partial
application, one of the library's tenets, but f(x)(y)(z)
is considered
too unfamiliar and too unattractive to appeal to JavaScript programmers.
Sanctuary's developers prefer a simple, unfamiliar construct to a complex,
familiar one. Familiarity can be acquired; complexity is intrinsic.
The lack of breathing room in f(x)(y)(z)
impairs readability. The simple
solution to this problem, proposed in #438, is to include a space when
applying a function: f (x) (y) (z)
.
Ramda also provides a special placeholder value, R.__
, which removes
the restriction that a function must be applied to its arguments in order.
The following expressions are equivalent:
R.reduce (R.__, 0, xs) (R.add)
R.reduce (R.add, R.__, xs) (0)
R.reduce (R.__, 0) (R.add) (xs)
R.reduce (R.__, 0) (R.add, xs)
R.reduce (R.__, R.__, xs) (R.add) (0)
R.reduce (R.__, R.__, xs) (R.add, 0)
Variadic functions
Ramda provides several functions which take any number of arguments. These
are known as variadic functions. Additionally, Ramda provides several
functions which take variadic functions as arguments. Although natural in
a dynamically typed language, variadic functions are at odds with the type
notation Ramda and Sanctuary both use, leading to some indecipherable type
signatures such as this one:
R.lift :: (*... -> *...) -> ([*]... -> [*])
Sanctuary has no variadic functions, nor any functions which take variadic
functions as arguments. Sanctuary provides two "lift" functions, each with
a helpful type signature:
S.lift2 :: Apply f => (a -> b -> c) -> f a -> f b -> f c
S.lift3 :: Apply f => (a -> b -> c -> d) -> f a -> f b -> f c -> f d
Implicit context
Ramda provides R.bind
and R.invoker
for working with methods.
Additionally, many Ramda functions use Function#call
or Function#apply
to preserve context. Sanctuary makes no allowances for this
.
Transducers
Several Ramda functions act as transducers. Sanctuary provides no support
for transducers.
Modularity
Whereas Ramda has no dependencies, Sanctuary has a modular design:
sanctuary-def provides type checking, sanctuary-type-classes
provides Fantasy Land functions and type classes, sanctuary-show
provides string representations, and algebraic data types are provided
by sanctuary-either, sanctuary-maybe, and sanctuary-pair.
Not only does this approach reduce the complexity of Sanctuary itself,
but it allows these components to be reused in other contexts.
Types
Sanctuary uses Haskell-like type signatures to describe the types of
values, including functions. 'foo'
, for example, is a member of String
;
[1, 2, 3]
is a member of Array Number
. The double colon (::
) is used
to mean "is a member of", so one could write:
'foo' :: String
[1, 2, 3] :: Array Number
An identifier may appear to the left of the double colon:
Math.PI :: Number
The arrow (->
) is used to express a function's type:
Math.abs :: Number -> Number
That states that Math.abs
is a unary function which takes an argument
of type Number
and returns a value of type Number
.
Some functions are parametrically polymorphic: their types are not fixed.
Type variables are used in the representations of such functions:
S.I :: a -> a
a
is a type variable. Type variables are not capitalized, so they
are differentiable from type identifiers (which are always capitalized).
By convention type variables have single-character names. The signature
above states that S.I
takes a value of any type and returns a value of
the same type. Some signatures feature multiple type variables:
S.K :: a -> b -> a
It must be possible to replace all occurrences of a
with a concrete type.
The same applies for each other type variable. For the function above, the
types with which a
and b
are replaced may be different, but needn't be.
Since all Sanctuary functions are curried (they accept their arguments
one at a time), a binary function is represented as a unary function which
returns a unary function: * -> * -> *
. This aligns neatly with Haskell,
which uses curried functions exclusively. In JavaScript, though, we may
wish to represent the types of functions with arities less than or greater
than one. The general form is (<input-types>) -> <output-type>
, where
<input-types>
comprises zero or more comma–space (,
)
-separated type representations:
() -> String
(a, b) -> a
(a, b, c) -> d
Number -> Number
can thus be seen as shorthand for (Number) -> Number
.
The question mark (?
) is used to represent types which include null
and undefined
as members. String?
, for example, represents the type
comprising null
, undefined
, and all strings.
Sanctuary embraces types. JavaScript doesn't support algebraic data types,
but these can be simulated by providing a group of data constructors which
return values with the same set of methods. A value of the Either type, for
example, is created via the Left constructor or the Right constructor.
It's necessary to extend Haskell's notation to describe implicit arguments
to the methods provided by Sanctuary's types. In x.map(y)
, for example,
the map
method takes an implicit argument x
in addition to the explicit
argument y
. The type of the value upon which a method is invoked appears
at the beginning of the signature, separated from the arguments and return
value by a squiggly arrow (~>
). The type of the fantasy-land/map
method
of the Maybe type is written Maybe a ~> (a -> b) -> Maybe b
. One could
read this as:
When the fantasy-land/map
method is invoked on a value of type Maybe a
(for any type a
) with an argument of type a -> b
(for any type b
),
it returns a value of type Maybe b
.
The squiggly arrow is also used when representing non-function properties.
Maybe a ~> Boolean
, for example, represents a Boolean property of a value
of type Maybe a
.
Sanctuary supports type classes: constraints on type variables. Whereas
a -> a
implicitly supports every type, Functor f => (a -> b) -> f a -> f b
requires that f
be a type which satisfies the requirements of the
Functor type class. Type-class constraints appear at the beginning of a
type signature, separated from the rest of the signature by a fat arrow
(=>
).
Type checking
Sanctuary functions are defined via sanctuary-def to provide run-time
type checking. This is tremendously useful during development: type errors
are reported immediately, avoiding circuitous stack traces (at best) and
silent failures due to type coercion (at worst). For example:
S.add (2) (true);
Compare this to the behaviour of Ramda's unchecked equivalent:
R.add (2) (true);
There is a performance cost to run-time type checking. Type checking is
disabled by default if process.env.NODE_ENV
is 'production'
. If this
rule is unsuitable for a given program, one may use create
to create a Sanctuary module based on a different rule. For example:
const S = sanctuary.create ({
checkTypes: localStorage.getItem ('SANCTUARY_CHECK_TYPES') === 'true',
env: sanctuary.env,
});
Occasionally one may wish to perform an operation which is not type safe,
such as mapping over an object with heterogeneous values. This is possible
via selective use of unchecked
functions.
Installation
npm install sanctuary
will install Sanctuary for use in Node.js.
Running Sanctuary in the browser is more involved. One must include a
<script>
for each dependency in addition to one for Sanctuary itself:
<script src="vendor/sanctuary-show.js"></script>
<script src="vendor/sanctuary-type-identifiers.js"></script>
<script src="vendor/sanctuary-type-classes.js"></script>
<script src="vendor/sanctuary-either.js"></script>
<script src="vendor/sanctuary-maybe.js"></script>
<script src="vendor/sanctuary-pair.js"></script>
<script src="vendor/sanctuary-def.js"></script>
<script src="vendor/sanctuary.js"></script>
To ensure compatibility one should use the dependency versions specified
in package.json.
For convenience one could define aliases for various modules:
const S = window.sanctuary;
const $ = window.sanctuaryDef;
API
Configure
Takes an options record and returns a Sanctuary module. checkTypes
specifies whether to enable type checking. The module's polymorphic
functions (such as I
) require each value associated with a
type variable to be a member of at least one type in the environment.
A well-typed application of a Sanctuary function will produce the same
result regardless of whether type checking is enabled. If type checking
is enabled, a badly typed application will produce an exception with a
descriptive error message.
The following snippet demonstrates defining a custom type and using
create
to produce a Sanctuary module which is aware of that type:
const {create, env} = require ('sanctuary');
const $ = require ('sanctuary-def');
const type = require ('sanctuary-type-identifiers');
const Identity = x => {
const identity = Object.create (Identity$prototype);
identity.value = x;
return identity;
};
Identity['@@type'] = 'my-package/Identity@1';
const Identity$prototype = {
'constructor': Identity,
'@@show': function() { return `Identity (${S.show (this.value)})`; },
'fantasy-land/map': function(f) { return Identity (f (this.value)); },
};
const IdentityType = $.UnaryType
(Identity['@@type'])
('http://example.com/my-package#Identity')
(x => type (x) === Identity['@@type'])
(identity => [identity.value]);
const S = create ({
checkTypes: process.env.NODE_ENV !== 'production',
env: env.concat ([IdentityType ($.Unknown)]),
});
S.map (S.sub (1)) (Identity (43));
See also env
.
The Sanctuary module's environment ((S.create ({checkTypes, env})).env
is a reference to env
). Useful in conjunction with create
.
> S.env
[ $.AnyFunction,
. $.Arguments,
. $.Array ($.Unknown),
. $.Boolean,
. $.Date,
. $.Error,
. $.HtmlElement,
. $.Null,
. $.Number,
. $.Object,
. $.RegExp,
. $.StrMap ($.Unknown),
. $.String,
. $.Symbol,
. $.Undefined,
. $.FiniteNumber,
. $.NonZeroFiniteNumber,
. S.EitherType ($.Unknown) ($.Unknown),
. $.Function ([$.Unknown, $.Unknown]),
. $.GlobalRegExp,
. $.NonGlobalRegExp,
. $.Integer,
. $.NonNegativeInteger,
. S.MaybeType ($.Unknown),
. $.Array2 ($.Unknown) ($.Unknown),
. S.PairType ($.Unknown) ($.Unknown),
. $.RegexFlags,
. $.Type,
. $.TypeClass,
. $.ValidDate,
. $.ValidNumber ]
A complete Sanctuary module which performs no type checking. This is
useful as it permits operations which Sanctuary's type checking would
disallow, such as mapping over an object with heterogeneous values.
See also create
.
> S.unchecked.map (S.show) ({x: 'foo', y: true, z: 42})
{x: '"foo"', y: 'true', z: '42'}
Opting out of type checking may cause type errors to go unnoticed.
> S.unchecked.add (2) ('2')
'22'
Classify
Returns the result of parsing the type identifier of the given value.
> S.type (S.Just (42))
{namespace: Just ('sanctuary-maybe'), name: 'Maybe', version: 1}
> S.type ([1, 2, 3])
{namespace: Nothing, name: 'Array', version: 0}
Returns true
iff the given value is a member of the specified type.
See $.test
for details.
> S.is ($.Array ($.Integer)) ([1, 2, 3])
true
> S.is ($.Array ($.Integer)) ([1, 2, 3.14])
false
Showable
Alias of show
.
> S.show (-0)
'-0'
> S.show (['foo', 'bar', 'baz'])
'["foo", "bar", "baz"]'
> S.show ({x: 1, y: 2, z: 3})
'{"x": 1, "y": 2, "z": 3}'
> S.show (S.Left (S.Right (S.Just (S.Nothing))))
'Left (Right (Just (Nothing)))'
Fantasy Land
Sanctuary is compatible with the Fantasy Land specification.
Curried version of Z.equals
which requires two arguments of the
same type.
To compare values of different types first use create
to
create a Sanctuary module with type checking disabled, then use that
module's equals
function.
> S.equals (0) (-0)
true
> S.equals (NaN) (NaN)
true
> S.equals (S.Just ([1, 2, 3])) (S.Just ([1, 2, 3]))
true
> S.equals (S.Just ([1, 2, 3])) (S.Just ([1, 2, 4]))
false
Returns true
iff the second argument is less than the first
according to Z.lt
.
> S.filter (S.lt (3)) ([1, 2, 3, 4, 5])
[1, 2]
Returns true
iff the second argument is less than or equal to
the first according to Z.lte
.
> S.filter (S.lte (3)) ([1, 2, 3, 4, 5])
[1, 2, 3]
Returns true
iff the second argument is greater than the first
according to Z.gt
.
> S.filter (S.gt (3)) ([1, 2, 3, 4, 5])
[4, 5]
Returns true
iff the second argument is greater than or equal
to the first according to Z.gte
.
> S.filter (S.gte (3)) ([1, 2, 3, 4, 5])
[3, 4, 5]
Returns the smaller of its two arguments (according to Z.lte
).
See also max
.
> S.min (10) (2)
2
> S.min (new Date ('1999-12-31')) (new Date ('2000-01-01'))
new Date ('1999-12-31')
> S.min ('10') ('2')
'10'
Returns the larger of its two arguments (according to Z.lte
).
See also min
.
> S.max (10) (2)
10
> S.max (new Date ('1999-12-31')) (new Date ('2000-01-01'))
new Date ('2000-01-01')
> S.max ('10') ('2')
'2'
Takes a lower bound, an upper bound, and a value of the same type.
Returns the value if it is within the bounds; the nearer bound otherwise.
See also min
and max
.
> S.clamp (0) (100) (42)
42
> S.clamp (0) (100) (-1)
0
> S.clamp ('A') ('Z') ('~')
'Z'
Type-safe version of Z.id
.
> S.id (Function) (42)
42
Curried version of Z.concat
.
> S.concat ('abc') ('def')
'abcdef'
> S.concat ([1, 2, 3]) ([4, 5, 6])
[1, 2, 3, 4, 5, 6]
> S.concat ({x: 1, y: 2}) ({y: 3, z: 4})
{x: 1, y: 3, z: 4}
> S.concat (S.Just ([1, 2, 3])) (S.Just ([4, 5, 6]))
Just ([1, 2, 3, 4, 5, 6])
> S.concat (Sum (18)) (Sum (24))
Sum (42)
Type-safe version of Z.empty
.
> S.empty (String)
''
> S.empty (Array)
[]
> S.empty (Object)
{}
> S.empty (Sum)
Sum (0)
Type-safe version of Z.invert
.
> S.invert (Sum (5))
Sum (-5)
Curried version of Z.filter
. Discards every element which does not
satisfy the predicate.
See also reject
.
> S.filter (S.odd) ([1, 2, 3])
[1, 3]
> S.filter (S.odd) ({x: 1, y: 2, z: 3})
{x: 1, z: 3}
> S.filter (S.odd) (S.Nothing)
Nothing
> S.filter (S.odd) (S.Just (0))
Nothing
> S.filter (S.odd) (S.Just (1))
Just (1)
Curried version of Z.reject
. Discards every element which satisfies
the predicate.
See also filter
.
> S.reject (S.odd) ([1, 2, 3])
[2]
> S.reject (S.odd) ({x: 1, y: 2, z: 3})
{y: 2}
> S.reject (S.odd) (S.Nothing)
Nothing
> S.reject (S.odd) (S.Just (0))
Just (0)
> S.reject (S.odd) (S.Just (1))
Nothing
Curried version of Z.takeWhile
. Discards the first element which
does not satisfy the predicate, and all subsequent elements.
See also dropWhile
.
> S.takeWhile (S.odd) ([3, 3, 3, 7, 6, 3, 5, 4])
[3, 3, 3, 7]
> S.takeWhile (S.even) ([3, 3, 3, 7, 6, 3, 5, 4])
[]
Curried version of Z.dropWhile
. Retains the first element which
does not satisfy the predicate, and all subsequent elements.
See also takeWhile
.
> S.dropWhile (S.odd) ([3, 3, 3, 7, 6, 3, 5, 4])
[6, 3, 5, 4]
> S.dropWhile (S.even) ([3, 3, 3, 7, 6, 3, 5, 4])
[3, 3, 3, 7, 6, 3, 5, 4]
Curried version of Z.map
.
> S.map (Math.sqrt) ([1, 4, 9])
[1, 2, 3]
> S.map (Math.sqrt) ({x: 1, y: 4, z: 9})
{x: 1, y: 2, z: 3}
> S.map (Math.sqrt) (S.Just (9))
Just (3)
> S.map (Math.sqrt) (S.Right (9))
Right (3)
> S.map (Math.sqrt) (S.Pair (99980001) (99980001))
Pair (99980001) (9999)
Replacing Functor f => f
with Function x
produces the B combinator
from combinatory logic (i.e. compose
):
Functor f => (a -> b) -> f a -> f b
(a -> b) -> Function x a -> Function x b
(a -> c) -> Function x a -> Function x c
(b -> c) -> Function x b -> Function x c
(b -> c) -> Function a b -> Function a c
(b -> c) -> (a -> b) -> (a -> c)
> S.map (Math.sqrt) (S.add (1)) (99)
10
Curried version of Z.flip
. Maps over the given functions, applying
each to the given value.
Replacing Functor f => f
with Function x
produces the C combinator
from combinatory logic:
Functor f => f (a -> b) -> a -> f b
Function x (a -> b) -> a -> Function x b
Function x (a -> c) -> a -> Function x c
Function x (b -> c) -> b -> Function x c
Function a (b -> c) -> b -> Function a c
(a -> b -> c) -> b -> a -> c
> S.flip (S.concat) ('!') ('foo')
'foo!'
> S.flip ([Math.floor, Math.ceil]) (1.5)
[1, 2]
> S.flip ({floor: Math.floor, ceil: Math.ceil}) (1.5)
{floor: 1, ceil: 2}
> S.flip (Cons (Math.floor) (Cons (Math.ceil) (Nil))) (1.5)
Cons (1) (Cons (2) (Nil))
Curried version of Z.bimap
.
> S.bimap (S.toUpper) (Math.sqrt) (S.Pair ('foo') (64))
Pair ('FOO') (8)
> S.bimap (S.toUpper) (Math.sqrt) (S.Left ('foo'))
Left ('FOO')
> S.bimap (S.toUpper) (Math.sqrt) (S.Right (64))
Right (8)
Curried version of Z.mapLeft
. Maps the given function over the left
side of a Bifunctor.
> S.mapLeft (S.toUpper) (S.Pair ('foo') (64))
Pair ('FOO') (64)
> S.mapLeft (S.toUpper) (S.Left ('foo'))
Left ('FOO')
> S.mapLeft (S.toUpper) (S.Right (64))
Right (64)
Curried version of Z.promap
.
> S.promap (Math.abs) (S.add (1)) (Math.sqrt) (-100)
11
Curried version of Z.alt
.
> S.alt (S.Nothing) (S.Just (1))
Just (1)
> S.alt (S.Just (2)) (S.Just (3))
Just (2)
> S.alt (S.Left ('X')) (S.Right (1))
Right (1)
> S.alt (S.Right (2)) (S.Right (3))
Right (2)
Type-safe version of Z.zero
.
> S.zero (Array)
[]
> S.zero (Object)
{}
> S.zero (S.Maybe)
Nothing
Takes a curried binary function, an initial value, and a Foldable,
and applies the function to the initial value and the Foldable's first
value, then applies the function to the result of the previous
application and the Foldable's second value. Repeats this process
until each of the Foldable's values has been used. Returns the initial
value if the Foldable is empty; the result of the final application
otherwise.
> S.reduce (S.add) (0) ([1, 2, 3, 4, 5])
15
> S.reduce (xs => x => S.prepend (x) (xs)) ([]) ([1, 2, 3, 4, 5])
[5, 4, 3, 2, 1]
Curried version of Z.traverse
.
> S.traverse (Array) (S.words) (S.Just ('foo bar baz'))
[Just ('foo'), Just ('bar'), Just ('baz')]
> S.traverse (Array) (S.words) (S.Nothing)
[Nothing]
> S.traverse (S.Maybe) (S.parseInt (16)) (['A', 'B', 'C'])
Just ([10, 11, 12])
> S.traverse (S.Maybe) (S.parseInt (16)) (['A', 'B', 'C', 'X'])
Nothing
> S.traverse (S.Maybe) (S.parseInt (16)) ({a: 'A', b: 'B', c: 'C'})
Just ({a: 10, b: 11, c: 12})
> S.traverse (S.Maybe) (S.parseInt (16)) ({a: 'A', b: 'B', c: 'C', x: 'X'})
Nothing
Curried version of Z.sequence
. Inverts the given t (f a)
to produce an f (t a)
.
> S.sequence (Array) (S.Just ([1, 2, 3]))
[Just (1), Just (2), Just (3)]
> S.sequence (S.Maybe) ([S.Just (1), S.Just (2), S.Just (3)])
Just ([1, 2, 3])
> S.sequence (S.Maybe) ([S.Just (1), S.Just (2), S.Nothing])
Nothing
> S.sequence (S.Maybe) ({a: S.Just (1), b: S.Just (2), c: S.Just (3)})
Just ({a: 1, b: 2, c: 3})
> S.sequence (S.Maybe) ({a: S.Just (1), b: S.Just (2), c: S.Nothing})
Nothing
Curried version of Z.ap
.
> S.ap ([Math.sqrt, x => x * x]) ([1, 4, 9, 16, 25])
[1, 2, 3, 4, 5, 1, 16, 81, 256, 625]
> S.ap ({x: Math.sqrt, y: S.add (1), z: S.sub (1)}) ({w: 4, x: 4, y: 4})
{x: 2, y: 5}
> S.ap (S.Just (Math.sqrt)) (S.Just (64))
Just (8)
Replacing Apply f => f
with Function x
produces the S combinator
from combinatory logic:
Apply f => f (a -> b) -> f a -> f b
Function x (a -> b) -> Function x a -> Function x b
Function x (a -> c) -> Function x a -> Function x c
Function x (b -> c) -> Function x b -> Function x c
Function a (b -> c) -> Function a b -> Function a c
(a -> b -> c) -> (a -> b) -> (a -> c)
> S.ap (s => n => s.slice (0, n)) (s => Math.ceil (s.length / 2)) ('Haskell')
'Hask'
Promotes a curried binary function to a function which operates on two
Applys.
> S.lift2 (S.add) (S.Just (2)) (S.Just (3))
Just (5)
> S.lift2 (S.add) (S.Just (2)) (S.Nothing)
Nothing
> S.lift2 (S.and) (S.Just (true)) (S.Just (true))
Just (true)
> S.lift2 (S.and) (S.Just (true)) (S.Just (false))
Just (false)
Promotes a curried ternary function to a function which operates on three
Applys.
> S.lift3 (S.reduce) (S.Just (S.add)) (S.Just (0)) (S.Just ([1, 2, 3]))
Just (6)
> S.lift3 (S.reduce) (S.Just (S.add)) (S.Just (0)) (S.Nothing)
Nothing
Curried version of Z.apFirst
. Combines two effectful actions,
keeping only the result of the first. Equivalent to Haskell's (<*)
function.
See also apSecond
.
> S.apFirst ([1, 2]) ([3, 4])
[1, 1, 2, 2]
> S.apFirst (S.Just (1)) (S.Just (2))
Just (1)
Curried version of Z.apSecond
. Combines two effectful actions,
keeping only the result of the second. Equivalent to Haskell's (*>)
function.
See also apFirst
.
> S.apSecond ([1, 2]) ([3, 4])
[3, 4, 3, 4]
> S.apSecond (S.Just (1)) (S.Just (2))
Just (2)
Curried version of Z.of
.
> S.of (Array) (42)
[42]
> S.of (Function) (42) (null)
42
> S.of (S.Maybe) (42)
Just (42)
> S.of (S.Either) (42)
Right (42)
Curried version of Z.chain
.
> S.chain (x => [x, x]) ([1, 2, 3])
[1, 1, 2, 2, 3, 3]
> S.chain (n => s => s.slice (0, n)) (s => Math.ceil (s.length / 2)) ('slice')
'sli'
> S.chain (S.parseInt (10)) (S.Just ('123'))
Just (123)
> S.chain (S.parseInt (10)) (S.Just ('XXX'))
Nothing
Type-safe version of Z.join
.
Removes one level of nesting from a nested monadic structure.
> S.join ([[1], [2], [3]])
[1, 2, 3]
> S.join ([[[1, 2, 3]]])
[[1, 2, 3]]
> S.join (S.Just (S.Just (1)))
Just (1)
> S.join (S.Pair ('foo') (S.Pair ('bar') ('baz')))
Pair ('foobar') ('baz')
Replacing Chain m => m
with Function x
produces the W combinator
from combinatory logic:
Chain m => m (m a) -> m a
Function x (Function x a) -> Function x a
(x -> x -> a) -> (x -> a)
> S.join (S.concat) ('abc')
'abcabc'
Performs a chain
-like computation with constant stack usage.
Similar to Z.chainRec
, but curried and more convenient due to the
use of the Either type to indicate completion (via a Right).
> S.chainRec (Array)
. (s => s.length === 2 ? S.map (S.Right) ([s + '!', s + '?'])
. : S.map (S.Left) ([s + 'o', s + 'n']))
. ('')
['oo!', 'oo?', 'on!', 'on?', 'no!', 'no?', 'nn!', 'nn?']
Curried version of Z.extend
.
> S.extend (S.joinWith ('')) (['x', 'y', 'z'])
['xyz', 'yz', 'z']
> S.extend (f => f ([3, 4])) (S.reverse) ([1, 2])
[4, 3, 2, 1]
Type-safe version of Z.duplicate
.
Adds one level of nesting to a comonadic structure.
> S.duplicate (S.Just (1))
Just (Just (1))
> S.duplicate ([1])
[[1]]
> S.duplicate ([1, 2, 3])
[[1, 2, 3], [2, 3], [3]]
> S.duplicate (S.reverse) ([1, 2]) ([3, 4])
[4, 3, 2, 1]
Type-safe version of Z.extract
.
> S.extract (S.Pair ('foo') ('bar'))
'bar'
Type-safe version of Z.contramap
.
> S.contramap (s => s.length) (Math.sqrt) ('Sanctuary')
3
Combinator
The I combinator. Returns its argument. Equivalent to Haskell's id
function.
> S.I ('foo')
'foo'
The K combinator. Takes two values and returns the first. Equivalent to
Haskell's const
function.
> S.K ('foo') ('bar')
'foo'
> S.map (S.K (42)) (S.range (0) (5))
[42, 42, 42, 42, 42]
The T (thrush) combinator. Takes a value and a function, and returns
the result of applying the function to the value. Equivalent to Haskell's
(&)
function.
> S.T (42) (S.add (1))
43
> S.map (S.T (100)) ([S.add (1), Math.sqrt])
[101, 10]
Function
Curries the given binary function.
> S.map (S.curry2 (Math.pow) (10)) ([1, 2, 3])
[10, 100, 1000]
Curries the given ternary function.
> const replaceString = S.curry3 ((what, replacement, string) =>
. string.replace (what, replacement)
. )
> replaceString ('banana') ('orange') ('banana icecream')
'orange icecream'
Curries the given quaternary function.
> const createRect = S.curry4 ((x, y, width, height) =>
. ({x, y, width, height})
. )
> createRect (0) (0) (10) (10)
{x: 0, y: 0, width: 10, height: 10}
Curries the given quinary function.
> const toUrl = S.curry5 ((protocol, creds, hostname, port, pathname) =>
. protocol + '//' +
. S.maybe ('') (S.flip (S.concat) ('@')) (creds) +
. hostname +
. S.maybe ('') (S.concat (':')) (port) +
. pathname
. )
> toUrl ('https:') (S.Nothing) ('example.com') (S.Just ('443')) ('/foo/bar')
'https://example.com:443/foo/bar'
Composition
Curried version of Z.compose
.
When specialized to Function, compose
composes two unary functions,
from right to left (this is the B combinator from combinatory logic).
The generalized type signature indicates that compose
is compatible
with any Semigroupoid.
See also pipe
.
> S.compose (Math.sqrt) (S.add (1)) (99)
10
Takes a sequence of functions assumed to be unary and a value of any
type, and returns the result of applying the sequence of transformations
to the initial value.
In general terms, pipe
performs left-to-right composition of a sequence
of functions. pipe ([f, g, h]) (x)
is equivalent to h (g (f (x)))
.
> S.pipe ([S.add (1), Math.sqrt, S.sub (1)]) (99)
9
Takes a sequence of functions assumed to be unary which return values
with a Chain, and a value of that Chain, and returns the result
of applying the sequence of transformations to the initial value.
In general terms, pipeK
performs left-to-right Kleisli composition
of an sequence of functions. pipeK ([f, g, h]) (x)
is equivalent to
chain (h) (chain (g) (chain (f) (x)))
.
> S.pipeK ([S.tail, S.tail, S.head]) (S.Just ([1, 2, 3, 4]))
Just (3)
Takes a binary function f
, a unary function g
, and two
values x
and y
. Returns f (g (x)) (g (y))
.
This is the P combinator from combinatory logic.
> S.on (S.concat) (S.reverse) ([1, 2, 3]) ([4, 5, 6])
[3, 2, 1, 6, 5, 4]
Pair type
Pair is the canonical product type: a value of type Pair a b
always
contains exactly two values: one of type a
; one of type b
.
The implementation is provided by sanctuary-pair.
A BinaryType
for use with sanctuary-def.
Pair's sole data constructor. Additionally, it serves as the
Pair type representative.
> S.Pair ('foo') (42)
Pair ('foo') (42)
fst (Pair (x) (y))
is equivalent to x
.
> S.fst (S.Pair ('foo') (42))
'foo'
snd (Pair (x) (y))
is equivalent to y
.
> S.snd (S.Pair ('foo') (42))
42
swap (Pair (x) (y))
is equivalent to Pair (y) (x)
.
> S.swap (S.Pair ('foo') (42))
Pair (42) ('foo')
Maybe type
The Maybe type represents optional values: a value of type Maybe a
is
either Nothing (the empty value) or a Just whose value is of type a
.
The implementation is provided by sanctuary-maybe.
A UnaryType
for use with sanctuary-def.
Maybe type representative.
The empty value of type Maybe a
.
> S.Nothing
Nothing
Constructs a value of type Maybe a
from a value of type a
.
> S.Just (42)
Just (42)
Returns true
if the given Maybe is Nothing; false
if it is a Just.
> S.isNothing (S.Nothing)
true
> S.isNothing (S.Just (42))
false
Returns true
if the given Maybe is a Just; false
if it is Nothing.
> S.isJust (S.Just (42))
true
> S.isJust (S.Nothing)
false
Takes a default value and a Maybe, and returns the Maybe's value
if the Maybe is a Just; the default value otherwise.
See also fromMaybe_
and
maybeToNullable
.
> S.fromMaybe (0) (S.Just (42))
42
> S.fromMaybe (0) (S.Nothing)
0
Variant of fromMaybe
which takes a thunk so the default
value is only computed if required.
> function fib(n) { return n <= 1 ? n : fib (n - 2) + fib (n - 1); }
> S.fromMaybe_ (() => fib (30)) (S.Just (1000000))
1000000
> S.fromMaybe_ (() => fib (30)) (S.Nothing)
832040
Returns the given Maybe's value if the Maybe is a Just; null
otherwise.
Nullable is defined in sanctuary-def.
See also fromMaybe
.
> S.maybeToNullable (S.Just (42))
42
> S.maybeToNullable (S.Nothing)
null
Takes a value and returns Nothing if the value is null
or undefined
;
Just the value otherwise.
> S.toMaybe (null)
Nothing
> S.toMaybe (42)
Just (42)
Takes a value of any type, a function, and a Maybe. If the Maybe is
a Just, the return value is the result of applying the function to
the Just's value. Otherwise, the first argument is returned.
See also maybe_
.
> S.maybe (0) (S.prop ('length')) (S.Just ('refuge'))
6
> S.maybe (0) (S.prop ('length')) (S.Nothing)
0
Variant of maybe
which takes a thunk so the default value
is only computed if required.
> function fib(n) { return n <= 1 ? n : fib (n - 2) + fib (n - 1); }
> S.maybe_ (() => fib (30)) (Math.sqrt) (S.Just (1000000))
1000
> S.maybe_ (() => fib (30)) (Math.sqrt) (S.Nothing)
832040
Discards each element which is Nothing, and unwraps each element which is
a Just. Related to Haskell's catMaybes
function.
See also lefts
and rights
.
> S.justs ([S.Just ('foo'), S.Nothing, S.Just ('baz')])
['foo', 'baz']
Takes a function and a structure, applies the function to each element
of the structure, and returns the "successful" results. If the result of
applying the function to an element is Nothing, the result is discarded;
if the result is a Just, the Just's value is included.
> S.mapMaybe (S.head) ([[], [1, 2, 3], [], [4, 5, 6], []])
[1, 4]
> S.mapMaybe (S.head) ({x: [1, 2, 3], y: [], z: [4, 5, 6]})
{x: 1, z: 4}
Takes a unary function f
which may throw and a value x
of any type,
and applies f
to x
inside a try
block. If an exception is caught,
the return value is Nothing; otherwise the return value is Just the
result of applying f
to x
.
See also encaseEither
.
> S.encase (eval) ('1 + 1')
Just (2)
> S.encase (eval) ('1 +')
Nothing
Binary version of encase
.
Ternary version of encase
.
Converts a Maybe to an Either. Nothing becomes a Left (containing the
first argument); a Just becomes a Right.
See also eitherToMaybe
.
> S.maybeToEither ('Expecting an integer') (S.parseInt (10) ('xyz'))
Left ('Expecting an integer')
> S.maybeToEither ('Expecting an integer') (S.parseInt (10) ('42'))
Right (42)
Either type
The Either type represents values with two possibilities: a value of type
Either a b
is either a Left whose value is of type a
or a Right whose
value is of type b
.
The implementation is provided by sanctuary-either.
A BinaryType
for use with sanctuary-def.
Either type representative.
Constructs a value of type Either a b
from a value of type a
.
> S.Left ('Cannot divide by zero')
Left ('Cannot divide by zero')
Constructs a value of type Either a b
from a value of type b
.
> S.Right (42)
Right (42)
Returns true
if the given Either is a Left; false
if it is a Right.
> S.isLeft (S.Left ('Cannot divide by zero'))
true
> S.isLeft (S.Right (42))
false
Returns true
if the given Either is a Right; false
if it is a Left.
> S.isRight (S.Right (42))
true
> S.isRight (S.Left ('Cannot divide by zero'))
false
Takes a default value and an Either, and returns the Right value
if the Either is a Right; the default value otherwise.
> S.fromEither (0) (S.Right (42))
42
> S.fromEither (0) (S.Left (42))
0
Converts an arbitrary value to an Either: a Left if the value is null
or undefined
; a Right otherwise. The first argument specifies the
value of the Left in the "failure" case.
> S.toEither ('XYZ') (null)
Left ('XYZ')
> S.toEither ('XYZ') ('ABC')
Right ('ABC')
> S.map (S.prop ('0'))
. (S.toEither ('Invalid protocol')
. ('ftp://example.com/'.match (/^https?:/)))
Left ('Invalid protocol')
> S.map (S.prop ('0'))
. (S.toEither ('Invalid protocol')
. ('https://example.com/'.match (/^https?:/)))
Right ('https:')
Takes two functions and an Either, and returns the result of
applying the first function to the Left's value, if the Either
is a Left, or the result of applying the second function to the
Right's value, if the Either is a Right.
> S.either (S.toUpper) (S.show) (S.Left ('Cannot divide by zero'))
'CANNOT DIVIDE BY ZERO'
> S.either (S.toUpper) (S.show) (S.Right (42))
'42'
Discards each element which is a Right, and unwraps each element which is
a Left.
See also rights
.
> S.lefts ([S.Right (20), S.Left ('foo'), S.Right (10), S.Left ('bar')])
['foo', 'bar']
Discards each element which is a Left, and unwraps each element which is
a Right.
See also lefts
.
> S.rights ([S.Right (20), S.Left ('foo'), S.Right (10), S.Left ('bar')])
[20, 10]
Takes a predicate and a value, and returns a Right of the value if it
satisfies the predicate; a Left of the value otherwise.
> S.tagBy (S.odd) (0)
Left (0)
> S.tagBy (S.odd) (1)
Right (1)
Takes two unary functions, f
and g
, the second of which may throw,
and a value x
of any type. Applies g
to x
inside a try
block.
If an exception is caught, the return value is a Left containing the
result of applying f
to the caught Error object; otherwise the return
value is a Right containing the result of applying g
to x
.
See also encase
.
> S.encaseEither (S.I) (JSON.parse) ('["foo","bar","baz"]')
Right (['foo', 'bar', 'baz'])
> S.encaseEither (S.I) (JSON.parse) ('[')
Left (new SyntaxError ('Unexpected end of JSON input'))
> S.encaseEither (S.prop ('message')) (JSON.parse) ('[')
Left ('Unexpected end of JSON input')
Binary version of encaseEither
.
Ternary version of encaseEither
.
Converts an Either to a Maybe. A Left becomes Nothing; a Right becomes
a Just.
See also maybeToEither
.
> S.eitherToMaybe (S.Left ('Cannot divide by zero'))
Nothing
> S.eitherToMaybe (S.Right (42))
Just (42)
Logic
Boolean "and".
> S.and (false) (false)
false
> S.and (false) (true)
false
> S.and (true) (false)
false
> S.and (true) (true)
true
Boolean "or".
> S.or (false) (false)
false
> S.or (false) (true)
true
> S.or (true) (false)
true
> S.or (true) (true)
true
Boolean "not".
See also complement
.
> S.not (false)
true
> S.not (true)
false
Takes a unary predicate and a value of any type, and returns the logical
negation of applying the predicate to the value.
See also not
.
> Number.isInteger (42)
true
> S.complement (Number.isInteger) (42)
false
Case analysis for the Boolean
type. boolean (x) (y) (b)
evaluates
to x
if b
is false
; to y
if b
is true
.
> S.boolean ('no') ('yes') (false)
'no'
> S.boolean ('no') ('yes') (true)
'yes'
Takes a unary predicate, a unary "if" function, a unary "else"
function, and a value of any type, and returns the result of
applying the "if" function to the value if the value satisfies
the predicate; the result of applying the "else" function to the
value otherwise.
See also when
and unless
.
> S.ifElse (x => x < 0) (Math.abs) (Math.sqrt) (-1)
1
> S.ifElse (x => x < 0) (Math.abs) (Math.sqrt) (16)
4
Takes a unary predicate, a unary function, and a value of any type, and
returns the result of applying the function to the value if the value
satisfies the predicate; the value otherwise.
See also unless
and ifElse
.
> S.when (x => x >= 0) (Math.sqrt) (16)
4
> S.when (x => x >= 0) (Math.sqrt) (-1)
-1
Takes a unary predicate, a unary function, and a value of any type, and
returns the result of applying the function to the value if the value
does not satisfy the predicate; the value otherwise.
See also when
and ifElse
.
> S.unless (x => x < 0) (Math.sqrt) (16)
4
> S.unless (x => x < 0) (Math.sqrt) (-1)
-1
Takes a structure containing zero or more predicates, and a value
of any type. Returns true
iff the value satisfies all of the
predicates. None of the subsequent predicates will be applied after
the first predicate not satisfied.
> S.allPass ([S.test (/q/), S.test (/u/), S.test (/i/)]) ('quiessence')
true
> S.allPass ([S.test (/q/), S.test (/u/), S.test (/i/)]) ('fissiparous')
false
Takes a structure containing zero or more predicates, and a value
of any type. Returns true
iff the value satisfies any of the
predicates. None of the subsequent predicates will be applied after
the first predicate satisfied.
> S.anyPass ([S.test (/q/), S.test (/u/), S.test (/i/)]) ('incandescent')
true
> S.anyPass ([S.test (/q/), S.test (/u/), S.test (/i/)]) ('empathy')
false
Array
Case analysis for the Array a
type.
> S.array (S.Nothing) (head => tail => S.Just (head)) ([])
Nothing
> S.array (S.Nothing) (head => tail => S.Just (head)) ([1, 2, 3])
Just (1)
> S.array (S.Nothing) (head => tail => S.Just (tail)) ([])
Nothing
> S.array (S.Nothing) (head => tail => S.Just (tail)) ([1, 2, 3])
Just ([2, 3])
Takes a start index i
, an end index j
, and an array, and returns
Just the [i,j)
slice of the array if possible; Nothing otherwise.
A negative index represents an offset from the length of the array.
See also take
, drop
, takeLast
,
and dropLast
.
> S.slice (1) (3) (['a', 'b', 'c', 'd', 'e'])
Just (['b', 'c'])
> S.slice (-3) (-1) (['a', 'b', 'c', 'd', 'e'])
Just (['c', 'd'])
> S.slice (1) (6) (['a', 'b', 'c', 'd', 'e'])
Nothing
Returns Just the element of the given array at the specified index if
the index is within the array's bounds; Nothing otherwise. A negative
index represents an offset from the length of the array.
> S.at (2) (['a', 'b', 'c', 'd', 'e'])
Just ('c')
> S.at (5) (['a', 'b', 'c', 'd', 'e'])
Nothing
> S.at (-2) (['a', 'b', 'c', 'd', 'e'])
Just ('d')
Returns Just the first element of the given array if the array contains
at least one element; Nothing otherwise.
> S.head ([1, 2, 3])
Just (1)
> S.head ([])
Nothing
Returns Just the last element of the given array if the array contains
at least one element; Nothing otherwise.
> S.last ([1, 2, 3])
Just (3)
> S.last ([])
Nothing
Returns Just all but the first of the given array's elements if the
array contains at least one element; Nothing otherwise.
> S.tail ([1, 2, 3])
Just ([2, 3])
> S.tail ([])
Nothing
Returns Just all but the last of the given array's elements if the
array contains at least one element; Nothing otherwise.
> S.init ([1, 2, 3])
Just ([1, 2])
> S.init ([])
Nothing
Returns Just the first N elements of the given array if N is greater
than or equal to zero and less than or equal to the length of the array;
Nothing otherwise.
> S.take (2) (['a', 'b', 'c', 'd', 'e'])
Just (['a', 'b'])
> S.take (5) (['a', 'b', 'c', 'd', 'e'])
Just (['a', 'b', 'c', 'd', 'e'])
> S.take (6) (['a', 'b', 'c', 'd', 'e'])
Nothing
Returns Just the last N elements of the given array if N is greater
than or equal to zero and less than or equal to the length of the array;
Nothing otherwise.
> S.takeLast (2) (['a', 'b', 'c', 'd', 'e'])
Just (['d', 'e'])
> S.takeLast (5) (['a', 'b', 'c', 'd', 'e'])
Just (['a', 'b', 'c', 'd', 'e'])
> S.takeLast (6) (['a', 'b', 'c', 'd', 'e'])
Nothing
Returns Just all but the first N elements of the given array if N is
greater than or equal to zero and less than or equal to the length of
the array; Nothing otherwise.
> S.drop (2) (['a', 'b', 'c', 'd', 'e'])
Just (['c', 'd', 'e'])
> S.drop (5) (['a', 'b', 'c', 'd', 'e'])
Just ([])
> S.drop (6) (['a', 'b', 'c', 'd', 'e'])
Nothing
Returns Just all but the last N elements of the given array if N is
greater than or equal to zero and less than or equal to the length of
the array; Nothing otherwise.
> S.dropLast (2) (['a', 'b', 'c', 'd', 'e'])
Just (['a', 'b', 'c'])
> S.dropLast (5) (['a', 'b', 'c', 'd', 'e'])
Just ([])
> S.dropLast (6) (['a', 'b', 'c', 'd', 'e'])
Nothing
Returns the number of elements of the given structure.
> S.size ([])
0
> S.size (['foo', 'bar', 'baz'])
3
> S.size (Nil)
0
> S.size (Cons ('foo') (Cons ('bar') (Cons ('baz') (Nil))))
3
> S.size (S.Nothing)
0
> S.size (S.Just ('quux'))
1
> S.size (S.Pair ('ignored!') ('counted!'))
1
Returns true
iff all the elements of the structure satisfy the
predicate.
See also any
and none
.
> S.all (S.odd) ([])
true
> S.all (S.odd) ([1, 3, 5])
true
> S.all (S.odd) ([1, 2, 3])
false
Returns true
iff any element of the structure satisfies the
predicate.
See also all
and none
.
> S.any (S.odd) ([])
false
> S.any (S.odd) ([2, 4, 6])
false
> S.any (S.odd) ([1, 2, 3])
true
Returns true
iff none of the elements of the structure satisfies
the predicate.
Properties:
-
forall p :: a -> Boolean, xs :: Foldable f => f a. S.none (p) (xs) = S.not (S.any (p) (xs))
-
forall p :: a -> Boolean, xs :: Foldable f => f a. S.none (p) (xs) = S.all (S.complement (p)) (xs)
See also all
and any
.
> S.none (S.odd) ([])
true
> S.none (S.odd) ([2, 4, 6])
true
> S.none (S.odd) ([1, 2, 3])
false
Returns the result of appending the first argument to the second.
See also prepend
.
> S.append (3) ([1, 2])
[1, 2, 3]
> S.append (3) (Cons (1) (Cons (2) (Nil)))
Cons (1) (Cons (2) (Cons (3) (Nil)))
> S.append ([1]) (S.Nothing)
Just ([1])
> S.append ([3]) (S.Just ([1, 2]))
Just ([1, 2, 3])
Returns the result of prepending the first argument to the second.
See also append
.
> S.prepend (1) ([2, 3])
[1, 2, 3]
> S.prepend (1) (Cons (2) (Cons (3) (Nil)))
Cons (1) (Cons (2) (Cons (3) (Nil)))
> S.prepend ([1]) (S.Nothing)
Just ([1])
> S.prepend ([1]) (S.Just ([2, 3]))
Just ([1, 2, 3])
Joins the strings of the second argument separated by the first argument.
Properties:
forall s :: String, t :: String. S.joinWith (s) (S.splitOn (s) (t)) = t
See also splitOn
.
> S.joinWith (':') (['foo', 'bar', 'baz'])
'foo:bar:baz'
Takes a value and a structure and returns true
iff the value is an
element of the structure.
See also find
.
> S.elem ('c') (['a', 'b', 'c'])
true
> S.elem ('x') (['a', 'b', 'c'])
false
> S.elem (3) ({x: 1, y: 2, z: 3})
true
> S.elem (8) ({x: 1, y: 2, z: 3})
false
> S.elem (0) (S.Just (0))
true
> S.elem (0) (S.Just (1))
false
> S.elem (0) (S.Nothing)
false
Takes a predicate and a structure and returns Just the leftmost element
of the structure which satisfies the predicate; Nothing if there is no
such element.
See also elem
.
> S.find (S.lt (0)) ([1, -2, 3, -4, 5])
Just (-2)
> S.find (S.lt (0)) ([1, 2, 3, 4, 5])
Nothing
Curried version of Z.foldMap
. Deconstructs a foldable by mapping
every element to a monoid and concatenating the results.
> S.foldMap (String) (f => f.name) ([Math.sin, Math.cos, Math.tan])
'sincostan'
> S.foldMap (Array) (x => [x + 1, x + 2]) ([10, 20, 30])
[11, 12, 21, 22, 31, 32]
Takes a function and a seed value, and returns an array generated by
applying the function repeatedly. The array is initially empty. The
function is initially applied to the seed value. Each application
of the function should result in either:
-
Nothing, in which case the array is returned; or
-
Just a pair, in which case the first element is appended to
the array and the function is applied to the second element.
> S.unfoldr (n => n < 1000 ? S.Just (S.Pair (n) (2 * n)) : S.Nothing) (1)
[1, 2, 4, 8, 16, 32, 64, 128, 256, 512]
Returns an array of consecutive integers starting with the first argument
and ending with the second argument minus one. Returns []
if the second
argument is less than or equal to the first argument.
> S.range (0) (10)
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
> S.range (-5) (0)
[-5, -4, -3, -2, -1]
> S.range (0) (-5)
[]
Splits its array argument into an array of arrays of equal,
adjacent elements. Equality is determined by the function
provided as the first argument. Its behaviour can be surprising
for functions that aren't reflexive, transitive, and symmetric
(see equivalence relation).
Properties:
forall f :: a -> a -> Boolean, xs :: Array a. S.join (S.groupBy (f) (xs)) = xs
> S.groupBy (S.equals) ([1, 1, 2, 1, 1])
[[1, 1], [2], [1, 1]]
> S.groupBy (x => y => x + y === 0) ([2, -3, 3, 3, 3, 4, -4, 4])
[[2], [-3, 3, 3, 3], [4, -4], [4]]
Reverses the elements of the given structure.
> S.reverse ([1, 2, 3])
[3, 2, 1]
> S.reverse (Cons (1) (Cons (2) (Cons (3) (Nil))))
Cons (3) (Cons (2) (Cons (1) (Nil)))
> S.pipe ([S.splitOn (''), S.reverse, S.joinWith ('')]) ('abc')
'cba'
Performs a stable sort of the elements of the given structure, using
Z.lte
for comparisons.
Properties:
S.sort (S.sort (m)) = S.sort (m)
(idempotence)
See also sortBy
.
> S.sort (['foo', 'bar', 'baz'])
['bar', 'baz', 'foo']
> S.sort ([S.Left (4), S.Right (3), S.Left (2), S.Right (1)])
[Left (2), Left (4), Right (1), Right (3)]
Performs a stable sort of the elements of the given structure, using
Z.lte
to compare the values produced by applying the given function
to each element of the structure.
Properties:
S.sortBy (f) (S.sortBy (f) (m)) = S.sortBy (f) (m)
(idempotence)
See also sort
.
> S.sortBy (S.prop ('rank')) ([
. {rank: 7, suit: 'spades'},
. {rank: 5, suit: 'hearts'},
. {rank: 2, suit: 'hearts'},
. {rank: 5, suit: 'spades'},
. ])
[ {rank: 2, suit: 'hearts'},
. {rank: 5, suit: 'hearts'},
. {rank: 5, suit: 'spades'},
. {rank: 7, suit: 'spades'} ]
> S.sortBy (S.prop ('suit')) ([
. {rank: 7, suit: 'spades'},
. {rank: 5, suit: 'hearts'},
. {rank: 2, suit: 'hearts'},
. {rank: 5, suit: 'spades'},
. ])
[ {rank: 5, suit: 'hearts'},
. {rank: 2, suit: 'hearts'},
. {rank: 7, suit: 'spades'},
. {rank: 5, suit: 'spades'} ]
If descending order is desired, one may use Descending
:
> S.sortBy (Descending) ([83, 97, 110, 99, 116, 117, 97, 114, 121])
[121, 117, 116, 114, 110, 99, 97, 97, 83]
Returns an array of pairs of corresponding elements from the given
arrays. The length of the resulting array is equal to the length of
the shorter input array.
See also zipWith
.
> S.zip (['a', 'b']) (['x', 'y', 'z'])
[Pair ('a') ('x'), Pair ('b') ('y')]
> S.zip ([1, 3, 5]) ([2, 4])
[Pair (1) (2), Pair (3) (4)]
Returns the result of combining, pairwise, the given arrays using the
given binary function. The length of the resulting array is equal to the
length of the shorter input array.
See also zip
.
> S.zipWith (a => b => a + b) (['a', 'b']) (['x', 'y', 'z'])
['ax', 'by']
> S.zipWith (a => b => [a, b]) ([1, 3, 5]) ([2, 4])
[[1, 2], [3, 4]]
Object
Takes a property name and an object with known properties and returns
the value of the specified property. If for some reason the object
lacks the specified property, a type error is thrown.
For accessing properties of uncertain objects, use get
instead.
> S.prop ('a') ({a: 1, b: 2})
1
Takes a property path (an array of property names) and an object with
known structure and returns the value at the given path. If for some
reason the path does not exist, a type error is thrown.
For accessing property paths of uncertain objects, use gets
instead.
> S.props (['a', 'b', 'c']) ({a: {b: {c: 1}}})
1
Takes a predicate, a property name, and an object and returns Just the
value of the specified object property if it exists and the value
satisfies the given predicate; Nothing otherwise.
See also gets
and prop
.
> S.get (S.is ($.Number)) ('x') ({x: 1, y: 2})
Just (1)
> S.get (S.is ($.Number)) ('x') ({x: '1', y: '2'})
Nothing
> S.get (S.is ($.Number)) ('x') ({})
Nothing
> S.get (S.is ($.Array ($.Number))) ('x') ({x: [1, 2, 3]})
Just ([1, 2, 3])
> S.get (S.is ($.Array ($.Number))) ('x') ({x: [1, 2, 3, null]})
Nothing
Takes a predicate, a property path (an array of property names), and
an object and returns Just the value at the given path if such a path
exists and the value satisfies the given predicate; Nothing otherwise.
See also get
.
> S.gets (S.is ($.Number)) (['a', 'b', 'c']) ({a: {b: {c: 42}}})
Just (42)
> S.gets (S.is ($.Number)) (['a', 'b', 'c']) ({a: {b: {c: '42'}}})
Nothing
> S.gets (S.is ($.Number)) (['a', 'b', 'c']) ({})
Nothing
StrMap
StrMap is an abbreviation of string map. A string map is an object,
such as {foo: 1, bar: 2, baz: 3}
, whose values are all members of
the same type. Formally, a value is a member of type StrMap a
if its
type identifier is 'Object'
and the values of its enumerable own
properties are all members of type a
.
Takes a string and a value of any type, and returns a string map with
a single entry (mapping the key to the value).
> S.singleton ('foo') (42)
{foo: 42}
Takes a string, a value of any type, and a string map, and returns a
string map comprising all the entries of the given string map plus the
entry specified by the first two arguments (which takes precedence).
Equivalent to Haskell's insert
function. Similar to Clojure's assoc
function.
> S.insert ('c') (3) ({a: 1, b: 2})
{a: 1, b: 2, c: 3}
> S.insert ('a') (4) ({a: 1, b: 2})
{a: 4, b: 2}
Takes a string and a string map, and returns a string map comprising all
the entries of the given string map except the one whose key matches the
given string (if such a key exists).
Equivalent to Haskell's delete
function. Similar to Clojure's dissoc
function.
> S.remove ('c') ({a: 1, b: 2, c: 3})
{a: 1, b: 2}
> S.remove ('c') ({})
{}
Returns the keys of the given string map, in arbitrary order.
> S.sort (S.keys ({b: 2, c: 3, a: 1}))
['a', 'b', 'c']
Returns the values of the given string map, in arbitrary order.
> S.sort (S.values ({a: 1, c: 3, b: 2}))
[1, 2, 3]
Returns the key–value pairs of the given string map, in arbitrary order.
> S.sort (S.pairs ({b: 2, a: 1, c: 3}))
[Pair ('a') (1), Pair ('b') (2), Pair ('c') (3)]
Returns a string map containing the key–value pairs specified by the
given Foldable. If a key appears in multiple pairs, the rightmost
pair takes precedence.
> S.fromPairs ([S.Pair ('a') (1), S.Pair ('b') (2), S.Pair ('c') (3)])
{a: 1, b: 2, c: 3}
> S.fromPairs ([S.Pair ('x') (1), S.Pair ('x') (2)])
{x: 2}
Number
Negates its argument.
> S.negate (12.5)
-12.5
> S.negate (-42)
42
Returns the sum of two (finite) numbers.
> S.add (1) (1)
2
Returns the sum of the given array of (finite) numbers.
> S.sum ([1, 2, 3, 4, 5])
15
> S.sum ([])
0
> S.sum (S.Just (42))
42
> S.sum (S.Nothing)
0
Takes a finite number n
and returns the subtract n
function.
> S.map (S.sub (1)) ([1, 2, 3])
[0, 1, 2]
Returns the product of two (finite) numbers.
> S.mult (4) (2)
8
Returns the product of the given array of (finite) numbers.
> S.product ([1, 2, 3, 4, 5])
120
> S.product ([])
1
> S.product (S.Just (42))
42
> S.product (S.Nothing)
1
Takes a non-zero finite number n
and returns the divide by n
function.
> S.map (S.div (2)) ([0, 1, 2, 3])
[0, 0.5, 1, 1.5]
Takes a finite number n
and returns the power of n
function.
> S.map (S.pow (2)) ([-3, -2, -1, 0, 1, 2, 3])
[9, 4, 1, 0, 1, 4, 9]
> S.map (S.pow (0.5)) ([1, 4, 9, 16, 25])
[1, 2, 3, 4, 5]
Returns the mean of the given array of (finite) numbers.
> S.mean ([1, 2, 3, 4, 5])
Just (3)
> S.mean ([])
Nothing
> S.mean (S.Just (42))
Just (42)
> S.mean (S.Nothing)
Nothing
Integer
Returns true
if the given integer is even; false
if it is odd.
> S.even (42)
true
> S.even (99)
false
Returns true
if the given integer is odd; false
if it is even.
> S.odd (99)
true
> S.odd (42)
false
Parse
Takes a string s
and returns Just (new Date (s))
if new Date (s)
evaluates to a ValidDate
value; Nothing otherwise.
As noted in #488, this function's behaviour is unspecified for some
inputs! MDN warns against using the Date
constructor
to parse date strings:
Note: parsing of date strings with the Date
constructor […] is
strongly discouraged due to browser differences and inconsistencies.
Support for RFC 2822 format strings is by convention only. Support for
ISO 8601 formats differs in that date-only strings (e.g. "1970-01-01")
are treated as UTC, not local.
> S.parseDate ('2011-01-19T17:40:00Z')
Just (new Date ('2011-01-19T17:40:00.000Z'))
> S.parseDate ('today')
Nothing
Takes a string and returns Just the number represented by the string
if it does in fact represent a number; Nothing otherwise.
> S.parseFloat ('-123.45')
Just (-123.45)
> S.parseFloat ('foo.bar')
Nothing
Takes a radix (an integer between 2 and 36 inclusive) and a string,
and returns Just the number represented by the string if it does in
fact represent a number in the base specified by the radix; Nothing
otherwise.
This function is stricter than parseInt
: a string
is considered to represent an integer only if all its non-prefix
characters are members of the character set specified by the radix.
> S.parseInt (10) ('-42')
Just (-42)
> S.parseInt (16) ('0xFF')
Just (255)
> S.parseInt (16) ('0xGG')
Nothing
Takes a predicate and a string which may or may not be valid JSON, and
returns Just the result of applying JSON.parse
to the string if the
result satisfies the predicate; Nothing otherwise.
> S.parseJson (S.is ($.Array ($.Integer))) ('[')
Nothing
> S.parseJson (S.is ($.Array ($.Integer))) ('["1","2","3"]')
Nothing
> S.parseJson (S.is ($.Array ($.Integer))) ('[0,1.5,3,4.5]')
Nothing
> S.parseJson (S.is ($.Array ($.Integer))) ('[1,2,3]')
Just ([1, 2, 3])
RegExp
Takes a RegexFlags and a pattern, and returns a RegExp.
> S.regex ('g') (':\\d+:')
/:\d+:/g
Takes a string which may contain regular expression metacharacters,
and returns a string with those metacharacters escaped.
Properties:
forall s :: String. S.test (S.regex ('') (S.regexEscape (s))) (s) = true
> S.regexEscape ('-=*{XYZ}*=-')
'\\-=\\*\\{XYZ\\}\\*=\\-'
Takes a pattern and a string, and returns true
iff the pattern
matches the string.
> S.test (/^a/) ('abacus')
true
> S.test (/^a/) ('banana')
false
Takes a pattern and a string, and returns Just a match record if the
pattern matches the string; Nothing otherwise.
groups :: Array (Maybe String)
acknowledges the existence of optional
capturing groups.
Properties:
forall p :: Pattern, s :: String. S.head (S.matchAll (S.regex ('g') (p)) (s)) = S.match (S.regex ('') (p)) (s)
See also matchAll
.
> S.match (/(good)?bye/) ('goodbye')
Just ({match: 'goodbye', groups: [Just ('good')]})
> S.match (/(good)?bye/) ('bye')
Just ({match: 'bye', groups: [Nothing]})
Takes a pattern and a string, and returns an array of match records.
groups :: Array (Maybe String)
acknowledges the existence of optional
capturing groups.
See also match
.
> S.matchAll (/@([a-z]+)/g) ('Hello, world!')
[]
> S.matchAll (/@([a-z]+)/g) ('Hello, @foo! Hello, @bar! Hello, @baz!')
[ {match: '@foo', groups: [Just ('foo')]},
. {match: '@bar', groups: [Just ('bar')]},
. {match: '@baz', groups: [Just ('baz')]} ]
String
Returns the upper-case equivalent of its argument.
See also toLower
.
> S.toUpper ('ABC def 123')
'ABC DEF 123'
Returns the lower-case equivalent of its argument.
See also toUpper
.
> S.toLower ('ABC def 123')
'abc def 123'
Strips leading and trailing whitespace characters.
> S.trim ('\t\t foo bar \n')
'foo bar'
Returns Just the portion of the given string (the second argument) left
after removing the given prefix (the first argument) if the string starts
with the prefix; Nothing otherwise.
See also stripSuffix
.
> S.stripPrefix ('https://') ('https://sanctuary.js.org')
Just ('sanctuary.js.org')
> S.stripPrefix ('https://') ('http://sanctuary.js.org')
Nothing
Returns Just the portion of the given string (the second argument) left
after removing the given suffix (the first argument) if the string ends
with the suffix; Nothing otherwise.
See also stripPrefix
.
> S.stripSuffix ('.md') ('README.md')
Just ('README')
> S.stripSuffix ('.md') ('README')
Nothing
Takes a string and returns the array of words the string contains
(words are delimited by whitespace characters).
See also unwords
.
> S.words (' foo bar baz ')
['foo', 'bar', 'baz']
Takes an array of words and returns the result of joining the words
with separating spaces.
See also words
.
> S.unwords (['foo', 'bar', 'baz'])
'foo bar baz'
Takes a string and returns the array of lines the string contains
(lines are delimited by newlines: '\n'
or '\r\n'
or '\r'
).
The resulting strings do not contain newlines.
See also unlines
.
> S.lines ('foo\nbar\nbaz\n')
['foo', 'bar', 'baz']
Takes an array of lines and returns the result of joining the lines
after appending a terminating line feed ('\n'
) to each.
See also lines
.
> S.unlines (['foo', 'bar', 'baz'])
'foo\nbar\nbaz\n'
Returns the substrings of its second argument separated by occurrences
of its first argument.
See also joinWith
and splitOnRegex
.
> S.splitOn ('::') ('foo::bar::baz')
['foo', 'bar', 'baz']
Takes a pattern and a string, and returns the result of splitting the
string at every non-overlapping occurrence of the pattern.
Properties:
forall s :: String, t :: String. S.joinWith (s) (S.splitOnRegex (S.regex ('g') (S.regexEscape (s))) (t)) = t
See also splitOn
.
> S.splitOnRegex (/[,;][ ]*/g) ('foo, bar, baz')
['foo', 'bar', 'baz']
> S.splitOnRegex (/[,;][ ]*/g) ('foo;bar;baz')
['foo', 'bar', 'baz']