I would combine `startsWith`

and `anyPass`

like this:

```
const textStartsWith = pipe (
map (startsWith),
anyPass,
flip (o) (String),
filter
)
console .log (
textStartsWith
(['pen', 'paper'])
(['pen', 'pencil', 'paper', '', undefined, true, 'books', 'paperback'])
)
```

```
<script src="https://cdnjs.cloudflare.com/ajax/libs/ramda/0.27.1/ramda.min.js"></script>
<script>const {pipe, map, startsWith, anyPass, flip, o, filter} = R </script>
```

If you want to be able to pass the arguments in one go, you can just wrap this up in `uncurry`

:

```
const textStartsWith = uncurryN (2) (pipe (
map (startsWith),
anyPass,
flip (o) (String),
filter
))
textStartsWith (query, target)
```

This does point out a missing function in Ramda, I think. Ramda has variadic `compose`

and `pipe`

functions, and a curried binary compose, `o`

. But there's no equivalent curried binary `pipe`

.

## If you read Haskell

One possible way to arrive at such an implementation is to make a fully curried function, and then paste a Haskell equivalent into http://pointfree.io.

So if we started with this function:

```
const f1 = (query) => (target) => filter (pipe (
String,
anyPass (map( startsWith) (query))
)) (target)
```

We can make a Haskell version like this:

```
\query -> \target -> filter ((anyPass ((map startsWith) query)) . string) target
```

which then returns this:

```
filter . (. string) . anyPass . map startsWith
```

which we can convert back into JS like the first answer above by noting that `foo . bar`

is the composition of `foo`

and `bar`

and that `(. foo)`

is equivalent to `flip (o) (foo)`

or `o (__, foo)`

And we can end up with something like the first snippet above.

## Update

User Kuncheria asked about `flip (o) (String)`

. Perhaps a walk through the signatures might help. We pass four functions to pipe.

`map (startsWith)`

has the signature `[String] -> [(String -> Boolean)]`

. It takes a list of Strings and returns a list of functions from String to Boolean.

`anyPass`

has the signature `[(a -> Boolean)] -> (a -> Boolean)`

. It takes a list of functions from some arbitrary type, `a`

to `Boolean`

and returns a single function from an `a`

to `Boolean`

(which will be `true`

exactly when at least one of those functions return true for the `a`

supplied.)

Now we can combine the output of `map (startsWith)`

(`[(String -> Boolean)]`

with the input to `anyPass`

, by substituting `String`

for `a`

, and so `pipe (map (startsWith), anyPass))`

has the signature `[String] -> (String -> Boolean)`

.

`flip (o) (String)`

is the most complex function here, and we'll explain it below. There we'll find out that its type is `(String -> c) -> (a -> c)`

.

And now substituting `Boolean`

for `c`

, we combine with the above to to see that `pipe (map (startsWith), anyPass, flip (o) (String))`

has the signature `[String] -> (a -> Boolean)`

.

`filter`

simply has the signature `(a -> Boolean) -> [a] -> [a]`

. It accepts a function that transforms a value of type `a`

into a boolean, and returns a function that takes a list of values of type `a`

and returns the filtered list of those for which the function returns `true`

.

So combining this with the above, we can note that our main function -- `pipe (map (startsWith), anyPass, flip (o) (String), filter)`

-- has the signature `[String] -> [a] -> [a]`

We might write the above discussion more compactly like this:

```
const textStartsWith = pipe (
map (startsWith), // [String] -> [(String -> Boolean)]
anyPass, // [(a -> Boolean)] -> (a -> Boolean)
// a = String => [String] -> (String -> Boolean)
flip (o) (String), // (String -> c) -> (a -> c)
// c = Boolean => [String] -> (a -> Boolean)
filter // (a -> Boolean) -> [a] -> [a]
// => [String] -> [a] -> [a]
)
```

But we still need to discuss `flip (o) (String)`

.

`o`

is a curried binary `compose`

function, whose signature is

```
o :: (b -> c) -> (a -> b) -> (a -> c)
```

We can `flip`

it, to get:

```
flip (o) :: (a -> b) -> (b -> c) -> (a -> c)
```

Now we run into a notational problem. We've been using `String`

to denote the String type. But in JS, `String`

is also a function: constructing a String out of any value. We can think of it as the function from some type `a`

to a String, that is with type `a -> String`

. So, since

```
flip (o) :: (a -> b) -> (b -> c) -> (a -> c)
```

We can see this:

```
flip (o) (String)
; ^----------------- Constructor function
flip (o) (a -> String)
; ^------------ Data type
flip (o) (String) :: (String -> c) -> (a -> c)
; ^ ^----- Data type
; +----------------- Constructor function
```

We can think of `flip (o) (String)`

as a function that accepts a function which transforms a String into type `c`

, and returns a function which transforms something of type `a`

into something of type `c`

. An example would be `length`

, the function which takes the length of a string:

```
const strLength = flip (o) (String) (length)
strLength ('abc') //=> 3 because String ('abc') = 'abc'
strLength (42) //=> 2 because String (42) = '42'
strLength (void 0) //=> 9 because String (void 0) = 'undefined'
strLength ({}) //=> 15 because String ({}) = 'object [Object]'
```