Thanks to the answers from Scott Sauyet and Bergi, I wrapped my head around it. In doing so, I felt there were still hoops to jump to put all the pieces together. I will document some questions I had in the journey, hope it could be of help to some.

Here's the example of `R.lift`

we try to understand:

```
var madd3 = R.lift((a, b, c) => a + b + c);
madd3([1,2,3], [1,2,3], [1]); //=> [3, 4, 5, 4, 5, 6, 5, 6, 7]
```

To me, there are **three questions to be answered before understanding it**.

- Fantasy-land's
`Apply`

spec (I will refer to it as `Apply`

) and what `Apply#ap`

does
- Ramda's
`R.ap`

implementation and what does `Array`

has to do with the `Apply`

spec
- What role does currying play in
`R.lift`

### Understanding the `Apply`

spec

In fantasy-land, an object implements `Apply`

spec when it has an `ap`

method defined (that object also has to implement `Functor`

spec by defining a `map`

method).

The `ap`

method has the following signature:

```
ap :: Apply f => f a ~> f (a -> b) -> f b
```

In fantasy-land's type signature notation:

`=>`

declares type constraints, so `f`

in the signature above refers to type `Apply`

`~>`

declares *method* declaration, so `ap`

should be a function declared on `Apply`

which wraps around a value which we refer to as `a`

(we will see in the example below, some fantasy-land's implementations of `ap`

are not consistent with this signature, but the idea is the same)

Let's say we have two objects `v`

and `u`

(`v = f a; u = f (a -> b)`

) thus this expression is valid `v.ap(u)`

, some things to notice here:

`v`

and `u`

both implement `Apply`

. `v`

holds a value, `u`

holds a function but they have the same 'interface' of `Apply`

(this will help in understanding the next section below, when it comes to `R.ap`

and `Array`

)
- The value
`a`

and function `a -> b`

are ignorant of `Apply`

, the function just transforms the value `a`

. It's the `Apply`

that puts value and function inside the container and `ap`

that extracts them out, invokes the function on the value and puts them back in.

### Understanding `Ramda`

's `R.ap`

The signature of `R.ap`

has two cases:

`Apply f => f (a → b) → f a → f b`

: This is very similar to the signature of `Apply#ap`

in last section, the difference is how `ap`

is invoked (`Apply#ap`

vs. `R.ap`

) and the order of params.
`[a → b] → [a] → [b]`

: This is the version if we replace `Apply f`

with `Array`

, remember that the value and function has to be wrapped in the same container in the previous section? That's why when using `R.ap`

with `Array`

s, the first argument is a list of functions, even if you want to apply only one function, put it in an Array.

Let's look at one example, I'm using `Maybe`

from `ramada-fantasy`

, which implements `Apply`

, one inconsistency here is that `Maybe#ap`

's signature is: `ap :: Apply f => f (a -> b) ~> f a -> f b`

. Seems some other `fantasy-land`

implementations also follow this, however, it shouldn't affect our understanding:

```
const R = require('ramda');
const Maybe = require('ramda-fantasy').Maybe;
const a = Maybe.of(2);
const plus3 = Maybe.of(x => x + 3);
const b = plus3.ap(a); // invoke Apply#ap
const b2 = R.ap(plus3, a); // invoke R.ap
console.log(b); // Just { value: 5 }
console.log(b2); // Just { value: 5 }
```

### Understanding the example of `R.lift`

In `R.lift`

's example with arrays, a function with arity of 3 is passed to `R.lift`

: `var madd3 = R.lift((a, b, c) => a + b + c);`

, how does it work with the three arrays `[1, 2, 3], [1, 2, 3], [1]`

? Also note that it's not curried.

Actually inside source code of `R.liftN`

(which `R.lift`

delegates to), the function passed in is *auto-curried*, then it iterates through the values (in our case, three arrays), reducing to a result: in each iteration it invokes `ap`

with the curried function and one value (in our case, one array). It's hard to explain in words, let's see the equivalent in code:

```
const R = require('ramda');
const madd3 = (x, y, z) => x + y + z;
// example from R.lift
const result = R.lift(madd3)([1, 2, 3], [1, 2, 3], [1]);
// this is equivalent of the calculation of 'result' above,
// R.liftN uses reduce, but the idea is the same
const result2 = R.ap(R.ap(R.ap([R.curry(madd3)], [1, 2, 3]), [1, 2, 3]), [1]);
console.log(result); // [ 3, 4, 5, 4, 5, 6, 5, 6, 7 ]
console.log(result2); // [ 3, 4, 5, 4, 5, 6, 5, 6, 7 ]
```

Once the expression of calculating `result2`

is understood, the example will become clear.

Here's another example, using `R.lift`

on `Apply`

:

```
const R = require('ramda');
const Maybe = require('ramda-fantasy').Maybe;
const madd3 = (x, y, z) => x + y + z;
const madd3Curried = Maybe.of(R.curry(madd3));
const a = Maybe.of(1);
const b = Maybe.of(2);
const c = Maybe.of(3);
const sumResult = madd3Curried.ap(a).ap(b).ap(c); // invoke #ap on Apply
const sumResult2 = R.ap(R.ap(R.ap(madd3Curried, a), b), c); // invoke R.ap
const sumResult3 = R.lift(madd3)(a, b, c); // invoke R.lift, madd3 is auto-curried
console.log(sumResult); // Just { value: 6 }
console.log(sumResult2); // Just { value: 6 }
console.log(sumResult3); // Just { value: 6 }
```

A better example suggested by Scott Sauyet in the comments (he provides quite some insights, I suggest you read them) would be easier to understand, at least it points the reader to the direction that `R.lift`

calculates the Cartesian product for `Array`

s.

```
var madd3 = R.lift((a, b, c) => a + b + c);
madd3([100, 200], [30, 40, 50], [6, 7]); //=> [136, 137, 146, 147, 156, 157, 236, 237, 246, 247, 256, 257]
```

Hope this helps.