How can a *time function* exist in functional programming?

You've almost answered your own question - if it's a time function, then all it needs is the appropriate input. For a language like Standard ML it could look something like:

```
val time_now : () -> time
fun time_now () = ...
```

for a suitable definition of `time`

, of course.

I [...] know that in functional programming, a function returns the same output, for same input, no matter how many times the function is called.

That is possible in Standard ML if you're careful...

For example, consider this:

```
f(x,y) = x*x + y;
```

[...] As such, wherever you've written `f(10,4)`

, you can replace it with `104`

, without altering the value of the whole expression. This property is referred to as *referential transparency* [...]

Aha! This calls for a change of language - let's try...Miranda(R)!

As you've correctly surmised, something like:

```
unit ::= Unit
time_now :: unit -> time
```

would only return the same `time`

value, no matter where it was used - not exactly what we're looking for. We need to use a different input for each call to `time_now`

:

```
time_taken x = t1 $seq x $seq t2 $seq (x, tdiff)
where
t1 = time_now u1
t2 = time_now u2
tdiff = t2 $minus_time t1
u1:u2:_ = ... || what goes here?
```

where:

```
minus_time :: time -> time -> time
```

and `time`

are already defined elsewhere.

(Note: while it is here, `seq`

isn't actually sequential in all the languages that define it...)

But what about:

```
times_taken xs = map time_taken xs
```

All that would happen is each element of the list would be paired with the same `time`

(difference) value - again, not exactly what was intended.

Favouring simplicity, we reuse the change made to `time_now`

- use a different input for each call to `time_taken`

:

```
times_taken xs = map2 time_taken xs us
where
us = ... || what about here?
```

That implies:

```
time_taken x u = t1 $seq x $seq t2 $seq (x, tdiff)
where
t1 = time_now u1
t2 = time_now u2
tdiff = t2 $minus_time t1
u1:u2:_ = ... || what goes here?
```

which in turn implies:

```
times_taken xs u = map2 time_taken xs us
where
us = ... || what about here?
```

so that `times_taken`

can also be used far and wide.

Now for the enigmatic `u1`

, `u2`

and `us`

- since we've added `u`

as an extra parameter to `time_taken`

and `times_taken`

, let's make use of it with the help of a new definition e.g. `parts`

:

```
time_taken x u = t1 $seq x $seq t2 $seq (x, tdiff)
where
t1 = time_now u1
t2 = time_now u2
tdiff = t2 $minus_time t1
u1:u2:_ = parts u
times_taken xs u = map2 time_taken xs us
where
us = parts u
```

While we're at it, let's also name the type of all these `u`

-values. Since `time_now`

uses an outside source of information, what about:

```
time_now :: outside_information -> time
parts :: outside_information -> [outside_information]
```

...yeah - on second thought, let's just use the initials:

```
time_now :: oi -> time
parts :: oi -> [oi]
```

Much better! This also allows us to provide `time_taken`

and `times_taken`

with their own type signatures:

```
time_taken :: * -> oi -> (*, time)
times_taken :: [*] -> oi -> [(*, time)]
```

That just leaves `parts`

and `time_now`

- how will they use their respective `oi`

arguments?

Well, you may recall the requirement for each `oi`

value to be unique for all this to work. But a regular definition:

```
oi ::= ...
```

would expose the constructors, which could then be reused at will...

Now consider:

```
what_time_taken :: * -> oi -> (*, time)
what_time_taken x u = t1 $seq x $seq t2 $seq (x, tdiff)
where
t1 = time_now u1
t2 = time_now u
tdiff = t2 $minus_time t1
u1:u2:_ = parts u
```

Did you see it?

In the local definition of `t2`

, `time_now`

has been applied to `u`

, instead of (presumably) `u2`

- `u`

is being used twice, contrary to the *single-use* property we're trying to maintain. This is Miranda(R), not Clean, so there are no uniqueness types which could be used to fend off such anomalies...

Those two observations suggest `oi`

needs to be predefined, like `char`

or `num`

- an implementation could then check if any `oi`

value has already been used and react accordingly e.g. raising a runtime error to stop the offending program (think of how division-by-zero is dealt with now). The simplest way `time_now`

and `parts`

can access this runtime check is for both to also be predefined (like `ord`

or `div`

) - together with `oi`

, they form an *abstract data type* provided by the implementation.

With that out of the way, let's bring everything together:

```
|| oi ADT
parts :: oi -> [oi]
time_now :: oi -> Time
minus_time :: time -> time -> time || defined elsewhere
time_taken :: * -> oi -> (*, time)
time_taken x u = t1 $seq x $seq t2 $seq (x, tdiff)
where
t1 = time_now u1
t2 = time_now u2
tdiff = t2 $minus_time t1
u1:u2:_ = parts u
times_taken :: [*] -> oi -> [(*, time)]
times_taken xs u = map2 time_taken xs us
where
us = parts u
```

By now, you've probably already noticed how the use of `parts`

, `u`

, etc form a tree embedded across `times_taken`

and `times_taken`

, with its leaves in the applications of `time_now`

. This suggests the existence of a single ancestral `oi`

value e.g:

```
start_here :: oi -> unit
```

We already know having something like:

```
start_up :: oi
```

is useless because it will always have the same value...wait a moment - we're trying to bring a new `oi`

value to `start_now`

? That's so *first-order*!

In Miranda(R), functions can be used like any other value of e.g. `bool`

, `char`

, or `num`

i.e. functions are *first-class* values. Let's just bring `start_here`

to a newly-made `oi`

value *inside the implementation*, since it already chooses how to process its input based on type:

We just need to extend it to cater for functions using `oi`

values; the implementation can then:

evaluate the input expression if it isn't already a function;

generate a new `oi`

value;

apply the function to the `oi`

value to form a new input expression;

which is then sent back for more processing, again based on type.

To obtain a new `oi`

value, the implementation can use a technique similar to what `parts`

uses to generate new `oi`

values.

To conclude:

How can a time function exist in functional programming?

By always being applied to a unique input value wherever it's called.