# How can a time function exist in functional programming?

I've to admit that I don't know much about functional programming. I read about it from here and there, and so came to know that in functional programming, a function returns the same output, for same input, no matter how many times the function is called. It's exactly like a mathematical function which evaluates to the same output for the same value of the input parameters which involves in the function expression.

For example, consider this:

``````f(x,y) = x*x + y; // It is a mathematical function
``````

No matter how many times you use `f(10,4)`, its value will always be `104`. 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 of an expression.

Conversely, in functional code, the output value of a function depends only on the arguments that are input to the function, so calling a function f twice with the same value for an argument x will produce the same result f(x) both times.

Can a time function (which returns the current time) exist in functional programming?

• If yes, then how can it exist? Does it not violate the principle of functional programming? It particularly violates referential transparency which is one of the property of functional programming (if I correctly understand it).

• Or if no, then how can one know the current time in functional programming?

• I think most (or all) functional languages are not so strict and combine functional and imperative programming. At least, this is my impression from F#. – Alex F Sep 1 '11 at 8:33
• @Adam: How would the caller know the current time in the first place? – Nawaz Sep 1 '11 at 8:35
• @Adam: Actually it is illegal (as in: impossible) in purely functional languages. – sepp2k Sep 1 '11 at 8:49
• @Adam: Pretty much. A general purpose language which is pure usually offers some facility to get at the "world state" (i.e. things like the current time, files in a directory etc.) without breaking referential transparency. In Haskell that's the IO monad and in Clean it's the world type. So in those languages a function which needs the current time would either take it as an argument or it would need to return an IO action instead of its actual result (Haskell) or take the world state as its argument (Clean). – sepp2k Sep 1 '11 at 9:00
• When thinking about FP it's easy to forget: a computer is a big chunk of mutable state. FP doesn't change that, it merely conceals it. – Daniel Sep 1 '11 at 14:56

Another way to explain it is this: no function can get the current time (since it keeps changing), but an action can get the current time. Let's say that `getClockTime` is a constant (or a nullary function, if you like) which represents the action of getting the current time. This action is the same every time no matter when it is used so it is a real constant.

Likewise, let's say `print` is a function which takes some time representation and prints it to the console. Since function calls cannot have side effects in a pure functional language, we instead imagine that it is a function which takes a timestamp and returns the action of printing it to the console. Again, this is a real function, because if you give it the same timestamp, it will return the same action of printing it every time.

Now, how can you print the current time to the console? Well, you have to combine the two actions. So how can we do that? We cannot just pass `getClockTime` to `print`, since print expects a timestamp, not an action. But we can imagine that there is an operator, `>>=`, which combines two actions, one which gets a timestamp, and one which takes one as argument and prints it. Applying this to the actions previously mentioned, the result is... tadaaa... a new action which gets the current time and prints it. And this is incidentally exactly how it is done in Haskell.

``````Prelude> System.Time.getClockTime >>= print
Fri Sep  2 01:13:23 東京 (標準時) 2011
``````

So, conceptually, you can view it in this way: A pure functional program does not perform any I/O, it defines an action, which the runtime system then executes. The action is the same every time, but the result of executing it depends on the circumstances of when it is executed.

I don't know if this was any clearer than the other explanations, but it sometimes helps me to think of it this way.

• It's not convincing to me. You conveniently called `getClockTime` an action instead of a function. Well, if you call so, then call every function action, then even imperative programming would become functional programmming. Or maybe, you would like to call it actional programmming. – Nawaz Sep 1 '11 at 16:54
• @Nawaz: The key thing to note here is that you cannot execute an action from within a function. You can only combine actions and functions together to make new actions. The only way of executing an action is to compose it into your `main` action. This allows pure functional code to be separated from imperative code, and this separation is enforced by the type system. Treating actions as first class objects also allow you to pass them around and build your own "control structures". – hammar Sep 1 '11 at 18:25
• Not everything in Haskell is a function - that's utter nonsense. A function is something whose type contains a `->` - that's how the standard defines the term and that's really the only sensible definition in the context of Haskell. So something whose type is `IO Whatever` is not a function. – sepp2k Sep 2 '11 at 10:08
• @sepp2k So, myList :: [a -> b] is a function? ;) – fuz Sep 10 '11 at 15:33
• @ThomasEding I'm really late to the party, but I just want to clarify this: `putStrLn` is not an action – it is a function that returns an action. `getLine` is a variable that contains an action. Actions are the values, variables and functions are the "containers"/"labels" we give those actions. – kqr Aug 12 '13 at 22:23

Yes and no.

Different functional programming languages solve them differently.

In Haskell (a very pure one) all this stuff has to happen in something called the I/O Monad - see here.

You can think of it as getting another input (and output) into your function (the world-state) or easier as a place where "impureness" like getting the changing time happens.

Other languages like F# just have some impureness built in and so you can have a function that returns different values for the same input - just like normal imperative languages.

As Jeffrey Burka mentioned in his comment: Here is the nice introduction to the I/O Monad straight from the Haskell wiki.

• I find it useful to not call things like getting the current time "functions" but something like "procedures" (though arguable the Haskell solution is an exception to this). – singpolyma Nov 16 '12 at 18:28
• from the Haskell perspective classical "procedures" (things that have types like '... -> ()') are somewhat trivial as a pure function with ... -> () cannot do anything at all. – Carsten Nov 16 '12 at 22:45
• but in this case this would be something like '() -> ...' (a constant function) and I would not call this a procedure - but call it as you wish :D – Carsten Nov 16 '12 at 22:46
• The typical Haskell term is "action". – Sebastian Redl May 31 '15 at 10:40

In Haskell one uses a construct called monad to handle side effects. A monad basically means that you encapsulate values into a container and have some functions to chain functions from values to values inside a container. If our container has the type:

``````data IO a = IO (RealWorld -> (a,RealWorld))
``````

we can safely implement IO actions. This type means: An action of type `IO` is a function, that takes a token of type `RealWorld` and returns a new token, together with a result.

The idea behind this is that each IO action mutates the outside state, represented by the magical token `RealWorld`. Using monads, one can chain multiple functions that mutate the real world together. The most important function of a monad is `>>=`, pronounced bind:

``````(>>=) :: IO a -> (a -> IO b) -> IO b
``````

`>>=` takes one action and a function that takes the result of this action and creates a new action out of this. The return type is the new action. For instance, let's pretend there is a function `now :: IO String`, which returns a String representing the current time. We can chain it with the function `putStrLn` to print it out:

``````now >>= putStrLn
``````

Or written in `do`-Notation, which is more familiar to an imperative programmer:

``````do currTime <- now
putStrLn currTime
``````

All this is pure, as we map the mutation and information about the world outside to the `RealWorld` token. So each time, you run this action, you get of course a different output, but the input is not the same: the `RealWorld` token is different.

• -1: I'm unhappy with the `RealWorld` smoke screen. Yet, the most important thing is how this purported object is passed on in a chain. The missing piece is where it starts, where the source or connection to the real world is -- it starts with the main function which runs in the IO monad. – u0b34a0f6ae Sep 6 '11 at 14:12
• @kaizer.se You can think of a global `RealWorld` object that is passed into the program when it starts. – fuz Sep 6 '11 at 14:21
• Basically, your `main` function takes a `RealWorld` argument. Only upon execution is it passed in. – Louis Wasserman Jun 13 '12 at 16:26
• You see, the reason why they hide the `RealWorld` and only provide puny functions to change it like `putStrLn`, is so some Haskell programmer doesn't change `RealWorld` with one of their programs such that Haskell Curry's address and birth-date is such they become next-door neighbors growing up (this could damage the time-space continuum in such a way to hurt the Haskell programming language.) – PyRulez Jul 22 '14 at 21:58
• `RealWorld -> (a, RealWorld)` does not break down as metaphor even under concurrency, as long as you keep in mind that the real world might be changed by other parts of the universe outside of your function (or your current process) at all times. So (a) the methaphor does not break down, and (b) every time a value that has `RealWorld` as its type is passed to a function, the function has to be re-evaluated, because the real world will have changed in the meantime (which is modeled as @fuz explained, giving back a different 'token value' every time we interact with the real world). – Qqwy May 8 '19 at 19:10

Most functional programming languages are not pure, i.e. they allow functions to not only depend on their values. In those languages it is perfectly possible to have a function returning the current time. From the languages you tagged this question with this applies to Scala and F# (as well as most other variants of ML).

In languages like Haskell and Clean, which are pure, the situation is different. In Haskell the current time would not be available through a function, but a so-called IO action, which is Haskell's way of encapsulating side effects.

In Clean it would be a function, but the function would take a world value as its argument and return a fresh world value (in addition to the current time) as its result. The type system would make sure that each world value can be used only once (and each function which consumes a world value would produces a new one). This way the time function would have to be called with a different argument each time and thus would be allowed to return a different time each time.

• This makes it sound as if Haskell and Clean do different things. From what I understand, they do the same, just that Haskell offers a nicer syntax (?) to accomplish this. – Konrad Rudolph Sep 1 '11 at 13:56
• @Konrad: They do the same thing in the sense that both use type system features to abstract side effects, but that's about it. Note that it's very well to explain the IO monad in terms of a world type, but the Haskell standard doesn't actually define a world type and it's not actually possible to get a value of type World in Haskell (while it's very possible and indeed necessary in clean). Further Haskell does not have uniqueness typing as a type system feature, so if it did give you access to a World, it could not ensure that you use it in a pure way the way Clean does. – sepp2k Sep 1 '11 at 14:22

"Current time" is not a function. It is a parameter. If your code depends on current time, it means your code is parameterized by time.

It can absolutely be done in a purely functional way. There are several ways to do it, but the simplest is to have the time function return not just the time but also the function you must call to get the next time measurement.

In C# you could implement it like this:

``````// Exposes mutable time as immutable time (poorly, to illustrate by example)
// Although the insides are mutable, the exposed surface is immutable.
public class ClockStamp {
public static readonly ClockStamp ProgramStartTime = new ClockStamp();
private ClockStamp _next;

private ClockStamp() {
this.Time = DateTime.Now;
}
public ClockStamp NextMeasurement() {
if (this._next == null) this._next = new ClockStamp();
return this._next;
}
}
``````

(Keep in mind that this is an example meant to be simple, not practical. In particular, the list nodes can't be garbage collected because they are rooted by ProgramStartTime.)

This 'ClockStamp' class acts like an immutable linked list, but really the nodes are generated on demand so they can contain the 'current' time. Any function that wants to measure the time should have a 'clockStamp' parameter and must also return its last time measurement in its result (so the caller doesn't see old measurements), like this:

``````// Immutable. A result accompanied by a clockstamp
public struct TimeStampedValue<T> {
public TimeStampedValue(ClockStamp time, T value) {
this.Time = time;
this.Value = value;
}
}

// Times an empty loop.
public static TimeStampedValue<TimeSpan> TimeALoop(ClockStamp lastMeasurement) {
var start = lastMeasurement.NextMeasurement();
for (var i = 0; i < 10000000; i++) {
}
var end = start.NextMeasurement();
var duration = end.Time - start.Time;
return new TimeStampedValue<TimeSpan>(end, duration);
}

public static void Main(String[] args) {
var clock = ClockStamp.ProgramStartTime;
var r = TimeALoop(clock);
var duration = r.Value; //the result
clock = r.Time; //must now use returned clock, to avoid seeing old measurements
}
``````

Of course, it's a bit inconvenient to have to pass that last measurement in and out, in and out, in and out. There are many ways to hide the boilerplate, especially at the language design level. I think Haskell uses this sort of trick and then hides the ugly parts by using monads.

• Interesting, but that `i++` in the for loop isn't referentially transparent ;) – snim2 Jun 13 '12 at 13:35
• @snim2 I'm not perfect. :P Take solace in the fact that the dirty mutableness doesn't affect the referential transparency of the result. If you pass the same 'lastMeasurement' in twice, you get a stale next measurement and return the same result. – Craig Gidney Jun 13 '12 at 13:41
• @Strilanc Thanks for this. I think in imperative code, so it's interesting to see functional concepts explained this way. I can then imagine a language where this natural and syntactically cleaner. – WW. Jul 10 '13 at 6:20
• You could in fact go the monad way in C# as well, thus avoiding the explicit passing of time stamps. You need something like `struct TimeKleisli<Arg, Res> { private delegate Res(TimeStampedValue<Arg>); }`. But code with this still wouldn't look as nice as Haskell with `do` syntax. – leftaroundabout Aug 3 '13 at 18:11
• @leftaroundabout you can sort of pretend that you have a monad in C# by implementing the bind function as a method called `SelectMany`, which enables the query comprehension syntax. You still can't program polymorphically over monads though, so it's all an uphill battle against the weak type system :( – sara Apr 17 '16 at 11:58

I am surprised that none of the answers or comments mention coalgebras or coinduction. Usually, coinduction is mentioned when reasoning about infinite data structures, but it is also applicable to an endless stream of observations, such as a time register on a CPU. A coalgebra models hidden state; and coinduction models observing that state. (Normal induction models constructing state.)

This is a hot topic in Reactive Functional Programming. If you're interested in this sort of stuff, read this: http://digitalcommons.ohsu.edu/csetech/91/ (28 pp.)

• Kieburtz, Richard B., "Reactive functional programming" (1997). CSETech. Paper 91 (link)
• And how is that related to this question? – Nawaz Sep 19 '14 at 2:06
• Your question was about modeling time-dependent behavior in a purely functional way, e.g., a function that returns the current system clock. You can either thread something equivalent to an IO monad through all the functions and their dependency tree to get access to that state; or you can model the state by defining the observation rules rather than the constructive rules. This is why modeling complex state inductively in functional programming seems so unnatural, because the hidden state is really a coinductive property. – Jeffrey Aguilera Sep 30 '14 at 21:12
• Great source! Is there anything more recent? The JS community still seems to be struggling with stream data abstractions. – Dmitri Zaitsev May 7 '18 at 5:53

Yes, it's possible for a pure function to return the time, if it's given that time as a parameter. Different time argument, different time result. Then form other functions of time as well and combine them with a simple vocabulary of function(-of-time)-transforming (higher-order) functions. Since the approach is stateless, time here can be continuous (resolution-independent) rather than discrete, greatly boosting modularity. This intuition is the basis of Functional Reactive Programming (FRP).

Yes! You are correct! Now() or CurrentTime() or any method signature of such flavour is not exhibiting referential transparency in one way. But by instruction to the compiler it is parameterized by a system clock input.

By output, Now() might look like not following referential transparency. But actual behaviour of the system clock and the function on top of it is adheres to referential transparency.

Yes, a getting time function can exist in functional programming using a slightly modified version on functional programming known as impure functional programming (the default or the main one is pure functional programming).

In case of getting the time (or reading file, or launching missile) the code needs to interact with the outer world to get the job done and this outer world is not based on the pure foundations of functional programming. To allow a pure functional programming world to interact with this impure outside world, people have introduced impure functional programming. After all, software which doesn't interact with the outside world isn't any useful other than doing some mathematical computations.

Few functional programming programming languages have this impurity feature inbuilt in them such that it is not easy to separate out which code is impure and which is pure (like F#, etc.) and some functional programming languages make sure that when you do some impure stuff that code is clearly stand out as compared to pure code, like Haskell.

Another interesting way to see this would be that your get time function in functional programming would take a "world" object which has the current state of the world like time, number of people living in the world, etc. Then getting time from which world object would be always pure i.e you pass in the same world state you will always get the same time.

• "After all a software which doesn't interact with the outside world isn't any useful other than doing some mathematical computations." As far as I understand, even in this case the input to the computations would be hard-coded in the program, also not very useful. As soon as you want to read input data to your mathematical computation from file or terminal, you need impure code. – Giorgio Sep 1 '11 at 11:49
• @Ankur: That is the same exact thing. If the program is interacting with something else than just itself(e.g. the world through they keyboard, so to speak) it's still impure. – identity Sep 1 '11 at 12:11
• @Ankur: Yes, I think you are right! Even though it might not be very practical to pass large input data on the command line, this can be a pure way of doing it. – Giorgio Sep 1 '11 at 12:28
• Having the "world object" including the number of people living in the world raises the executing computer to a near omniscient level. I think the normal case is that it includes things like how many files are on your HD and what's the home directory of the current user. – ziggystar Sep 1 '11 at 12:42
• @ziggystar - the "world object" doesn't actually include anything - it is simply a proxy for the changing state of the world outside of the program. Its only purpose is to explicitly mark mutable state in a way that the type system can identify it. – Kris Nuttycombe Sep 1 '11 at 15:29

Your question conflates two related measures of a computer language: functional/imperative and pure/impure.

A functional language defines relationships between inputs and outputs of functions, and an imperative language describes specific operations in a specific order to perform.

A pure language does not create or depend on side effects, and an impure language uses them throughout.

One-hundred percent pure programs are basically useless. They may perform an interesting calculation, but because they cannot have side effects they have no input or output so you would never know what they calculated.

To be useful at all, a program has to be at least a smidge impure. One way to make a pure program useful is to put it inside a thin impure wrapper. Like this untested Haskell program:

``````-- this is a pure function, written in functional style.
fib 0 = 0
fib 1 = 1
fib n = fib (n-1) + fib (n-2)

-- This is an impure wrapper around the pure function, written in imperative style
-- It depends on inputs and produces outputs.
main = do
putStrLn "Please enter the input parameter"
putStrLn "Starting time:"
getCurrentTime >>= print
let inputInt = read inputStr    -- this line is pure
let result = fib inputInt       -- this is also pure
putStrLn "Result:"
print result
putStrLn "Ending time:"
getCurrentTime >>= print
``````
• It would be helpful if you could address the specific issue of getting the time, and explained a little about to what extent we consider `IO` values and results pure. – AndrewC Sep 28 '12 at 10:31
• In fact, even 100% pure programs heat up the CPU, which is a side-effect. – Jörg W Mittag Nov 26 '14 at 17:13

You're broaching a very important subject in functional programming, that is, performing I/O. The way many pure languages go about it is by using embedded domain-specific languages, e.g., a sublanguage whose task it is to encode actions, which can have results.

The Haskell runtime for example expects me to define an action called `main` that is composed of all actions that make up my program. The runtime then executes this action. Most of the time, in doing so it executes pure code. From time to time the runtime will use the computed data to perform I/O and feeds back data back into pure code.

You might complain that this sounds like cheating, and in a way it is: by defining actions and expecting the runtime to execute them, the programmer can do everything a normal program can do. But Haskell's strong type system creates a strong barrier between pure and "impure" parts of the program: you cannot simply add, say, two seconds to the current CPU time, and print it, you have to define an action that results in the current CPU time, and pass the result on to another action that adds two seconds and prints the result. Writing too much of a program is considered bad style though, because it makes it hard to infer which effects are caused, compared to Haskell types that tell us everything we can know about what a value is.

Example: `clock_t c = time(NULL); printf("%d\n", c + 2);` in C, vs. `main = getCPUTime >>= \c -> print (c + 2*1000*1000*1000*1000)` in Haskell. The operator `>>=` is used to compose actions, passing the result of the first to a function resulting in the second action. This looking quite arcane, Haskell compilers support syntactic sugar that allows us to write the latter code as follows:

``````type Clock = Integer -- To make it more similar to the C code

-- An action that returns nothing, but might do something
main :: IO ()
main = do
-- An action that returns an Integer, which we view as CPU Clock values
c <- getCPUTime :: IO Clock
-- An action that prints data, but returns nothing
print (c + 2*1000*1000*1000*1000) :: IO ()
``````

The latter looks quite imperative, doesn't it?

If yes, then how can it exist? Does it not violate the principle of functional programming? It particularly violates referential transparency

It does not exist in a purely functional sense.

Or if no, then how can one know the current time in functional programming?

It may first be useful to know how a time is retrieved on a computer. Essentially there is onboard circuitry that keeps track of the time (which is the reason a computer would usually need a small cell battery). Then there might be some internal process that sets the value of time at a certain memory register. Which essentially boils down to a value that can be retrieved by the CPU.

For Haskell, there is a concept of an 'IO action' which represents a type that can be made to carry out some IO process. So instead of referencing a `time` value we reference a `IO Time` value. All this would be purely functional. We aren't referencing `time` but something along the lines of 'read the value of the time register'.

When we actually execute the Haskell program, the IO action would actually take place.

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...)

``````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:

• using quotes for printing `char` values;

• using the decimal point (if needed) for printing `num` values.

We just need to extend it to cater for functions using `oi` values; the implementation can then:

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

2. generate a new `oi` value;

3. apply the function to the `oi` value to form a new input expression;

4. 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.

It can be answered without introducing other concepts of FP.

# Possibility 1: time as function argument

A language consists of

1. language core and
2. standard library.

Referential transparency is a property of language core, but not standard library. By no means is it a property of programs written in that language.

Using OP's notation, should one have a function

``````f(t) = t*v0 + x0; // mathematical function that knows current time
``````

They would ask standard library to get current time, say `1.23`, and compute the function with that value as an argument `f(1.23)` (or just `1.23*v0 + x0`, referential transparency!). That way the code gets to know the current time.

# Possibility 2: time as return value

Can a time function (which returns the current time) exist in functional programming?

Yes, but that function has to have an argument and you would have to compute it with different inputs so it returns different current time, otherwise it would violate the principals of FP.

``````f(s) = t(s)*v0 + x0; // mathematical function t(s) returns current time
``````

This is an alternative approach to what I've described above. But then again, the question of obtaining those different inputs `s` in the first place still comes down to standard library.

# Possibility 3: functional reactive programming

The idea is that function `t()` evaluates to current time paired with function `t2`. When one needs current time again later they are to call `t2()`, it will then give function `t3` and so on

``````(x, t2) = t(); // it's x o'clock now
...
(x2, t3) = t2(); // now it's already x2 o'clock
...
t(); x; // both evaluate to the initial time, referential transparency!
``````

There's more to FP but I believe it's out of the scope of OP. For example, how does one ask standard library to compute a function and act upon its return value in purely functional way: that one is rather about side effects than referential transparency.