# Pure Functions: Does “No Side Effects” Imply “Always Same Output, Given Same Input”?

The two conditions that define a function as `pure` are as follows:

1. No side effects (i.e. only changes to local scope are allowed)
2. Always return the same output, given the same input

If the first condition is always true, are there any times the second condition is not true?

I.e. is it really only necessary with the first condition?

• Your premises are ill-specified. "Input" is too broad. Functions can be thought two have kinds of input. Their arguments, and "environmental"/"contextual". A function that returns the system time could be thought to be pure (even though it's obv not) if you don't distinguish between these two kinds of input. – Alexander Mar 5 at 3:22
• @Alexander: In the context of "pure function", "input" is commonly understood to mean the parameters / arguments that are passed explicitly (by whatever mechanism the programming language uses). That's part of the definition of "pure function". But you are right, it's important to mind the definition. – sleske Mar 5 at 8:01
• Trivial counter-example: return the value of a global variable. No side effects (the global is only ever read!), but still potentially different results every time. (If you don't like globals, return the address of a local variable which depends on the call stack at run time). – Peter A. Schneider Mar 5 at 15:17
• You need to expand your definition of "side effects"; you say that a pure method does not produce side effects, but you need to also note that a pure method does not consume side effects produced elsewhere. – Eric Lippert Mar 5 at 15:28
• @sleske Perhaps commonly understood, but the lack of that distinction is the exact cause of OP's confusion. – Alexander Mar 5 at 15:54

Here are a few counterexamples that do not change the outer scope but are still considered impure:

• `function a() { return Date.now(); }`
• `function b() { return window.globalMutableVar; }`
• `function c() { return document.getElementById("myInput").value; }`
• `function d() { return Math.random(); }` (which admittedly does change the PRNG, but is not considered observable)

Accessing non-constant non-local variables is enough to be able to violate the second condition.

I always think of the two conditions for purity as complementary:

• the result evaluation must not have effects on side state
• the evaluation result must not be affected by side state

The term side effect only refers to the first, the function modifying the non-local state. However, sometimes read operations are considered as side effects as well: when they are operations and involve writing as well, even if their primary purpose is to access a value. Examples for that are generating a pseudo-random number that modifies the generator's internal state, reading from an input stream that advances the read position, or reading from an external sensor that involves a "take measurement" command.

• Thanks Bergi. For some reason I thought side effects included reading variables outside of local scope, but I guess it is only a side effect if it writes such external variables. – Magnus Mar 5 at 6:40
• Note that the two conditions are actually logically independent: This answer shows that 1. does not imply 2., but there are also many counterexamples that 2. does not imply 1. - for example, a function `setDate(newDate)` that sets the computer's current date to `newDate` has property 2. (the return value can be `newDate` or nothing), but it still violates 1. (it sets the current date). – sleske Mar 5 at 8:08
• If `prompt("you choose")` does not have side effects, we should take a step back and clarify the meaning of side effects. – Holger Mar 5 at 8:57
• @Magnus Yes, exactly that's what effect means. I'll try to clarify in my answer as well, I didn't expect such large attention and want to make answer worthy of dozens of votes :-) – Bergi Mar 5 at 13:09
• Well for all you know Math.random() returns a thermal diode. It's not actually specified to use a bad RNG. – Joshua Mar 5 at 22:39

The "normal" way of phrasing what a pure function is, is in terms of referential transparency. A function is pure if it is referentially transparent.

Referential Transparency, roughly, means that you can replace the call to the function with its return value or vice versa at any point in the program, without changing the meaning of the program.

So, for example, if C's `printf` were referentially transparent, these two programs should have the same meaning:

``````printf("Hello");
``````

and

``````5;
``````

and all of the following programs should have the same meaning:

``````5 + 5;

printf("Hello") + 5;

printf("Hello") + printf("Hello");
``````

Because `printf` returns the number of characters written, in this case 5.

It gets even more obvious with `void` functions. If I have a function `void foo`, then

``````foo(bar, baz, quux);
``````

should be the same as

``````;
``````

I.e. since `foo` returns nothing, I should be able to replace it with nothing without changing the meaning of the program.

It is clear, then, that neither `printf` nor `foo` are referentially transparent, and thus neither of them are pure. In fact, a `void` function can never be referentially transparent, unless it is a no-op.

I find this definition much easier to handle as the one you gave. It also allows you to apply it at any granularity you want: you can apply it to individual expressions, to functions, to entire programs. It allows you, for example, to talk about a function like this:

``````func fib(n):
return memo[n] if memo.has_key?(n)
return 1 if n <= 1
return memo[n] = fib(n-1) + fib(n-2)
``````

We can analyze the expressions that make up the function and easily conclude that they are not referentially transparent and thus not pure, since they use a mutable data structure, namely the `memo` array. However, we can also look at the function and can see that it is referentially transparent and thus pure. This is sometimes called external purity, i.e. a function that appears pure to the outside world, but is implemented impure internally.

Such functions are still useful, because while impurity infects everything around it, the external pure interface builds a kind of "purity barrier", where the impurity only infects the three lines of the function, but does not leak out into the rest of the program. These three lines are much easier to analyze for correctness than the entire program.

• That impurity affects the whole program once you have concurrency. – R.. Mar 5 at 16:27
• @R.. Can you think of a way that concurrency could make the described Fibonacci function externally impure? I can't. Writing to `memo[n]` is idempotent, and failing to read from it merely wastes CPU cycles. – Brilliand Mar 5 at 22:12
• I agree with both of you. Impurity can lead to concurrency problems, but it doesn't in this specific case. – Jörg W Mittag Mar 5 at 22:17
• @R.. It's not hard to imagine a concurrency-aware version. – immibis Mar 5 at 23:48
• @Brilliand For example, `memo[n] = ...` may first create a dictionary entry, and then store the value into it. This leaves a window during which another thread could see an uninitialized entry. – immibis Mar 5 at 23:49

It seems to me that the second condition you have described is a weaker constraint than the first.

Let me give you an example, suppose you have a function to add one that also logs to the console:

``````function addOneAndLog(x) {
console.log(x);
return x + 1;
}
``````

The second condition you supplied is satisfied: this function always returns the same output when given the same input. It is, however, not a pure function because it includes the side effect of logging to the console.

A pure function is, strictly speaking, a function that satisfies the property of referential transparency. That is the property that we can replace a function application with the value it produces without changing the behaviour of the program.

Suppose we have a function that simply adds:

``````function addOne(x) {
return x + 1;
}
``````

We can replace `addOne(5)` with `6` anywhere in our program and nothing will change.

By contrast, we cannot replace `addOneAndLog(x)` with the value `6` anywhere in our program without changing behaviour because the first expression results in something being written to the console whereas the second one does not.

We consider any of this extra behaviour that `addOneAndLog(x)` performs besides returning output as a side-effect.

• "It seems to me that the second condition you have described is a weaker constraint than the first." No, the two conditions are logically independent. – sleske Mar 5 at 8:03
• @sleske you are mistaken. I have provided clear definitions for the terms pure and side-effect. Within these constraints, there is nothing that a function with no side effects besides return the same output for a given input. I have however provided examples where the second condition can be satisfied without the first. The fundamnetal concept to understand the notion of purity is referential transparency. – TheInnerLight Mar 5 at 9:11
• Small typo: There is nothing that a function with no side effects can do besides returning the same output for a given input. – TheInnerLight Mar 5 at 9:18
• What about something like returning the current time? That does not have side effects, but it does return a different output for the same input. Or more generally, any function where the result depends not only on the input parameters, but also on a (changeable) global variable. – sleske Mar 5 at 9:24
• It seems you are using a different definition of "side effect" than what is commonly used. A side effect is commonly defined as "an observable effect besides returning a value" or an "observable change in state" - see e.g. Wikipedia , this post on softwareengineering.SE. You are totally right that `Date.now()` is not pure/referentially transparent, but not because it has side-effects, but because its result depends on more than just its input. – sleske Mar 5 at 10:05

You could have a source of randomness from outside the system. Say part of your calculation includes the room temperature. Executing the function will yield different results each time (depending on the external random element) but you don't really change the state of your program by executing it.

All I can think of, anyway.

• According to me, these "randomness from outside the system" are a form of side effect. Functions with these behaviors are not "pures". – Joseph M. Dion Mar 5 at 1:06

Problem with FP definitions is that they are very artificial. Each evaluation/calculation has side-effects on the evaluator. It's theoretically true. A deny of this shows only that FP apologists ignore philosophy and logic: an "evaluation" means changing of the state of some intelligent environment (machine, brain, etc). This is the nature of the evaluation process. No changes - no "calculi". The effect can be very visible: heating the CPU or its failure, shutting down the motherboard in case of overheating, and so on.

When you talk about referential transparency, you should understand that information about such transparency is available for human as a creator of the whole system and holder of semantical information and may be not available for the compiler. For example, a function can read some external resource and it will have IO monad in its signature but it will return the same value all the time (for example, the result of `current_year > 0`). The compiler does not know that function will return always the same result, so the function is impure but has referentially transparent property and can be substituted with `True` constant.

So, to avoid such inaccuracy, we should distinguish mathematical functions and "functions" in programming languages. Functions in Haskell are always impure and definition of purity related to them is always very conditionally: they are running on real hardware with real side-effects and physical properties, which is wrong for mathematical functions. This means that the example with "printf" function is totally incorrect.

But not all mathematical functions are pure too: each function which has `t` (time) as a parameter may be impure: `t` holds all effects and stochastic nature of the function: in common case you have input signal and have not idea about actual values, it can be even a noise.

If the first condition is always true, are there any times the second condition is not true?

Yes

Consider simple code snippet below

``````public int Sum(int a, int b){
Random rnd = new Random();
return rnd.Next(1, 10);
}
``````

This code will return random output for same given set of inputs - however it does not have any side effect.

The overall effect of both the points #1 & #2 you mentioned when combined together means : At any point of time if function `Sum` with same i/p is replaced with its result in a program, overall meaning of program does not change. This is nothing but Referential transparency.

• But in this case, the first condition is not verified: writing to the console is considered a side effect, since it changes the state of the machine itself. – Right leg Mar 5 at 8:30
• @Rightleg thx for pointing it out. Somehow I misunderstood OP totally other way. corrected answer. – Rahul Agarwal Mar 5 at 8:41
• Doesn't it change the state of the random generator? – Eric Duminil Mar 5 at 9:14
• Generating a random number is itself a side effect, unless the state of the random number generator is supplied explicitly which would make the function satisfy condition 2. – TheInnerLight Mar 5 at 9:23
• `rnd` doesn't escape the function, so the fact that its state changes doesn't matter to the purity of the function, but the fact that the `Random` constructor uses the current time as a seed value means that there are "inputs" other than `a` and `b`. – Sneftel Mar 5 at 11:14