# Declaring floats, why default type double?

I am curious as to why float literals must be declared as so:

``````float f = 0.1f;
``````

``````float f = 0.1;
``````

Why is the default type a double, why can't the compiler infer that it is a float from looking at the leftside of the assignment? Google only turns up explanation on what the default values are, not why they are so.

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There is a ton of information about doubles on this page, it is a great read for understanding floats and IEEE 754 better. –  RyPope May 4 '13 at 1:40
I've always wondered this actually. It appears the issue lies with how the compiler detects decimal-numbers to begin with. It appears to default to double literal...I've always had personal issues with using doubles anyway (why would you need so much precision, even in fields of science or engineering?) –  Singular1ty May 4 '13 at 1:40
I think there would be no downside to the compiler being able to recognise that. So as far as I can see there is no real reason behind it. A quick googling didn't point me a valid reason either, but I could be wrong. –  Jubbat May 4 '13 at 1:42
It's the way it was defined. You can invent your own language and do it differently, if you wish. –  Hot Licks May 4 '13 at 2:00
As to why the compiler can't infer the type, it's because, in the C-like languages, expression evaluation is strictly independent of the use of the expression (though C++ probably can be said to violate this from time to time). –  Hot Licks May 4 '13 at 2:02

That's a question that would be best asked of the designers of the Java language.

But I expect that the reasoning was something along the following lines:

They needed to distinguish between the two types of literals because they do actually mean different values ... from a mathematical perspective.

Supposing they made "float" the default for literals, consider this example

``````// (Hypothetical "java" code ... )
double d = 0.1;
double d2 = 0.1d;
``````

In the above, the `d` and `d2` would actually have different values. In the first case, a low precision `float` value is converted to a higher precision `double` value at the point of assignment. But you cannot recover precision that isn't there.

I posit that a language design where those two statements are both legal, and mean different things is a BAD idea ... considering that the actual meaning of the first statement is different to the "natural" meaning.

By doing it the way they've done it:

``````double d = 0.1f;
double d2 = 0.1;
``````

are both legal, and mean different things again. But in the first statement, the programmer's intention is clear, and the second statement the "natural" meaning is what the programmer gets. And in this case:

``````float f = 0.1f;
float f2 = 0.1;    // compilation error!
``````

... the compiler picks up the mismatch.

I am guessing using floats is the exception and not the rule (using doubles instead) with modern hardware so at some point it would make sense to assume that the user intends 0.1f when he writes `float f = 0.1;`

They could do that already. But the problem is coming up with a set of type conversion rules that work ... and are simple enough that you don't need a degree in Java-ology to actually understand. Having `0.1` mean different things in different context would be confusing. And consider this:

``````void method(float f) { ... }
void method(double d) { ... }

// Which overload is called in the following?
this.method(1.0);
``````

Programming language design is tricky. A change in one area can have consequences in others.

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While the difference in precision is clear I suppose it makes sense that they decided to require the users to be explicit about the choice but I wonder for how long it will keep making sense. I am guessing using floats is the exception and not the rule (using doubles instead) with modern hardware so at some point it would make sense to assume that the user intends 0.1f when he writes float f = 0.1; –  arynaq May 4 '13 at 13:31

Ha, this is just the tip of the iceberg my friend.

Programmers coming from other languages certainly don't mind having to add a little `F` to a literal compared to:

``````SomeReallyLongClassName x = new SomeReallyLongClassName();
``````

Pretty redundant, right?

It's true that you'd have to talk to core Java developers themselves to get more background. But as a pure surface-level explanation, one important concept to understand is what an expression is. In Java (I'm no expert so take this with a grain of salt), I believe at the compiler level your code is analyzed in terms of expressions; so:

``````float f
``````

has a type, and

``````0.1f
``````

also has a type (`float`).

Generally speaking, if you're going to assign one expression to another, the types must agree. There are a few very specific cases where this rule is relaxed (e.g., boxing a primitive like `int` in a reference type such as `Integer`); but in general it holds.

It might seem silly in this case, but here's a very similar case where it doesn't seem so silly:

``````double getDouble() {
// some logic to return a double
}

void example() {
float f = getDouble();
}
``````

Now in this case, we can see that it makes sense for the compiler to spot something wrong. The value returned by `getDouble` will have 64 bits of precision whereas `f` can only contain 32 bits; so, without an explicit cast, it's possible the programmer has made a mistake.

These two scenarios are clearly different from a human point of view; but my point about expressions is that when code is first broken down into expressions and then analyzed, they are the same.

I'm sure the compiler authors could have written some not-so-clever logic to re-interpret literals based on the types of expressions they're assigned to; they simply didn't. Probably it wasn't considered worth the effort in comparison to other features.

For perspective, plenty of languages are able to do type inference; in C#, for example, you can do this:

``````var x = new SomeReallyLongClassName();
``````

And the type of `x` will be inferred by the compiler based on that assignment.

For literals, though, C# is the same as Java in this respect.

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`float` has a very little precision, and so a more interesting question is; why it is supported at all? There are rare situations when `float` can same some memory (if you have millions of them) or you need them for exchanging data with something which expects float.
In general, using `double` is a better choice, almost as fast for modern PCs, and the memory save is minor compared with the extra precision it gives.