# Why is the "f" required when declaring floats?

Example:

``````float timeRemaining = 0.58f;
``````

Why is the `f` is required at the end of this number?

• Probably, because otherwise it would be treated as `double`. Jul 17, 2012 at 9:35
• 0.58 (without the f suffix) is a literal of type double and one cannot assign a double value to a float, just like one cannot assign an int value to a string. However you can assign a float value to a double because here you are widening (C# will implicitly convert this for you as no precision will be lost). Jul 17, 2012 at 9:40
• possible duplicate of Why should we use literals in C#? Jul 17, 2012 at 9:42
• @AVD Although this is a duplicate, the question title above doesn't yield your link in the possible duplicate list. So this may be adding value in terms of more search criteria at least. Jul 17, 2012 at 9:44
• @AdamHouldsworth - all road goes to `double & int`. Jul 17, 2012 at 9:46

Your declaration of a float contains two parts:

1. It declares that the variable `timeRemaining` is of type `float`.
2. It assigns the value `0.58` to this variable.

The problem occurs in part 2.

The right-hand side is evaluated on its own. According to the C# specification, a number containing a decimal point that doesn't have a suffix is interpreted as a `double`.

So we now have a `double` value that we want to assign to a variable of type `float`. In order to do this, there must be an implicit conversion from `double` to `float`. There is no such conversion, because you may (and in this case do) lose information in the conversion.

The reason is that the value used by the compiler isn't really 0.58, but the floating-point value closest to 0.58, which is 0.57999999999999978655962351581366... for `double` and exactly 0.579999946057796478271484375 for `float`.

Strictly speaking, the `f` is not required. You can avoid having to use the `f` suffix by casting the value to a `float`:

``````float timeRemaining = (float)0.58;
``````
• Two questions, how did you arrive at the number '0.579999946057796478271484375', and how will the `(float) 0.58` work? You said earlier that there is no conversion, because information might be lost, then how come the cast will work? May 4, 2014 at 15:53
• 1. I used the Windows calculator, which uses up to 34 digits. 2. I said there is no implicit conversion. A cast is an explicit conversion, so you are explicitly telling the compiler you want the conversion, and that is allowed. Jun 2, 2014 at 15:46
• Interesting ... I hope you're still monitoring this post. I got introduced to suffixes having run into 'm' previously for the webcast I'm viewing. How did you get the Windows calculator to display .58 as the float value? I tried a couple buttons that looked like they'd force this to happen but no ... kept getting 0.58. I have to respect a man who knows his tools so well ... Apr 1, 2016 at 11:14
• I understand the whole F thing for float but why? When you declared the variable is declared it as a float so when compiled it should know this value is a float. And when you declare a double same thing. It doesn't make sense because you have float myvalue = 2.4; now when compiled the compiler should already know float is the type of variable. Am I missing something? Thanks! Mar 11, 2017 at 5:08
• @FrankG. Two reasons: 1. The expression `2.4` is interpreted as a double everywhere else. 2. Implicit narrowing conversions (like from double to float) are not allowed. If you want to make an exception to these rules, then you must have a very good reason. Saving 1 key stroke is not likely to be good enough. Mar 14, 2017 at 16:59

Because there are several numeric types that the compiler can use to represent the value `0.58`: `float`, `double` and `decimal`. Unless you are OK with the compiler picking one for you, you have to disambiguate.

The documentation for `double` states that if you do not specify the type yourself the compiler always picks `double` as the type of any real numeric literal:

By default, a real numeric literal on the right side of the assignment operator is treated as double. However, if you want an integer number to be treated as double, use the suffix d or D.

Appending the suffix `f` creates a `float`; the suffix `d` creates a `double`; the suffix `m` creates a `decimal`. All of these also work in uppercase.

However, this is still not enough to explain why this does not compile:

``````float timeRemaining = 0.58;
``````

The missing half of the answer is that the conversion from the `double` `0.58` to the `float` `timeRemaining` potentially loses information, so the compiler refuses to apply it implicitly. If you add an explicit cast the conversion is performed; if you add the `f` suffix then no conversion will be needed. In both cases the code would then compile.

• but how can it be a double or a decimal if the variable is a float, I am missing something Jul 17, 2012 at 9:41
• @BlazArt Yes, the sentence that states the compiler doesn't even try to check the assignment target. The reason for this will be buried in the design choices made by the compiler team. I would guess it is best to be explicit in the face of possible confusion, or it was too expensive to bother implementing instead of just having two rules, one for `int` and one for `double`. Jul 17, 2012 at 9:42
• @BlazArt: Just finished fleshing out the answer, please have a look again.
– Jon
Jul 17, 2012 at 9:44
• Regarding the information loss, can you tell me how the cast is actually done, with respect to the IEEE 754 format they are stored in? Double has higher precision, so does that mean that cast from float to double will always work, like `double a = 0.69f;`? May 4, 2014 at 15:55
• @Cupidvogel: Yes, the spec guarantees (in §6.1.2) that "the other implicit numeric conversions never lose any information", which among others includes converting `float` to `double`.
– Jon
May 5, 2014 at 9:44

The problem is that .NET, in order to allow some types of implicit operations to be carried out involving `float` and `double`, needed to either explicitly specify what should happen in all scenarios involving mixed operands or else allow implicit conversions between the types to be performed in one direction only; Microsoft chose to follow the lead of Java in allowing the direction which occasionally favors precision, but frequently sacrifices correctness and generally creates hassle.

In almost all cases, taking the `double` value which is closest to a particular numeric quantity and assigning it to a `float` will yield the `float` value which is closest to that same quantity. There are a few corner cases, such as the value 9,007,199,791,611,905; the best `float` representation would be 9,007,200,328,482,816 (which is off by 536,870,911), but casting the best `double` representation (i.e. 9,007,199,791,611,904) to `float` yields 9,007,199,254,740,992 (which is off by 536,870,913). In general, though, converting the best `double` representation of some quantity to `float` will either yield the best possible `float` representation, or one of two representations that are essentially equally good.

Note that this desirable behavior applies even at the extremes; for example, the best `float` representation for the quantity 10^308 matches the `float` representation achieved by converting the best `double` representation of that quantity. Likewise, the best `float` representation of 10^309 matches the `float` representation achieved by converting the best `double` representation of that quantity.

Unfortunately, conversions in the direction that doesn't require an explicit cast are seldom anywhere near as accurate. Converting the best `float` representation of a value to `double` will seldom yield anything particularly close to the best `double` representation of that value, and in some cases the result may be off by hundreds of orders of magnitude (e.g. converting the best `float` representation of 10^40 to `double` will yield a value that compares greater than the best `double` representation of 10^300.

Alas, the conversion rules are what they are, so one has to live with using silly typecasts and suffixes when converting values in the "safe" direction, and be careful of implicit typecasts in the dangerous direction which will frequently yield bogus results.