ulong foo = 0;
ulong bar = 0UL;//this seems redundant and unnecessary. but I see it a lot.

I also see this in referencing the first element of arrays a good amount

blah = arr[0UL];//this seems silly since I don't expect the compiler to magically
                //turn '0' into a signed value

Can someone provide some insight to why I need 'UL' throughout to specify specifically that this is an unsigned long?

7 Answers 7

void f(unsigned int x)

void f(int x)
f(3); // f(int x)
f(3u); // f(unsigned int x)

It is just another tool in C++; if you don't need it don't use it!


In the examples you provide it isn't needed. But suffixes are often used in expressions to prevent loss of precision. For example:

unsigned long x = 5UL * ...

You may get a different answer if you left off the UL suffix, say if your system had 16-bit ints and 32-bit longs.

Here is another example inspired by Richard Corden's comments:

unsigned long x = 1UL << 17;

Again, you'd get a different answer if you had 16 or 32-bit integers if you left the suffix off.

The same type of problem will apply with 32 vs 64-bit ints and mixing long and long long in expressions.

  • You should flesh this example out a bit. This is a pretty common source of bugs in production code (assuming 16bit int, 32 bit long): int x = 17; unsigned long ul = (1 << x); Commented Aug 14, 2009 at 9:11
  • Here's another example that relates to the signedness and not the size of the types: "unsigned long ul = (( possiblyNegativeValue + 1 ) > 100 ) ? v1 : v2;" In the example if possiblyNevativeValue is say -2, then the result of he relational operation is false. If we have '1ul' then '-2' is first promoted to unsigned long (and so becomes MAX_ULONG-2) and the result of the relational operation is true. Commented Aug 14, 2009 at 9:20

Some compiler may emit a warning I suppose.
The author could be doing this to make sure the code has no warnings?

  • 1
    +1 Yes, this should really be done anywhere the compiler is generating a warning.
    – patros
    Commented Aug 13, 2009 at 18:35

Sorry, I realize this is a rather old question, but I use this a lot in c++11 code...

ul, d, f are all useful for initialising auto variables to your intended type, e.g.

auto my_u_long = 0ul;
auto my_float  = 0f;
auto my_double = 0d;

Checkout the cpp reference on numeric literals: http://www.cplusplus.com/doc/tutorial/constants/

  • 3
    Why use auto then?
    – ZuOverture
    Commented Oct 6, 2017 at 9:59
  • 1
    @ZuOverture That has been asked and answered many times, but the obvious answer here is that auto makes code more concise, less redundant, and less prone to accidentally incomplete refactoring. Using auto also lets normal construction of class and arithmetic types be more consistent with other forms of initialisation (e.g. new) that must specify the type on (at least) the right-hand side of the assignment operator. Commented Nov 2, 2017 at 20:20
  • 1
    auto does not stick well with adding type to the name of the variable and forcing it further with specifier, does it? It's pointless. I'm just saying that this example above is bad.
    – ZuOverture
    Commented Nov 3, 2017 at 3:08
  • @ZuOverture Agreed on the type named variables - I personally name variables according to their semantic context and shy away from Hungarian Notation. I only named the variables as such to make it clear to OP what was going on.
    – schanq
    Commented Mar 9, 2018 at 14:19

You don't normally need it, and any tolerable editor will have enough assistance to keep things straight. However, the places I use it in C# are (and you'll see these in C++):

  • Calling a generic method (template in C++), where the parameter types are implied and you want to make sure and call the one with an unsigned long type. This happens reasonably often, including this one recently:
    Tuple<ulong, ulong> = Tuple.Create(someUlongVariable, 0UL);
    where without the UL it returns Tuple<ulong, int> and won't compile.
  • Implicit variable declarations using the var keyword in C# or the auto keyword coming to C++. This is less common for me because I only use var to shorten very long declarations, and ulong is the opposite.

When you feel obligated to write down the type of constant (even when not absolutely necessary) you make sure:

  1. That you always consider how the compiler will translate this constant into bits
  2. Who ever reads your code will always know how you thought the constant looks like and that you taken it into consideration (even you, when you rescan the code)
  3. You don't spend time if thoughts whether you need to write the 'U'/'UL' or don't need to write it

also, several software development standards such as MISRA require you to mention the type of constant no matter what (at least write 'U' if unsigned)

in other words it is believed by some as good practice to write the type of constant because at the worst case you just ignore it and at the best you avoid bugs, avoid a chance different compilers will address your code differently and improve code readability


I feel like a lot of answers are missing a huge reason why the suffix is helpful. When using an unsigned long as an r-value it can make code look cleaner.

Let's say you're in a situation where you need to check if the 6th bit from a bitfield is on. The code looks very clean when using the suffix....

bool sixthBitIsOn = (bitfield >> 5) & 1ul;

And without using the suffix....

bool sixthBitIsOn = (bitfield >> 5) & static_cast<unsigned long>(1);

As you can see not using the suffix here forces us to perform an ugly-looking inline cast just so we can compare with a positive least significant bit, but the suffix allows us to create an unsigned long as an r-value for quick usage.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.