# Why does a C# System.Decimal remember trailing zeros?

Is there a reason that a C# System.Decimal remembers the number of trailing zeros it was entered with? See the following example:

``````public void DoSomething()
{
decimal dec1 = 0.5M;
decimal dec2 = 0.50M;
Console.WriteLine(dec1);            //Output: 0.5
Console.WriteLine(dec2);            //Output: 0.50
Console.WriteLine(dec1 == dec2);    //Output: True
}
``````

The decimals are classed as equal, yet dec2 remembers that it was entered with an additional zero. What is the reason/purpose for this?

It can be useful to represent a number including its accuracy - so 0.5m could be used to mean "anything between 0.45m and 0.55m" (with appropriate limits) and 0.50m could be used to mean "anything between 0.495m and 0.545m".

I suspect that most developers don't actually use this functionality, but I can see how it could be useful sometimes.

I believe this ability first arrived in .NET 1.1, btw - I think decimals in 1.0 were always effectively normalized.

• For the reasons explained, 0.5 and 0.50 do have different information. Precision is very relevant in some fields, namely mathematics and chemistry. Jun 8, 2010 at 11:39
• That would be a nice theory, except that the number of digits returned by division operations has nothing to do with the number of digits in the divisor or dividend. For most situations requiring multiplication or division, it would seem like `Decimal` should offer a method to multiply by a `Double`, with the result rounded to a specified level of precision; if the result can't accommodate that much precision, throw an exception. Otherwise, `Decimal` loses its semantic advantages versus scaling values up by 100 (or the number of subdivisions per currency unit) and using `Double`. May 24, 2012 at 22:28
• @supercat: Hmm... you're right about the division part, certainly. It could still be that the theory is the ability to be able to represent a number and its accuracy, but the practice is that it's not well implemented for arithmetic. (It could still be useful when propagating data from another source, of course.) May 24, 2012 at 22:35
• @JonSkeet: If I were designing a `Decimal` type, I wouldn't include operators to multiply or divide two `Decimals`; instead I would require functions with arguments specifying precision. I'd probably include `Decimal` times `Integer` and `Decimal` times `Long` operators, though. I'd also throw an exception any time an operator would truncate precision. For most financial applications, though, I would think the best type would in many cases be a concatenation of a `Double` with a scaling factor (specified as a number, rather than a power, to allow for non-decimal currencies). May 24, 2012 at 22:45
• @supercat: I don't see why a `Double` (which inherently uses a power of 2, not a number, as a scale - once that's removed it's not really a `Double` any more) would be a wise choice. Nor do I think that it's really important to support non-decimal currencies, to be honest. How many developers' lives would benefit from that support? May 24, 2012 at 22:48

I think it was done to provide a better internal representation for numeric values retrieved from databases. Dbase engines have a long history of storing numbers in a decimal format (avoiding rounding errors) with an explicit specification for the number of digits in the value.

Compare the SQL Server decimal and numeric column types for example.

• It's specifically mapping between .NET's decimal type and SQL server's decimal type that can create problems. If you use `decimal(19,6)` in the database, and `decimal` in C#, and then the user enters `0.5M`, when you store it and retrieve it from the database, you'll get back `0.500000`, which is more precision than the user entered. You either have to store precision in a separate field, or impose a set precision on the field for all values. Aug 24, 2011 at 11:48

Decimals represent fixed-precision decimal values. The literal value `0.50M` has the 2 decimal place precision embedded, and so the decimal variable created remembers that it is a 2 decimal place value. Behaviour is entirely by design.

The comparison of the values is an exact numerical equality check on the values, so here, trailing zeroes do not affect the outcome.

• "Fixed-precision" could be misleading here. It's a floating point type, like `float` and `double` - it's just that the point is a decimal point instead of a binary point (and the limits are different). Jun 8, 2010 at 11:21