I have a float variable and would like to get only the part after the comma, so if I have 3.14. I would like to get 14 as an integer. How can I do that?
The cheating way to do it is:
edit2: OK OK OK OK. Here is the most paranoid never fail version I can come up with. This will return the first 9 digits (or less, if there aren't that many) of the decimal portion of the floating point number. This is guaranteed to not overflow an Int32. We use the invariant culture so we know that we can use a period as the decimal separator. 


You can subtract the integer portion from the value itself to retrieve the fractional part.
You can then multiply it to get the fractional part represented as an integer at whatever precision you'd like. Mapping the fractional portion to an integer has some challenges  many floating point numbers cannot be represented as a base10 integer, and thus may require more digits to represent than an integer can support. Also, what of the case of numbers like 3.1 and 3.01? Mapping directly to an integer would both result in 1. 


Try
David's "cheating version" answer doesn't seem to be very popular at the moment, but after looking into this for the better part of the day, I found the System.Version class. It has a constructor which takes a string. Using Reflector, I saw that it works by splitting the string into an array. I ran a test getting the fractional part of the arbitrary number 1234567891.1234567891m. With 1,000,000 iterations, it was 50% faster than the other answer I posted in spite of the fact that I first had to convert the decimal number to a string for the sake of the Version constructor. So David is getting a bad break when using a string conversion concept seems to be a bright way to go. Microsoft did. 


Here's another version that also tells how many digits are part of the fractional makeup, which I needed.
It's similar in idea to David's answer (his noncheating version). However, I used the decimal type instead of double, which slows things down, but improves accuracy. If I convert David's (again, noncheating version) answer to use a decimal type (in which case his "precision" variable can be changed to the constant zero), my answer runs about 25% faster. Note that I also changed his code to provide the number of fractional digits in my testing. 


Here's the "noncheating" answer:
We use precision instead of 0 to make up for the fact that floating point numbers don't work very well with decimal numbers. You can adjust it to suit your application. This is why I think the "cheating" string way is actually better. 


Actually all solutions until now are wrong as they don't consider that using






To suggest something different than the others, an extension method (with a method similar to David's):
Edit: I didn't use the "best" answer, because it omitted the hardest part, which is converting an arbitrary decimal number, and did not work for negative numbers. I added the correction requested in David's answer. 


This will result in some odd unpredictable values. Floating point numbers are not stored as a decimal  the exponent part is a power of 2, not 10. This means that some numbers (for instance 1.1) can't be accurately expressed as a float (1.1 ends up something like 1.099999999998) The problem is that for some numbers the starting number may not be one of these while the decimal part on its own might be. So your number is x.y You get the integer part x You do x.y  x to get 0.y Sometimes x.y can be expressed as a float and 0.y can't, so rather than get y you'll get some big value with lots of 0s or 9s in it. @David's 'cheating' way is actually the best way  least prone to this issue anyway. However I'd look at why you need to do this  floats are great for very fast maths, but a bit rubbish for accuracy. If accuracy is important use a 


Just in case some wants another cheating way for it:
where 100 is used shift the decimal part. 


I saw a and fast way to convert floats/doubles to integers representative of their digits using a bitmask and the GetBits method... It only works if the results fit into a 32 bit integer, but it's still really slick... I can't take credit for it, but have a look: http://stsdb.com/showthread.php?t=58&p=285&viewfull=1#post285 

