I'm studying C, and the idea of guard digits and rounding errors came up. Do practitioners of scripting languages (I'm thinking of Python and Perl here) need to worry about this stuff? What if they are doing scientific programming?

I would have to disagree with Lutz... While the rounding errors you mentioned do exist in Python/Perl/Ruby, they have absolutely nothing to do with the languages being implemented in C. The problem goes deeper than that. Floatingpoint numbers, like all data, are represented in binary on modern computers. Just as there are numbers with periodic decimal representations (e.g., 1/3 = 0.333333...), there are also numbers with periodic binary representations (e.g., 1/10 = 0.0001100110011...). Since these numbers cannot be exactly represented in (a finite amount of) computer memory, any calculations involving them will introduce error. This can be worked around by using highprecision math libraries, which represent the numbers either as the two numbers of a fraction (i.e., "numerator = 1, denominator = 10") or as string instead of using a native binary representation. However, because of the extra work involved in doing any calculations on numbers that are being stored as something else, these libraries necessarily slow down any math that has to go through them. 


It depends.
(Or, if you really want to hide what's going on:
) As expected, this yields:
Also as expected, this is not done in one CPU instruction. 


There are several types of noninteger numbers in Python:
would give you the standard float. Its type is However, there is also fractional type:
which has exact arithmetics with rational numbers. In the case you want to perform rounding, but are not satisfied with the number of meaningful digits on your computer, or the fact that it could be different across platforms, decimal type is your friend:
You'll be able to set its precision to, say, 100 digits, if you want to. Or set it to 2 for bank applications. As long as computers are stupid, we'll probably need this many different types. At least, in accordance with Pythonic principles, Python requires you to make an explicit choice about what you want from your numbers. Moreover, it's a big misunderstanding that exact arithmetics doesn't lead to problems with rounding. Any time you round exact value to do something useful for a user to it  e.g. print it to the user or add that many dollars to user's bank account  you encounter "strange behavior" of rounding. This is inherent to noninteger arithmetics. 


It depends on how you represent your numbers, not the language you use. For example, if I write all my code in 8051 assember, but have implemented a slick rational number library, then round off isn't a problem. 1/3 is only equal to 1/3. However if I am using the latest snazzy dynamic language, and it uses IEE754 floats, then all the limitations of IEEE754 apply. If you need to care about the details of the numbers you generate, then you need to understand their representation and how they are manipulated by your choice of tools. Update:PDL is a popular library for doing scientific computing in Perl. 


Since the underlying intepreter of both CPython and Perl are implemented in C, they behave like a C program. For Python there is SciPY and NumPy for scientific computation. 


You can do multiple precision calculations with Python, with external modules. The Multi Precision Math section in the official web site lists many of them. 


Well, you're not immune to floating point errors in Ruby. For example:



When you do scientific programming, you'll always have to worry about rounding errors, no matter which programming language or numeric library you use. Proof: Say you want to track the movement of a molecule near the border of the universe. The size of the universe is about 93 billion lightyears (as far as we know). A molecule is pretty tiny, so you'll want at least nanometer precision (10^6). That's 50 orders of magnitude. For some reason, you need to rotate that molecule. That involves You must create the error equation to be sure that you keep enough digits so that the final result will have a know maximum error. I don't know any "simple" numeric library which can do this operation automatically (say, as part of the call to 


Sure they do! An example from Python 2.6:
As lutz says, since scripting languages are often implemented in C, they inherit these "features". Compensating for them in the language would undoubtedly mean some kind of tradeoff in performance or portability. 

