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All the methods in System.Math takes double as parameters and returns parameters. The constants are also of type double. I checked out MathNet.Numerics, and the same seems to be the case there.

Why is this? Especially for constants. Isn't decimal supposed to be more exact? Wouldn't that often be kind of useful when doing calculations?

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This is a classic speed-versus-accuracy trade off.

However, keep in mind that for PI, for example, the most digits you will ever need is 41.

The largest number of digits of pi that you will ever need is 41. To compute the circumference of the universe with an error less than the diameter of a proton, you need 41 digits of pi †. It seems safe to conclude that 41 digits is sufficient accuracy in pi for any circle measurement problem you're likely to encounter. Thus, in the over one trillion digits of pi computed in 2002, all digits beyond the 41st have no practical value.

In addition, decimal and double have a slightly different internal storage structure. Decimals are designed to store base 10 data, where as doubles (and floats), are made to hold binary data. On a binary machine (like every computer in existence) a double will have fewer wasted bits when storing any number within its range.

Also consider:

System.Double      8 bytes    Approximately ±5.0e-324 to ±1.7e308 with 15 or 16 significant figures
System.Decimal    12 bytes    Approximately ±1.0e-28 to ±7.9e28 with 28 or 29 significant figures

As you can see, decimal has a smaller range, but a higher precision.

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nice quote! Where did you find that? – Jrud Nov 5 at 14:36
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web.sbu.edu/math/PiDay.html – John Gietzen Nov 5 at 14:39
Very nice indeed! – Svish Nov 5 at 22:31
Amusing analysis on digits of pi, but just to be contrary: What if I want to measure, not the number of protons it would take to make a circle around the universe, but the number of quarks it would take to fill the volume of the universe? And the universe is expanding, so how long until we would need 42 digits? – Jay Nov 5 at 23:03
And on the mildly serious side, I think far fewer than 41 digits have "practical value". I wonder what the most digits of pi are that were ever needed for any real-world application? – Jay Nov 5 at 23:06
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Double is a built-in type. Is is supported by FPU/SSE core (formerly known as "Math coprocessor"), that's why it is blazingly fast. Especially at multiplication and scientific functions.

Decimal is actually a complex structure, consisting of several integers.

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Neither Decimal nor float or double are good enough if you require something to be precise. Furthermore, Decimal is so expensive and overused out there it is becoming a regular joke.

If you work in fractions and require ultimate precision, use fractions. It's same old rule, convert once and only when necessary. Your rounding rules too will vary per app, domain and so on, but sure you can find an odd example or two where it is suitable. But again, if you want fractions and ultimate precision, the answer is not to use anything but fractions. Consider you might want a feature of arbitrary precision as well.

The actual problem with CLR in general is that it is so odd and plain broken to implement a library that deals with numerics in generic fashion largely due to bad primitive design and shortcoming of the most popular compiler for the platform. It's almost the same as with Java fiasco.

double just turns out to be the best compromise covering most domains, and it works well, despite the fact MS JIT is still incapable of utilising a CPU tech that is about 15 years old now.

[piece to users of MSDN slowdown compilers]

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Our friend Tony the Pony has written some comments about this here

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No, - decimals are no more "exact" than doubles, or forthat matter, any type. The concept of "exactness", (when speaking about numerical representations in a compuiter), is what is wrong. Any type is absolutely 100% exact at representing some numbers. unsigned bytes are 100% exact at representing the whole numbers from 0 to 255. but they're no good for fractions or for negatives or integers outside the range.

Decimals are 100% exact at representing a certain set of base 10 values. doubles (since they store their value using binary IEEE exponential representation) are exact at representing a set of binary numbers. Neither is any more exact than than the other in general, they are simply for different purposes.

To elaborate a bit furthur, since I seem to not be clear enough for some readers...

If you take every number which is representable as a decimal, and mark every one of them on a number line, between every adjacent pair of them there is an additional infinity of real numbers which are not representable as a decimal. The exact same statement can be made about the numbers which can be represented as a double. If you marked every decimal on the number line in blue, and every double in red, except for the integers, there would be very few places where the same value was marked in both colors. In general, for 99.99999 % of the marks, (please don't nitpick my percentage) the blue set (decimals) is a completely different set of numbers from the red set (the doubles).

This is because by our very definition for the blue set is that it is a base 10 mantissa/exponent representation, and a double is a base 2 mantissa/exponent representation. Any value represented as base 2 mantissa and exponent, (1.00110101001 x 2 ^ (-11101001101001) means take the mantissa value (1.00110101001) and multiply it by 2 raised to the power of the exponent (when exponent is negative this is equivilent to dividing by 2 to the power of the absolute value of the exponent). This means that where the exponent is negative, (or where any portion of the mantissa is a fractional binary) the number cannot be represented as a decimal mantissa and exponent, and vice versa.

For any arbitrary real number, that falls randomly on the real number line, it will either be closer to one of the blue decimals, or to one of the red doubles.

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This is not pedentry Jay. This is less than the minimum you need to understand in order to do floating point math accurately and efficiently. The purpose of doubles is to enable fast calculation of physical quantities where the representation error is far less than the measurement error; understanding that is crucial. – Eric Lippert Nov 5 at 15:17
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@Jay, in math, there are indeed exact numbers. In the real world, we can only 'measure' real things to a certain precision. As soon as anyone begins to talk about accuracy, however, the actual value of whatever it is you are measuring comes into play. And 'real' users DO NOT use decimal values, they measure real things. Real things are not decimal or binary. They have a real value. Whatever that real value is, it is a toss up as to whether the closest binary representation, or the closest decimal representation, will be closer to the actual real value. – Charles Bretana Nov 5 at 17:17
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@Bruno. it's not nonsense at all. If you take every number which is representable as a decimal, between every adjacent pair of them there are an infinity of real numbers which are not representable as a decimal. Same is true for the doubles. But these are completely different sets of numbers. For any arbitrary real number, that falls randomly on the real number line, it will either be closer to one of the decimals, or to one of the doubles. – Charles Bretana Nov 5 at 17:21
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@Charles: "For any arbitrary real number, that falls randomly on the real number line, it will either be closer to one of the blue decimals, or to one of the red doubles." Umm, no actually. Any number that can be exactly expressed as a binary fraction can also be exactly expressed as a decimal fraction, but the reverse is not true. Express each as a product of primes: 2=2 (easy enough), 10=2*5. Take any binary fraction, express as x/2^n, and you can convert to a decimal fraction by multiplying by 5^n/5^n. But there is no way to do this in reverse if the numerator of the decimal fraction ... – Jay Nov 5 at 18:30
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(continued) is not divisible by 5^n. So for example binary .1 = decimal .5, binary .01 = decimal .25, binary, binary .001 = decimal .125, etc. But decimal .1 ... right off the bat there's no exact binary equivalent. Your statement would be true if you were comparing two bases that were relatively prime, like base 10 and base 3. – Jay Nov 5 at 18:31
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If I were to hazard a guess, I'd say those functions leverage low-level math functionality (perhaps in C) that does not use decimals internally, and so returning a decimal would require a cast from double to decimal anyway. Besides, the purpose of the decimal value type is to ensure accuracy; these functions do not and cannot return 100% accurate results without infinite precision (e.g., irrational numbers).

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Decimal is more precise but has less of a range. You would generally use Double for physics and mathematical calculations but you would use Decimal for financial and monetary calculations.

See the following articles on msdn for details.

Double http://msdn.microsoft.com/en-us/library/678hzkk9.aspx

Decimal http://msdn.microsoft.com/en-us/library/364x0z75.aspx

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-1 because decimal is no more precise than a double. It depends on what value you are trying to represent. try to represent the binary rational number 0.00101101 x 2^(-00011011001). you will find that a double can represent it with 100% acccuracy, a decimal cannot. – Charles Bretana Nov 5 at 14:40
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I changed the word from "exact" as used in the question to "precise" as used by the MSDN articles. Precise is the precision to which the number is represented. Decimal has a greater precision than Double.... – Robin Day Nov 5 at 14:42
took off by downvote, but would still make the (i'll admit picky) point that regardless of the precision (number of digits) the exactness of the computer representation of a value depends more on which real value you are trying to represent, than it does on how many digits you get to represent it with. But +1 for making distinction between physics/math and financial/monetary applications – Charles Bretana Nov 5 at 14:49
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Charles, you are indeed making the very common error of confusing precision with accuracy. A figure can be very precise without being accurate: I am 1.4293859838 metres tall -- extremely precise, not at all accurate. Or, I am 1.78 metres tall -- not at all precise, but rather more accurate. Neither figure is exact. – Eric Lippert Nov 5 at 15:14
@Eric, Your statement above cannot be evaluated w/o knowing what your real height is... (Are you a short person?) But I do understand the difference. If I said the sun was 1.5782371876433124165413 inches away, that is extremely precise, but not very accurate. But (to us your example), 1.78 could be equally precise if it was actually 1.7800000000000000000000000. Precision 'allows' us to get more accuracy, because the higher the precision, the smaller the spaces are between adjacent 'representable' values. 'Accuracy' brings in the distance between the exact true value and the represented value. – Charles Bretana Nov 5 at 16:26

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