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What is the difference between Decimal, Float and Double in .NET?

When would someone use one of these?

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IMO, Skeet's answer is not complete without cgreeno's answer –  Chibueze Opata Jul 15 '12 at 14:38
interesting article zetcode.com/lang/csharp/datatypes –  GibboK Mar 1 at 14:20
sometimes wikipedia isnt a bad choise. –  C4ud3x Sep 25 at 12:23

13 Answers 13

up vote 1112 down vote accepted

float and double are floating binary point types. In other words, they represent a number like this:


The binary number and the location of the binary point are both encoded within the value.

decimal is a floating decimal point type. In other words, they represent a number like this:


Again, the number and the location of the decimal point are both encoded within the value – that's what makes decimal still a floating point type instead of a fixed point type.

The important thing to note is that humans are used to representing non-integers in a decimal form, and expect exact results in decimal representations; not all decimal numbers are exactly representable in binary floating point – 0.1, for example – so if you use a binary floating point value you'll actually get an approximation to 0.1. You'll still get approximations when using a floating decimal point as well – the result of dividing 1 by 3 can't be exactly represented, for example.

As for what to use when:

  • For values which are "naturally exact decimals" it's good to use decimal. This is usually suitable for any concepts invented by humans: financial values are the most obvious example, but there are others too. Consider the score given to divers or ice skaters, for example.

  • For values which are more artifacts of nature which can't really be measured exactly anyway, float/double are more appropriate. For example, scientific data would usually be represented in this form. Here, the original values won't be "decimally accurate" to start with, so it's not important for the expected results to maintain the "decimal accuracy". Floating binary point types are much faster to work with than decimals.

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float/double usually do not represent numbers as 101.101110, normally it is represented as something like 1101010 * 2^(01010010) - an exponent –  Hazzard Aug 13 at 21:50
@Hazzard: That's what the "and the location of the binary point" part of the answer means. –  Jon Skeet Aug 13 at 21:57
I must have missed that, my bad –  Hazzard Aug 13 at 21:59

Precision is the main difference.

Float - 7 digits (32 bit)

Double-15-16 digits (64 bit)

Decimal -28-29 significant digits (128 bit)

Decimals have much higher precision and are usually used within financial applications that require a high degree of accuracy. Decimals are much slower (up to 20X times in some tests) than a double/float.

Decimals and Floats/Doubles cannot be compared without a cast whereas Floats and Doubles can. Decimals also allow the encoding or trailing zeros.

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@Thecrocodilehunter: sorry, but no. Decimal can represent all numbers that can be represented in decimal notation, but not 1/3 for example. 1.0m / 3.0m will evaluate to 0.33333333... with a large but finite number of 3s at the end. Multiplying it by 3 will not return an exact 1.0. –  Erik P. Nov 29 '11 at 21:14
@Thecrocodilehunter: I think you're confusing accuracy and precision. They are different things in this context. Precision is the number of digits available to represent a number. The more precision, the less you need to round. No data type has infinite precision. –  Igby Largeman Jan 6 '12 at 17:42
@Thecrocodilehunter: You're assuming that the value that is being measured is exactly 0.1 -- that is rarely the case in the real world! Any finite storage format will conflate an infinite number of possible values to a finite number of bit patterns. For example, float will conflate 0.1 and 0.1 + 1e-8, while decimal will conflate 0.1 and 0.1 + 1e-29. Sure, within a given range, certain values can be represented in any format with zero loss of accuracy (e.g. float can store any integer up to 1.6e7 with zero loss of accuracy) -- but that's still not infinite accuracy. –  Daniel Pryden Jan 10 '12 at 1:49
@Thecrocodilehunter: You missed my point. 0.1 is not a special value! The only thing that makes 0.1 "better" than 0.10000001 is because human beings like base 10. And even with a float value, if you initialize two values with 0.1 the same way, they will both be the same value. It's just that that value won't be exactly 0.1 -- it will be the closest value to 0.1 that can be exactly represented as a float. Sure, with binary floats, (1.0 / 10) * 10 != 1.0, but with decimal floats, (1.0 / 3) * 3 != 1.0 either. Neither is perfectly precise. –  Daniel Pryden Jan 10 '12 at 18:27
@Thecrocodilehunter: You still don't understand. I don't know how to say this any more plainly: In C, if you do double a = 0.1; double b = 0.1; then a == b will be true. It's just that a and b will both not exactly equal 0.1. In C#, if you do decimal a = 1.0m / 3.0m; decimal b = 1.0m / 3.0m; then a == b will also be true. But in that case, neither of a nor b will exactly equal 1/3 -- they will both equal 0.3333.... In both cases, some accuracy is lost due to representation. You stubbornly say that decimal has "infinite" precision, which is false. –  Daniel Pryden Jan 10 '12 at 19:29

float is a single precision (32 bit) floating point data type as defined by IEEE 754 (it is used mostly in graphic libraries).

double is a double precision (64 bit) floating point data type as defined by IEEE 754 (probably the most normally used data type for real values).

decimal is a 128-bit floating point data type, it should be used where precision is of extreme importance (monetary calculations).

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Actually, decimal is not a floating-point data type. –  Tor Haugen Mar 6 '09 at 11:39
Technically, it is a floating point data type as it stores exponent and mantissa. –  Mehrdad Afshari Mar 6 '09 at 11:41
It's a floating decimal point type rather than a float binary point type. –  Jon Skeet Mar 6 '09 at 11:46
Keep in mind also, that float and double (as defined by the IEEE) can represent Infinity, Negative Infinity, and NaN (all useful in abstract math) whereas decimal (geared towards business math) can not. –  BrainSlugs83 Jun 23 '11 at 19:35
Very good explanation, clear and short. –  Afshin Mehrabani Oct 15 '12 at 7:26

The Decimal structure is strictly geared to financial calculations requiring accuracy, which are relatively intolerant of rounding. Decimals are not adequate for scientific applications, however, for several reasons:

  • A certain loss of precision is acceptable in many scientific calculations because of the practical limits of the physical problem or artifact being measured. Loss of precision is not acceptable in finance.
  • Decimal is much (much) slower than float and double for most operations, primarily because floating point operations are done in binary, whereas Decimal stuff is done in base 10 (i.e. floats and doubles are handled by the FPU hardware, such as MMX/SSE, whereas decimals are calculated in software).
  • Decimal has an unacceptably smaller value range than double, despite the fact that it supports more digits of precision. Therefore, Decimal can't be used to represent many scientific values.
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float 7 digits of precision

double has about 15 digits of precision

decimal has about 28 digits of precision

If you need better accuracy, use double instead of float. In modern CPUs both data types have almost the same performance. The only benifit of using float is they take up less space. Practically matters only if you have got many of them.

I found this is interesting. What Every Computer Scientist Should Know About Floating-Point Arithmetic

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-1: Use decimal in accounting applications. –  Roger Lipscombe Jul 6 '13 at 18:10
@RogerLipscombe: I would consider double proper in accounting applications in those cases (and basically only those cases) where no integer type larger than 32 bits was available, and the double was being used as though it were a 53-bit integer type (e.g. to hold a whole number of pennies, or a whole number of hundredths of a cent). Not much use for such things nowadays, but many languages gained the ability to use double-precision floating-point values long before they gained 64-bit (or in some cases even 32-bit!) integer math. –  supercat May 29 at 17:57
  1. Double and float can be divided by integer zero without an exception at both compilation and run time.
  2. Decimal cannot be divided by integer zero. Compilation will always fail if you do that.
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They sure can! They also also have a couple of "magic" values such as Infinity, Negative Infinity, and NaN (not a number) which make it very useful for detecting vertical lines while computing slopes... Further, if you need to decide between calling float.TryParse, double.TryParse, and decimal.TryParse (to detect if a string is a number, for example), I recommend using double or float, as they will parse "Infinity", "-Infinity", and "NaN" properly, whereas decimal will not. –  BrainSlugs83 Jun 23 '11 at 19:29

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for more information you can go to source of this picture:


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-1 for claiming that decimal is 96 bits. MSDN clearly says 128. –  Ben Voigt 2 days ago
And if you dig deeper, it's 102 bits used, 128 stored. No way to fit that in 12 bytes. –  Ben Voigt 2 days ago

Integers, as was mentioned, are whole numbers. They can't store the point something, like .7, .42, and .007. If you need to store numbers that are not whole numbers, you need a different type of variable. You can use the double type, or the float type. You set these types of variables up in exactly the same way: instead of using the word int, you type double, or float. Like this:

float myFloat;
double myDouble;

(Float is short for "floating point", and just means a number with a point something on the end.)

The difference between the two is in the size of the numbers that they can hold. For float, you can have up to 7 digits in your number. For doubles, you can have up to 16 digits. To be more precise, here's the official size:

float: 1.5 × 10-45 to 3.4 × 1038 double: 5.0 × 10-324 to 1.7 × 10308

Float is a 32-bit number and double is a 64-bit number.

Double click your new button to get at the code. Add the following three lines to your button code:

double myDouble;
myDouble = 0.007;

Halt your program and return to the coding window. Change this line:

myDouble = 0.007;
myDouble = 12345678.1234567;

Run your programme and click your double button. The message box correctly displays the number. Add another number on the end, though, and C# will again round up or down. The moral is, if you want accuracy, careful of rounding!

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Upvoted for using .42 and .007 in your example. : D –  PruitIgoe Aug 12 '13 at 17:14

This has been an interesting thread of me, as today, we've just had a nasty little bug, concerning "decimal" having less precision than a "float".

In our C# code, we are reading numeric values from an Excel spreadsheet, converting them into a decimal, then sending this decimal back to a Service, to save into a SQL Server database.

Microsoft.Office.Interop.Excel.Range cell = ...
object cellValue = cell.Value2;
if (cellValue != null)
    decimal value = 0;
    Decimal.TryParse(cellValue.ToString(), out value);

Now, for almost all of our Excel values, this worked beautifully. But for some, very small Excel values, using "decimal.TryParse" lost the value completely. One such example:

  • cellValue = 0.00006317592

  • Decimal.TryParse(cellValue.ToString(), out value); would return 0

The solution, bizarrely, was to convert the Excel values into a double first, and then into a decimal.

Microsoft.Office.Interop.Excel.Range cell = ...
object cellValue = cell.Value2;
if (cellValue != null)
    double valueDouble = 0;
    double.TryParse(cellValue.ToString(), out valueDouble);
    decimal value = (decimal)valueDouble;

Even though double has less precision than a decimal, this actually ensured small numbers would still be recognised. For some reason, "double.TryParse" was actually able to retrieve such small numbers, whereas "decimal.TryParse" would set them to zero.

Odd. Very odd.

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Out of curiosity, what was the raw value of cellValue.ToString()? Decimal.TryParse("0.00006317592", out val) seems to work... –  micahtan Aug 27 '12 at 23:57
-1 Don't get me wrong, if true, it's very interesting but this is a separate question, it's certainly not an answer to this question. –  weston May 22 '13 at 14:19
Maybe because the Excel cell was returning a double and ToString() value was "6.31759E-05" therefore the decimal.Parse() didn't like the notation. I bet if you checked the return value of Decimal.TryParse() it would have been false. –  SergioL Oct 15 at 20:44

float ~ ±1.5 x 10-45 to ±3.4 x 1038 --------7 figures
double ~ ±5.0 x 10-324 to ±1.7 x 10308 ------15 or 16 figures
decimal ~ ±1.0 x 10-28 to ±7.9 x 1028 --------28 or 29 figures

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For applications such as games and embedded systems where memory and performance are both critical, float is usually the numeric type of choice as it is faster and half the size of a double. Integers used to be the weapon of choice, but floating point performance has overtaken integer in modern processors. Decimal is right out!

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+1 for the most creative answer. –  Diwas Pathak Jul 16 at 4:54

Note: I've deleted my previous answer, and I'm going to attempt to explain this in a different way. I apologize for the length, and apparent rambling nature, but it will all come together in the end. I will assume you know what binary and decimal numbers are, and how to do basic binary to decimal conversion, even if it's with a calculator.

Most people think the difference between formats is simply about precision, and to a great degree that is important, but there's also something very important that is harder to grasp.

float and double are binary floating point types, while decimal is a decimal floating point type.

All floating point (and fixed point, which I won't go into) numbers (ex. .1) can be expressed as either their decimal number or a fraction (ie 1/10). These are called Rational numbers. Rational numbers, by definition are numbers that can be represented both fractionally and decimally.

The opposite is not true. These fall into two categories, Irrational numbers and Infinitely repeating fractionals. Irrational numbers cannot be represented as fractions and are irrational in every number base (other than itself), and will go on infinitely regardless of binary or decimal. Repeating fractionals infinitely repeat the same pattern (not necessarily the same number, but pattern of numbers) over and over and these it turns out are base dependent.

Regardless, neither of these types of numbers can be be accurately represented in floating (or fixed) point number formats. Examples are Pi, e, 1/3, 2/3 (in decimal), etc..

Humans work with numbers in base-10, which is the definition of decimal. Decca being 10 in Greek.

Computers work in base-2, or binary. And the important thing to remember is that computers do math most efficiently in base-2. Often, numbers are also stored in base-2 representation. Because computers can only work with finite data, there are practical limits to the size of the numbers you can work with in standard numeric formats. Any numbers which are larger (or smaller or requires more precision) than what is defined by the limits of the storage format are rounded. Also, by definition, a computer can only accurately work with rational and non-infinite numbers because it has to have the entire number in memory to work on it. (it's possible to write a program that can calculate numbers without them being fully in memory, but that's not how the standard numeric formats work).

Now, the problem is that there is an inherent "impedance mismatch" between base-2 and base-10 numbers relating to infinitely repeating fractional numbers. What's repeating in one base, is not repeating in another and vice versa. And this has to do with the fractional math representation.

Consider that in base-10, 1/3 is infinitely repeating. 1/3 = .3333333... That seems obvious on its face. However, if you think about it... I just represented the same number 2 ways. One of them was accurate, one of them was not. 1/3 is accurate. .3333333... is an approximation. This leads one to the conclusion that if you can store an infinitely repeating decimal number accurately in fractional format, can it be stored in other formats accurately? And the answer is yes. 1/3 can be accurately stored in base-2.

1/3 in binary is 1 / 10, which results in 0.1 in a binary floating point format. Imagine that. 1/3 is not an infinite number in binary.

Ok, so that leads us to the inverse conclusion that finite numbers in decimal might be infinitely repeating numbers in binary. And this is in fact true as well. 1/10 in decimal is one of those numbers.

This results in: 1 / 1010 (decimal 10 in binary) = 0.00011001100110011001100110011001100110011001100110011001100110...

Which when rounded back to decimal is actually something like 0.10000000149011612

This is why trying to store .1 (or certain other numbers that would seem to be easily storable) in binary floating point formats (such as float or double) you get rounding errors. And, why math with these numbers can be inaccurate. Because the computer is doing math in a different base than you as a human are doing it, and arriving at a different number in cases where the result is infinitely repeating (or the source numbers are infinitely repeating)

Now, the difference between these binary floating point types and the decimal type is that decimal, while still stored ultimately as binary, is not represented as binary in it's internal storage... The computer treats the numbers as decimal base-10, and does math as base 10 on these formats. So if you store 1/10 in a decimal type variable, then this is a finite number (and within the precision of the format) and is not rounded. 1/3 however cannot be represented in this format and is infinitely repeating and is rounded.

So what this boils down to.. the difference between float or double and decimal is:

  • 1/3 = .333333333... dec, .1 binary
  • 1/10 = .1 dec, .0001100110011... binary

This inherent impedance mismatch is exacerbated by the conversion back to decimal for use by humans. It's like when you translate something from English to Japanese, then back to English. Something gets lost in the translation quite often.

With the decimal type, the computer works with math the way humans work with math (up to the precision of it's format).

Beyond this "infinite/non-infinite" impedance mismatch, then you simply have the precision of each format, and calculations will be rounded beyond that precision.

  • float is accurate to 7 digits
  • double is accurate to 15-16 digits
  • decimal is accurate to 28-29 significant digits

Also, float and double are faster than decimal, by about an order of magnitude based on the benchmark here:


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The Decimal, Double, and Float variable types are different in the way that they store the values. Precision is the main difference where float is a single precision (32 bit) floating point data type, double is a double precision (64 bit) floating point data type and decimal is a 128-bit floating point data type.

Float - 32 bit (7 digits)

Double - 64 bit (15-16 digits)

Decimal - 128 bit (28-29 significant digits)

More about...the difference between Decimal, Float and Double


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