Mathematically, consider for this question the rational number

```
8725724278030350 / 2**48
```

where `**`

in the denominator denotes exponentiation, i.e. the denominator is `2`

to the `48`

th power. (The fraction is not in lowest terms, reducible by 2.) This number is **exactly** representable as a `System.Double`

. Its decimal expansion is

```
31.0000000000000'49'73799150320701301097869873046875 (exact)
```

where the apostrophes do not represent missing digits but merely mark the boudaries where rounding to **15** resp. **17** digits is to be performed.

Note the following: If this number is rounded to 15 digits, the result will be `31`

(followed by thirteen `0`

s) because the next digits (`49...`

) begin with a `4`

(meaning round *down*). But if the number is *first* rounded to 17 digits and *then* rounded to 15 digits, the result could be `31.0000000000001`

. This is because the first rounding rounds up by increasing the `49...`

digits to `50 (terminates)`

(next digits were `73...`

), and the second rounding might then round up again (when the midpoint-rounding rule says "round away from zero").

(There are many more numbers with the above characteristics, of course.)

Now, it turns out that .NET's standard string representation of this number is `"31.0000000000001"`

. **The question: Isn't this a bug?** By standard string representation we mean the `String`

produced by the parameterles `Double.ToString()`

instance method which is of course identical to what is produced by `ToString("G")`

.

An interesting thing to note is that if you cast the above number to `System.Decimal`

then you get a `decimal`

that is `31`

exactly! See this Stack Overflow question for a discussion of the surprising fact that casting a `Double`

to `Decimal`

involves first rounding to 15 digits. This means that casting to `Decimal`

makes a correct round to 15 digits, whereas calling `ToSting()`

makes an incorrect one.

To sum up, we have a floating-point number that, when output to the user, is `31.0000000000001`

, but when converted to `Decimal`

(where **29** digits are available), becomes `31`

exactly. This is unfortunate.

Here's some C# code for you to verify the problem:

```
static void Main()
{
const double evil = 31.0000000000000497;
string exactString = DoubleConverter.ToExactString(evil); // Jon Skeet, http://csharpindepth.com/Articles/General/FloatingPoint.aspx
Console.WriteLine("Exact value (Jon Skeet): {0}", exactString); // writes 31.00000000000004973799150320701301097869873046875
Console.WriteLine("General format (G): {0}", evil); // writes 31.0000000000001
Console.WriteLine("Round-trip format (R): {0:R}", evil); // writes 31.00000000000005
Console.WriteLine();
Console.WriteLine("Binary repr.: {0}", String.Join(", ", BitConverter.GetBytes(evil).Select(b => "0x" + b.ToString("X2"))));
Console.WriteLine();
decimal converted = (decimal)evil;
Console.WriteLine("Decimal version: {0}", converted); // writes 31
decimal preciseDecimal = decimal.Parse(exactString, CultureInfo.InvariantCulture);
Console.WriteLine("Better decimal: {0}", preciseDecimal); // writes 31.000000000000049737991503207
}
```

The above code uses Skeet's `ToExactString`

method. If you don't want to use his stuff (can be found through the URL), just delete the code lines above dependent on `exactString`

. You can still see how the `Double`

in question (`evil`

) is rounded and cast.

**ADDITION:**

OK, so I tested some more numbers, and here's a table:

```
exact value (truncated) "R" format "G" format decimal cast
------------------------- ------------------ ---------------- ------------
6.00000000000000'53'29... 6.0000000000000053 6.00000000000001 6
9.00000000000000'53'29... 9.0000000000000053 9.00000000000001 9
30.0000000000000'49'73... 30.00000000000005 30.0000000000001 30
50.0000000000000'49'73... 50.00000000000005 50.0000000000001 50
200.000000000000'51'15... 200.00000000000051 200.000000000001 200
500.000000000000'51'15... 500.00000000000051 500.000000000001 500
1020.00000000000'50'02... 1020.000000000005 1020.00000000001 1020
2000.00000000000'50'02... 2000.000000000005 2000.00000000001 2000
3000.00000000000'50'02... 3000.000000000005 3000.00000000001 3000
9000.00000000000'54'56... 9000.0000000000055 9000.00000000001 9000
20000.0000000000'50'93... 20000.000000000051 20000.0000000001 20000
50000.0000000000'50'93... 50000.000000000051 50000.0000000001 50000
500000.000000000'52'38... 500000.00000000052 500000.000000001 500000
1020000.00000000'50'05... 1020000.000000005 1020000.00000001 1020000
```

The first column gives the exact (though truncated) value that the `Double`

represent. The second column gives the string representation from the `"R"`

format string. The third column gives the usual string representation. And finally the fourth column gives the `System.Decimal`

that results from converting this `Double`

.

We conclude the following:

- Round to 15 digits by
`ToString()`

and round to 15 digits by conversion to`Decimal`

disagree in very many cases - Conversion to
`Decimal`

also rounds incorrectly in many cases, and the errors in these cases cannot be described as "round-twice" errors - In my cases,
`ToString()`

seems to yield a bigger number than`Decimal`

conversion when they disagree (no matter which of the two rounds correctly)

I only experimented with cases like the above. I haven't checked if there are rounding errors with numbers of other "forms".

`ToString()`

method? We can all agree that if`ToString()`

returned`"-42.8"`

on this number, it would be a bug, even if`Double`

s are "not exact values" (your words). So`ToString()`

might have a bug, even if the precision of a floating-point number is not unlimited. – Jeppe Stig Nielsen Jun 18 '12 at 14:56