The question is well discussed but since I was digging this problem for a while I would like to share some of my results.

**Problem definition:** Decimals are known to be much slower than doubles but financial applications cannot tolerate any artefacts that arise when calculations are performed on doubles.

**Research**

My aim was to measure different approaches of storing float-pointing numbers and to make a conclusion which one should be used for our application.

If was acceptable for us to use `Int64`

to store floating point numbers with fixed precision. Multiplier of 10^6 was giving us both: enough digits to store fractions and stil a big range to store large amounts. Of course, you have to be careful whith this approach (multiplication and division operations might become tricky), but we were ready and wanted to measure this approach as well. One thing you have to keep in mind except for possible calculation errors and overflows, is that usually you cannot expose those long numbers to public API. So all internal calculations could be performed with longs but before sending the numbers to the user they should be converted to something more friendly.

I've implemented a simple prototype class that wraps a long value to a decimal-like structure (called it `Money`

) and added it to the measurments.

```
public struct Money : IComparable
{
private readonly long _value;
public const long Multiplier = 1000000;
private const decimal ReverseMultiplier = 0.000001m;
public Money(long value)
{
_value = value;
}
public static explicit operator Money(decimal d)
{
return new Money(Decimal.ToInt64(d * Multiplier));
}
public static implicit operator decimal (Money m)
{
return m._value * ReverseMultiplier;
}
public static explicit operator Money(double d)
{
return new Money(Convert.ToInt64(d * Multiplier));
}
public static explicit operator double (Money m)
{
return Convert.ToDouble(m._value * ReverseMultiplier);
}
public static bool operator ==(Money m1, Money m2)
{
return m1._value == m2._value;
}
public static bool operator !=(Money m1, Money m2)
{
return m1._value != m2._value;
}
public static Money operator +(Money d1, Money d2)
{
return new Money(d1._value + d2._value);
}
public static Money operator -(Money d1, Money d2)
{
return new Money(d1._value - d2._value);
}
public static Money operator *(Money d1, Money d2)
{
return new Money(d1._value * d2._value / Multiplier);
}
public static Money operator /(Money d1, Money d2)
{
return new Money(d1._value / d2._value * Multiplier);
}
public static bool operator <(Money d1, Money d2)
{
return d1._value < d2._value;
}
public static bool operator <=(Money d1, Money d2)
{
return d1._value <= d2._value;
}
public static bool operator >(Money d1, Money d2)
{
return d1._value > d2._value;
}
public static bool operator >=(Money d1, Money d2)
{
return d1._value >= d2._value;
}
public override bool Equals(object o)
{
if (!(o is Money))
return false;
return this == (Money)o;
}
public override int GetHashCode()
{
return _value.GetHashCode();
}
public int CompareTo(object obj)
{
if (obj == null)
return 1;
if (!(obj is Money))
throw new ArgumentException("Cannot compare money.");
Money other = (Money)obj;
return _value.CompareTo(other._value);
}
public override string ToString()
{
return ((decimal) this).ToString(CultureInfo.InvariantCulture);
}
}
```

**Experiment**

I measured following operations: addition, subtraction, multiplication, division, equality comparison and relative (greater/less) comparison. I was measuring operations on the following types: `double`

, `long`

, `decimal`

and `Money`

. Each operation was performed 1.000.000 times. All numbers were pre-allocated in arrays, so calling custom code in constructors of `decimal`

and `Money`

should not affect the results.

```
Added moneys in 5.445 ms
Added decimals in 26.23 ms
Added doubles in 2.3925 ms
Added longs in 1.6494 ms
Subtracted moneys in 5.6425 ms
Subtracted decimals in 31.5431 ms
Subtracted doubles in 1.7022 ms
Subtracted longs in 1.7008 ms
Multiplied moneys in 20.4474 ms
Multiplied decimals in 24.9457 ms
Multiplied doubles in 1.6997 ms
Multiplied longs in 1.699 ms
Divided moneys in 15.2841 ms
Divided decimals in 229.7391 ms
Divided doubles in 7.2264 ms
Divided longs in 8.6903 ms
Equility compared moneys in 5.3652 ms
Equility compared decimals in 29.003 ms
Equility compared doubles in 1.727 ms
Equility compared longs in 1.7547 ms
Relationally compared moneys in 9.0285 ms
Relationally compared decimals in 29.2716 ms
Relationally compared doubles in 1.7186 ms
Relationally compared longs in 1.7321 ms
```

**Conclusions**

- Addition, subtraction, multiplication, comparison operations on
`decimal`

are ~15 times slower than operations on `long`

or `double`

; division is ~30 times slower.
- Performance of
`Decimal`

-like wrapper is better than performance of `Decimal`

but still significantly worse than performance of `double`

and `long`

due to lack of support from CLR.
- Performing calculations on
`Decimal`

in absolute numbers is quite fast: 40.000.000 operations per second.

**Advice**

- Unless you have a very heavy calculation case, use decimals. In relative numbers they are slower than longs and doubles, but absolute numbers look good.
- There is not much point in re-implementing
`Decimal`

with your own structure due to abcense of support from CLR. You might make it faster than `Decimal`

but it will never be as fast as `double`

.
- If performance of
`Decimal`

is not enough for your application, than you might want consider switching your calculations to `long`

with fixed precision. Before returning the result to the client it should be converted to `Decimal`

.