Please read an introduction to floatingpoint. This is a typical floating point problem. Binary floating points can't represent
0.01 * 100 is approximately 1.
If it happens to be rounded to
0.999... you get
0, and if it gets rounded to
1.000... you get 1. Which one of those you get is undefined.
The jit compiler is not required to round the same way every time it encounters a similar expression(or even the same expression in different contexts). In particular it can use higher precision whenever it wants to, but can downgrade to 32 bit floats if it thinks that's a good idea.
One interesting point is an explicit cast to
float (even if you already have an expression of type
float). This forces the JITer to reduce the precision to 32 bit floats at that point. The exact rounding is still undefined though.
Since the rounding is undefined, it can vary between .net versions, debug/release builds, the presence of debuggers (and possibly the phase of the moon :P).
Storage locations for floating-point numbers (statics, array elements, and fields of classes) are of fixed size. The
supported storage sizes are float32 and float64. Everywhere else (on the evaluation stack, as arguments, as
return types, and as local variables) floating-point numbers are represented using an internal floating-point
When a floating-point value whose internal representation has greater range and/or precision than its nominal type is put in a storage location, it is automatically coerced to the type of the storage location. This can involve
a loss of precision or the creation of an out-of-range value (NaN, +infinity, or -infinity). However, the value might be retained in the internal representation for future use, if it is reloaded from the storage location without
having been modified. It is the responsibility of the compiler to ensure that the retained value is still valid at the time of a subsequent load, taking into account the effects of aliasing and other execution threads (see memory model (§12.6)). This freedom to carry extra precision is not permitted, however, following the execution of an explicit conversion (conv.r4 or conv.r8), at which time the internal representation must be
exactly representable in the associated type.
Your specific problem can be solved by using
Decimal, but similar problems with
3*(1/3f) won't be solved by this, since
Decimal can't represent one third exactly either.