*This is a summary of my own research and information from the excellent answer by @Pascal Cuoq.*

There are two places where we can truncate the 3-bits we need: the **exponent**, and the **mantissa** (significand). Both approaches run into problems which have to be explicitly handled in order for the calculations to behave as if we used a hypothetical native 61-bit IEEE format.

### Truncating the mantissa

We shorten the mantissa by 3 bits, resulting in a `1s+11e+49m`

format. When we do that, performing calculations in double-precision and then rounding after each computation exposes us to double rounding problems. Fortunately, double rounding can be avoided by using a special rounding mode (round-to-odd) for the intermediate computations. There is an academic paper describing the approach and proving its correctness for all doubles - as long as we truncate at least 2 bits.

Portable implementation in C99 is straightforward. Since round-to-odd is not one of the available rounding modes, we emulate it by using `fesetround(FE_TOWARD_ZERO)`

, and then setting the last bit if the `FE_INEXACT`

exception occurs. After computing the final `double`

this way, we simply round to nearest for storage.

The format of the resulting float loses about 1 significant (decimal) digit compared to a full 64-bit double (from 15-17 digits to 14-16).

### Truncating the exponent

We take 3 bits from the exponent, resulting in a `1s+8e+52m`

format. This approach (applied to a hypothetical introduction of 63-bit floats in OCaml) is described in an article. Since we reduce the range, we have to handle out-of-range exponents on both the positive side (by simply 'rounding' them to infinity) and the negative side. Doing this correctly on the negative side requires biasing the inputs to any operation in order to ensure that we get subnormals in the 64-bit computation whenever the 61-bit result needs to be subnormal. This has to be done a bit differently for each operation, since what matters is not whether the operands are subnormal, but whether we expect the result to be (in 61-bit).

The resulting format has significantly reduced range since we borrow a whopping 3 out of 11 bits of the exponent. The range goes down from 10^{-308}...10^{308} to about 10^{-38} to 10^{38}. Seems OK for computation, but we still lose a lot.

### Comparison

Both approaches yield a well-behaved 61-bit float. I'm personally leaning towards **truncating the mantissa**, for three reasons:

- the "fix-up" operations for round-to-odd are simpler, do not differ from operation to operation, and can be done
*after* the computation
- there is a proof of mathematical correctness of this approach
- giving up one significant digit seems less impactful than giving up a big chunk of the double's range

Still, for some uses, truncating the exponent might be more attractive (especially if we care more about precision than range).