Early drafts of IEEE-754 (2008) defined guidelines for what the widths of the exponent and significand fields of arbitrary-width floats "should" be. This was not a hard requirement, but merely recommended practice. It was deemed to be too cumbersome for the minimal benefit provided, so it was dropped from the standard altogether, and replaced with:
Language standards should define mechanisms supporting extendable
precision for each supported radix. Language standards supporting
extendable precision shall permit users to specify p and emax.
Language standards shall also allow the specification of an extendable
precision by specifying p alone; in this case emax shall be defined by
the language standard to be at least 1000×p when p is ≥ 237 bits in a
binary format or p is ≥ 51 digits in a decimal format.
(3.7 Extended and extendable precisions, p14).
That said, the standard still defines (without requiring) "interchange formats" of every multiple-of-32-bits size larger than 128 in the tables in clause 3.6 (p13). Specifically, the binary format of width
k has a
round(4*log2(k)) - 13 bit exponent. For the specific case of
k=256, this gives:
exponent: round(4*log2(256)) - 13 = 32 - 13 = 19
significand: 256 - 1 - 19 = 236
For a 384-bit wide format that followed this formula, the exponent width would be:
round(4*log2(384)) - 13 = round(34.339850002884624) - 13 = 21 bits
Please be aware that there are lots of packages out there for arbitrary-precision floating-point arithmetic that do not adhere to this guidelines. This is only the definition of the "binary256 interchange format", not what any given implementation necessarily uses.