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std::bit_width finds minimum bits required to represent an integral number x as 1+floor(log(x))

Why does std::bit_width return 0 for the value 0? Shouldn't it return 1, Since the number of bits required to represent 0 is 1?

Also, I think the 1 in the formula is an offset.

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    The standard specifies this behavior explicitly, but doesn't give any motivation for it. – Nate Eldredge Apr 18 at 4:47
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    Why should it return 1? If you want to hold zero apples, you need zero baskets, no? So for example if you were to store data as a length and a pointer to a buffer of variable length, you wouldn't even have to use any buffer at all to represent zero because you would have a length of zero to begin with. – CherryDT Apr 18 at 4:52
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    It's also logical from another perspective: it returns the position of the highest-value 1-bit from the right, starting with 1, so 0 would indicate there being no 1-bit at all. Or, from another perspective: 2^0=1, so a 0-bits-long number can represent exactly 1 state: zero. Therefore, zero bits are enough to represent the number zero. – CherryDT Apr 18 at 4:57
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    @rohitt: yes you need the length zero, but this is no different from having to either store the length or know the maximum possible length in advance either way. If you want to represent the number 5, you need 3 bits, but you additionally need to remember somehow that you need 3 bits, otherwise you couldn't differentiate the number 5 from a larger number including more bits when they come in a bitstream. And with zero it's no different, you need 0 bits to store it but you need to still store or somehow remember how much you need to read/write - nothing in this case. – CherryDT Apr 18 at 5:00
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    We don't really need one digit to represent zero. Using one digit for zero is needed only inside a human-readable sentence where we need to detect the presence of a number. Otherwise, when we already know there is a number there, the empty sequence of digits is a perfectly good representation for zero, which is also more regular. Try writing an algorithm to convert naturals into variable-length bit strings and vice versa: it's easier if we represent zero as the empty string. Indeed, when we need the one-digit zero, we need to implement a special case just for that. – chi Apr 18 at 10:04
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There is a strange bit of history to bit_width.

The function that would eventually become known as bit_width started life as log2, as part of a proposal adding integer power-of-two functions. log2 was specified to produce UB when passed 0.

Because that's how logarithms work.

But then, things changed. The function later became log2p1, and for reasons that are not specified was given a wider contract ("wide contract" in C++ parlance means that more stuff is considered valid input). Specifically, 0 is valid input, and yields the value of 0.

Which is not how logarithms work, but whatever.

As C++20 neared standardization, a name conflict was discovered (PDF). The name log2p1 happens to correspond to the name of an IEEE-754 algorithm, but it's a radically different one. Also, functions in other languages with similar inputs and results use a name like bit_length. So it was renamed to bit_width.

And since it's not pretending to do a logarithm anymore, the behavior at 0 can be whatever we want.

Indeed, the Python function int.bit_length has the exact same behavior. Leading zeros are not considered part of the bit length, and since a value of 0 contains all leading zeros...

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  • Very minor quibble, but I don't think it's accurate to say "UB when passed 0... Because that's how logarithms work". UB means "can do literally anything including having effects way outside the return value of this function". In particular, the behavior of the newer spec is 100% compliant with the older one, because "return 0" is a perfectly valid implementation of UB. – psmears Apr 19 at 14:23
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    @psmears: "including having effects way outside the return value of this function" That's what happens when you take the logarithm of 0 as well. It is a thing you cannot do, and if you do it, then your math is broken and ceases to be actual math. – Nicol Bolas Apr 19 at 14:54
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    It's perfectly valid (and useful) in mathematics to extend the real number line to include plus/minus infinity, and to define log 0 to be minus infinity. Or to treat log as a partial function on the reals. This answer currently says "that is not how logarithms work" about a behavior that is 100% conformant with the part you describe as "that is how logarithms work", which seems a bit inconsistent :) – psmears Apr 19 at 15:03
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    @psmears so what's tan 90 – Ray Wu Apr 19 at 17:38
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    The function formerly known as log2p1 actually does work exactly like a logarithm; the issue is that the formula it evaluates is not floor(log(n) + 1) but ceil(log(n + 1)). Why the committee did not describe it using the second formula, which works for all n, but instead used the first one which has an awkward discontinuity at n=0 and therefore needs to be described more wordily, is anyone's guess (this is the C++ standard committee we're talking about, after all). – trentcl Apr 19 at 19:18
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Because mathematically it makes sense:

bit_width(x) = log2(round_up_to_nearest_integer_power_of_2(x + 1))
bit_width(0) = log2(round_up_to_nearest_integer_power_of_2(0 + 1))
             = log2(1)
             = 0
0
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To elaborate what was said in the comments:

Assume "bit width" means "least number of bits required to store the (nonnegative integer) number". Intuitively we need at least log2(n) bits rounding up, so it is a formula close to ceil(log2(n)), so 255 would require ceil(log2(255)) = ceil(7.99..) = 8 bits, but this doesn't work for powers of 2, so we can add a fudge factor of 1 to n to get ceil(log2(n+1)). This happens to be mathematically equivalent to 1+floor(log2(n)) for positive n, but log2(0) is not defined or defined as something unuseful like negative infinitiy in the floor version.

If we use the ceiling formula for 0, we get the result. You can also see I didn't write out leading zeros, and as Nicol Bolas points out, 0 is all leading zeros.

n bin(n) bit_width(n)
8 1000 4
7 111 3
6 110 3
5 101 3
4 100 3
3 11 2
2 10 2
1 1 1
0 0

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