I was thinking about this today and stumbled upon this question, my thoughts led me to this result. TLDR, while I find it "elegant" in that it only uses a few lines of code (could easily be a one liner), and has some mild math that simplifies to something relatively simple conceptually, this is mostly "interesting" and I haven't tested it.
If you think of an unsigned integer as being a single digit with radix 2^n where n is the number of bits in the integer, then you can map those numbers to radians around the unit circle, e.g.
radians(x) = x * (2 * pi * rad / 2^n)
When the integer overflows, it is equivalent to wrapping around the circle. So calculating the carry is equivalent to calculating the number of times multiplication would wrap around the circle. To calculate the number of times we wrap around the circle we divide radians(x) by 2pi radians. e.g.
wrap(x) = radians(x) / (2*pi*rad)
= (x * (2*pi*rad / 2^n)) / (2*pi*rad / 1)
= (x * (2*pi*rad / 2^n)) * (1 / 2*pi*rad)
= x * 1 / 2^n
= x / 2^n
Which simplifies to
wrap(x) = x / 2^n
This makes sense. The number of times a number, for example, 15 with radix 10, wraps around is
15 / 10 = 1.5, or one and a half times. However, we can't use 2 digits here (assuming we are limited to a single 2^64 digit).
Say we have a * b, with radix R, we can calculate the carry with
Consider that: wrap(a * b) = a * wrap(b)
wrap(a * b) = (a * b) / R
a * wrap(b) = a * (b / R)
a * (b / R) = (a * b) / R
carry = floor(a * wrap(b))
Take for example
a = 9 and
b = 5, which are factors of 45 (i.e.
9 * 5 = 45).
wrap(5) = 5 / 10 = 0.5
a * wrap(5) = 9 * 0.5 = 4.5
carry = floor(9 * wrap(5)) = floor(4.5) = 4
Note that if the carry was 0, then we would not have had overflow, for example if
a = 2,
In C/C++ (if the compiler and architecture supports it) we have to use long double.
Thus we have:
long double wrap = b / 18446744073709551616.0L; // this is b / 2^64
unsigned long carry = (unsigned long)(a * wrap); // floor(a * wrap(b))
bool overflow = carry > 0;
unsigned long c = a * b;
c here is the lower significant "digit", i.e. in base 10
9 * 9 = 81,
carry = 8, and
c = 1.
This was interesting to me in theory, so I thought I'd share it, but one major caveat is with the floating point precision in computers. Using long double, there may be rounding errors for some numbers when we calculate the
wrap variable depending on how many significant digits your compiler/arch uses for long doubles, I believe it should be 20 more more to be sure. Another issue with this result, is that it may not perform as well as some of the other solutions simply by using floating points and division.