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Suppose you have two numbers, both signed integers, and you want to sum them but can't use your language's conventional + and - operators. How would you do that?

Based on

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That's just a challenge, chill down. – maxxtack Mar 11 '11 at 23:47
It sounds more like homework. Please use the [homework] tag. – S.Lott Mar 11 '11 at 23:48
It souns like i've alerady done it in a crazy way and now i want to see your solutions – maxxtack Mar 11 '11 at 23:50
@S.Lott maybe, but typically, homework assignements don't get the [esoteric] tag... :-) – corsiKa Mar 11 '11 at 23:50
Why didn't you ask Google? It's full of solutions to this problem. – hoha Mar 11 '11 at 23:51

11 Answers 11

Since ++ and -- are not + and - operators:

int add(int lhs, int rhs) {
    if (lhs < 0)
        while (lhs++) --rhs;
        while (lhs--) ++rhs;
    return rhs;
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Wouldn't -- and ++ count as using the built in addition and subtraction? – Nathan Ostgard Mar 11 '11 at 23:52
Let's hear it for the letter of the rules, rather than the spirit! – Will Hartung Mar 11 '11 at 23:52

Using Bitwise operations just like Adder Circuits

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Using bitwise logic:

int sum = 0;
int carry = 0;

while (n1 > 0 || n2 > 0) {
  int b1 = n1 % 2;
  int b2 = n2 % 2;

  int sumBits = b1 ^ b2 ^ carry;
  sum = (sum << 1) | sumBits;
  carry = (b1 & b2) | (b1 & carry) | (b2 & carry);
  n1 /= 2;
  n2 /= 2;
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I think this results in sum being bit-reversed. – tc. Mar 12 '11 at 4:25

If we're obeying the letter of the rules:

a += b;

Otherwise has a pretty complete list.

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This version has a restriction on the number range:

(((int64_t)a << 32) | ((int64_t)b & INT64_C(0xFFFFFFFF)) % 0xFFFFFFFF

This also counts under the "letter of the rules" category.

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Not mine, but cute

int a = 42;
int b = 17;
char *ptr = (char*)a;
int result = (int)&ptr[b];
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In Common Lisp:

(defun esoteric-sum (a b)
  (let ((and (logand a b)))
    (if (zerop and)
        ;; No carrying necessary.
        (logior a b)
        ;; Combine the partial sum with the carried bits again.
        (esoteric-sum (logxor a b) (ash and 1)))))

That's taking the bitwise-and of the numbers, which figures out which bits need to carry, and, if there are no bits that require shifting, returns the bitwise-or of the operands. Otherwise, it shifts the carried bits one to the left and combines them again with the bitwise-exclusive-or of the numbers, which sums all the bits that don't need to carry, until no more carrying is necessary.

Here's an iterative alternative to the recursive form above:

(defun esoteric-sum-iterative (a b)
  (loop for first = a then (logxor first second)
        for second = b then (ash and 1)
        for and = (logand first second)
        until (zerop and)
        finally (return (logior first second))))

Note that the function needs another concession to overcome Common Lisp's reluctance to employ fixed-width two's complement arithmetic—normally an immeasurable asset—but I'd rather not cloud the form of the function with that accidental complexity.

If you need more detail on why that works, please ask a more detailed question to probe the topic.

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Simple example in Python, complete with a simple test:


def adder(a, b, carry):
    sum = a ^ b ^ carry
    carry = (a & b) | (carry & (a ^ b))
    #print "%d + %d = %d (carry %d)" % (a, b, sum, carry)
    return sum, carry

def add_two_numbers(a, b):
    carry = 0
    result = 0
    for n in range(NUM_BITS):
        mask = 1 << n
        bit_a = (a & mask) >> n
        bit_b = (b & mask) >> n
        sum, carry = adder(bit_a, bit_b, carry)
        result = result | (sum << n)
    return result

if __name__ == '__main__':
    assert add_two_numbers(2, 3) == 5
    assert add_two_numbers(57, 23) == 80

    for a in range(10):
        for b in range(10):
            result = add_two_numbers(a, b)
            print "%d + %d == %d" % (a, b, result)
            assert result == a + b
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Here's something different than what's been posted already. Use the facts that:

log (a^b) = b * log a
e^a * e^b = e^(a + b)


log (e^(a + b)) = log(e^a * e^b) = a + b (if the log is base e)

So just find log(e^a * e^b).

Of course this is just theoretical, in practice this is going to be inefficient and most likely inexact too.

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Not very creative, I know, but in Python:


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Cringe. Nobody builds an adder from 1-bit adders anymore.

do {
  sum = a ^ b;
  carry = a & b;
  a = sum;
  b = carry << 1;
} while (b);
return sum;

Of course, arithmetic here is assumed to be unsigned modulo 2n or twos-complement. It's only guaranteed to work in C if you convert to unsigned, perform the calculation unsigned, and then convert back to signed.

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