# MIPS division of signed integers

I'm wondering if anyone might know how to perform a division between two signed integers in MIPS, WITHOUT using the built in division operations.

In the problem specs, I'm told the divisor register, ALU, and quotient register are all 32 bits wide, and the remainder register is 64 bits.

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Think of how you'd perform a binary division by hand:

``````# a/b, where a=2011 and b=18

1101111 ←quotient
┌────────────         ↓
10010 │ 11111011011  a
-10010↓↓↓↓↓↓  -64b × 1
───────↓↓↓↓↓
11010↓↓↓↓↓
-10010↓↓↓↓↓  -32b × 1
───────↓↓↓↓
10001↓↓↓↓
-00000↓↓↓↓  -16b × 0
───────↓↓↓
100011↓↓↓
-10010↓↓↓   -8b × 1
───────↓↓
100010↓↓
-10010↓↓   -4b × 1
───────↓
100001↓
-10010↓   -2b × 1
───────
11111
-10010   -1b × 1
──────
1101  remainder
``````

This “grade school” long division algorithm can be written (in Python — I'll let you convert it to MIPS) as:

``````def unsigned_divide(dividend, divisor):
if divisor == 0:
raise ZeroDivisionError()
if dividend < divisor:
return 0
# Determine the position of the first digit of the quotient
shift_amt = dividend.bit_length() - divisor.bit_length()
# Loop to find each bit of the quotient
quotient = 0
while shift_amt >= 0:
# Calculate one bit of the quotient
if dividend >= (divisor << shift_amt):
# new bit is 1
dividend -= (divisor << shift_amt)
quotient |= (1 << shift_amt)
# Move to the next digit
shift_amt -= 1
return quotient
``````

For signed division, you can just divide the absolute values while keeping track of the sign (assuming you want C-style truncating division):

``````def signed_divide(dividend, divisor):
is_negative = (dividend < 0) ^ (divisor < 0)
abs_quotient = unsigned_divide(abs(dividend), abs(divisor))
return -abs_quotient if is_negative else abs_quotient
``````
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