# multiplication chains that result in a constant modulo a power of 2

Is there a practical algorithm that gives "multiplication chains"

To clarify, the goal is to produce a multiplication change of an arbitrary and exact length
Multiplication chains of length 1 are trivial.

A "multiplication chain" would be defined as 2 numbers, {start} and {multiplier}, used in code:

`````` Given a pointer to array of size [{count}]   // count is a parameter
a = start;
do
{
a = a * multiplier;  // Really: a = (a * multiplier) MOD (power of 2
*(pointer++) = a;
}
while (a != {constant} )
// Postcondition:  all {count} entries are filled.
``````

I'd like to find a routine that takes three parameters
1. Power of 2
2. Stopping {constant}
3. {count} - Number of times the loop will iterate

The routine would return {start} and {multiplier}.

Ideally, a {Constant} value of 0 should be valid.

Trivial example:

``````power of 2 = 256
stopping constant = 7
number of times for the loop = 1
returns {7,1}
``````

Nontrivial example:

``````power of 2 = 256
stopping constant = 1
number of times for the loop = 49
returns {25, 19}
``````

The maximum {count} for a given power of 2 can be fairly small.
For example, 2^4 (16) seems to be limited to a count of 4

-
I don't see what the Power of 2 has to do with this... why is it commented out and what does that comment mean? –  Jeremy Ruten Nov 1 '08 at 4:29
The number of steps isn't clear, either. Presumably, that is some sort of upper bound on the number of multiplication loops permitted. –  Jonathan Leffler Nov 1 '08 at 4:33
{a} is a standard integer type, eg. 8, 16, 32 or 64 bits, so multiplication is implicitly reduced to the size of the output type. –  Procedural Throwback Nov 1 '08 at 4:33
@Jeremy: I think the purpose of the power of 2 is shown by the comment. –  Jonathan Leffler Nov 1 '08 at 4:34
So why not return multiplier=1 and start=constant? This problem specification seems both unclear and unmotivated. –  Darius Bacon Nov 1 '08 at 4:37

Here is a method for computing the values for start and multiplier for the case when constant is odd:

1. Find such odd m (m = multiplier) that order of m modulo 2^D is at least count, meaning that smallest n such that m^n = 1 (mod 2^D) is at least count. I don't know any other way to find such m than to make a random guess, but from a little experimenting it seems that half of odd numbers between 1 and 2^D have order 2^(D-2) which is maximal. (I tried for D at most 12.)

2. Compute x such that x * m^count = 1 (mod 2^D) and set start = x * constant (mod 2^D).

Such x can be found with "extended euclidean algorithm": Given a and b with no common divisor, it gives you x and y such that a * x + b * y = 1. Here a=m^count mod 2^D and b = 2^D.

edit: If constant happens to be even, you can divide it with a power of 2, say 2^k, to make in odd, then do the above for input {constant/2^k, count, 2^(D-k)} and finally return {start*2^k,multiplier}.

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Really nice - I had seen the cycles of 2^(D-2), but didn't take things further. For even 'c', there are cycles of up to 2^(D-3), shouldn't something similar work? –  Procedural Throwback Nov 1 '08 at 20:01
Now that should do it for cases where c isn't zero. –  mattiast Nov 1 '08 at 20:19
That makes sense, and that explains why the cycle lengths for some even #'s were so much shorter, since I need to hunt in the 2^(D-k) range. –  Procedural Throwback Nov 1 '08 at 20:24
With odd multipliers (relatively prime to 2^D), odd starting points give the maximum cycle length, even starting points are shorter but still never hit 0. So that leaves the even multipliers to get to 0, with only the length remaining? –  Procedural Throwback Nov 1 '08 at 20:29
I see, for even dividers, the power of 2 determines the count, not quite sure how to get the intermediate value yet. What's with those "other" odd multipliers that don't form a cycle - Shouldn't any relatively prime pair form a cycle? –  Procedural Throwback Nov 1 '08 at 20:43

You are asking for nontrivial solutions to the following modular equation:

``s * m^N = C (mod 2^D)``

where

• s is the starting constant
• m is the multiplier
• N is the number of iterations (given by the problem)
• C is the final constant (given by the problem)
• D is the exponent of the power of 2 (given by the problem)

Have a look at Euler's theorem in number theory.

For an arbitrary odd m (which is prime with 2^D), you have

``m^phi(2^D) = 1 (mod 2^D)``

thus

``C * m^phi(2^D) = C (mod 2^D)``

and finally

``C * m^(phi(2^D)-N) * m^N = C (mod 2^D)``

Take

``s = C * m^(phi(2^D)-N)``

and you're done. The Euler's phi function of a power of 2 is half that power of 2, i.e.:

``phi(2^D) = 2^(D-1)``

Example. Let

• N = 5
• C = 3
• 2^D = 16
• phi(16) = 8

Choose arbitrarily m = 7 (odd), and compute

``````3 * 7^(8-5) = 1029
s = 1029 mod 16 = 5
``````

Now

``````s * m^N = 5 * 7^5 = 84035
84035 mod 16 = 3 == C
``````
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With an odd m, I can't reach 0 - which makes sense now that I see the equation. With even 'm', it will reach 0 eventually. Is there a different form of an equation to get a constant of 0. –  Procedural Throwback Nov 1 '08 at 5:48
if C is 0 then you can choose s = C*... = 0 (this is again a trivial solution...) –  Federico A. Ramponi Nov 1 '08 at 5:53
How so? C = 0, N=13, 2^D = 256 Start = 0 wouldn't satisfy N=13 –  Procedural Throwback Nov 1 '08 at 6:05
Note that my answer provides s, m such that after exactly N iterations you reach C. But you could reach C also in less than N iterations, i.e. you could loop several times between a sequence of numbers x, y, z, C, x, y, z, C... –  Federico A. Ramponi Nov 1 '08 at 6:05
Can this be changed to give the first "C" (since that would be the terminating condition of the while loop) ? –  Procedural Throwback Nov 1 '08 at 6:07

Why wouldn't this satisfy the requirements?

``````start = constant;
multiplier = 1;
``````

Update: I see now that the number of loops is one of the input parameters. It sounds like this problem is a special case of, or at least related to, the discrete logarithm problem.

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Errr...yes. So probably the 'start' should be a fourth parameter to the routine (assuming the purpose of the number of steps is clarified). –  Jonathan Leffler Nov 1 '08 at 4:40
Yes, this is the trivial case, where number of loops is 1. Number of loops is a parameter to the calculation algorithm. –  Procedural Throwback Nov 1 '08 at 4:46