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Lets say I have guessed a lottery number of:

1689

And the way the lottery works is, the order of the digits don't matter as long as the digits match up 1:1 with the digits in the actual winning lottery number.

So, the number 1689 would be a winning lottery number with:

1896, 1698, 9816, etc..

As long as each digit in your guess was present in the target number, then you win the lottery.

Is there a mathematical way I can do this?

I've solved this problem with a O(N^2) looping checking each digit against each digit of the winning lottery number (separating them with modulus). Which is fine, it works but I want to know if there are any neat math tricks I can do.

For example, at first... I thought I could be tricky and just take the sum and product of each digit in both numbers and if they matched then you won.

^ Do you think that would work?

However, I quickly disproved this when I found that lottery guess: 222, and 124 have the different digits but the same product and sum.

Anyone know any math tricks I can use to quickly determine if the digits in num1 match the digits in num2 regardless of order?

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2+2+2 = 6, 1+2+4 = 7, so they don't have the same sum. I think this sum/product method may actually work as long as the number of digits in each number is equal. –  MahlerFive Feb 19 '09 at 21:15
    
Well, the product trick will be defeated by zeros; 0123 and 0222 have the same product and sub. –  Daniel LeCheminant Feb 19 '09 at 21:18
    
Also, if both numbers are the same except for 3 digits, one containing 449 and the 368, they'll both have the same product and sum (since those numbers both have the same product and sum, and both + and * are commutative) –  Daniel LeCheminant Feb 19 '09 at 21:50
    
For such short numbers, you have to seriously consider the constant that Big-O notation ignores. 4*NN is faster than 100*NlogN for any N that makes a reasonable length lottery ticket. –  Sparr Feb 26 '09 at 20:35

14 Answers 14

up vote 16 down vote accepted

How about going through each number, and counting up the number of appearances of each digit (into two different 10 element arrays)? After you'd done the totaling, compare the counts of each digit. Since you only look at each digit once, that's O(N).

Code would look something like:

for(int i=0; i<digit_count; i++)
{
   guessCounts[guessDigits[i] - '0']++;
   actualCounts[actualDigits[i] - '0']++;
}

bool winner = true;
for(int i=0; i<10 && winner; i++)
{
   winner &= guessCounts[i] == actualCounts[i];
}

Above code makes the assumption that guessDigits and actualDigits are both char strings; if they held the actual digits then you can just skip the - '0' business.

There are probably optimizations that would make this take less space or terminate sooner, but it's a pretty straightforward example of an O(N) approach.

By the way, as I mentioned in a comment, the multiplication/sum comparison will definitely not work because of zeros. Consider 0123 and 0222. Product is 0, sum is 6 in both cases.

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Nice! This is fastest so far, hadn't thought of that. –  KingNestor Feb 19 '09 at 21:19
    
Bucket sort FTW! –  Brian Postow Feb 19 '09 at 21:31
    
Hey, you don't have to use two digit arrays. Just use ++ for the guesscount, and -- for the actual count. Then you just have to compare with 0 at the end. –  DevinB Feb 19 '09 at 21:41
    
@devinb - Yeah, I made a comment to that effect on Renze's solution, which does what you suggest. That would be "an optimization that takes less space" :) –  Daniel LeCheminant Feb 19 '09 at 21:48

Split into array, sort array, join into string, compare strings.

(Not a math trick, I know)

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Still, good answer. I hadn't thought of this. –  KingNestor Feb 19 '09 at 21:10

You can place the digits into an array, sort the array, then compare the arrays element by element. This will give you O( NlogN ) complexity which is better than O( N^2 ).

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Very true. Faster than my O(N^2). Thanks! –  KingNestor Feb 19 '09 at 21:21

If N can become large, sorting the digits is the answer.

Because digits are 0..9 you can count the number of occurrences of each digit of the lottery answer in an array [0..9].

To compare you can subtract 1 for each digit you encounter in the guess. When you encounter a digit where the count is already 0, you know the guess is different. When you get through all the digits, the guess is the same (as long as the guess has as many digits as the lottery answer).

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@KingNestor - Renze's solution gets rid of the need for a second array, which is nice, and it would terminate sooner. +1! –  Daniel LeCheminant Feb 19 '09 at 21:28

For each digit d multiply with the (d+1)-th prime number.

This is more mathematical but less efficient than the sorting or bucket methods. Actually it is the bucket method in disguise.

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I wonder... for really long numbers, what would you store the product in? :] –  Daniel LeCheminant Feb 19 '09 at 21:42
    
@Daniel L: java.math.BigInteger :-) –  starblue Feb 19 '09 at 21:52

I'd sort both number's digits and compare them.

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If you are only dealing with 4 digits I dont think you have to put much thought into which algorithm you use. They will all perform roughly the same.

Also 222 and 124 dont have the same sum

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You're right that 222 and 124 don't - but 023 and 014 have the same product and sum... –  Tomas Lycken Feb 19 '09 at 21:15
    
Nice catch. I wonder, do you think the SUM and Product comparison would work alright? –  KingNestor Feb 19 '09 at 21:15

You have to consider that when n is small, the order of efficiency is irrelevant, and the constants start to matter more. How big can your numbers actually get? Can you get up to 10 digits? 20? 100? If your numbers have just a few digits, n^2 really isn't that bad. If you have strings of thousands of digits, then you might actually need to do something more clever like sorting or bucketing. (i.e. count the 0s, count the 1s, etc.)

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I'm not doing this to be super efficient. I'm doing it to see if there are clever ways to go about it other than the obvious. –  KingNestor Feb 19 '09 at 21:14

I'm stealing the answer from Yuliy, and starblue (upvote them)

Bucketing is the fastest aside from the O(1)

lottonumbers == mynumbers;

Sorting is O(nlog2n)

Bucketsort is an O(n) algorithm.

So all you need to do is do it twice (once for your numbers, once for the target-set), and if the numbers of the digits add up, then they match. Any kind of sorting is an added overhead that is unnecessary in this case.

array[10] digits;
while(targetnum > 0)
{
    short currDig = targetnum % 10;
    digits[currDig]++;
    targetnum = targetnum / 10;
}
while(mynum > 0)
{
    short myDig = mynum % 10;
    digits[myDig]--;
    mynum = mynum / 10;
}
for(int i = 0; i < 10; i++)
{
   if(digits[i] == 0)
      continue;
   else
     //FAIL TO MATCH
}

Not the prettiest code, I'll admit.

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So far, Renze de Waal's answer is the fastest. It involves a single 10 element array, and a single pass. I don't think this beats it? –  KingNestor Feb 19 '09 at 21:38
    
Actually, our answers are the same. They've both only got one array, and you NEED two passes (to go through each number.) Daniel L's solution is more elegant but just as correct. –  DevinB Feb 20 '09 at 13:29
    
Sorry, that was unclear. Daniel L's, Renze de Waal's and my answer are algorithmically the same. Daniel L is just a better coder than I. –  DevinB Feb 20 '09 at 13:55

Create an array of 10 integers subscripted [0 .. 9].

Initialize each element to a different prime number

Set product to 1.

Use each digit from the number, to subscript into the array, pull out the prime number, and multiply the product by it.

That gives you a unique representation which is digit order independent.

Do the same procedure for the other number.

If the unique representations match, then the original numbers match.

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If there are no repeating digits allowed (not sure if this is the case though) then use a 10-bit binary number. The most significant bit represents the digit 9 and the LSB represents the digit 0. Work through each number in turn and flip the appropriate bit for each digit that you find

So 1689 would be: 1101000010

and 9816 would also be: 1101000010

then a XOR or a subtract will leave 0 if you are a winner

This is just a simple form of bucketing

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Just for fun, and thinking outside of the normal, instead of sorting and other ways, do the deletion-thing. If resultstring is empty, you have a winner!

    Dim ticket As String = "1324"
    Dim WinningNumber As String = "4321"

    For Each s As String In WinningNumber.ToCharArray
        ticket = Replace(ticket, s, "", 1, 1)
    Next

    If ticket = "" Then MsgBox("WINNER!")
    If ticket.Length=1 then msgbox "Close but no cigar!"

This works with repeating numbers too..

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Humm. what happens if your winning number is 3344? –  EvilTeach Feb 20 '09 at 14:07
    
If the ticket is "3434", "3443", "4433", "4343" or "4334" its a win. In my example above when thicketnumber is "1324" you will have a rest of "12" wich mean all numbers didnt match and its a no win. –  Stefan Feb 20 '09 at 18:19
    
I see what you mean now. So I Added ,1,1 to the replace function so its only replacing one occurance of the number every iteration. –  Stefan Feb 21 '09 at 7:55

Sort digits before storing a number. After that, your numbers will be equal.

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Only if its a winning number. ;) –  Stefan Feb 19 '09 at 21:11

One cute solution is to use a variant of Zobrist hashing. (Yes, I know it's overkill, as well as probabilistic, but hey, it's "clever".)

Initialize a ten-element array a[0..9] to random integers. Then, for each number d[], compute the sum of a[d[i]]. If the numbers contained the same digits, the resulting numbers will be equal; with high probability (~ 1 in how many possible ints there are), the opposite is true as well.

(If you know that there will be at most 10 digits total, then you can use the fixed numbers 1, 10, 100, ... instead of random numbers for guaranteed success. This is bucket sorting in not-too-much disguise.)

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It doesn't make any sense –  Román Aug 12 '10 at 9:27

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