Generating unique codes that are different in two digits

I want to generate unique code numbers (composed of 7 digits exactly). The code number is generated randomly and saved in MySQL table.

I have another requirement. All generated codes should differ in at least two digits. This is useful to prevent errors while typing the user code. Hopefully, it will prevent referring to another user code while doing some operations as it is more unlikely to miss two digits and match another existing user code.

The generate algorithm works simply like:

1. Retrieve all previous codes if any from MySQL table.
2. Generate one code at a time.
3. Subtract the generated code with all previous codes.
4. Check the number of non-zero digits in the subtraction result.
5. If it is > 1, accept the generated code and add it to previous codes.
6. Otherwise, jump to 2.
7. Repeat steps from 2 to 6 for the number of requested codes.
8. Save the generated codes in the DB table.

The algorithm works fine, but the problem is related to performance. It takes a very long to finish generating the codes when requesting to generate a large number of codes like: 10,000.

The question: Is there any way to improve the performance of this algorithm?

I am using perl + MySQL on Ubuntu server if that matters.

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5 Answers

Have you considered a variant of the Luhn algorithm? Luhn is used to generate a check digit for strings of numbers in lots of applications, including credit card account numbers. It's part of the ISO-7812-1 standard for generating identifiers. It will catch any number that is entered with one incorrect digit, which implies any two valid numbers differ in a least two digits.

Check out Algorithm::LUHN in CPAN for a perl implementation.

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Check digit is an excellent idea for this application. –  Bill Ruppert Mar 21 '11 at 17:05
This is a really good idea. It also ensures that no two codes can vary by only one digit, because changing any digit will also change the checksum. –  Nick Johnson Mar 22 '11 at 2:24
Correction - changing the digit will probably change the checksum. You could definitely create two codes that only differ by one character if you tried. –  Nick Johnson Mar 22 '11 at 2:35
Single digit errors (one wrong digit with no transpositions) will always be caught. Every digit contributes unique a value between 0 and 9 inclusive to the checksum (0,1,2,3,4,5,6,7,8,9 or 0,2,4,6,8,1,3,5,7,9 depending if in an even or odd position). If the digit changes, the total checksum will change by some non-zero value equal or less than nine, which guarantees the total checksum mod 10 will also change. –  ataylor Mar 22 '11 at 3:23
Two numbers could share all but one digit with if some of the digits are transposed, though. –  ataylor Mar 22 '11 at 3:40
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Use a hash.

After generating a successful code (not conflicting with any existing code), but that code in the hash table, and also put the 63 other codes that differ by exactly one digit into the hash.

To see if a randomly generated code will conflict with an existing code, just check if that code exists in the hash.

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Don't retrieve the existing codes, just generate a potential new code and see if there are any conflicting ones in the database:

``````SELECT code FROM table WHERE abs(code-?) regexp '^[1-9]?0*\$';
``````

(where the placeholder is the newly generated code).

Ah, I missed the generating lots of codes at once part. Do it like this (completely untested):

``````my @codes = existing_codes();

my \$frontwards_index = {};
my \$backwards_index = {};
for my \$code (@codes) {
index_code(\$code, \$frontwards_index);
index_code(reverse(\$code), \$backwards_index);
}

my @new_codes = map generate_code(\$frontwards_index, \$backwards_index), 1..10000;

sub index_code {
my (\$code, \$index) = @_;
push @{ \$index{ substr(\$code, 0, length(\$code)/2) } }, \$code;
return;
}

sub check_index {
my (\$code, \$index) = @_;
my \$found = grep { (\$_ ^ \$code) =~ y/\0//c <= 1 } @{ \$index{ substr(\$code, 0, length(\$code)/2 } };
return \$found;
}

sub generate_code {
my (\$frontwards_index, \$backwards_index) = @_;

my \$new_code;
do {
\$new_code = sprintf("%07d", rand(10000000));
} while check_index(\$new_code, \$frontwards_index)
|| check_index(reverse(\$new_code), \$backwards_index);
index_code(\$new_code, \$frontwards_index);
index_code(reverse(\$new_code), \$backwards_index);
return \$new_code;
}
``````
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Regex searches can't be indexed, so this is only marginally better than the existing solution. –  Nick Johnson Mar 22 '11 at 2:25
@Nick Johnson: there's a big difference between making the server read through all the existing data and making the server return all the existing data. But my SQL solution isn't actually helpful since many new codes are needed. –  ysth Mar 22 '11 at 2:32
There's a constant-factor difference. Which means it's still not going to scale well. –  Nick Johnson Mar 22 '11 at 2:35
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Howabout:

Generate a 6 digit code by autoincrementing the previous one. Generate a 1 digit code by incrementing the previous one mod 10. Concatenate the two.

Presto, guaranteed to differ in two digits. :D

(Yes, being slightly facetious. I'm assuming that 'random' or at least quasi-random is necessary. In which case, generate a 6 digit random key, repeat until its not a duplicate (i.e. make the column unique, repeat until the insert doesn't fail the constraint), then generate a check digit, as someone already said.)

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Put the numbers 0 through 9,999,999 in an augmented binary search tree. The augmentation is to keep track of the number of sub-nodes to the left and to the right. So for example when your algorithm begins, the top node should have value 5,000,000, and it should know that it has 5,000,000 nodes to the left, and 4,999,999 nodes to the right. Now create a hashtable. For each value you've used already, remove its node from the augmented binary search tree and add the value to the hashtable. Make sure to maintain the augmentation.

To get a single value, follow these steps.

1. Use the top node to determine how many nodes are left in the tree. Let's say you have n nodes left. Pick a random number between 0 and n. Using the augmentation, you can find the nth node in your tree in log(n) time.
2. Once you've found that node, compute all the values that would make the value at that node invalid. Let's say your node has value 1,111,111. If you already have 2,111,111 or 3,111,111 or... then you can't use 1,111,111. Since there are 8 other options per digit and 7 digits, you only need to check 56 possible values. Check to see if any of those values are in your hashtable. If you haven't used any of those values yet, you can use your random node. If you have used any of them, then you can't.
3. Remove your node from the augmented tree. Make sure that you maintain the augmented information.
4. If you can't use that value, return to step 1.
5. If you can use that value, you have a new random code. Add it to the hashtable.

Now, checking to see if a value is available takes O(1) time instead of O(n) time. Also, finding another available random value to check takes O(log n) time instead of... ah... I'm not sure how to analyze your algorithm.

Long story short, if you start from scratch and use this algorithm, you will generate a complete list of valid codes in O(n log n). Since n is 10,000,000, it will take a few seconds or something.

Did I do the math right there everybody? Let me know if that doesn't check out or if I need to clarify anything.

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