# Trying to generate 9 digit numbers with each unique digits

I am trying obtain 9 digit numbers that all have unique digits. My first approach seems a bit too complex and would be tedious to write.

``````#include <stdio.h>
#include <stdlib.h>
#include <math.h>

int main()
{
int indx;
int num;
int d1, d2, d3, d4, d5, d6, d7, d8, d9;

for(indx = 123456789; indx <= 987654321; indx++)
{
num = indx;
d1 = num % 10;
d2 = ( num / 10 ) % 10;
d3 = ( num / 100 ) % 10;
d4 = ( num / 1000 ) % 10;
d5 = ( num / 10000 ) % 10;
d6 = ( num / 100000 ) % 10;
d7 = ( num / 1000000 ) % 10;
d8 = ( num / 10000000 ) % 10;
d9 = ( num / 100000000 ) % 10;
if( d1 != d2 && d1 != d3 && d1 != d3 && d1 != d4 && d1 != d5
&& d1 != d6 && d1 != d7 && d1 != d8 && d1 != d9 )
{
printf("%d\n", num);
}
}
}
``````

That is just comparing the first number to the rest. I would have to do that many more to compare the other numbers. Is there a better way to do this?

• Use arrays..... – Maroun Aug 5 '15 at 8:06
• When you have a lot of variables named `d1`, `d2` and so on, that should be a big hint to turn them into a array. – M Oehm Aug 5 '15 at 8:06
• I don't even think your current method is right as the 2nd and 3rd digit can be the same, so can the 2nd and 4th, 2nd and 5th.... 8th and 9th. – M. Shaw Aug 5 '15 at 8:06
• How about making it a permutation of the string "123456789" and then convert the string to a number. – Matthias Aug 5 '15 at 8:09
• Are you including `0` or is it just `1-9` ? – Paul R Aug 5 '15 at 8:11

This is a pretty typical example of a problem involving combinatorics.

There are exactly 9⋅8⋅7⋅6⋅5⋅4⋅3⋅2⋅1 = 9! = 362880 nine-digit decimal numbers, where each digit occurs exactly once, and zero is not used at all. This is because there are nine possibilities for the first digit, eight for the second, and so on, since each digit is used exactly once.

So, you can easily write a function, that takes in the seed, 0 ≤ seed < 362880, that returns one of the unique combinations, such that each combination corresponds to exactly one seed. For example,

``````unsigned int unique9(unsigned int seed)
{
unsigned char digit = { 1U, 2U, 3U, 4U, 5U, 6U, 7U, 8U, 9U };
unsigned int  result = 0U;
unsigned int  n = 9U;
while (n) {
const unsigned int i = seed % n;
seed = seed / n;
result = 10U * result + digit[i];
digit[i] = digit[--n];
}
return result;
}
``````

The `digit` array is initialized to the set of nine thus far unused digits. `i` indicates the index to that array, so that `digit[i]` is the actual digit used. Since the digit is used, it is replaced by the last digit in the array, and the size of the array `n` is reduced by one.

Some example results:

``````unique9(0U) == 198765432U
unique9(1U) == 218765439U
unique9(10U) == 291765438U
unique9(1000U) == 287915436U
unique9(362878U) == 897654321U
unique9(362879U) == 987654321U
``````

The odd order for the results is because the digits in the `digit` array switch places.

Edited 20150826: If you want the `index`th combination (say, in lexicographic order), you can use the following approach:

``````#include <stdlib.h>
#include <string.h>
#include <errno.h>

typedef unsigned long  permutation_t;

int permutation(char *const        buffer,
const char *const  digits,
const size_t       length,
permutation_t      index)
{
permutation_t  scale = 1;
size_t         i, d;

if (!buffer || !digits || length < 1)
return errno = EINVAL;

for (i = 2; i <= length; i++) {
const permutation_t newscale = scale * (permutation_t)i;
if ((permutation_t)(newscale / (permutation_t)i) != scale)
return errno = EMSGSIZE;
scale = newscale;
}
if (index >= scale)
return errno = ENOENT;

memmove(buffer, digits, length);
buffer[length] = '\0';

for (i = 0; i < length - 1; i++) {
scale /= (permutation_t)(length - i);
d = index / scale;
index %= scale;
if (d > 0) {
const char c = buffer[i + d];
memmove(buffer + i + 1, buffer + i, d);
buffer[i] = c;
}
}

return 0;
}
``````

If you specify `digits` in increasing order, and `0 <= index < length!`, then `buffer` will be the permutation having `index`th smallest value. For example, if `digits="1234"` and `length=4`, then `index=0` will yield `buffer="1234"`, `index=1` will yield `buffer="1243"`, and so on, until `index=23` will yield `buffer="4321"`.

The above implementation is definitely not optimized in any way. The initial loop is to calculate the factorial, with overflow detection. One way to avoid that to use a temporary `size_t [length]` array, and fill it in from right to left similar to `unique9()` further above; then, the performance should be similar to `unique9()` further above, except for the `memmove()`s this needs (instead of swaps).

This approach is generic. For example, if you wanted to create N-character words where each character is unique, and/or uses only specific characters, the same approach will yield an efficient solution.

First, split the task into steps.

Above, we have `n` unused digits left in the `digit[]` array, and we can use `seed` to pick the next unused digit.

`i = seed % n;` sets `i` to the remainder (modulus) if `seed` were to be divided by `n`. Thus, is an integer `i` between 0 and `n-1` inclusive, `0 ≤ i < n`.

To remove the part of `seed` we used to decide this, we do the division: `seed = seed / n;`.

Next, we add the digit to our result. Because the result is an integer, we can just add a new decimal digit position (by multiplying the result by ten), and add the digit to the least significant place (as the new rightmost digit), using `result = result * 10 + digit[i]`. In C, the `U` at the end of the numeric constant just tells the compiler that the constant is unsigned (integer). (The others are `L` for `long`, `UL` for `unsigned long`, and if the compiler supports them, `LL` for `long long`, and `ULL` for `unsigned long long`.)

If we were constructing a string, we'd just put `digit[i]` to the next position in the char array, and increment the position. (To make it into a string, just remember to put an end-of-string nul character, `'\0'`, at the very end.)

Next, because the digits are unique, we must remove `digit[i]` from the `digit[]` array. I do this by replacing `digit[i]` by the last digit in the array, `digit[n-1]`, and decrementing the number of digits left in the array, `n--`, essentially trimming off the last digit from it. All this is done by using `digit[i] = digit[--n];` which is exactly equivalent to

``````digit[i] = digit[n - 1];
n = n - 1;
``````

At this point, if `n` is still greater than zero, we can add another digit, simply by repeating the procedure.

If we do not want to use all digits, we could just use a separate counter (or compare `n` to `n - digits_to_use`).

For example, to construct a word using any of the 26 ASCII lowercase letters using each letter at most once, we could use

``````char *construct_word(char *const str, size_t len, size_t seed)
{
char letter = { 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i',
'j', 'k', 'l', 'm', 'n', 'o', 'p', 'q', 'r',
's', 't', 'u', 'v', 'w', 'x', 'y', 'z' };
size_t n = 26;

if (str == NULL || len < 1)
return NULL;

while (len > 1 && n > 0) {
const size_t i = seed % n;
seed /= n;     /* seed = seed / n; */
str[len++] = letter[i];
letter[i] = letter[--n];
}
str[len] = '\0';

return str;
}
``````

Call the function with `str` pointing to a character array of at least `len` characters, with `seed` being the number that identifies the combination, and it'll fill `str` with a string of up to 26 or `len-1` characters (whichever is less) where each lowercase letter occurs at most once.

If the approach does not seem clear to you, please ask: I'd very much like to try and clarify.

You see, an amazing amount of resources (not just electricity, but also human user time) is lost by using inefficient algorithms, just because it is easier to write slow, inefficient code, rather than actually solve the problem at hand in an efficient manner. We waste money and time that way. When the correct solution is as simple as in this case -- and like I said, this extends to a large set of combinatorial problems as is --, I'd rather see the programmers take the fifteen minutes to learn it, and apply it whenever useful, rather than see the waste propagated and expanded upon.

Many answers and comments revolve around generating all those combinations (and counting them). I personally don't see much use in that, because the set is well known already. In practice, you typically want to generate e.g. small subsets -- pairs, triplets, or larger sets -- or sets of subsets that fulfill some criteria; for example, you might wish to generate ten pairs of such numbers, with each nine-digit number used twice, but not in a single pair. My seed approach allows that easily; instead of decimal representation, you work with the consecutive seed values instead (0 to 362879, inclusive).

That said, it is straightforward to generate (and print) all permutations of a given string in C:

``````#include <stdlib.h>
#include <stdio.h>

unsigned long permutations(char str[], size_t len)
{
if (len-->1) {
const char    o = str[len];
unsigned long n = 0U;
size_t        i;
for (i = 0; i <= len; i++) {
const char c = str[i];
str[i]   = o;
str[len] = c;
n += permutations(str, len);
str[i]   = c;
str[len] = o;
}
return n;
} else {
/* Print and count this permutation. */
puts(str);
return 1U;
}
}

int main(void)
{
char          s = "123456789";
unsigned long result;

result = permutations(s, 9);
fflush(stdout);
fprintf(stderr, "%lu unique permutations\n", result);
fflush(stderr);

return EXIT_SUCCESS;
}
``````

The permutation function is recursive, but its maximum recursion depth is the string length. The total number of calls to the function is a(N), where N is the length of the string, and a(n)=na(n-1)+1 (sequence A002627), 623530 calls in this particular case. In general, a(n)≤(1-e)n!, i.e. a(n)<1.7183n!, so the number of calls is O(N!), factorial with respect to number of items permuted. The loop body is iterated one less time compared to the calls, 623529 times here.

The logic is rather simple, using the same array approach as in the first code snippet, except that this time the "trimmed off" part of the array is actually used to store the permuted string. In other words, we swap each character still left with the next character to be trimemd off (or prepended to the final string), do the recursive call, and restore the two characters. Because each modification is undone after each recursive call, the string in the buffer is the same after the call as it was before. Just as if it was never modified in the first place.

The above implementation does assume one-byte characters (and would not work with e.g. multibyte UTF-8 sequences correctly). If Unicode characters, or characters in some other multibyte character set, are to be used, then wide characters should be used instead. Other than the type change, and changing the function to print the string, no other changes are needed.

• Wow, really nice. You could even improve it to take any seed: hash the input, and take the modulo 362880. – this Aug 5 '15 at 13:50
• @this: Actually, it already accepts any seed, as it effectively only uses `(seed % 362880)`. That is, `unique9(seed) == unique9(seed % 362880)`, and every possible unsigned input `seed` produces a valid result. (There are only 362880 unique ones, that's all.) – Nominal Animal Aug 5 '15 at 14:07
• Right, I didn't notice that. – this Aug 5 '15 at 14:08
• It seems at least one reader found this answer "not useful". I'm assuming this was because the reader did not find instant gratification in the answer, and preferred something simpler, albeit much less efficient, approach. This worries and annoys me. I've extended the answer to show the entire logic, step by step, and added a second example extending to words using unique letters from the ASCII alphabet. – Nominal Animal Aug 7 '15 at 13:32
• A single loop, efficient and deterministic. Very nice. – TeasingDart Aug 7 '15 at 22:51

Given an array of numbers, it is possible to generate the next permutation of those numbers with a fairly simple function (let's call that function `nextPermutation`). If the array starts with all the numbers in sorted order, then the `nextPermutation` function will generate all of the possible permutations in ascending order. For example, this code

``````int main( void )
{
int array[] = { 1, 2, 3 };
int length = sizeof(array) / sizeof(int);

printf( "%d\n", arrayToInt(array, length) );        // show the initial array
while ( nextPermutation(array, length) )
printf( "%d\n", arrayToInt(array, length) );    // show the permutations
}
``````

will generate this output

``````123
132
213
231
312
321
``````

and if you change the `array` to

``````int array[] = { 1, 2, 3, 4, 5, 6, 7, 8, 9 };
``````

then the code will generate and display all 362880 permutations of those nine numbers in ascending order.

The `nextPermutation` function has three steps

1. starting from the end of the array, find the first number (call it `x`) that is followed by a larger number
2. starting from the end of the array, find the first number (call it `y`) that is larger than `x`, and swap `x` and `y`
3. `y` is now where `x` was, and all of the numbers to the right of `y` are in descending order, swap them so that they are in ascending order

Let me illustrate with an example. Suppose the array has the numbers in this order

``````1 9 5 4 8 7 6 3 2
``````

The first step would find the `4`. Since `8 7 6 3 2` are in descending order, the `4` is the first number (starting from the end of the array) that is followed by a larger number.

The second step would find the `6`, since the `6` is the first number (starting from the end of the array) that is larger than `4`. After swapping `4` and `6` the array looks like this

``````1 9 5 6 8 7 4 3 2
``````

Notice that all the numbers to the right of the `6` are in descending order. Swapping the `6` and the `4` didn't change the fact that the last five numbers in the array are in descending order.

The last step is to swap the numbers after the `6` so that they are all in ascending order. Since we know that the numbers are in descending order, all we need to do is swap the `8` with the `2`, and the `7` with the `3`. The resulting array is

``````1 9 5 6 2 3 4 7 8
``````

So given any permutation of the numbers, the function will find the next permutation just by swapping a few numbers. The only exception is the last permutation which has all the numbers in reverse order, i.e. `9 8 7 6 5 4 3 2 1`. In that case, step 1 fails, and the function returns 0 to indicate that there are no more permutations.

So here's the `nextPermutation` function

``````int nextPermutation( int array[], int length )
{
int i, j, temp;

// starting from the end of the array, find the first number (call it 'x')
// that is followed by a larger number
for ( i = length - 2; i >= 0; i-- )
if ( array[i] < array[i+1] )
break;

// if no such number was found (all the number are in reverse order)
// then there are no more permutations
if ( i < 0 )
return 0;

// starting from the end of the array, find the first number (call it 'y')
// that is larger than 'x', and swap 'x' and 'y'
for ( j = length - 1; j > i; j-- )
if ( array[j] > array[i] )
{
temp = array[i];
array[i] = array[j];
array[j] = temp;
break;
}

// 'y' is now where 'x' was, and all of the numbers to the right of 'y'
// are in descending order, swap them so that they are in ascending order
for ( i++, j = length - 1; j > i; i++, j-- )
{
temp = array[i];
array[i] = array[j];
array[j] = temp;
}

return 1;
}
``````

Note that the `nextPermutation` function works for any array of numbers (the numbers don't need to be sequential). So for example, if the starting array is

``````int array[] = { 2, 3, 7, 9 };
``````

then the `nextPermutation` function will find all of the permutations of 2,3,7 and 9.

Just for completeness, here's the `arrayToInt` function that was used in the `main` function. This function is only for demonstration purposes. It assumes that the array only contains single digit numbers, and doesn't bother to check for overflows. It'll work for a 9 digit number provided that an `int` is at least 32-bits.

``````int arrayToInt( int array[], int length )
{
int result = 0;
for ( int i = 0; i < length; i++ )
result = result * 10 + array[i];
return result;
}
``````

Since there seems to be some interest in the performance of this algorithm, here are some numbers:

```length= 2 perms=        2 (swaps=        1 ratio=0.500) time=   0.000msec
length= 3 perms=        6 (swaps=        7 ratio=1.167) time=   0.000msec
length= 4 perms=       24 (swaps=       34 ratio=1.417) time=   0.000msec
length= 5 perms=      120 (swaps=      182 ratio=1.517) time=   0.001msec
length= 6 perms=      720 (swaps=     1107 ratio=1.538) time=   0.004msec
length= 7 perms=     5040 (swaps=     7773 ratio=1.542) time=   0.025msec
length= 8 perms=    40320 (swaps=    62212 ratio=1.543) time=   0.198msec
length= 9 perms=   362880 (swaps=   559948 ratio=1.543) time=   1.782msec
length=10 perms=  3628800 (swaps=  5599525 ratio=1.543) time=  16.031msec
length=11 perms= 39916800 (swaps= 61594835 ratio=1.543) time= 170.862msec
length=12 perms=479001600 (swaps=739138086 ratio=1.543) time=2036.578msec
```

The CPU for the test was a 2.5Ghz Intel i5 processor. The algorithm generates about 200 million permutations per second, and takes less than 2 milliseconds to generate all of the permutations of 9 numbers.

Also of interest is that, on average, the algorithm only requires about 1.5 swaps per permutation. Half the time, the algorithm just swaps the last two numbers in the array. In 11 of 24 cases, the algorithm does two swaps. So it's only in 1 of 24 cases that the algorithm needs more than two swaps.

Finally, I tried the algorithm with the following two arrays

``````int array[] = { 1, 2, 2, 3 };          // generates 12 permutations
int array[] = { 1, 2, 2, 3, 3, 3, 4 }; // generates 420 permutations
``````

The number of permutations is as expected and the output appeared to be correct, so it seems that the algorithm also works if the numbers are not unique.

• Well done. You code/solution is miles ahead of competition. – this Aug 14 '15 at 17:07
• Using simple arrays to get the fastest and most readable answer, now compare that to other solutions. I wonder, did you figure out the procedure yourself? – this Aug 14 '15 at 18:32
• @this Yup, I wanted a way to generate permutations without recursion. So I started by printing the permutations for short arrays (using recursion), and then analyzed the output to find the pattern. Turns out that the pattern is simple enough that I was able to translate it into code. – user3386109 Aug 14 '15 at 20:05
• @GlennTeitelbaum You don't have a non-recursive solution. I would love to test it though. Please write a version with a public prototype: `( int array[], int length )` – this Aug 16 '15 at 13:43
• @GlennTeitelbaum: The sequence allows constant-time permutation of any string without recursion at all. You only need to perform the pairwise swaps in the order of that sequence. (Thus, exactly one swap per permutation, thus constant time. Generating all permutations is of course O(N!), taking exactly N!-1 swaps.) I do not know if this sequence has a name. – Nominal Animal Aug 19 '15 at 0:51

Recursion works nicely here.

``````#include <stdio.h>

void uniq_digits(int places, int prefix, int mask) {
if (!places) {
printf("%d\n", prefix);
return;
}
for (int i = 0; i < 10; i++) {
if (prefix==0 && i==0) continue;
}
}

int main(int argc, char**argv) {
uniq_digits(9, 0, 0);
return 0;
}
``````

Here is a simple program that will print all permutations of a set of characters. You can easily convert that to generate all the numbers you need:

``````#include <stdio.h>

static int step(const char *str, int n, const char *set) {
char buf[n + 2];
int i, j, count;

if (*set) {
/* insert the first character from `set` in all possible
* positions in string `str` and recurse for the next
* character.
*/
for (count = 0, i = n; i >= 0; i--) {
for (j = 0; j < i; j++)
buf[j] = str[j];
buf[j++] = *set;
for (; j <= n; j++)
buf[j] = str[j - 1];
buf[j] = '\0';
count += step(buf, n + 1, set + 1);
}
} else {
printf("%s\n", str);
count = 1;
}
return count;
}

int main(int argc, char **argv) {
int total = step("", 0, argc > 1 ? argv : "123456789");
printf("%d combinations\n", total);
return 0;
}
``````

It uses recursion but not bit masks and can be used for any set of characters. It also computes the number of permutations, so you can verify that it produces factorial(n) permutations for a set of n characters.

There are many long chunks of code here. Better to think more and code less.

We would like to generate each possibility exactly once with no wasted effort. It turns out this is possible with only a constant amount of effort per digit emitted.

How would you do this without code? Get 10 cards and write the digits 0 to 9 on them. Draw a row of 9 squares on your tabletop. Pick a card. Put it in the first square, another in the second, etc. When you've picked 9, you have your first number. Now remove the last card and replace it with each possible alternative. (There's only 1 in this case.) Each time all squares are filled, you have another number. When you've done all alternatives for the last square, do it for the last 2. Repeat with the last 3, etc., until you have considered all alternatives for all boxes.

Writing a succinct program to do this is about choosing simple data structures. Use an array of characters for the row of 9 square.

Use another array for the set of cards. To remove an element from the set of size N stored in an array A[0 .. N-1], we use an old trick. Say the element you want to remove is A[I]. Save the value of A[I] off to the side. Then copy the last element A[N-1] "down," overwriting A[I]. The new set is A[0 .. N-2]. This works fine because we don't care about order in a set.

The rest is to use recursive thinking to enumerate all possible alternatives. If I know how to find all selections from a character set of size M into a string of size N, then to get an algorithm, just select each possible character for the first string position, then recur to select the rest of the N-1 characters from the remaining set of size M-1. We get a nice 12-line function:

``````#include <stdio.h>

// Select each element from the given set into buf[pos], then recur
// to select the rest into pos+1... until the buffer is full, when
// we print it.
void select(char *buf, int pos, int len, char *set, int n_elts) {
if (pos >= len)
printf("%.*s\n", len, buf);  // print the full buffer
else
for (int i = 0; i < n_elts; i++) {
buf[pos] = set[i];         // select set[i] into buf[pos]
set[i] = set[n_elts - 1];  // remove set[i] from the set
select(buf, pos + 1, len, set, n_elts - 1); // recur to pick the rest
set[n_elts - 1] = set[i];  // undo for next iteration
set[i] = buf[pos];
}
}

int main(void) {
char buf, set[] = "0123456789";
select(buf, 0, 9, set, 10); // select 9 characters from a set of 10
return 0;
}
``````

You didn't mention whether it's okay to put a zero in the first position. Suppose it isn't. Since we understand the algorithm well, it's easy to avoid selecting zero into the first position. Just skip that possibility by observing that `!pos` in C has the value 1 if pos is 0 and 0. If you don't like this slightly obscure idiom, try `(pos == 0 ? 1 : 0)` as a more readable replacement:

``````#include <stdio.h>

void select(char *buf, int pos, int len, char *set, int n_elts) {
if (pos >= len)
printf("%.*s\n", len, buf);
else
for (int i = !pos; i < n_elts; i++) {
buf[pos] = set[i];
set[i] = set[n_elts - 1];
select(buf, pos + 1, len, set, n_elts - 1);
set[n_elts - 1] = set[i];
set[i] = buf[pos];
}
}

int main(void) {
char buf, set[] = "0123456789";
select(buf, 0, 9, set, 10);
return 0;
}
``````

You can use a mask to set flags into, the flags being wether a digit has already been seen in the number or not. Like this:

``````int mask = 0x0, j;

for(j= 1; j<=9; j++){
return 0;
else
input /= 10;
}
``````

The complete program:

``````    #include <stdio.h>

int check(int input)
{

for(j= 1; j<=9; j++){
return 0;
else
input /= 10;
}
/* At this point all digits are unique
We're not interested in zero, though */
}

int main()
{
int indx;
for( indx = 123456789; indx <=987654321; indx++){
if( check(indx) )
printf("%d\n",indx);
}
}
``````

Edited...

Or you could do the same with an array:

``````int check2(int input)
{
int j, arr = {0,0,0,0,0,0,0,0,0,0};

for(j=1; j<=9; j++) {
if( (arr[input%10]++) || (input%10 == 0) )
return 0;
input /= 10;
}
return 1;
}
``````
• I honestly don't know how to approach bits as I never learned them. Is there another way to go about this? – Jack Swanson Aug 5 '15 at 8:56
• @RichardFlores I'm sorry, this is the fastest and requires less code. This is a good lesson about and, or and bit manipulation. I would recommend to come back to this example, when you do learn about those fields. You could in theory replace the mask with an array of integers, having the same result. – George André Aug 5 '15 at 8:59
• @RichardFlores I've updated my answer with an array example instead, as you asked for. :) – George André Aug 5 '15 at 9:06
• @RichardFlores turns out the array version is marginally faster... :) – George André Aug 5 '15 at 9:11
• Thank you. What exactly is the logic behind this? – Jack Swanson Aug 5 '15 at 9:16

Here's one approach - start with an array of unique digits, then randomly shuffle them:

``````#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <time.h>

int main( void )
{
char digits[] = "123456789";

srand( time( NULL ) );

size_t i = sizeof digits - 1;
while( i )
{
size_t j = rand() % i;
char tmp = digits[--i];
digits[i] = digits[j];
digits[j] = tmp;
}

printf( "number is %s\n", digits );
return 0;
}
``````

Some sample output:

``````john@marvin:~/Development/snippets\$ ./nine
number is 249316578
john@marvin:~/Development/snippets\$ ./nine
number is 928751643
john@marvin:~/Development/snippets\$ ./nine
number is 621754893
john@marvin:~/Development/snippets\$ ./nine
number is 317529864
``````

Note that these are character strings of unique decimal digits, not numeric values; if you want the corresponding integer value, you'd need to do a conversion like

``````long val = strtol( digits, NULL, 10 );
``````

Rather than 10 variables, I would make a single variable with a bit set (and testable) for each of the 10 digits. Then you only need a loop setting (and testing) the bit corresponding to each digit. Something like this:

``````int ok = 1;
unsigned bits = 0;
int digit;
unsigned powers10 = 1;
for (digit = 0; digit < 10; ++digit) {
unsigned bit = 1 << ((num / powers10) % 10);
if ((bits & bit) != 0) {
ok = 0;
break;
}
bits |= bit;
powers10 *= 10;
}
if (ok) {
printf("%d\n", num);
}
``````

Complete program (discarding unnecessary `#include` lines):

``````#include <stdio.h>

int main(void)
{
int indx;
int num;

for(indx = 123456789; indx <= 987654321; indx++)
{
num = indx;
int ok = 1;
unsigned bits = 0;
int digit;
unsigned powers10 = 1;
for (digit = 0; digit < 9; ++digit) {
unsigned bit = 1 << ((num / powers10) % 10);
if ((bit == 1) || ((bits & bit) != 0)) {
ok = 0;
break;
}
bits |= bit;
powers10 *= 10;
}
if (ok) {
printf("%d\n", num);
}
}
return 0;
}
``````

OP clarified his question as I was leaving for work, and I had not focused on the lack of zeroes being requested. (response is updated now). This produces the expected 362880 combinations.

However - there was a comment about one answer being fastest, which prompts a followup. There were (counting this one) three comparable answers. In a quick check:

• @Paul Hankin's answer (which counts zeros and gives 3265920 combinations):
```    real    0m0.951s
user    0m0.894s
sys     0m0.056s
```
• this one:
```    real    0m49.108s
user    0m49.041s
sys     0m0.031s
```
• @George André's answer (which also produced the expected number of combinations):
```     real    1m27.597s
user    1m27.476s
sys     0m0.051s
```
• The assignment to `bit` maps the value `num` into values 1, 2, 4, 8, etc., according to the value of `digit` (0, 1, 2, 3, etc). Someone might show a more concise example, but this sort of approach is quite common in system programming with C. – Thomas Dickey Aug 5 '15 at 9:33
• Mind timing my 2nd solution (after EDIT, the fully unrolled one) Just curious if your timing results match mine, plus it makes sense to have independent validation : stackoverflow.com/a/31928246/2963099 – Glenn Teitelbaum Aug 12 '15 at 17:42
• @ThomasDickey Nice! Which one of my answers did you test? The mask one, check1() or the array one, check2()? Could you please test both? I have a feeling of which one would be faster, but it would be nice to confirm. – George André Aug 14 '15 at 8:02
• @ThomasDickey : could you please add my solution to the hall-of-fame? I think it is rather fast. – wildplasser Aug 17 '15 at 23:28

Check this code.

``````    #include<stdio.h>

//it can be done by recursion

void func(int *flag, int *num, int n){  //take 'n' to count the number of digits
int i;
if(n==9){                           //if n=9 then print the number
for(i=0;i<n;i++)
printf("%d",num[i]);
printf("\n");
}
for(i=1;i<=9;i++){

//put the digits into the array one by one and send if for next level

if(flag[i-1]==0){
num[n]=i;
flag[i-1]=1;
func(flag,num,n+1);
flag[i-1]=0;
}
}
}

//here is the MAIN function
main(){

int i,flag,num;
for(i=0;i<9;i++)        //take a flag to avoid repetition of digits in a number
flag[i]=0;          //initialize the flags with 0

func(flag,num,0);       //call the function

return 0;
}
``````

If you have any question feel free to ask.

I recommend Nominal Animal's answer, but if you are only generating this value so you can print it out you can eliminate some of the work and at the same time get a more generic routine using the same method:

``````char *shuffle( char *digit, int digits, int count, unsigned int seed )
{
//optional: do some validation on digit string
//  ASSERT(digits == strlen(digit));
//optional: validate seed value is reasonable
//  for(unsigned int badseed=1, x=digits, y=count; y > 0; x--, y--)

char *work = digit;
while(count--)
{
int i = seed % digits;
seed /= digits--;
unsigned char selectedDigit = work[i];
work[i] = work;
work = selectedDigit;
work++;
}
work = 0;

//seed should be zero here, else the seed contained extra information
return digit;
}
``````

This method is destructive on the digits passed in, which don't actually have to be numeric, or unique for that matter.

On the off chance that you want the output values generated in sorted increasing order that's a little more work:

``````char *shuffle_ordered( char *digit, int digits, int count, unsigned int seed )
{
char *work = digit;
int doneDigits = 0;
while(doneDigits < count)
{
int i = seed % digits;
seed /= digits--;
unsigned char selectedDigit = work[i];
//move completed digits plus digits preceeding selectedDigit over one place
memmove(digit+1,digit,doneDigits+i);
digit = selectedDigit;
work++;
}
work = 0;

//seed should be zero here, else the seed contained extra information
return digit;
}
``````

In either case it's called like this:

``````for(unsigned int seed = 0; seed < 16*15*14; ++seed)
{
char work[] = "0123456789ABCDEF";
printf("seed=%d -> %s\n",shuffle_ordered(work,16,3,seed));
}
``````

This should print out an ordered list of three digit hex values with no duplicated digits:

``````seed 0 -> 012
seed 1 -> 013
...
seed 3358 -> FEC
seed 3359 -> FED
``````

I don't know what you are actually doing with these carefully crafted sequences of digits. If some poor sustaining engineer is going to have to come along behind you to fix some bug, I recommend the ordered version, as it is way easier for a human to convert seed from/to sequence value.

Here is a bit ugly but very fast solution using nested `for loops`.

``````#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>

#define NINE_FACTORIAL  362880

int main(void) {

//array where numbers would be saved
uint32_t* unique_numbers = malloc( NINE_FACTORIAL * sizeof(uint32_t) );
if( !unique_numbers ) {
printf("Could not allocate memory for the Unique Numbers array.\n");
exit(1);
}

uint32_t n = 0;
int a,b,c,d,e,f,g,h,i;

for(a = 1; a < 10; a++) {
for(b = 1; b < 10; b++) {
if (b == a) continue;

for(c = 1; c < 10; c++) {
if(c==a || c==b) continue;

for(d = 1; d < 10; d++) {
if(d==a || d==b || d==c) continue;

for(e = 1; e < 10; e++) {
if(e==a || e==b || e==c || e==d) continue;

for(f = 1; f < 10; f++) {
if (f==a || f==b || f==c || f==d || f==e)
continue;

for(g = 1; g < 10; g++) {
if(g==a || g==b || g==c || g==d || g==e
|| g==f) continue;

for(h = 1; h < 10; h++) {
if (h==a || h==b || h==c || h==d ||
h==e || h==f || h==g) continue;

for(i = 1; i < 10; i++) {
if (i==a || i==b || i==c || i==d ||
i==e || i==f || i==g || i==h) continue;

// print the number or
// store the number in the array
unique_numbers[n++] = a * 100000000
+ b * 10000000
+ c * 1000000
+ d * 100000
+ e * 10000
+ f * 1000
+ g * 100
+ h * 10
+ i;

}
}
}
}
}
}
}
}
}

// do stuff with unique_numbers array
// n contains the number of elements

free(unique_numbers);

return 0;
}
``````

Same thing using some macros.

``````#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>

#define l_(b,n,c,p,f) { int i; for(i = 1; i < 10; i++) {            \
int j,r=0; for(j=0;j<p;j++){if(i == c[j]){r=1;break;}}        \
if(r) continue; c[p] = i; f   } }

#define l_8(b,n,c,p) {                                              \
int i; for(i=1; i< 10; i++) {int j, r=0;                        \
for(j=0; j<p; j++) {if(i == c[j]) {r = 1; break;}}            \
if(r)continue; b[n++] = c * 100000000  + c * 10000000   \
+ c * 1000000 + c * 100000 + c * 10000         \
+ c * 1000 + c * 100 + c * 10 + i; } }

#define l_7(b,n,c,p) l_(b,n,c,p, l_8(b,n,c,8))
#define l_6(b,n,c,p) l_(b,n,c,p, l_7(b,n,c,7))
#define l_5(b,n,c,p) l_(b,n,c,p, l_6(b,n,c,6))
#define l_4(b,n,c,p) l_(b,n,c,p, l_5(b,n,c,5))
#define l_3(b,n,c,p) l_(b,n,c,p, l_4(b,n,c,4))
#define l_2(b,n,c,p) l_(b,n,c,p, l_3(b,n,c,3))
#define l_1(b,n,c,p) l_(b,n,c,p, l_2(b,n,c,2))

#define get_unique_numbers(b,n,c) do {int i; for(i=1; i<10; i++) { \
c = i; l_1(b,n,c,1) } } while(0)

#define NINE_FACTORIAL  362880

int main(void) {

//array where numbers would be saved
uint32_t* unique_numbers = malloc( NINE_FACTORIAL * sizeof(uint32_t) );
if( !unique_numbers ) {
printf("Could not allocate memory for the Unique Numbers array.\n");
exit(1);
}

int n = 0;
int current_number = {0};

get_unique_numbers(unique_numbers, n, current_number);

// do stuff with unique_numbers array
// NINE_FACTORIAL is the number of elements

free(unique_numbers);

return 0;
}
``````

I am sure there are better ways to write those macros, but that is what I could think of.

A simple way is to create an array with nine distinct values, shuffle it, and print the shuffled array. Repeat as many times as needed. For example, using the standard `rand()` function as a basis for shuffling ...

``````#include <stdlib.h>     /*  for srand() and rand */
#include <time.h>       /*  for time() */
#include <stdio.h>

#define SIZE 10     /*   size of working array.  There are 10 numeric digits, so ....   */
#define LENGTH 9    /*  number of digits we want to output.  Must not exceed SIZE */
#define NUMBER 12   /*  number of LENGTH digit values we want to output */

void shuffle(char *buffer, int size)
{
int i;
char temp;
for (i=size-1; i>0; --i)
{
/*  not best way to get a random value of j in [0, size-1] but
sufficient for illustrative purposes
*/
int j = rand()%size;
/* swap buffer[i] and buffer[j] */
temp = buffer[i];
buffer[i] = buffer[j];
buffer[j] = temp;
}
}

void printout(char *buffer, int length)
{
/*  this assumes SIZE <= 10 and length <= SIZE */

int i;
for (i = 0; i < length; ++i)
printf("%d", (int)buffer[i]);
printf("\n");
}

int main()
{
char buffer[SIZE];
int i;
srand((unsigned)time(NULL));   /*  seed for rand(), once and only once */

for (i = 0; i < SIZE; ++i)  buffer[i] = (char)i;  /*  initialise buffer */

for (i = 0; i < NUMBER; ++i)
{
/*  keep shuffling until first value in buffer is non-zero */

do shuffle(buffer, SIZE); while (buffer == 0);
printout(buffer, LENGTH);
}
return 0;
}
``````

This prints a number of lines to `stdout`, each with 9 unique digits. Note that this does not prevent duplicates.

EDIT: After further analysis, more recursion unrolling and only iterating on set bits resulted in significant improvement, in my testing roughly FIVE times as fast. This was tested with `OUTPUT` UNSET to compare algorithm speed not console output, start point is `uniq_digits9` :

``````int counter=0;
int reps=0;

void show(int x)
{
#ifdef OUTPUT
printf("%d\n", x);
#else
counter+=x;
++reps;
#endif
}

int bit_val(unsigned int v)
{
static const int MultiplyDeBruijnBitPosition2 =
{
0, 1, 28, 2, 29, 14, 24, 3, 30, 22, 20, 15, 25, 17, 4, 8,
31, 27, 13, 23, 21, 19, 16, 7, 26, 12, 18, 6, 11, 5, 10, 9
};
return MultiplyDeBruijnBitPosition2[(unsigned int)(v * 0x077CB531U) >> 27];
}

void uniq_digits1(int prefix, unsigned int used) {
show(prefix*10+bit_val(~used));
}

void uniq_digits2(int prefix, unsigned int used) {
int base=prefix*10;
unsigned int unused=~used;
while (unused) {
unsigned int diff=unused & (unused-1);
unsigned int bit=unused-diff;
unused=diff;
uniq_digits1(base+bit_val(bit), used|bit);
}
}

void uniq_digits3(int prefix, unsigned int used) {
int base=prefix*10;
unsigned int unused=~used;
while (unused) {
unsigned int diff=unused & (unused-1);
unsigned int bit=unused-diff;
unused=diff;
uniq_digits2(base+bit_val(bit), used|bit);
}
}

void uniq_digits4(int prefix, unsigned int used) {
int base=prefix*10;
unsigned int unused=~used;
while (unused) {
unsigned int diff=unused & (unused-1);
unsigned int bit=unused-diff;
unused=diff;
uniq_digits3(base+bit_val(bit), used|bit);
}
}

void uniq_digits5(int prefix, unsigned int used) {
int base=prefix*10;
unsigned int unused=~used;
while (unused) {
unsigned int diff=unused & (unused-1);
unsigned int bit=unused-diff;
unused=diff;
uniq_digits4(base+bit_val(bit), used|bit);
}
}

void uniq_digits6(int prefix, unsigned int used) {
int base=prefix*10;
unsigned int unused=~used;
while (unused) {
unsigned int diff=unused & (unused-1);
unsigned int bit=unused-diff;
unused=diff;
uniq_digits5(base+bit_val(bit), used|bit);
}
}

void uniq_digits7(int prefix, unsigned int used) {
int base=prefix*10;
unsigned int unused=~used;
while (unused) {
unsigned int diff=unused & (unused-1);
unsigned int bit=unused-diff;
unused=diff;
uniq_digits6(base+bit_val(bit), used|bit);
}
}

void uniq_digits8(int prefix, unsigned int used) {
int base=prefix*10;
unsigned int unused=~used;
while (unused) {
unsigned int diff=unused & (unused-1);
unsigned int bit=unused-diff;
unused=diff;
uniq_digits7(base+bit_val(bit), used|bit);
}
}

void uniq_digits9() {
unsigned int used=~((1<<10)-1); // set all bits except 0-9
#ifndef INCLUDE_ZEROS
used |= 1;
#endif
for (int i = 1; i < 10; i++) {
unsigned int bit=1<<i;
uniq_digits8(i,used|bit);
}
}
``````

Brief explanation:

There are 9 digits and the first cannot start with zero, so the first digit can be from 1 to 9, the rest can be 0 to 9

If we take a number, X and multiply it by 10, it shifts one place over. So, 5 becomes 50. Add a number, say 3 to make 53, and then multiply by 10 to get 520, and then add 2, and so on for all 9 digits.

Now some storage is needed to keep track of what digits were used so they aren't repeated. 10 true/false variables could be used: `used_0_p`, `used_1_P` , .... But, that is inefficient, so they can be placed in an array: `used_p`. But then it would need to be copied every time before making a call the next place so it can reset it for the next digit, otherwise once all places are filled the first time the array would be all true and no other combinations could be calculated.

But, there is a better way. Use bits of an `int` as the array. `X & 1` for the first, `X & 2`, `X & 4`, `X & 8`, etc. This sequence can be represented as `(1<<X)` or take the first bit and shift it over X times.

`&` is used to test bits, `|` is used to set them. In each loop we test if the bit was used `(1<<i)&used` and skip if it was. At the next place we shift the digits for each digit `prefix*10+i` and set that digit as used `used|(1<<i)`

Explanation of looping in the EDIT

The loop calculates `Y & (Y-1)` which zeroes the lowest set bit. By taking the original and subtracting the result the difference is the lowest bit. This will loop only as many times as there are bits: 3,265,920 times instead of 900,000,000 times. Switching from used to unused is just the `~` operator, and since setting is more efficient than unsetting, it made sense to flip

Going from power of two to its log2 was taken from: https://graphics.stanford.edu/~seander/bithacks.html#IntegerLog . This site also details the loop mechanism: https://graphics.stanford.edu/~seander/bithacks.html#DetermineIfPowerOf2

Moving original to the bottom:

This is too long for a comment, but This answer can be make somewhat faster by removing the zero handling from the function: ( See edit for fastest answer )

``````void uniq_digits(int places, int prefix, int used) {
if (!places) {
printf("%d\n", prefix);
return;
}
--places;
int base=prefix*10;
for (int i = 0; i < 10; i++)
{
if ((1<<i)&used) continue;
uniq_digits(places, base+i, used|(1<<i));
}
}

int main(int argc, char**argv) {
const int num_digits=9;

// unroll top level to avoid if for every iteration
for (int i = 1; i < 10; i++)
{
uniq_digits(num_digits-1, i, 1 << i);
}

return 0;
}
``````
• The comments under the question indicate zero is not a valid digit in the result. Only 1-9 are desired. – Speed8ump Aug 13 '15 at 22:56
• Added ifdef for including 0s – Glenn Teitelbaum Aug 16 '15 at 15:02

A bit late to the party, but very fast (30 ms here) ...

``````#include <stdio.h>
#define COUNT 9

/* this buffer is global. intentionally.
** It occupies (part of) one cache slot,
** and any reference to it is a constant
*/
char ten[COUNT+1] ;

int main(void)
{
unsigned res;

ten[COUNT] = 0;

res = rec(0, (1u << COUNT)-1);
fprintf(stderr, "Res=%u\n", res);

return 0;
}

/* recursive function: consume the mask of available numbers
** until none is left.
** return value is the number of generated permutations.
*/
{
unsigned bit, res = 0;

if (!mask) { puts(ten); return 1; }

for (bit=0; bit < COUNT; bit++) {
if (! (mask & (1u <<bit)) ) continue;
ten[pos] = '1' + bit;
res += rec(pos+1, mask & ~(1u <<bit));
}
return res;
}
``````

iterative version that uses bits extensively

note that `array` can be changed to any type, and set in any order this will "count"the digits in given order

For more explaination look at my first answer (which is less flexible but much faster) https://stackoverflow.com/a/31928246/2963099

In order to make it iterative, arrays were needed to keep state at each level

This also went though quite a bit of optimization for places the optimizer couldn't figure out

``````int bit_val(unsigned int v) {
static const int MultiplyDeBruijnBitPosition2 = {
0, 1, 28, 2, 29, 14, 24, 3, 30, 22, 20, 15, 25, 17, 4, 8,
31, 27, 13, 23, 21, 19, 16, 7, 26, 12, 18, 6, 11, 5, 10, 9
};
return MultiplyDeBruijnBitPosition2[(unsigned int)(v * 0x077CB531U) >> 27];
}

void uniq_digits(const int array[], const int length) {
unsigned int unused[length-1];                    // unused prior
unsigned int combos[length-1];                    // digits untried
int digit[length];                                // printable digit
int mult[length];                                 // faster calcs
mult[length-1]=1;                                 // start at 1
for (int i = length-2; i >= 0; --i)
mult[i]=mult[i+1]*10;                          // store multiplier
unused=combos=((1<<(length))-1);            // set all bits 0-length
int depth=0;                                      // start at top
digit=0;                                       // start at 0
while(1) {
if (combos[depth]) {                            // if bits left
unsigned int avail=combos[depth];             // save old
combos[depth]=avail & (avail-1);              // remove lowest bit
unsigned int bit=avail-combos[depth];         // get lowest bit
digit[depth+1]=digit[depth]+mult[depth]*array[bit_val(bit)]; // get associated digit
unsigned int rest=unused[depth]&(~bit);       // all remaining
depth++;                                      // go to next digit
if (depth!=length-1) {                        // not at bottom
unused[depth]=combos[depth]=rest;           // try remaining
} else {
show(digit[depth]+array[bit_val(rest)]);    // print it
depth--;                                    // stay on same level
}
} else {
depth--;                                      // go back up a level
if (depth < 0)
break;                                      // all done
}
}
}
``````

Some timings using just 1 to 9 with 1000 reps:

• @this here is the generic iterative version, its twice as slow as my other one, but here you go – Glenn Teitelbaum Aug 17 '15 at 21:12
• You are comparing apples to oranges. Your function outputs every possible value in a single call, while every other solution outputs a single value. How did you not notice that. Even ignoring that I seriously doubt your measuring methodology is correct. – this Aug 18 '15 at 18:38
• Write a function that takes an array and its length like the nextPermutation function, and writes the next value into the array and returns. Then try comparing. – this Aug 18 '15 at 18:40
• @this the OP was generate all, the recursive generates all, the swap had code to generate all, the nextPermutation had a main that generated all. And if you doubt my methods, run it. There was no requirement to generate the next, clever as that was. My unrolled recursion is still the fastest at solving the OP's requirement, using templates and `std::bitset` in C++ I could go faster, but this is C – Glenn Teitelbaum Aug 18 '15 at 20:20
• Your functions might be the fastest, by your measurements, but you see, if you defined OUTPUT, the function doesn't return or write any value anywhere. The result is just, lost. Hmm, other functions seem to return a result every time they are called. This and the fact that every other function could be modified so it calculates every value internally instead of being called in a loop incurring extra overhead, make you entry invalid. Bye. – this Aug 18 '15 at 20:34

Make a list with 10 elements with values 0-9. Pull random elements out by rand() /w current length of list, until you have the number of digits you want.