# Maximum сontinuous achievable number

SO,

The problem

Definitions

• Let's define a natural number `N` as a writable number (WN) for number set in `M` numeral system, if it can be written in this numeral system from members of `U` using each member no more than once. More strict definition of 'written': - here `CONCAT` means concatenation.
• Let's define a natural number `N` as a continuous achievable number (CAN) for symbol set in `M` numeral system if it is a WN-number for `U` and `M` and also `N-1` is a CAN-number for `U` and `M` (Another definition may be `N` is CAN for `U` and `M` if all `0 .. N` numbers are WN for `U` and `M`). More strict:

Issue

Let we have a set of `S` natural numbers: (we are treating zero as a natural number) and natural number `M`, `M>1`. The problem is to find maximum CAN (MCAN) for given `U` and `M`. Given set `U` may contain duplicates - but each duplicate could not be used more than once, of cause (i.e. if `U` contains {x, y, y, z} - then each `y` could be used 0 or 1 time, so `y` could be used 0..2 times total). Also `U` expected to be valid in `M`-numeral system (i.e. can not contain symbols `8` or `9` in any member if `M=8`). And, of cause, members of `U` are numbers, not symbols for `M` (so `11` is valid for `M=10`) - otherwise the problem will be trivial.

My approach

I have in mind a simple algorithm now, which is simply checking if current number is CAN via:

1. Check if `0` is WN for given `U` and `M`? Go to 2: We're done, MCAN is null
2. Check if `1` is WN for given `U` and `M`? Go to 3: We're done, MCAN is `0`
3. ...

So, this algorithm is trying to build all this sequence. I doubt this part can be improved, but may be it can? Now, how to check if number is a WN. This is also some kind of 'substitution brute-force'. I have a realization of that for `M=10` (in fact, since we're dealing with strings, any other `M` is not a problem) with PHP function:

``````//\$mNumber is our N, \$rgNumbers is our U
function isWriteable(\$mNumber, \$rgNumbers)
{
if(in_array((string)\$mNumber, \$rgNumbers=array_map('strval', \$rgNumbers), true))
{
return true;
}
for(\$i=1; \$i<=strlen((string)\$mNumber); \$i++)
{
foreach(\$rgKeys = array_keys(array_filter(\$rgNumbers, function(\$sX) use (\$mNumber, \$i)
{
return \$sX==substr((string)\$mNumber, 0, \$i);
})) as \$iKey)
{
\$rgTemp = \$rgNumbers;
unset(\$rgTemp[\$iKey]);
if(isWriteable(substr((string)\$mNumber, \$i), \$rgTemp))
{
return true;
}
}
}
return false;
}
``````

-so we're trying one piece and then check if the rest part could be written with recursion. If it can not be written, we're trying next member of `U`. I think this is a point which can be improved.

Specifics

As you see, an algorithm is trying to build all numbers before `N` and check if they are WN. But the only question is - to find MCAN, so, question is:

• May be constructive algorithm is excessive here? And, if yes, what other options could be used?
• Is there more quick way to determine if number is WN for given `U` and `M`? (this point may have no sense if previous point has positive answer and we'll not build and check all numbers before `N`).

Samples

```U = {4, 1, 5, 2, 0}
M = 10
```

then MCAN = 2 (3 couldn't be reached)

```U = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11}
M = 10
```

then MCAN = 21 (all before could be reached, for `22` there are no two `2` symbols total).

-
The second example appears to be incorrect because `11 > 10` –  Jan Dvorak Sep 20 '13 at 10:16
@JanDvorak why incorrect? `11>10` - yes, but 10 can be combined from `1` and `0` - which are present in `U` –  Alma Do Sep 20 '13 at 10:17
I mean, why is `11` in `U` if `M=10`? –  Jan Dvorak Sep 20 '13 at 10:18
@Jack - what question? And please, don't suggest programmers for such things. It isn't a dumping ground for SO off-topic. –  Oded Sep 20 '13 at 13:40
This question seems like it may be more appropriate for cs.stackexchange.com. –  RBarryYoung Sep 20 '13 at 15:13

Hash the digit count for digits from `0` to `m-1`. Hash the numbers greater than `m` that are composed of one repeated digit.

MCAN is bound by the smallest `digit` for which all combinations of that digit for a given `digit count` cannot be constructed (e.g., X000,X00X,X0XX,XX0X,XXX0,XXXX), or `(digit count - 1)` in the case of zero (for example, for all combinations of four digits, combinations are needed for only three zeros; for a zero count of zero, MCAN is null). Digit counts are evaluated in ascending order.

Examples:

``````1. MCAN (10, {4, 1, 5, 2, 0})
3 is the smallest digit for which a digit-count of one cannot be constructed.
MCAN = 2

2. MCAN (10, {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11})
2 is the smallest digit for which a digit-count of two cannot be constructed.
MCAN = 21

3. (from Alma Do Mundo's comment below) MCAN (2, {0,0,0,1,1,1})
1 is the smallest digit for which all combinations for a digit-count of four
cannot be constructed.
MCAN = 1110

4. (example from No One in Particular's answer)
MCAN (2, {0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1,1,1,1111,11111111})
1 is the smallest digit for which all combinations for a digit-count of five
cannot be constructed.
MCAN = 10101
``````
-
I think error is starting from Store numbers greater than m as additional counts. A sample: `MCAN(10, {0,1,2}) = 2` while `MCAN(10, {10, 2}) = null` - but both `0,1,2` and `10, 2` have same symbols –  Alma Do Sep 20 '13 at 13:32
@AlmaDoMundo good point. let me think about it some more. –  גלעד ברקן Sep 20 '13 at 13:33
@AlmaDoMundo in this set `MCAN(10, {10, 2})` , can the numbers 102 and 210 be created? –  גלעד ברקן Sep 20 '13 at 13:49
MCAN is an abbreviation. From `{10, 2}` only `102` and `210` could be created, yes, so even 0 is not a WN for `{10, 2}` - and so MCAN is null –  Alma Do Sep 20 '13 at 13:51
@AlmaDoMundo does my suggestion work better now? –  גלעד ברקן Sep 20 '13 at 14:12

The recursion steps I've made are:

1. If the digit string is available in your alphabet, mark it used and return immediately
2. If the digit string is of length 1, return failure
3. Split the string in two and try each part

This is my code:

``````\$u = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11];

echo ncan(\$u), "\n"; // 21

// the functions

function satisfy(\$n, array \$u)
{
if (!empty(\$u[\$n])) { // step 1
--\$u[\$n];
return \$u;
} elseif (strlen(\$n) == 1) { // step 2
return false;
}

// step 3
for (\$i = 1; \$i < strlen(\$n); ++\$i) {
\$u2 = satisfy(substr(\$n, 0, \$i), \$u);
if (\$u2 && satisfy(substr(\$n, \$i), \$u2)) {
return true;
}
}

return false;
}

function is_can(\$n, \$u)
{
return satisfy(\$n, \$u) !== false;
}

function ncan(\$u)
{
\$umap = array_reduce(\$u, function(&\$result, \$item) {
@\$result[\$item]++;
return \$result;
}, []);
\$i = -1;

while (is_can(\$i + 1, \$umap)) {
++\$i;
}

return \$i;
}
``````
-
Thank you for your work. As I see, it's also constructive algorithm: check if number is WN, then go to next, while number is WN, right? –  Alma Do Sep 21 '13 at 8:04
@AlmaDoMundo Yes, I don't think there's another way; and if there is, I would love to know about it :) –  Ja͢ck Sep 21 '13 at 8:11
I'm trying actually to understand such way in an answer above (it seems it is non-constructive) - unfortunately, with no success currently. –  Alma Do Sep 21 '13 at 8:18
@AlmaDoMundo and Jack, if you have time, could you please show an example where my algorithm does not work, to help me better understand? –  גלעד ברקן Sep 21 '13 at 11:56
@AlmaDoMundo But `isWriteable(101, [10, 0, 1])` is `false`. I'm arguing that it should be `true`. –  Ja͢ck Sep 21 '13 at 13:48

Here is another approach:

1) Order the set U with regards to the usual numerical ordering for base M.
2) If there is a symbol between 0 and (M-1) which is missing, then that is the first number which is NOT MCAN.
3) Find the fist symbol which has the least number of entries in the set U. From this we have an upper bound on the first number which is NOT MCAN. That number would be {xxxx} N times. For example, if M = 4 and U = { 0, 0, 0, 1, 1, 1, 2, 2, 2, 3, 3}, then the number 333 is not MCAN. This gives us our upper bound.
4) So, if the first element of the set U which has the small number of occurences is x and it has C occurences, then we can clearly represent any number with C digits. (Since every element has at least C entries).
5) Now we ask if there is any number less than (C+1)x which can't be MCAN? Well, any (C+1) digit number can have either (C+1) of the same symbol or only at most (C) of the same symbol. Since x is minimal from step 3, (C+1)y for y < x can be done and (C)a + b can be done for any distinct a, b since they have (C) copies at least.

The above method works for set elements of only 1 symbol. However, we now see that it becomes more complex if multi-symbol elements are allowed. Consider the following case:

U = { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1,1,1,1111,11111111}

Define c(A,B) = the number of 'A' symbols of 'B' length.

So for our example, c(0,1) = 15, c(0,2) = 0, c(0,3) = 0, c(0,4) = 0, ... c(1,1) = 3, c(1,2) = 0, c(1,3) = 0, c(1,4) = 1, c(0,5) = 0, ..., c(1,8) = 1

The maximal 0 string we can't do is 16. The maximal 1 string we can't do is also 16.
1 = 1
11 = 1+1
111 = 1+1+1
1111 = 1111
11111 = 1+1111
111111 = 1+1+1111
1111111 = 1+1+1+1111
11111111 = 11111111
111111111 = 1+11111111
1111111111 = 1+1+11111111
11111111111 = 1+1+1+11111111
111111111111 = 1111+11111111
1111111111111 = 1+1111+11111111
11111111111111 = 1+1+1111+11111111
111111111111111 = 1+1+1+1111+11111111

But can we make the string 11111101111? We can't because the last 1 string (1111) needs the only set of 1's with the 4 in a row. Once we take that, we can't make the first 1 string (111111) because we only have an 8 (which is too big) or 3 1-lengths which are too small.

So for multi-symbols, we need another approach.

We know from sorting and ordering our strings what is the minimum length we can't do for a given symbol. (In the example above, it would be 16 zeros or 16 ones.) So this is our upper bound for an answer.

What we have to do now is start a 1 and count up in base M. For each number we write it in base M and then determine if we can make it from our set U. We do this by using the same approach used in the coin change problem: dynamic programming. (See for example http://www.geeksforgeeks.org/dynamic-programming-set-7-coin-change/ for the algorithm.) The only difference is that in our case we only have finite number of each elements, not an infinite supply.

Instead of subtracting the amount we are using like in the coin change problem, we strip the matching symbol off of the front of the string we are trying to match. (This is the opposite of our addition - concatenation.)

-
Thank you, I'll see it –  Alma Do Sep 21 '13 at 15:05
@AlmaDoMundo and No One in Particular, isn't this the same as my answer? –  גלעד ברקן Sep 21 '13 at 15:06
groovy, I was typing my answer when yours was posted. I do believe that they are the same. I bow to your first answer. –  No One in Particular Sep 21 '13 at 15:07
@NoOneinParticular in that case, I bow to yours as well! –  גלעד ברקן Sep 21 '13 at 15:08
@NoOneinParticular You might need to address the case when `XXX` can be constructed from `X` and `XX`, for example. I cannot seem to find this in your answer. –  גלעד ברקן Sep 21 '13 at 15:12