Despite the last 30 minutes i spent on trying to understand time and space complexity better, i still can't confidently determine those for the algorithm below:

```
bool checkSubstr(std::string sub)
{
//6 OR(||) connected if statement(checks whether the parameter
//is among the items in the list)
}
void checkWords(int start,int end)
{
int wordList[2] ={0};
int j = 0;
if (start < 0)
{
start = 0;
}
if (end>cAmount)
{
end = cAmount -1;
}
if (end-start < 2)
{
return;
}
for (int i = start; i <= end-2; i++)
{
if (crystals[i] == 'I' || crystals[i] == 'A')
{
continue;
}
if (checkSubstr(crystals.substr(i,3)))
{
wordList[j] = i;
j++;
}
}
if (j==1)
{
crystals.erase(wordList[0],3);
cAmount -= 3;
checkWords(wordList[0]-2,wordList[0]+1);
}
else if (j==2)
{
crystals.erase(wordList[0],(wordList[1]-wordList[0]+3));
cAmount -= wordList[1]-wordList[0]+3;
checkWords(wordList[0]-2,wordList[0]+1);
}
}
```

The function basically checks a sub-string of the whole string for predetermined (3 letter, e.g. "SAN") combinations of letters. Sub-string length can be 4-6 no real way to determine, depends on the input(pretty sure it's not relevant, although not 100%).

My reasoning:

If there are n letters in the string, worst case scenario, we have to check each of them. Again depending on the input, this can be done 3 ways.

- All 6 length sub-strings: If this is the case the function runs n/6 times, each running 8(or 10?) processes, which(i think) means that its time complexity is O(n).
- All 4 length sub-strings: Pretty much the same reason above, O(n).
- 4 and 6 length sub-strings mixed: Can't see why this would be different than previous 2. O(n)

As for the space complexity, i am completely lost. However, i have an idea: If the function recurs for maximum amount of time,it will require: n/4 x The Amount Used In One Run which made me think it should be O(n). Although, i'm not convinced this is correct. I thought maybe seeing someone else's thought process on this example would help me understand how to calculate time and space complexity better. Thank you for your time.

EDIT: Let me provide clearer information. We read a combination of 6 different letters into a string, this can be (almost)any combination in any length. 'crystals' is the string, and we are looking for 6 different 3 letter combinations in that list of letters. Sort of like a jewel matching game. Now the starting list contains no matches(none of the 6 predetermined combinations exist in the first place). Therefore the only way matches can occur from then on is by swaps or matches disappearing. Once a swap is processed by top level code, the function is called to check for matches, and if a match is found the function recurs after deleting the "match" part of the string.

Now let's look at how the code is looking for a match. To demonstrate a swap of 2 letters:

ABA B-R ZIB(no spaces or '-' in the actual string, used for better demonstration),

B and R is being swapped. This swap only effects the 6 letters starting from 2nd letter and ending on 7th letter. In other words, the letters the first A and last B can form a match with are same, before and after the swap, thus no point checking for matches including those words. So a sub-string of 6 letters sent to the checking algorithm. Similarly, if a formed match disappears(gets deleted from the string) the range of effected letters is 4. So when i thought of a worst case scenario, i imagined either 1 swap creating a whole chain reaction and matching all the way till there are not enough letters to form a match, or each match happens with a swap. Again, i am not saying this is how we should think when calculating time and space complexity but this is how the code works. Hope this is clear enough if not let me know and i can provide more details. It's also important to note that swap amount and places are a part of the input we read.

EDIT: Here is how the function is called on top level for the first time:
`checkWords(swaps[i]-2,swaps[i]+3);`

`if (checkSubstr(crystals.substr(i,3))) { ... }`

– Filipe Gonçalves Sep 13 '15 at 12:47