Say there are "n" numbers from which we select "p" numbers (p less than n) such that the selected "p" numbers are sorted. A selected number can be repeated. How can we calculate the number of combinations we can select? For example if we have a set of numbers say {1,2,3,4,5,6} (n=6) and we are to select 3 numbers from the set (p=3) which are sorted. So we can have {1,2,3}, {1,1,2}, {2,3,6}, {4,5,5}, {5,5,5} ........ Since all of these combinations are sorted they are valid. How can we find the number of such sorted combinations we can get? Any help is appreciated. Thanks.

I fail to see how the sorting affects the result. For each possible combination with repetitions, there will be a corresponding sorted permutation. Hence the question boils down to number of combinations of n elements taken p at a time with replacement. That is the straight forward formula, (n1+p)C(p) = factorial(n1+p) / (factorial(p) * factorial(n1) ) Here is an explanation of the formula, and another one from wolfram. 


Thanks a lot for the quick responses. What I meant from the word sorted, was that when we select p elements from a set of numbers of n elements, the selected p elements should be sorted. Take this small example. If the set is {1,2,3,4} (so n = 4) and we are to select 3 elements (p = 3), the number of ways we can select p elements (with replacement) will be 4*4*4=64. So the selections will have {1,1,1},{1,1,2},{1,1,3}{1,1,4},{1,2,1}.....{3,1,1}...{4,4,4}. But in these selections, not all are sorted. In this example, {1,2,1} and {3,1,1} are not sorted. I wanted to get the number of sorted selections. 


@BiGYaN's answer here, is correct but lacks the humor in journey to get this result (even on the links provided), so I decided to add this 
We need sequences such as: {[1,1,1], [1,1,2], .... , [2,2,3], [2,2,4],...}. Now, for such a sequences scan the pattern from left and try to reason if we want to increment digits or not. For ex: start from just left of d1 and reason if you want to increment d1 right here or not, if you decide not  d1 would be '1' and now moving ahead ask the same question just before d2, if you again decide not to up, d2 is '1' again. You can choose to up 5 times anytime because range is [16] and d1 should be 6 at least, if you decide to raise it 5 times to get [6,6,6]. So, the problem becomes to select proper place for 5 ups among
This could be [up d1 up up up up d2 d3] which yields [2,6,6], or [d1 up up up d2 up d3 up] which yields [1,4,5] or any combination like this. So, actually the answer is  C(5 up's + 3 d's, 5 up's) or, more generally
where, k things are to be selected in sorted order out of n things. 


The number of ways you can choose Informal demonstration: Suppose I have n blue boxes. I put them in a row (so they're sorted), and then take k red balls. I put the red balls anywhere I like in the row except at the end, so the row must still end with a blue box. Now, for each red ball I select the following blue box. If two or more red balls are sidebyside, they both correspond to the same blue box. So every arrangement of red balls and blue boxes corresponds to some selection with replacement of blue boxes, and every selection of blue boxes corresponds to some arrangement of red balls and blue boxes. How many ways can I arrange the red balls and blue boxes? My row must end with a blue box, so I take that one away, and now I can arrange the remaining n1 blue boxes and k red balls in any way I choose. Or, in otherwords, I can choose k of the k + n1 positions and put red balls at those positions, filling in the remaining positions with the blue boxes. 

