This is a very clever way of doing this. The only thing I think I would suggest changing is the v > amount and v < amount to use >= and <= respectively as the code currently fails to work out an exact value. To be fair the OP didn't mention this, but I would think it makes sense.

@Enigmativity thank you for the comment. I've made the changes you have mentioned.

Thanks @Koray Very nice and clear. Liked it +1. Only problem is it taking longer than knapsack solution in below comments. This took around 10s for 5 digit amount :(

@PravinDeshmukh did you have a chance to compare performance of my updated code with Knapsack approach? Is it still too bad? :)

@Koray Yes, I tried revised code as well, but that too couldn't make significant difference :(

@PravinDeshmukh I wonder if could Edit 2 solve your requirements. I d appreciate if you'd have time to test it. Thanks.

This question is very much fun for me. Tonight I had a great few hours on thinking about it, thanks. I hope Edit3 is valid and fast enough.

Impressed! Not sure what you have done there, I just had copy-pasted code snippet into my solution and it did well for 9 digit amounts as well, very much performant than previous. Kudos! (still in testing)

It's exciting for me to have the test results. Please send me the inputs if any bug you might find.

Edit3 is more or less the same as the other dp approaches but in a forward style. Instead of looking if a number can be built by using any number in the set and a valid denomination, you look for the numbers that can be built and add all denominations to mark the next buildable numbers. Complexity doesn't change, but I'm still unsure about the general impact (backwards can skip potentially a lot of denoms when there are a lot of hits, forward can skip numbers that cannot be built entirely but builds the same number several times potentially even though only added once it has to be checked).

I am thinking that forward is better when there are a lot of gaps or even for rounding down in general. While the backwards standard approach is probably better for rounding up because we know the first number found >= amount is the best, not with the forward approach.

@maraca Some concerns about Edit3: 1. Should the size of ba be amount + denomsMax + 1? RoundAmount(10, new []{10}, false) will result in ArgumentOutOfRange exception. 2. Should hsOK have a initial value of denoms? Because a valid amount can be constructed by a single denom isn't it?

(Continued with my comment above) For point 2, if we call RoundAmount(10, new[]{9}, false), the result is not expected.

@maraca and Juniver Hazoic thank you very much for your comments. I will examine your comments in detail, when I find time; today, I hope.

@JuniverHazoic You made valid points.

@JuniverHazoic Yes you are right, the algorithm never returns 0, it fails when the amount is smaller than the smallest denomination and you are rounding down. The simplest fix for that is to initialize retval with 0 (always).

@JuniverHazoic The size needed when rounding down is amount + 1 and when rounding up it is more difficult. If you have a denominator d > amount then d + 1 is enough (but following bound is maybe better), otherwise you can estimate it by the lowest denomination (amount + dLow - 1) / dLow * dLow + 1) (rounding amount up by lowest denomination).

I have updated code. Thank you very much for finding the bugs. I hope its ok now.

Perfect! Couldn't find any test which might fail this. so far this has been through testing quite comfortably. Appreciate your efforts. Thanks & Cheers!

@PravinDeshmukh thank you very much. I had good time thinking about this problem. If you find any other bugs about this code, please send the inputs.

I am slightly disappointed. You didn't even incorporate the improvements mentioned in the comments. amount + denomsMax * 2 + 1 is a really really bad upper bound. (amount + dLow - 1) / dLow * dLow + 1 is so much better. Also no early exit possible, like my algo does with the modulo. My algorithm would outperform this one easily. @PravinDeshmukh

@maraca I have no idea how your improvements about upper bound would work. In my tests this upper bound was the min I could get. You are wellcome to add your code to your answer so that I can test-compare and see what I am doing wrong.

@Koray we are looking for the smallest number >= amount which we know can be achieved, everything above that can be discarded. So if we round the amont by the smallest denomination upwards we get an achievable number, which is <= amount + dMin - 1, so a much smaller array has to be constructed than when using amount + dMax * 2 + 1. Of course my algorithm will not always be faster, but in general... (still +1).

@maraca It would be a nice challenge for me, really. I want to see your code. I cannot understand everything you write and write your algorithm's code. If you are disapointed because you didn't got the reputation of the bounty (don't be offended, I'm sure your are not, but if you are) I would be happy to give you mine if there is a way to do so. This was just for fun for me. Now I will re-read your comments, and review my code.

@maraca I think I can convert Java code. And please add the test code so that I could compare. It's really hard to me to understand English.

@Koray ok I will try, I forgot rounding direction {up, down} so double the test cases.

@maraca if I use 'BitArray ba = new BitArray(amount + denoms.Min() - 1);' I have to put an extra if after 'int = v1+v2;' which would be slower. And can you add the test code please, I could'nt understand yout test case clearly. What are denoms array, amout valuse, and the combinations? :) sorry.

@Koray changing queue to stack improves the times because of the order in which the numbers are tested (you will first generate all multiples of dMax + all the other denominators, so you will advance in steps of dMax until the number becomes bigger than amount, then you will take dMax one less time + the 2nd highest denominations (now on top of stack) and add all denominations to it... because you add to end of stack if you find something new it gets really complicated to follow, but you are going back and forth again (in terms of amount of current valid number) until the stack is empty.

*top of stack, not end. I think it should only make a (potentially big) difference if the amount can be built, otherwise it should be the same.

@maraca Thanks Guys, you two took it to next level in terms of optimizations. But the thing is, I have seperate algorithm, a recursive function, which checks if amount is achievable or not. If it isn't - only then RoundAmount is called. So I'm not really worried of scenario where amount is achievable and still passed to RoundAmount function (It's a nice addition though) So Edit 4 was OK for me :)

@Koray Please check solution update on my question. Notice the code section // Set Lowerbound I'm hoping to hear a feedback from you, also expecting your suggestions

@PravinDeshmukh I cannot imagine imagine that your recursive function (backtracking?) is performing very good, just because the problem of finding out if that number can be built has at least the complexity of all the dp solutions O(a*d). So if you are checking that you do the same work at least twice. Also for gcd > 1 you go way further than you have to. I highly recommend to call the rounding function directly without any checks before.

@maraca Yes, you make absolute sense. I should only be calling RoundAmount. The only reason that IsAchievable function separately written is that it can be used somewhere else as well.

@Koray edit 7 is quite impressive, I did some tests and incorporated your ideas into my algorithm to get the ultimate hybrid between the two! (Edited my answer).