Suppose I have K arrays of different sizes:

A1 = [X1, X2, X3 .... Xn]

A2 = [Y1, Y2, Y3 .... Ym] .. and K-2 more such arrays.

All arrays contain elements of same data type.

And then I have a function, F = f(Xn, Ym,...K-2 more such elements). The function basically requires exactly one element from each array, and my objective is to find a maximum value for this function. And also, which all elements make it maximum.

Important Info

Nature of function: All arrays are sorted (descending order). And first element in each array provides the best solution to the function (maximizes the function within its peer set). So, the ideal case would be picking up the first element from each array. But there is a constraint, which I can best describe as:

Suppose these elements are numbers, then I have to keep their total sum less than some constant value. So the constraint is:

Xn + Ym + ... and others <= Constant

EDIT: As @Spektre asked, the function is exponential in nature.

How can I solve this without brute force? Any pointers on solutions to similar existing problems would also help!

I understand divide & conquer, dynamic programming and linear programming upto the extent taught in Introduction to Algorithms-CLRS. So, if I can apply any of those, I am not able to figure that out with respect to this problem.

EDIT: An example function and dataset for the above problem:

Maximize: F = ax + by + cz

The above function was not very accurate representation of original problem.

UPDATE: Example function updated

F = xh(x)g(x) + yh(y)g(y) + zh(z)g(z)

h and g are non decreasing linear function of x/y/z. Range of h varies from 1 to 2. Range of g varies from 1 to 50. Domain of x,y,z is positive real numbers with average value in millions (consider 10 million as maximum for the example case ahead).

Example dataset (x,y,z are in millions):

x is in [20,18,17,15,12,9,8,5]

y is in [26,21,16,13,6,3,2,1]

z is in [45,42,41,40,12,3,2,1,0]

So the arrays contain random but sorted values.

And a,b,c > 1 So take a = 2, b=3 and c=4 for instance making the function as:

F = 2x + 3y + 4z

The constraint: x + y + z <= 50

I've updated the example function after Spektre's solution, but that algorithm should still be valid as function is still an increasing function of x,y,z.

Example code of h(), g() and arrays (in JavaScript)

function h(a) {
    var h = 1 + 0.0000001 * a;
    return h;

function g(a) {
    var g = (50 / 10000000) * a;
    return g;

function f(x, y, z) {
    var f = x * Math.pow(h(x), g(x)) + y * Math.pow(h(y), g(y)) + z * Math.pow(h(z), g(z));
    return f;

var maxSum = 5000000;

function isSumLessThanMax(x, y, z) {

    if (x + y + z <= maxSum) {
        return true;
    else {
        return false;

var x = [2000000, 1800000, 1700000, 1500000, 1200000, 900000, 800000, 500000];

var y = [2600000, 2100000, 1600000, 1300000, 600000, 300000, 200000, 100000];

var z = [4500000, 4200000, 4100000, 4000000, 1200000, 300000, 200000, 100000, 0];
  • if it requires exactly one element, then why does your signature is f(XAn, XBm ...)? Apr 11, 2016 at 9:35
  • 1
    @Anmol need to go away from PC for a time will be back. The main idea is sort the array by their significance to output value. and then iteratively construct possible solutions only around the sum treshold remembering the best solution. Do you have example function and dataset for testing?
    – Spektre
    Apr 11, 2016 at 10:26
  • Your presentation is extremely confusing -- you say "Suppose I have n arrays of different sizes", and then you go on to specify that A (presumably the first of these arrays) has exactly n elements! Did you really mean that? Separately, you specify the function as F = f(Xn, Ym ...) -- it's not clear from this if the function takes n elements or n arrays. Please fix these problems and I'll undo my -1. Apr 11, 2016 at 12:39
  • In the meantime, are the numbers in these arrays all relatively small integers, and is the function F always a sum having a term for each of the k arrays? If both of these things are true then there's a nice DP for solving it optimally in O(nkT) time, where T is the maximum value that can be obtained by adding together a single number from each of the k arrays, and each array has size <= n: Let g(i, x) be the maximum value that can be achieved on the subproblem that considers just the first i (i <= n) arrays, under the constraint that the chosen terms sum to at most x (x <= your threshold). Apr 11, 2016 at 12:46
  • If f always increases(or decreases) and one variable doesn't depend on another variable (f don't have something like x/y). x = 0, y = 0, z = 0, f = 3 x = 1, y = 0, z = 0, f = 4, x_rate = 1 x = 0, y = 1, z = 0, f = 5, y_rate = 2 x = 0, y = 0, z = 1, f = 6, z_rate = 3 (or we can start from 1, or take 10 step - for example use 10 and 20 values to find rates) And now we can more effecienly get X,Y,Z...s. Just find maximum available value for array with max rate etc. Yeah, it's not completly, can be variants where this algorithm does not work.
    – ostapische
    Apr 11, 2016 at 13:15

4 Answers 4


The example data you provided so far offers some opportunities for optimization:

First of all, rather than comparing x's, y's, and z's, use the intermediate calculation, x*h(x)^g(x), or a pre-calculated table-lookup of those values. Looking at rounded and proportionally reduced output for an easier visual, x / 100000 and Math.round(x * Math.pow(h(x), g(x)) / 100000), we see that some values are more than an order of magnitude greater than others.

xs = { 20, 18, 17, 15, 12,  9,  8, 5}
     {124, 80, 65, 43, 24, 13, 11, 6}

ys = { 26,  21, 16, 13, 6, 3, 2, 1}
     {525, 155, 52, 29, 7, 3, 2, 1}

zs = {    45,    42,    41,    40, 12, 3, 2, 1}
     {192306, 66268, 46965, 33467, 24, 3, 2, 1}

Group variables and their intermediate functional results as tuples according to a calibrated choice of ranges of magnitude k. For example, using our reduced overview, let's say k = 500:

[385 * k]    [133 * k]   ...  [2 * k]
(45,192306)  (42,66268)  ...  any x or y

It makes no sense to try different possibilities for zs when we have one value that's more than 150 times greater than any x or y. Once we've removed the larger variable, our search is now: maximize f'(x,y), where x + y <= 50 - 45).

If you foresee data results with extreme differences in magnitude, because f is actually linear in the intermediate calculation, call it i(x), you could implement a calibration at each round of elimination, until faced with choices within the same order of magnitude, where you would use brute-force with a greedy early exit.

  • Thank you! I'll try this and update here. Btw, though calibration is a very simple operation, we can do it without any explicit calibration, right? Just take a magnitude k, and see if f(a1)/f(a2) < k, else reject a2. Was there any other intention of calibration? Apr 12, 2016 at 16:44
  • @Anmol What I meant by calibration is establishing a relevant magnitude that could illuminate an obvious choice (like 500 in my example). I guess the maximum few for each array could help determine that. Apr 12, 2016 at 16:54
  • IOW 1. discard all prefixes above the constraint's total from the arrays; 2. pick the biggest head below the current total; and 3. reduce the total by the head's value; 4. goto 1. This directly finds the answer. This because f (x,y,z) is actually = v (x) + v (y) + v (z) with monotonically increasing v. So we get a sorted tuple as the result. If there were equals to pick, must pick such that leaves the largest yet not picked on the rest of the arrays. For the last array, pick the largest element not above the remaining total. At each step, if impossible to pick, backtrack.
    – Will Ness
    Apr 13, 2016 at 9:17
  • (addition to 2. above: put aside the picked-from array of course). ... backtrack, discard the picked element, and try again. This happens when 45 is picked (no further pick possible, as ~(5 < 50-45) ). So 42 is the next possible pick (but it could be from some other array, too). This suggest a lazy functional implementation, coded with the usual list's flatmap, and order-preserving merge used instead of plain append in the equal picks cases, as one possibility. Another is to maintain a candidates-set of arrays to pick from, winnowing it down by examining the next elements in each.
    – Will Ness
    Apr 13, 2016 at 10:04
  • @WillNess would it be useful to keep a sum of minimums, that way avoid picking 45? Also, would it make a difference if the data is a 15-tuplet as the OP suggested, rather than a triple? Apr 13, 2016 at 11:36

Well now it is much more clearer. As the max sum is applied to input variables not the output values of f then it is much more simple. So here first simple approach in C++:

double MaxSum = 50.0;
double X[] = { 20.0,18.0,17.0,15.0,12.0,9.0,8.0,5.0 };     int Nx=sizeof(X)/sizeof(double);
double Y[] = { 26.0,21.0,16.0,13.0, 6.0,3.0,2.0,1.0 };     int Ny=sizeof(Y)/sizeof(double);
double Z[] = { 45.0,42.0,41.0,40.0,12.0,3.0,2.0,1.0,0.0 }; int Nz=sizeof(Z)/sizeof(double);
double f(double x,double y,double z)
    return pow(2.0,x)+pow(3.0,y)+pow(4.0,z);
void solve()
    int cnt;    // just tested solutions counter
    int x,y,z;
    bool init;
    double sum,a,aa,xx,yy,zz,x1,y1,z1;
    // near max sum only
    init=true; sum=0.0;
    for (x=0;x<Nx;x++) { x1=X[x]; sum+=x1; if (sum<=MaxSum)
    for (y=0;y<Ny;y++) { y1=Y[y]; sum+=y1; if (sum<=MaxSum)
    for (z=0;z<Nz;z++) { z1=Z[z]; sum+=z1; if (sum<=MaxSum)
        cnt++;                                          // update counter for debug purposes
        a=f(X[x],Y[y],Z[z]);                            // compute actual solution
        if ((init)||(aa<a)) { init=false; aa=a; xx=x1; yy=y1; zz=z1; }  // remeber the best one
    if (sum          <=MaxSum) z=Nz; sum-=z1; }
    if (sum+Z[0]     <=MaxSum) y=Ny; sum-=y1; }
    if (sum+Z[0]+Y[0]<=MaxSum) x=Nx; sum-=x1; }
    // here:
    // cnt is number of tested solutions
    // Nx*Ny*Nz is number of all possibilities
    // found solution aa=f(xx,yy,zz)


[   0.027 ms]Solution 19342813113834066800000000=f(5,3,42) tested 64 of 576 combinations

The idea is test only those combinations which sum is near MaxSum constraint. As you can see the loops are almost identical so you can nest as many of them as you want. If you got variable count of the input arrays then you can use


  1. The program basically loops through "all possiblities" from the biggest one to lowest.

  2. Then test only if the target sum is smaller or equal to MaxSum.

  3. after that if partial sum is small enough that even if used the biggest values from unused arrays still fits into the MaxSum stop that loop to avoid un-necessary iterations. This effectively cut down the complexity from brute-force O(n^k) to O(g(n)^k) where n is average array size, k is the number of arrays and g(n) is average number of tested values per array (depends on the MaxSum,n,k and array values. In your test case g(n)=2)


Now if you got background information about the function f and know that some variables are more significant then others (in your test case the Z array) Then you can limit that variable on first few biggest values that still fits into that limit ignoring the small values of that array. This can be done recursively on other arrays too but VERY CAREFULLY so you do not miss the actual solution.

  • @fjardon I would be interested in the reason too but there is almost none chance for such response downvoters usually down vote (sometimes even not read fully) and go away for good. The more responsible usually add comment with what is wrong.
    – Spektre
    Apr 11, 2016 at 13:04
  • @Spektre Thanks a lot. I am still comprehending it (trying it in Java). Apr 11, 2016 at 13:08
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    @Anmol are you sure this code formatting is better in this case? You do not see the symmetry of the indexes now so clear or it is just me?
    – Spektre
    Apr 11, 2016 at 14:31
  • 1
    @Anmol I rolled back to edit 4 (before the formatting changes
    – Spektre
    Apr 11, 2016 at 14:44
  • 1
    @WillNess I've updated the function and also put a pastebin. The domain and range of the data, and nature of function are now like real data. Apr 12, 2016 at 6:03

You may be interested in greedy algorithms. That's simple but useful idea. First my thought when I see such problem is try to approach using this technique.

Another approach is method of gradient descent.


Dynamic programming is a technique that will work well in your case. Since you know a bit more about your data -- namely that the lists are sorted -- you can optimize the search to not go too far down a sub-optimal path.

This is not a quick answer with pseudocode. I highly recommend watching MIT's algorithms course in its entirety, but Lectures 19-22 relate to dynamic programming. Here is the playlist on youtube.

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