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I have a problem with one algorithm.

There are given n boxes, each one has fixed weight and strength (both given in kg). Box's strength tells us what is the maximum weight it can bear. We have to form the highest pile of given boxes (each of them has the same height). You should propose an algorithm that will always give an optimal solution, which is the longest sequence of k boxes (k <= n).

Well, that is a solution I have already figured out:

  1. Firstly, we sort all of the boxes by their weight (heaviest goes at the bottom) and form a pile of them.
  2. Secondly, we sort that pile by strength (the strongest goes at the bottom).
  3. Then, for each box, starting from the bottom, we try to pull it down to the bottom as long as its strength enables it.
  4. In the end, we have to figure out how many boxes must be removed from the top, which cause the situation that some boxes below carry much more weight than they could.

It seems that this algorithm works quite well, but I am not sure whether it gives always the optimal solution - probably it doesn't. I have been wondering about the dynamic solution, similar to the solution for knapsack problem, but I don't feel certain if it can be solved this way. There's seemingly no optimal substructure for my problem.

Thank you in advance for any help. :)

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Similar to:- stackoverflow.com/questions/6893041/… –  QuentinUK Aug 11 '11 at 17:05

3 Answers 3

In default of a cleverer answer, I would try branch and bound, building the tower from the bottom up. Given a partially built tower, you can put a bound on the height of the completed tower. If the partially built tower can sustain an extra weight of X, you can work out how many boxes you could add before the extra weight is more than X - just pick out remaining boxes in order of increasing weight, ignoring their strength. If there are boxes of zero weight, put them aside in a pre-processing stage and shove them on the top later. A less accurate bound would be X divided by the weight of the lightest unused box.

Given such a bound, use backtracking search to build your tower, discarding all partial answers which could not possibly be extended to produce a higher tower than the best answer found so far.

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Here's an algorithm in Javascript

// Array of boxes [weight,strength] 
var AB=[[1,2],[3,4],[7,3],[1,10],[10,1],[4,8], [1,10]];

// for each item make set of items Potentially Above
// can leave this out and just say all others are Potentially Above
var w=0,s=1;// indices for weight, strength 
for(var i=0; i<AB.length;i++){
    var B = AB[i];
    B.pa=[];// array of potentially above boxes
    for(var j=0; j<AB.length;j++){
        if(i!=j && AB[j][w]<=B[s]){// not the same box and box B can support it
            B.pa.push(j);// at to array of potentially above boxes
// Display the weights that each box can support
for(var i=0; i<AB.length;i++){
    var B = AB[i];
    c("Item"+i+" Weight="+B[w]+", Strength="+B[s]+", Weights= "+B.pa );

var stacksMax=[];
var heightMax=0;

var stack = [];// height of boxes in stack
var height=0;
var canCarryWt=1e99;//Infinity;// the ground can carry anything
// Try each box in turn as the lowest  box
for(var i=0; i<AB.length;i++){
    stack = Array(AB.length);// array of heights

// Test a box for the boxes it can support (recursive)  
function testBox(i){
    if(!stack[i]){// avoid cyclic 
        var B=AB[i];
        if(canCarryWt>=B[w]){// cadd add this box
            var couldCarryWt=canCarryWt;
            canCarryWt = Math.min(canCarryWt-B[w],B[s]); 

            // test sub items
            for(var j=0;j<B.pa.length;j++){

             // test height for being the highest
                 stacksMax = [];// clear all the stacks 
                 heightMax = height;
                 // add a copy of stack to stacksMax
              // reset values

// Sort and Display
var topFirst=true;
var sortedStack=Array(heightMax)
for(var k=0; k<stacksMax.length; k++){
    // Sort items 
     for(var i=0;i<stack.length;i++){
            if(topFirst){// nb heights are 1..
                 sortedStack[stack[i]-1]=i;// -1 for 0array
    // Display 
    var weightSupported=0;
    for(i=0;i<heightMax;i++) {
        var B= AB[sortedStack[i]];
    var status = (B[s]>= weightSupported)?"OK":"ERROR";
        c("Height"+i+" Box="+sortedStack[i] + ",["+B[w]+","+B[s] + "] "+status);
// Display functions
function c(s){
    // this depends on your environment
function drawHorizRule(){  
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You can solve this using dynamic programming.

weight[i] := weight of box i
strength[i] := strength of box i
N(w,b) := maximum number of boxes you can stack <= weight w with box b on bottom

Notice that to calculate N(w,b), you put box b on the bottom. Then you calculate the maximum number of boxes you can put on top of it. Well this is easily done if you loop through the possible boxes that can be placed above it.

You then have the recurrence relation:

N(w,b) = 1+max{ N( min(w-weight[b],strength[b]),i ) }

Your answer is then: max{ N(W,b) } where W=sum(weight[i]).

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Does the answer should be max{N(W,b)}, not min{N(W,b)}, doesn't it? And one more thing. N(w,b) is the maximum number of boxes I can stack, which total weight is less than or equal w and on the bottom of them is b box? –  RobertMarianski Aug 11 '11 at 18:42
1. Oh sorry, that was a typo. Nice catch. 2. Yes that is correct. –  tskuzzy Aug 11 '11 at 18:44
Do I take it that this assumes that there is effectively an infinite supply of boxes of each possible type? It seems to me that if you have to keep track of how many boxes of each type are still available for use, the state space of a dynamic programming approach will be unmanageable. –  mcdowella Aug 11 '11 at 18:55
@tskuzzy: Well, it is quite what I've thought about if consider it as a dynamic problem, so fill the table like for knapsacks. But it is said in the body of the problem that we have to give a sequence of boxes (I suppose that it could be numbers as well as pairs of weight and strength) that form a pile, not just the maximum number we can stack from given set. –  RobertMarianski Aug 11 '11 at 18:59
@mcdowella: No, there are finite number (equal n) of boxes and there is nothing like a box type. Some boxes could have the same weight or strength (or even both) as well as there could be not even two same boxes. –  RobertMarianski Aug 11 '11 at 19:16

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