# Find the amount of water in ith cup in a pyramid structure?

This question was asked in a forum. Any suggestions?

There is a pyramid with 1 cup at level , 2 at level 2 , 3 at level 3 and so on.. It looks something like this

``````  1
2 3
4 5 6
``````

every cup has capacity C. you pour L liters of water from top . when cup 1 gets filled , it overflows to cup 2,3 equally, and when they get filled , Cup 4 and 6 get water only from 2 and 3 resp but 5 gets water from both the cups and so on. Now given C and L .Find the amount of water in ith cup ?

-
What have you tried? –  Louis Wasserman Aug 1 '12 at 17:40
My preliminary steps to solve this problem: 1. If given a cup index i (example 4) how to find at which level this cup is located? 2. Find the number of source for the ith cup 2. Find how much input water is left after filling each level? –  AKh Aug 1 '12 at 17:41
Is what you initially tried not working? –  Dennis Meng Aug 1 '12 at 17:49
Did you have a look at flow networks? en.wikipedia.org/wiki/Flow_network –  Baz Aug 1 '12 at 17:49
Seems like there is a link to Paskal's triangle –  oleksii Aug 1 '12 at 17:50
show 1 more comment

Each glass has an incoming flow, an amount of water in the glass, and maybe some outgoing flow (overflow).

If each glass can contain 1 unit of water, and you pour 15 units of water, you get the following (overflow amount in parenthesis):

``````Incoming flow = 15, capacity = 1

Level 1:               1(14)
Level 2:           1(6)     1(6)
Level 3:       1(2)     1(5)     1(2)
Level 4:    1(1)   1(2.5)  1(2.5)    1(1)
Level 5:   1  1(0.75)  1(1.5)  1(0.75)   1
Level 6:  0 0.375 1(0.125) 1(0.125) 0.375 0
Level 7: 0 0  0.0625   0.125    0.0625   0 0
``````

The incoming flow to the first level is L. The incoming flow from glass `c` on level `r` is `Fin(c, r)`, and could be written as:

``````Fin(0, r) = 0
Fin(r+1, r) = 0
Fin(1, 1) = L
Fin(c, r) = Fout(c - 1, r - 1)/2 + Fout(c, r - 1)/2
``````

The amount of water in that glass is:

``````A(c, r) = Min(C, Fin(c, r))
``````

And the outgoing flow is:

``````Fout(c, r) = Max(0, Fin(c, r) - C)
``````

I don't see any obvious formula for evaluating `A(c, r)` without doing it recursively.

To get from an index to a row and glass position, you can do:

``````index = r*(r-1)/2 + c

r = floor((1 + sqrt(8*index - 7))/2)
c = index - r*(r-1)/2

``````
-
how did you come up with formula for r? Basically we have one formula: index = r*(r-1)/2 +c with 2 unknowns: r and c. How do you get r from there? –  Maggie Sep 14 '13 at 13:56
@Maggie If you set `c` to 1, you get the index of the first glass on each row. (`index = r(r-1)/2+1`) If you solve that for `r`, you get the formula for the row given any index. Though if it isn't the first glass on the row, you will have a decimal part you don't need. So you wrap it with `floor()`. –  Markus Jarderot Sep 14 '13 at 14:30
Thanx, I get it now. You algorithm needs some slight modifications, but otherwise: great solution and great explanation! –  Maggie Sep 14 '13 at 14:47

If you model the pyramid into a graph, the problem converts into a breadth first search. As you traverse each node, get its neighbours and store their overflow quantity. If a neighbour was already retrieved by a previous node (this will happen in the case of 5 node because node 2 and node 3 have an edge to it), you will have to update the overflow based on its capacity and what's already been filled (by node 2; assuming node 2 was traversed before node 3).

-

Some ideas: (1) The important is knowing which two cups are inputs to the ith cup. (2) The important is know the Minimum Lleft that will bring you water from your left side and what level Lright will bring you water from your right side (3) So you need to know which cups provide water to cup ith. This is easier, thinking quick, if you start numbering from 0. Cup ith will fill (i-1)*2+1 and i*2, what means that cup kth will receive water from (for k%2=1) (k-1)/2 and (k+1)/2 (for k%2=0) k/2 and k/2+1 (4) With that you should check that for any L you will calculate the difference L-Lleft and L-Lright. When positive the water provided is the result of dividing by 2^n the calculated difference, where n is the level of the cup.

-
Can please elaborate? –  AKh Aug 6 '12 at 0:18

The pascal triangle solution for calculating binomial coefficient can be used to solve this problem. We just need to tweak the algorithm a little bit and instead of calculating binomial coefficients, we calculate the water level. Given ith cup, we calculate level and index to find out where the cup sits in the triangle.

The cups are modelled as

``````    0         Level 1
1   2       Level 2
3   4   5     Level 3
``````

getIndex() and getLevel() returns the index and level. Index and Level starts at 1.

``````public static int getIndex(int i) {
int totalNodes = i + 1;
double d = (-3 + Math.sqrt(9 - 8*(1-totalNodes)))/2;
int level = (int)Math.floor(d);
int total = ((level+1)*(level+2))/2;
int index = 0;
if(total==totalNodes) index = level;
else{
level++;
index = totalNodes - total - 1;
}

return ++index;
}

public static int getLevel(int i) {
int totalNodes = i + 1;
double d = (-3 + Math.sqrt(9 - 8*(1-totalNodes)))/2;
int level = (int)Math.floor(d);
int total = ((level+1)*(level+2))/2;
int index = 0;
if(total==totalNodes) index = level;
else{
level++;
index = totalNodes - total - 1;
}

return ++level;
}
``````

k is kth cup starting at 0. C is cup capacity, L is total water.

``````public static double getWaterLevel(double C, double L, int k) {
int n = getLevel(k);
int index = getIndex(k);
double[] water = new double[index+1];

water[1] = L;

for(int i = 2; i <= n; i++)
{
boolean overflowed = false;

for(int j = Math.min(i, index); j > 0; j--) {
double over = 0;
if(water[j]>C) over = (water[j]-C)/2;
if(water[j-1]>C) over += (water[j-1]-C)/2;

water[j] = over;

if(!overflowed && over!=0) overflowed=true;
}

if(!overflowed) break; // no more overflow. stop
}

return water[index] > C ? C : water[index];
}
``````
-

Here is a simple and comprehensible implementation:

``````public class main {
static float total_water = 50;
static int N = 20;
static glass[][] pyramid = new glass[N][N];

public static void main(String[] args) {
build_pyramid();
pour_water(0, 0, total_water);
print_pyramid();
print_total_water_stored();
}

private static void print_total_water_stored() {
float total = 0;
for (int i = 0; i < N; i++) {
for (int j = 0; j <= i; j++)
total += pyramid[i][j].filled;
}
System.out.println("total water stored= " + total);
}

private static void pour_water(int row, int col, float water) {
if (water >= (pyramid[row][col].capacity - pyramid[row][col].filled)) {
water -= (pyramid[row][col].capacity - pyramid[row][col].filled);
pyramid[row][col].filled = pyramid[row][col].capacity;
pour_water(row + 1, col, water / 2);
pour_water(row + 1, col + 1, water / 2);
} else {
pyramid[row][col].filled += water;
}
}

public static void build_pyramid() {
for (int i = 0; i < N; i++) {
for (int j = 0; j < N; j++)
pyramid[i][j] = new glass(1);
}
}

public static void print_pyramid() {
for (int i = 0; i < N; i++) {
for (int j = 0; j <= i; j++)
System.out.print(pyramid[i][j].filled + " ");
System.out.println();
}
}
}

class glass {
float capacity;
float filled;

glass(float cap) {
capacity = cap;
filled = 0;
}
}
``````
-