# Solving the water jug problem

While reading through some lecture notes on preliminary number theory, I came across the solution to water jug problem (with two jugs) which is summed as thus:

Using the property of the G.C.D of two numbers that GCD(a,b) is the smallest possible linear combination of a and b, and hence a certain quantity Q is only measurable by the 2 jugs, iff Q is a n*GCD(a,b), since Q=sA + tB, where:

``````n = a positive integer
A = capacity of jug A
B=  capacity of jug B
``````

And, then the method to the solution is discussed

Another model of the solution is to model the various states as a state-space search problem as often resorted to in Artificial Intelligence.

My question is: What other known methods exist which models the solution, and how? Google didn't throw up much.

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An amazing and amusing approach (for 3 jugs) is through barycentric coordinates (really!), as described at the always brilliant website Cut-the-Knot: Barycentric coordinates: A Curious Application.

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Strictly for 2 Jug Problem

``````Q = A * x + B * y
``````

Q = Gallons you need.

Note: The Q must be a multiple of Gcd(A,B) else there is no solution. If Gcd(A,B) == 1, There is a solution for Any Q.

1) Method 1 : Extended Euclid's Algorithm will solve it faster than any Graph Algorithm.

2) Method 2: Here's a Naive Approach. (note, this can throw 2 solutions, You'll have to choose which is shorter)

The Problem in question can be simply solved by `repeatedly` Fill from one bucket A to another bucket B (order doesnt matter) until it fills up with the amount you want...ofcoz, when a bucket fillsup, you empty it and continue.

``````    A = 3, B = 4 and Q = 2
``````

Repeatedly Fill A->B

``````    A B
######
0 0
4 0
1 3
1 0
0 1
4 1
2 3 <-Solution
``````

Lets try and observe what happens if we go the other way round, Fill B->A

``````A  B
#####
0  0
0  3
3  0
3  3
4  2 <- Solution
``````

In this case filling B->A gives us the goal state faster than A->B

Generic N Jugs Here's an interesting paper

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Deciding which one to fill to first: does this - "IF(Q is b/w A AND B) THEN max(A, B) ELSE min(A, B)" help actually? – amar Mar 21 '13 at 2:22
@AMAR, I don't think so. Can't say for sure. Do you have any proof? – st0le Mar 21 '13 at 15:43
Nope. It was a question. I had tried it in a problem with hit and trial to smaller 5-6 pairs. Not sure if it works for all. – amar Mar 28 '13 at 11:51
Is it possible to have jugs with such volumes that it takes same number of steps for both the approaches: filling A first and filling B first?? – user1414696 Jul 9 '15 at 7:21

This type of problem is often amenable to dynamic programming techniques. I've ofetn seen this specific problem used as an example in operations research courses. One nice step-by-step description is here.

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The search space method is what I would've suggested. I made a program to solve generic water jugs problems using a BFS. Could send it to you if you wish.

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Yes, do share here please. – amar Mar 21 '13 at 2:24

I encountered this problem during one of my studies. As you, and as st0le said here, I found as answer to the problem the Extended Euclide's algorithm. But this answer do not satisfied me, because I think it's a quantitative answer, not a qualitative one (that is, the algorithm does not say what step to take to reach the result).

I think I found a different solution to the problem that always reach the result with the minimum number of steps.

Here it is:

1. Check problem's feasibility:
• Q is a multiple of the MCD(A,B);
• Q is <= max(A,B).
2. Choose the service jug (that is, the one you will refill with the pump). Supposing A > B (you can easily find which jug is the bigger one):

``````if(Q is multiple of B)
return B

a_multiplier = 1
b_multiplier = 1
difference = A - B
a_multiple = A
b_multiple = B
while(|difference| differs Q)
if b_multiple < a_multiple
b_multiple = b_multiplier + 1
b_multiple = b_multiplier * B
else
a_multiple = a_multiplier + 1
a_multiple = a_multiplier * A

difference = a_multiple - b_multiple

if(difference < 0)
return B
else
return A
``````
3. start the filling process:

• fill with the pump the service jug (if empty)

• fill the other jug using the service one

• check fullness of the other jug and, in case, empty it

• stop when the bigger jug contains Q

Below you find a very naive implementation of the algorithm in c++. Feel free to reuse it, or improve it as you need.

``````#include <cstdio>
#include <cstdlib>
#include <cstring>

unsigned int mcd(unsigned int a, unsigned int b) {
// using the Euclide's algorithm to find MCD(a,b)
unsigned int a_n = a;
unsigned int b_n = b;
while(b_n != 0) {
unsigned int a_n1 = b_n;
b_n = a_n % b_n;
a_n = a_n1;
}
return a_n;
}

unsigned int max(unsigned int a, unsigned int b) {
return a < b ? b : a;
}

unsigned int min(unsigned int a, unsigned int b) {
return a > b ? b : a;
}

void getServiceJugIndex(unsigned int capacities[2], unsigned int targetQty, unsigned int &index) {
unsigned int biggerIndex = capacities[0] < capacities[1] ? 1 : 0;
unsigned int smallerIndex = 1 - biggerIndex;
if(targetQty % capacities[smallerIndex] == 0) {
// targetQty is a multiple of the smaller jug, so it's convenient to use this one
// as 'service' jug
index = smallerIndex;
return;
}

unsigned int multiples[2] = {capacities[0], capacities[1]};
unsigned int multipliers[2] = {1, 1};
int currentDifference = capacities[0] - capacities[1];
while(abs(currentDifference) != targetQty) {
if(multiples[smallerIndex] < multiples[biggerIndex])
multiples[smallerIndex] = capacities[smallerIndex] * ++multipliers[smallerIndex];
else
multiples[biggerIndex] = capacities[biggerIndex] * ++multipliers[biggerIndex];

currentDifference = multiples[biggerIndex] - multiples[smallerIndex];
}

index = currentDifference < 0 ? smallerIndex : biggerIndex;
}

void print_step(const char *message, unsigned int capacities[2], unsigned int fillings[2]) {
printf("%s\n\n", message);
for(unsigned int i = max(capacities[0], capacities[1]); i > 0; i--) {
if(i <= capacities[0]) {
char filling[9];
if(i <= fillings[0])
strcpy(filling, "|=====| ");
else
strcpy(filling, "|     | ");
printf("%s", filling);
} else {
printf("        ");
}
if(i <= capacities[1]) {
char filling[8];
if(i <= fillings[1])
strcpy(filling, "|=====|");
else
strcpy(filling, "|     |");
printf("%s", filling);
} else {
printf("       ");
}
printf("\n");
}
printf("------- -------\n\n");
}

void twoJugsResolutor(unsigned int capacities[2], unsigned int targetQty) {
if(capacities[0] == 0 && capacities[1] == 0) {
printf("ERROR: Both jugs have 0 l capacity.\n");
return;
}
// 1. check feasibility
//  1.1. calculate MCD and verify targetQty is reachable
unsigned int mcd = ::mcd(capacities[0], capacities[1]);
if ( targetQty % mcd != 0 ||
//  1.2. verify that targetQty is not more than max capacity of the biggest jug
targetQty > max(capacities[0], capacities[1])) {
printf("The target quantity is not reachable with the available jugs\n");
return;
}
// 2. choose 'service' jug
unsigned int serviceJugIndex;
getServiceJugIndex(capacities, targetQty, serviceJugIndex);
unsigned int otherJugIndex = 1 - serviceJugIndex;
unsigned int finalJugIndex = capacities[0] > capacities[1] ? 0 : 1;
// 3. start fill process
unsigned int currentFilling[2] = {0, 0};
while(currentFilling[finalJugIndex] != targetQty) {
// 3.1 fill with the pump the service jug (if needed)
if(currentFilling[serviceJugIndex] == 0) {
currentFilling[serviceJugIndex] = capacities[serviceJugIndex];
print_step("Filling with the pump the service jug", capacities, currentFilling);
}

// 3.2 fill the other jug using the service one
unsigned int thisTimeFill = min(currentFilling[serviceJugIndex], capacities[otherJugIndex] - currentFilling[otherJugIndex]);
currentFilling[otherJugIndex] += thisTimeFill;
currentFilling[serviceJugIndex] -= thisTimeFill;
print_step("Filling the other jug using the service one", capacities, currentFilling);
// 3.3 check fullness of the other jug and, in case, empty it
if(currentFilling[otherJugIndex] == capacities[otherJugIndex]) {
currentFilling[otherJugIndex] = 0;
print_step("Empty the full jug", capacities, currentFilling);
}
}
printf("Done\n");
}

int main (int argc, char** argv) {
if(argc < 4)
return -1;
unsigned int jugs[] = {atoi(argv[1]), atoi(argv[2])};
unsigned int qty = atoi(argv[3]);

twoJugsResolutor(jugs, qty);
}
``````

I don't know if there is any mathematical concept behind the process I described to choose the right jug to minimize the number of needed steps, I use it as an heuristic.