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:

- Check problem's feasibility:
- Q is a multiple of the MCD(A,B);
- Q is <= max(A,B).

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
```

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.

I hope this can help you.