# What algorithm to use to determine minimum number of actions required to get the system to "Zero" state?

This is kind of more generic question, isn't language-specific. More about idea and algorithm to use.

The system is as follows:

It registers small loans between groups of friends. `Alice` and `Bill` are going to lunch, Bill's card isn't working, so Alice pays for his meal, \$10.
The next day `Bill` and `Charles` meet each other on a railway station, Chales has no money for ticket, so `Bill` buys him one, for \$5. Later that day `Alice` borrows \$5 from `Charles` and \$1 from `Bill` to buy her friend a gift.

Now, assuming they all registered that transactions in the system, it looks like this:

``````Alice -> Bill \$10
Bill -> Alice \$1
Bill -> Charles \$5
Charles -> Alice \$5
``````

So, now, only thing that needs to be done is `Bill` giving `Alice` \$4 (he gave her \$1 and `Charlie` transferred his \$5 to `Alice` alredy) and they're at the initial state.

If we scale that to many diffrent people, having multiple transaction, what would be the best algorithm to get as little transactions as possible?

This actually looks like a job that the double entry accounting concept could help with.

Your transactions could be structured as bookkeeping entries thus:

``````                          Alice  Bill  Charles  Balance
Alice   -> Bill    \$10      10    10-       0        0
Bill    -> Alice    \$1       9     9-       0        0
Bill    -> Charles  \$5       9     4-       5-       0
Charles -> Alice    \$5       4     4-       0        0
``````

And there you have it. At each transaction, you credit one ledger account and debit another so that the balance is always zero. At at the end, you simply work out the minimal number transactions to be applied to each account to return it to zero.

For this simple case, it's a simple \$4 transfer from Bill to Alice. What you need to do is to reduce at least one account (but preferably two) to zero for every transaction added. Let's say you had the more complicated:

``````                          Alice  Bill  Charles  Balance
Alice   -> Bill    \$10      10    10-       0        0
Bill    -> Alice    \$1       9     9-       0        0
Bill    -> Charles  \$5       9     4-       5-       0
Charles -> Alice    \$5       4     4-       0        0
Charles -> Bill     \$1       4     5-       1        0
``````

Then the transactions needed would be:

``````Bill     -> Alice   \$4       0     1-       1        0
Bill     -> Charles \$1       0     0        0        0
``````

Unfortunately, there are some states where this simple greedy strategy does not generate the best solution (kudos to `j_random_hacker` for pointing this out). One example is:

``````                 Alan  Bill  Chas  Doug  Edie  Fred  Bal
Bill->Alan   \$5    5-    5     0     0     0     0    0
Bill->Chas  \$20    5-   25    20-    0     0     0    0
Doug->Edie   \$2    5-   25    20-    2     2-    0    0
Doug->Fred   \$1    5-   25    20-    3     2-    1-   0
``````

Clearly, this could be reversed in four moves (since four moves is all it took to get there) but, if you choose your first move unwisely `(Edie->Bill \$2)`, five is the minimum you'll get away with.

You can solve this particular problem with the following rules:

• (1) if you can wipe out two balances, do it.
• (2) otherwise if you can wipe out one balance and set yourself up to wipe out two in the next move, do it.
• (3) otherwise, wipe out any one balance.

That would result in the following sequence:

• (a)  not applicable,  can be achieved with `Alan->Bill \$5`.
• (b)  can be done with `Chas->Bill \$20`.
• (c) and (d), similar reasoning with Doug, Edie and Fred, for four total moves.

However, that works simply because of the small number of possibilities. As the number of people rises and the group inter-relations becomes more complex, you'll most likely need an exhaustive search to find the minimum number of moves required (basically the rules 1, 2 and 3 above but expanded to handle more depth).

I think that is what will be required to give you the smallest number of transactions in all circumstances. However, it may be that that's not required for the best answer (best, in this case, meaning maximum "bang per buck"). It may be that even the basic 1/2/3 rule set will give you a good-enough answer for your purposes.

• @j_random_hacker. There is no single transaction that can reduce more than two people to zero balance (as you've said) so, as long as you use the greedy method (zero two people) where possible or zero one person if greedy is not possible, that's the minimum number of moves. Because addition is commutative, it makes no difference what order thing are done in (within those rules), just make sure no-one leaves zero balance once they've been put there. May 21, 2009 at 3:47
• @Pax: No, your simple greedy approach isn't optimal for all cases. Consider these balances: a=-5 b=25 c=-20 d=3 e=-2 f=1. If you cancel a with b first, then you can finish in a total of 4 moves because the pair (b=20, c=-20) appears; but some choices that your greedy algo could make will result in 5 moves (e.g. f->b, e->b, d->a, a->b, c->b) because no such "matched pair" appears. May 22, 2009 at 2:58
• Basically, whenever the balances can be broken into k "independent subproblems", you can solve each one in one step less than the number of balances in that subproblem, reducing the total number of steps needed by k -- but finding those subproblems is very hard. -1 for now (to get your attention :). May 22, 2009 at 3:03
• @j_random_hacker, after further investigation (finding a sequence that breaks the greedy algorithm), I've updated the answer to (hopefully) incorporate your concerns. May 22, 2009 at 4:55
• @Pax: Whoops, yes "f=1" in my example should have been "f=-1". (Sorry that must have been quite confusing!) Your update's good, and yes, based on the NP-hardness of the Subset Sum Problem I would guess that (something amounting to) an exhaustive search is actually needed to guarantee optimality. For practical cases your heuristic will do just fine of course. May 22, 2009 at 12:41

Intuitively, this sounds like an NP-complete problem (it reduces to a problem very like bin packing), however the following algorithm (a modified form of bin packing) should be pretty good (no time for a proof, sorry).

1. Net out everyone's positions, i.e. from your example above:

Alice = \$4 Bill = \$-4 Charles = \$0

2. Sort all net creditors from highest to lowest, and all debtors from lowest to highest, then match by iterating over the lists.

3. At some point you might need to split a person's debts to net everything out - here it is probably best to split into the biggest chunks possible (i.e. into the bins with the most remaining space first).

This will take something like O(n log n) (again, proper proof needed).

See the Partition Problem and Bin Packing for more information (the former is a very similar problem, and if you limit yourself to fixed precision transactions, then it is equivalent - proof needed of course).

• +1. Amazing that this answer, which is actually the closest to being correct, gets voted down. If an unbounded number of transactions are allowed to take place, then yes, this problem is equivalent to solving multiple subset-sum problems -- every subset of m nonzero balances that sums to 0 can be resolved in m-1 steps. See my (upcoming) answer for more details. May 20, 2009 at 22:27
• Agree 100%. n-log-n due to the sort requirement. Just want to note explicitly that this only becomes a bin packing problem when there is some probability that payments may be exactly matched, thereby reducing the total number of required transactions. To the extent that payment granularity departs from some small set of integers and approaches something more like the real number set, simple sorting and netting is as good as it gets.
– user447688
Jun 10, 2009 at 11:34
• Hi, can you elaborate on what you mean by match by iterating over the lists? Say after sorting, creditors = [8,5,5] and debtors = [-10,-8], how do you get the minimum number of transactions from here? Apr 13, 2020 at 18:13

I have created an Android app which solves this problem. You can input expenses during the trip, it even recommends you "who should pay next". At the end it calculates "who should send how much to whom". My algorithm calculates minimum required number of transactions and you can setup "transaction tolerance" which can reduce transactions even further (you don't care about \$1 transactions) Try it out, it's called Settle Up:

https://market.android.com/details?id=cz.destil.settleup

Description of my algorithm:

I have basic algorithm which solves the problem with n-1 transactions, but it's not optimal. It works like this: From payments, I compute balance for each member. Balance is what he paid minus what he should pay. I sort members according to balance increasingly. Then I always take the poorest and richest and transaction is made. At least one of them ends up with zero balance and is excluded from further calculations. With this, number of transactions cannot be worse than n-1. It also minimizes amount of money in transactions. But it's not optimal, because it doesn't detect subgroups which can settle up internally.

Finding subgroups which can settle up internally is hard. I solve it by generating all combinations of members and checking if sum of balances in subgroup equals zero. I start with 2-pairs, then 3-pairs ... (n-1)pairs. Implementations of combination generators are available. When I find a subgroup, I calculate transactions in the subgroup using basic algorithm described above. For every found subgroup, one transaction is spared.

The solution is optimal, but complexity increases to O(n!). This looks terrible but the trick is there will be just small number of members in reality. I have tested it on Nexus One (1 Ghz procesor) and the results are: until 10 members: <100 ms, 15 members: 1 s, 18 members: 8 s, 20 members: 55 s. So until 18 members the execution time is fine. Workaround for >15 members can be to use just the basic algorithm (it's fast and correct, but not optimal).

Source code:

Source code is available inside a report about algorithm written in Czech. Source code is at the end and it's in English:

http://www.settleup.info/files/master-thesis-david-vavra.pdf

• great app. Using it from past 8 months.
– nbi
Nov 13, 2015 at 10:55
• Quite late to the party, but I don't think this is an optimal solution. You don't have any guarantee that using smaller groups first will lead to the best solution(i.e. your algorithm is still greedy, but better than the easy one). As an example take this case:[1,2,-3, 6,7,-14,19,21,-42,-65,-62,130]. If you take away the group [1,2,-3] you will be forced to use just 2 groups(of 3 and 9), while 3 groups of 4 is possible. Oct 6, 2016 at 21:06

I found a practical solution which I implemented in Excel:

• find out who ows the most

• let that person pay the complete amount he ows to the one who should get the most

• that makes the first person zero

• repeat this proces taken into account that one of (n-1) persons has a changed amount

It should result in a maximum of (n-1) transfers and the nice thing about it is that no one is doing more than one payment. Take the (modified) example of jrandomhacker:

a=-5 b=25 c=-20 d=3 e=-2 f=-1 (sum should be zero!)

1. c -> b 20. result: a=-5 b=5 c=0 d=3 e=-2 f=-1

2. a -> b 5 result: a=0 b=0 c=0 d=3 e=-2 f=-1

3. e -> d 2 result a=0 b=0 c=0 d=1 e=0 f=-1

4. f -> d 1

Now, everyone is satisfied and no one is bothered by making two or more payments. As you can see, it is possible that one person recieves more than one payment (person d in this example).

• What if the person who owes the most would need to pay more than the person who should get the most would get? i.e. if instead of b=25 there would be b=15 and g=10 Jan 5, 2020 at 18:08

I have designed a solution using a somewhat different approach to the ones that have been mentioned here. It uses a linear programming formulation of the problem, drawing from the Compressed Sensing literature, especially from this work by Donoho and Tanner (2005).

I have written a blog post describing this approach, along with a tiny R package that implements it. I would love to get some feedback from this community.

Cheers.

Well, the first step is to totally ignore the transactions. Just add them up. All you actually need to know is the net amount of debt a person owes/owns.

You could very easily find transactions by then creating a crazy flow graph and finding max flow. Then a min cut...

Some partial elaboration: There is a source node, a sink node, and a node for each person. There will be an edge between every pair of nodes except no edge between source node and sink node. Edges between people have infinite capacity in both directions. Edges coming from source node to person have capacity equal to the net debt of the person (0 if they have no net debt). Edges going from person node to sink node have capacity equal to the net amount of money that person is owed (0 if they have no net owed).

Apply max flow and/or min cut will give you a set of transfers. The actual flow amount will be how much money will be transfered.

• Could you elaborate on how max flow could be used here? What are the nodes? What are the edges? I'm -1ing just to get your attention, a good explanation will flip the sign :) May 22, 2009 at 12:43
• @j_random_hacker: I added some elaboration. That said, I admit I am unsure how good the answers this gives will be. I invite you to analyze further :) May 22, 2009 at 13:55
• Well, I've offered a graph-based algorithm, which probably doesn't give optimal results. Anyone care to offer a linear programming solution and a dynamic programming solution? May 22, 2009 at 14:47
• Thanks Brian. But the fact that capacities on the person-to-person edges is infinite means that many suboptimal solutions could be produced. E.g. if there are 4 people, a owes b \$20 and c owes d \$20, then max flow might find the optimal solution (20 on the edge a->b and 20 on the edge c->d), but putting \$17.50 on edges a->b and c->d, and \$2.50 on a->d and c->b, is also a maximum flow. May 22, 2009 at 16:53
• We somehow need to reduce the number of edges with nonzero flow -- I looked at Minimum Cost Flow, but that seems to have the same problem since the per-edge cost is multiplied by the flow through that edge (we want a fixed per-edge cost if there is any flow in that edge). May 22, 2009 at 16:55

Only if someone owes more than 2 people, whom also owe to the same set, can you reduce the number of transactions from the simple set.

That is, the simple set is just find each balance and repay it. That's no more than N! transactions.

If A owes B and C, and some subset of B C owe each other, so B owes C, then instead of: A -> B, A -> C (3 transactions). You'd use: A -> B, B -> C (2 transactions).

So in other words you are building a directed graph and you want to trim vertices on order to maximize path length and minimize total edges.

Sorry, I don't have an algorithm for you.

You should be able to solve this in O(n) by first determining how much each person owes and is owed. Transfer the debts of anyone who owes less than he is owed to his debtors (thus turning that person into an end point). Repeat until you can't transfer any more debts.

• This is O(1), but may result in as much as 2*OPT transfers, since in the best case a transfer eliminates 2 people from consideration but your algorithm may sometimes only eliminate 1 person from consideration. May 22, 2009 at 14:45
• I'm not sure where you got O(1) from. You have to go through all the people (hence the O(n) factor). However, the reduction will eliminate only 1 person each time (and exactly one person each time).
– Elie
May 22, 2009 at 15:06

This is the code I wrote to solve this type of a problem in Java. I am not 100% sure if this gives the least number of transactions. The code's clarity and structure can be improved a lot.

In this example:

• Sarah spent \$400 on car rental. The car was used by Sarah, Bob, Alice and John.
• John spent \$100 on groceries. The groceries were consumed by Bob and Alice.

``````import java.util.*;
public class MoneyMinTransactions {

static class Expense{
String spender;
double amount;
List<String> consumers;
public Expense(String spender, double amount, String... consumers){
this.spender = spender;
this.amount = amount;
this.consumers = Arrays.asList(consumers);
}

}

static class Owed{
String name;
double amount;
public Owed(String name, double amount){
this.name = name;
this.amount = amount;
}
}

public static void main(String[] args){
List<Expense> expenseList = new ArrayList<>();
expenseList.add(new Expense("Sarah", 400, "Sarah", "John", "Bob", "Alice"));
//make list of who owes how much.
Map<String, Double> owes = new HashMap<>();
for(Expense e:expenseList){
double owedAmt = e.amount/e.consumers.size();
for(String c : e.consumers){
if(!e.spender.equals(c)){
if(owes.containsKey(c)){
owes.put(c, owes.get(c) + owedAmt);
}else{
owes.put(c, owedAmt);
}
if(owes.containsKey(e.spender)){
owes.put(e.spender, owes.get(e.spender) + (-1 * owedAmt));
}else{
owes.put(e.spender, (-1 * owedAmt));
}
}
}
}
//make transactions.
// We need to settle all the negatives with positives. Make list of negatives. Order highest owed (i.e. the lowest negative) to least owed amount.
List<Owed> owed = new ArrayList<>();
for(String s : owes.keySet()){
if(owes.get(s) < 0){
}
}
Collections.sort(owed, new Comparator<Owed>() {
@Override
public int compare(Owed o1, Owed o2) {
return Double.compare(o1.amount, o2.amount);
}
});
//take the highest negative, settle it with the best positive match:
// 1. a positive that is equal to teh absolute negative amount is the best match.
// 2. the greatest positive value is the next best match.
// todo not sure if this matching strategy gives the least number of transactions.
for(Owed owedPerson: owed){
while(owes.get(owedPerson.name) != 0){
double negAmt = owes.get(owedPerson.name);
String s = getBestMatch(negAmt, owes);
double posAmt = owes.get(s);
if(posAmt > Math.abs(negAmt)){
owes.put(owedPerson.name, 0.0);
owes.put(s, posAmt - Math.abs(negAmt));
System.out.println(String.format("%s paid %s to %s", s, Double.toString((posAmt - Math.abs(negAmt))), owedPerson.name));
}else{
owes.put(owedPerson.name, -1 * (Math.abs(negAmt) - posAmt));
owes.put(s, 0.0);
System.out.println(String.format("%s paid %s to %s", s, Double.toString(posAmt), owedPerson.name));
}
}
}

}

private static String getBestMatch(double negAmount, Map<String, Double> owes){
String greatestS = null;
double greatestAmt = -1;
for(String s: owes.keySet()){
double amt = owes.get(s);
if(amt > 0){
if(amt == Math.abs(negAmount)){
return s;
}else if(greatestS == null || amt > greatestAmt){
greatestAmt = amt;
greatestS = s;
}
}
}
return greatestS;
}

}
``````

If you take states as nodes of graph then you will be able to use shortest path algorithm to know the answer.

• That's technically true, but unless you have a pruning algorithm, it will take a worst case of exponential time to the number of states in order to complete, assuming that testing each state is O(1). May 22, 2009 at 14:44