Summary of Question
I am not sure I have understood the question correctly, so first I will summarize my understanding.
We have a graph with vertices v1,v2,..,vn and weighted edges. Let the weight between vi and vj be W[i,j]
Each vertex starts with a number of stones, let us call the number of stones on vertex vi equal to A[i]
You wish to perform multiple transfers in order to maximise the value of min(A[i] for i = 1..n)
x stones can be transferred between vi and vj if x>W[i,j], this operation transforms the values as:
A[i] -= x
A[j] += x-W[i,j] # Note fewer stones arrive than leave
Is this correct?
I believe this problem is NP-hard because it can be used to solve 3-SAT, a known NP-complete problem.
For a 3-sat example with M clauses such as:
Construct a directed graph which has a node for each clause (with no stones), a node for each variable with 3M+1 stones, and two auxiliary nodes for each variable with 1 stone (one represents the variable having a positive value, and one represents the variable having a negative value.
Then connect the nodes as shown below:
This graph will have a solution with all vertices having value >= 1, if and only if the 3-sat is soluble.
The point is that each red node (e.g. for variable A) can only send stones to either A=1 or A=0, but not both. If we provide stones to the green node A=1, then this node can supply stones to all of the blue clauses which use that variable in a positive sense.
(Your original question does not involve a directed graph, but I doubt that this additional change will make a material difference to the complexity of the problem.)
I am afraid it is going to be very hard to get an O(n) solution to this problem.