/* MAXFLOW, Maximum Flow Problem */ /* Written in GNU MathProg by Andrew Makhorin */ /* The Maximum Flow Problem in a network G = (V, E), where V is a set of nodes, E within V x V is a set of arcs, is to maximize the flow from one given node s (source) to another given node t (sink) subject to conservation of flow constraints at each node and flow capacities on each arc. */ param n, integer, >= 2; /* number of nodes */ set V, default {1..n}; /* set of nodes */ set E, within V cross V; /* set of arcs */ param a{(i,j) in E}, > 0; /* a[i,j] is capacity of arc (i,j) */ param s, symbolic, in V, default 1; /* source node */ param t, symbolic, in V, != s, default n; /* sink node */ var x{(i,j) in E}, >= 0, <= a[i,j]; /* x[i,j] is elementary flow through arc (i,j) to be found */ var flow, >= 0; /* total flow from s to t */ s.t. node{i in V}: /* node[i] is conservation constraint for node i */ sum{(j,i) in E} x[j,i] + (if i = s then flow) /* summary flow into node i through all ingoing arcs */ = /* must be equal to */ sum{(i,j) in E} x[i,j] + (if i = t then flow); /* summary flow from node i through all outgoing arcs */ maximize obj: flow; /* objective is to maximize the total flow through the network */ solve; printf{1..56} "="; printf "\n"; printf "Maximum flow from node %s to node %s is %g\n\n", s, t, flow; printf "Starting node Ending node Arc capacity Flow in arc\n"; printf "------------- ----------- ------------ -----------\n"; printf{(i,j) in E: x[i,j] != 0}: "%13s %11s %12g %11g\n", i, j, a[i,j], x[i,j]; printf{1..56} "="; printf "\n"; data; /* These data correspond to an example from [Christofides]. */ /* Optimal solution is 29 */ param n := 9; param : E : a := 1 2 14 1 4 23 2 3 10 2 4 9 3 5 12 3 8 18 4 5 26 5 2 11 5 6 25 5 7 4 6 7 7 6 8 8 7 9 15 8 9 20; end;