package routing import ( "testing" ) // TestProbabilityExtrapolation tests that probabilities for tried channels are // extrapolated to untried channels. This is a way to improve pathfinding // success by steering away from bad nodes. func TestProbabilityExtrapolation(t *testing.T) { ctx := newIntegratedRoutingContext(t) // Create the following network of nodes: // source -> expensiveNode (charges routing fee) -> target // source -> intermediate1 (free routing) -> intermediate(1-10) (free routing) -> target g := ctx.graph expensiveNode := newMockNode() expensiveNode.baseFee = 10000 g.addNode(expensiveNode) g.addChannel(ctx.source, expensiveNode, 100000) g.addChannel(ctx.target, expensiveNode, 100000) intermediate1 := newMockNode() g.addNode(intermediate1) g.addChannel(ctx.source, intermediate1, 100000) for i := 0; i < 10; i++ { imNode := newMockNode() g.addNode(imNode) g.addChannel(imNode, ctx.target, 100000) g.addChannel(imNode, intermediate1, 100000) // The channels from intermediate1 all have insufficient balance. g.nodes[intermediate1.pubkey].channels[imNode.pubkey].balance = 0 } // It is expected that pathfinding will try to explore the routes via // intermediate1 first, because those are free. But as failures happen, // the node probability of intermediate1 will go down in favor of the // paid route via expensiveNode. // // The exact number of attempts required is dependent on mission control // config. For this test, it would have been enough to only assert that // we are not trying all routes via intermediate1. However, we do assert // a specific number of attempts to safe-guard against accidental // modifications anywhere in the chain of components that is involved in // this test. ctx.testPayment(5) // If we use a static value for the node probability (no extrapolation // of data from other channels), all ten bad channels will be tried // first before switching to the paid channel. ctx.mcCfg.AprioriWeight = 1 ctx.testPayment(11) }