# Running: For now, just modify the script to your liking: `JULIA_NUM_THREADS=8 julia paralleleureqa.jl` ## Modification You can change the binary and unary operators in `eureqa.jl` here: ``` const binops = [plus, mult] const unaops = [sin, cos, exp]; ``` E.g., you can add another binary function with: ``` const binops = [plus, mult, (x, y)->x^2*y] ``` You can change the dataset here: ``` const nvar = 5; const X = rand(100, nvar); # Here is the function we want to learn (x2^2 + cos(x3)) const y = ((cx,)->cx^2).(X[:, 2]) + cos.(X[:, 3]) ``` by either loading in a dataset, or modifying the definition of `y`. ### Hyperparameters Turn on annealing by setting the following in `paralleleureqa.jl`: `const annealing = true` Annealing allows each evolutionary cycle to turn down the exploration rate over time: at the end (temperature 0), it will only select solutions better than existing solutions. The following parameter, parsimony, is how much to punish complex solutions: ` const parsimony = 0.01 ` Finally, the following determins how much to scale temperature by (T between 0 and 1). ` const alpha = 10.0 ` Larger alpha means more exploration. One can also adjust the relative probabilities of each mutation here: ``` weights = [8, 1, 1, 1] ``` (for: 1. perturb constant, 2. mutate operator, 3. append a node, 4. delete a subtree). # TODO - Record hall of fame - Optionally migrate the hall of fame, rather than current bests