func patternsolver(fn bench.Func, db *sql.DB) (*pattern.Method, optim.Mesh) { low, up := fn.Bounds() max, min := up[0], low[0] mesh := &optim.InfMesh{StepSize: (max - min) / 10} p := initialpoint(fn) mesh.SetOrigin(p.Pos) return pattern.New(p, pattern.DB(db)), mesh }
func swarmsolver(fn bench.Func, db *sql.DB) (optim.Method, optim.Mesh) { low, up := fn.Bounds() n := 20 + 1*len(low) return New( NewPopulationRand(n, low, up), VmaxBounds(fn.Bounds()), DB(db), ), &optim.BoxMesh{&optim.InfMesh{}, low, up} }
func initialpoint(fn bench.Func) *optim.Point { low, up := fn.Bounds() max, min := up[0], low[0] pos := make([]float64, len(low)) for i := range low { pos[i] = rand.Float64()*(max-min) + min } return &optim.Point{pos, math.Inf(1)} }
func patternsolver(fn bench.Func, db *sql.DB) (optim.Method, optim.Mesh) { low, up := fn.Bounds() max, min := up[0], low[0] pos := make([]float64, len(low)) for i := range pos { pos[i] = low[i] + (up[i]-low[i])/3 } m := &optim.BoxMesh{&optim.InfMesh{StepSize: (max - min) / 10}, low, up} m.SetOrigin(pos) p := &optim.Point{pos, math.Inf(1)} return New(p, DB(db)), m }
func swarmsolver(fn bench.Func, db *sql.DB, n int) optim.Method { low, up := fn.Bounds() if n < 0 { n = 30 + 1*len(low) if n > maxeval/500 { n = maxeval / 500 } } return swarm.New( swarm.NewPopulationRand(n, low, up), swarm.VmaxBounds(fn.Bounds()), swarm.DB(db), ) }