func main() {
dt := make([]atm.Datapoint, 4)
ch_ts := timestep.MasterTimeStep()
for i := 0; i < 4; i++ {
t := make([]float64, 3)
t[0] = 335 //AbsZero + 60
t[1] = 303 //AbsZero + 30
t[2] = 254 //AbsZero - 20
f := make([]float64, 9)
dt[i] = *atm.NewDatapoint(t, f)
fmt.Print(&dt[i])
dt[i].Idx = i
dt[i].Area = atm.KM * math.Pi * math.Pow(atm.EarthR, 2) // 4 pi r^2 / (4 gridpoints)
dt[i].BoundL = []float64{atm.KM * math.Pi * atm.EarthR / 2, atm.KM * math.Pi * atm.EarthR / 2, atm.KM * math.Pi * atm.EarthR / 2}
dt[i].Cp = []float64{atm.CpConst, atm.CpConst, atm.CpConst}
dt[i].K = atm.KConst
dt[i].A = atm.A
}
dt[0].Lat = 45.0
dt[0].Long = -45.0
dt[0].NPole = true
dt[1].Lat = 45.0
dt[1].Long = 45.0
dt[1].NPole = true
dt[2].Lat = -45.0
dt[2].Long = -45.0
dt[2].SPole = true
dt[3].Lat = -45.0
dt[3].Long = 45.0
dt[3].SPole = true
FluxIn := &atm.FluxInput{4, []int{2, 3, 4, 1, 3, 4, 1, 2, 4, 1, 2, 3}, []int{0, 3, 3, 6, 6, 9, 9, 12},
make(chan *atm.Datapoint), make(chan *atm.FluxComponent)}
ch1 := FluxIn.ChFlux
GCMIn := &atm.GCMInput{4, make(chan *atm.Datapoint), FluxIn.ChFluxComp}
ch2 := GCMIn.Ch
out1 := atm.Flux(*FluxIn)
out2 := atm.Gcm(*GCMIn)
for i := 0; i < 10; i++ {
// Running the simulation
fmt.Printf("Run %d!\n", i)
for _, d := range dt {
ch1 <- &d
<-out1
}
for _, d := range dt {
ch2 <- &d
<-out2
}
for _, d := range dt {
fmt.Print(&d)
}
<-ch_ts
}
}
package solar
import (
timestep "github.com/Arrow/GoGCM/util/timestep"
"math"
"testing"
)
var ch chan timestep.Tstep = timestep.MasterTimeStep()
var ch_sol chan float64 = Solar()
func notNearEqual(a, b, closeEnough float64) bool {
absDiff := math.Fabs(a - b)
if absDiff < closeEnough {
return false
}
return true
}
func TestSolar(t *testing.T) {
const n = 100
for i := 0; i < n; i++ {
s := <-ch_sol
if notNearEqual(s, S_Start, float64((i+1)*5)) {
t.Errorf("Not close enough! %d (Expected: %d)", s, S_Start)
}
}
}
func BenchmarkSolar(b *testing.B) {
const n = 1
