I've been searching with little success how to solve this problem. The script below is supposed to perform planet simulations. planet1_pars will define 1st planet parameters. set_grids_fakePlanet will create a grid for each of the parameters of a hypothetical planet put into the system. This function will return a generator not a list/array with tons of parameter values. planet2_pars will give me a set of parameters previously created in set_grids_fakePlanet, hence each time I execute planet2_pars it will give me a different set of parameters from the hypothetical planet. ComputeTTV will do some calculations and return what I need each time I execute run_rebound, which is my main function that will call all these mentioned functions above. Whenever I execute run_rebound, I need to give it the hypothetical planet parameter so it run the simulation.

```
def planet1_pars():
P_p1,m_p1,e_p1 = 0.7920639164 / 365.25, 29.32*3.0027e-6, 0.0 #P[yrs], m[solar],e[fixed]
inc_p1,omega_p1,M_p1 = 77.4041697839 * np.pi/180, 90., 0.
return P_p1,m_p1,e_p1,inc_p1,omega_p1,M_p1
def set_grids_fakePlanet(pars_p1):
P_p1,m_p1,e_p1,inc_p1,omega_p1,M_p1 = [*pars_p1]
#min max periods in which to put a planet
Pmin = P_p1 * 2.02 # Pmin ~ 0.0196/365.25 #shortest period found so far in exoplanet.eu
Pmax = P_p1 * 2.05
#set grids
P_grid = np.arange(Pmin, Pmax, P_p1 * 0.005)
m_p2_grid = np.arange(.5, 320, 1) * 3.0027e-6 # every 1 Earth mass to 1 Jupiter
e_grid = [0.0]#np.linspace(0,0.1, 10) # e=1 may cause code to blow up
inc_grid = [inc_p1]#np.linspace(60,90, 5)
omega_grid = [0.0]#np.linspace(0,360, 5)
M_grid = [0.0]#np.linspace(0,360, 5)
#store grid vals, each column is a parameter, last column TTV amplitude
#[n,m] n is max_size(P,e,inc,omega,M) ** m. m is # of orbital parameters + 1 ttv amp
size = len(P_grid) * len(m_p2_grid) * len(e_grid) * len(inc_grid) * len(omega_grid) * len(M_grid)
results = np.zeros([size,6+1]) * np.nan
peiom_grid = ((x,k,y,w,j,z) for x in P_grid for k in m_p2_grid for y in e_grid for w in inc_grid
for j in omega_grid for z in M_grid)
return peiom_grid
def planet2_pars():
for pars_p2 in peiom_grid:
return pars_p2
#2nd planet
# m_p2, P_p2, e_p2, inc_p2, omega_p2, M_p2 = system_parameters(n*m_p1, P_p2,e_p2,inc_p2,omega_p2,M_p2)
def computeTTVs(sim, P_p1, P_p2):
N=34
transittimes = np.zeros(int(N))
p = sim.particles
i = 0
while i<N:
y_old = p[1].y - p[0].y # (Thanks to David Martin for pointing out a bug in this line!)
t_old = sim.t
if P_p1 > P_p2:
sim.integrate(sim.t+ (P_p2 * 0.05)) # check for transits every 0.5 time units. Note that 0.5 is shorter than one orbit
else:
sim.integrate(sim.t+ (P_p1 * 0.05)) #5% of period ~ 1h which is shorter than Tdur=2h
t_new = sim.t
if y_old*(p[1].y-p[0].y)<0. and p[1].x-p[0].x>0.: # sign changed (y_old*y<0), planet in front of star (x>0)
while t_new-t_old>1e-7: # bisect until prec of 1e-5 reached
if y_old*(p[1].y-p[0].y)<0.:
t_new = sim.t
else:
t_old = sim.t
sim.integrate( (t_new+t_old)/2.)
transittimes[i] = sim.t
i += 1
sim.integrate(sim.t+ P_p1 * 0.01) # integrate 0.05 to be past the transit
A = np.vstack([np.ones(N), range(N)]).T
c, m = np.linalg.lstsq(A, transittimes, rcond=-1)[0] # fits a linear model and get period m and t0 c
comp_t0s = c + m*np.array(range(N))
OC = transittimes-comp_t0s # in years
OC *= 365.25*24*60
amp = rms(OC)
# amp = np.diff([np.min(OC), np.max(OC)])[0]
return amp #in minutes
def run_rebound(pars_p2):
ms=1.02 #solar unit
P_p1,m_p1,e_p1,inc_p1,omega_p1,M_p1 = planet1_pars()
P_p2,m_p2,e_p2,inc_p2,omega_p2,M_p2 = [*pars_p2] #fake planet
#start simulation
sim = rebound.Simulation()
sim.G = 39.478 #AU^3 yr^-2 Ms^-1
sim.add(m=ms)
sim.add(m=m_p1, P=P_p1, e=e_p1, inc=inc_p1, omega=omega_p1, M=M_p1)
sim.add(m=m_p2, P=P_p2, e=e_p2, inc=inc_p2, omega=omega_p2, M=M_p2)
#put outcomes in a list
results = [P_p2,m_p2,e_p2,inc_p2*(180/np.pi),omega_p2,M_p2, computeTTVs(sim, P_p1, P_p2)]
return results
```

Question: I tried to make it parallel using the threading library as in:

```
peiom_grid = set_grids_fakePlanet(planet1_pars()) #make the fake planet grid as a generator variable
import threading
start = time.time()
for pars in peiom_grid:
t1 = threading.Thread(target=run_rebound, args=(pars,))
t1.start()
t1.join()
end = time.time()
print((end-start) /60, 'min')
```

In this manner, I see the 8 CPU I got is being used but at a rate which is less than 50%. And it takes ~ 1.2 min to run (the grids are small because I am testing, but ideally the grids should be lager so it may take days to run).

I also tried MultiProcessing

```
from multiprocessing import Process
start = time.time()
if __name__ == '__main__':
for pars in peiom_grid:
p = Process(target=run_rebound, args=(pars,))
p.start()
p.join()
end = time.time()
print((end-start) /60, 'min')
```

it takes ~ 1.7min

and without any parallelization

```
start = time.time()
for pars in peiom_grid:
run_rebound(pars)
end = time.time()
print((end-start)/60, 'min')
```

it takes ~ 1.34 min

I think I am not doing any parallelization because the difference between the runs above with/without parallelization isn't significant. I cannot find where the issue is. I followed a few examples and check several examples on stack overflow but nothing... Hope you guys can give me some feedback.

`numpy`

well, with large arrays, the GIL would be less of a problem;`numpy`

releases the GIL when performing operations on sufficiently large arrays of primitives. It does look like a lot of the code here is not using`numpy`

optimally (there's an array or two, but mostly it's doing Python level work with Python level types), so the point about the GIL stands.in Pythonis no help... Multithreading in most other programming languagescanbe used for parallel computation. Python is a special case because of the GIL. That was a design decision that the author made back when typical workstation computers had only one CPU core, and because it affects the language semantics, we're basically stuck with it. Newer languages don't have anything like the GIL. Nor do older languages with simpler run-time support libraries that don't need to be thread-aware.1more comment