# Runge-Kutta 4 With CUDA Fortran

I am trying to convert this FORTRAN program (motion of pendulum) to CUDA FORTRAN but I can use only 1 block with two threads. Is there any way to use more then 2 threads....

``````MODULE CB
REAL :: Q,B,W
END MODULE CB

PROGRAM PENDULUM
USE CB
IMPLICIT NONE
INTEGER, PARAMETER :: N=10,L=100,M=1
INTEGER :: I,count_rate,count_max,count(2)
REAL :: PI,H,T,Y1,Y2,G1,G1F,G2,G2F
REAL :: DK11,DK21,DK12,DK22,DK13,DK23,DK14,DK24

REAL, DIMENSION (2,N) :: Y

PI = 4.0*ATAN(1.0)
H  = 3.0*PI/L
Q  = 0.5
B  = 0.9
W  = 2.0/3.0
Y(1,1) = 0.0
Y(2,1) = 2.0

DO I = 1, N-1
T  = H*I
Y1 = Y(1,I)
Y2 = Y(2,I)
DK11 = H*G1F(Y1,Y2,T)
DK21 = H*G2F(Y1,Y2,T)
DK12 = H*G1F((Y1+DK11/2.0),(Y2+DK21/2.0),(T+H/2.0))
DK22 = H*G2F((Y1+DK11/2.0),(Y2+DK21/2.0),(T+H/2.0))
DK13 = H*G1F((Y1+DK12/2.0),(Y2+DK22/2.0),(T+H/2.0))
DK23 = H*G2F((Y1+DK12/2.0),(Y2+DK22/2.0),(T+H/2.0))
DK14 = H*G1F((Y1+DK13),(Y2+DK23),(T+H))
DK24 = H*G2F((Y1+DK13),(Y2+DK23),(T+H))
Y(1,I+1) = Y(1,I)+(DK11+2.0*(DK12+DK13)+DK14)/6.0
Y(2,I+1) = Y(2,I)+(DK21+2.0*(DK22+DK23)+DK24)/6.0

! Bring theta back to the region [-pi,pi]
Y(1,I+1) = Y(1,I+1)-2.0*PI*NINT(Y(1,I+1)/(2.0*PI))

END DO

call system_clock ( count(2), count_rate, count_max )

WRITE (6,"(2F16.8)") (Y(1,I),Y(2,I),I=1,N,M)

END PROGRAM PENDULUM

FUNCTION G1F (Y1,Y2,T) RESULT (G1)
USE CB
IMPLICIT NONE
REAL :: Y1,Y2,T,G1
G1 = Y2
END FUNCTION G1F

FUNCTION G2F (Y1,Y2,T) RESULT (G2)
USE CB
IMPLICIT NONE
REAL :: Y1,Y2,T,G2
G2 = -Q*Y2-SIN(Y1)+B*COS(W*T)
END FUNCTION G2F
``````

CUDA FORTRAN VERSION OF PROGRAM

``````MODULE KERNEL

CONTAINS
attributes(global) subroutine mykernel(Y_d,N,L,M)

INTEGER,value:: N,L,M
INTEGER ::tid
REAL:: Y_d(:,:)
REAL :: PI,H,T,G1,G1F,G2,G2F
REAL,shared :: DK11,DK21,DK12,DK22,DK13,DK23,DK14,DK24,Y1,Y2

PI = 4.0*ATAN(1.0)
H  = 3.0*PI/L
Y_d(1,1) = 0.0
Y_d(2,1) = 2.0

DO I = 1, N-1
T  = H*I
Y1 = Y_d(1,I)
Y2 = Y_d(2,I)

if(tid==1)then
DK11 = H*G1F(Y1,Y2,T)
else
DK21 = H*G2F(Y1,Y2,T)
endif

if(tid==1)then
DK12 = H*G1F((Y1+DK11/2.0),(Y2+DK21/2.0),(T+H/2.0))
else
DK22 = H*G2F((Y1+DK11/2.0),(Y2+DK21/2.0),(T+H/2.0))
endif

if(tid==1)then
DK13 = H*G1F((Y1+DK12/2.0),(Y2+DK22/2.0),(T+H/2.0))
else
DK23 = H*G2F((Y1+DK12/2.0),(Y2+DK22/2.0),(T+H/2.0))
endif

if(tid==1)then
DK14 = H*G1F((Y1+DK13),(Y2+DK23),(T+H))
else
DK24 = H*G2F((Y1+DK13),(Y2+DK23),(T+H))
endif

if(tid==1)then
Y_d(1,I+1) = Y1+(DK11+2.0*(DK12+DK13)+DK14)/6.0
else
Y_d(2,I+1) = Y2+(DK21+2.0*(DK22+DK23)+DK24)/6.0
endif

Y_d(1,I+1) = Y_d(1,I+1)-2.0*PI*NINT(Y_d(1,I+1)/(2.0*PI))

END DO

end subroutine mykernel

attributes(device) FUNCTION G1F (Y1,Y2,T) RESULT (G1)
IMPLICIT NONE
REAL :: Y1,Y2,T,G1
G1 = Y2
END FUNCTION G1F

attributes(device) FUNCTION G2F (Y1,Y2,T) RESULT (G2)
IMPLICIT NONE
REAL :: Y1,Y2,T,G2
G2 = -0.5*Y2-SIN(Y1)+0.9*COS((2.0/3.0)*T)
END FUNCTION G2F

END MODULE KERNEL

PROGRAM PENDULUM

use cudafor
use KERNEL

IMPLICIT NONE
INTEGER, PARAMETER :: N=100000,L=1000,M=1
INTEGER :: I,d,count_max,count_rate

REAL,device :: Y_d(2,N)
REAL, DIMENSION (2,N) :: Y
INTEGER :: count(2)

call mykernel<<<1,2>>>(Y_d,N,L,M)

Y=Y_d

WRITE (6,"(2F16.8)") (Y(1,I),Y(2,I),I=1,N,M)

END PROGRAM PENDULUM
``````
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Unless `g1f` and `g2f` are computationally expensive functions which can be evaluated using parallelism (such as a matrix-vector product), or unless you are planning on applying the Runge-Kutta integrator to many systems in parallel (such as in a particle system), this question is an exercise in futility. – talonmies Jan 29 '13 at 6:38
@VladimirF: The point is you can't get rid of the loop. This is an ODE integrator - the values at one trip through the loop dependent on the results of the calculation from the previous trip through the loop. – talonmies Jan 29 '13 at 7:00

The "outer" part is the dependence of `Y(1:2,i+1)` on `Y(1:2,i)`. At each time step, you need to use the values of `Y(1:2,i)` to calculate `Y(1:2,i+1)`, so it's not possible to perform the calculations for multiple time steps in parallel, simply because of the serial dependence structure -- you need to know what happens at time `i` to calculate what happens at time `i+1`, you need to know what happens at time `i+1` to calculate what happens at time `i+2`, and so on. The best that you can hope to do is to calculate `Y(1,i+1)` and `Y(2,i+1)` in parallel, which is exactly what you do.
The "inner" part is based on the dependencies between the intermediate values in the Runge-Kutta scheme, the `DK11`, `DK12`, etc. values in your code. When calculating `Y(1:2,i+1)`, each of the `DK[n,m]` depends on `Y(1:2,i)` and for `m > 1`, each of the `DK[n,m]` depends on both `DK[1,m-1]` and `DK[2,m-1]`. If you draw a graph of these dependencies (which my ASCII art skills aren't really good enough for!), you'll see that there are at each step of the calculation only two possible sub-calculations that can be performed in parallel.