# BiCG algorithm in Fortran not working properly?

I'm working on a Bi-Conjugate Gradient algorithm in Fortran and have it fully code, following the algorithm in Saad, Y. "Iterative Methods for Sparse Linear Systems" (the plain BiCG method). However, it is not converging in the required number of iterations, nor is it returning the correct results.

The algorithm is given as in the "Unpreconditioned version" on Wikipedia (http://en.wikipedia.org/wiki/Biconjugate_gradient_method#Unpreconditioned_version_of_the_algorithm)

I am still relatively new to Fortran, and do not understand why exactly this is not behaving as expected because as far as I know its coded exactly as specified. If someone sees any unorthodox code, or faults in the algorithm I would be very grateful!

I have included a test matrix for simplicity:

``````    !
!////////////////////////////////////////////////////////////////////////
!
!      BiCG_main.f90
!      Created: 19 February 2013 12:01
!      By: Robin  Fox
!
!////////////////////////////////////////////////////////////////////////
!
PROGRAM bicg_main
!
IMPLICIT NONE
!-------------------------------------------------------------------
! Program to implement the Bi-Conjugate Gradient method
!-------------------------------------------------------------------
!
COMPLEX(KIND(0.0d0)), DIMENSION(:,:), ALLOCATABLE       ::A
COMPLEX(KIND(0.0d0)), DIMENSION(:), ALLOCATABLE         ::b
COMPLEX(KIND(0.0d0)), DIMENSION(:), ALLOCATABLE         ::x0, x0s
COMPLEX(KIND(0.0d0)), DIMENSION(:), ALLOCATABLE         ::x, xs
COMPLEX(KIND(0.0d0)), DIMENSION(:), ALLOCATABLE         ::p, ps
COMPLEX(KIND(0.0d0))                                    ::alpha, rho0, rho1, r_rs
COMPLEX(KIND(0.0d0)), DIMENSION(:), ALLOCATABLE         ::r,rs, res_vec
COMPLEX(KIND(0.0d0)), DIMENSION(:), ALLOCATABLE         ::Ax, ATx
COMPLEX(KIND(0.0d0)), DIMENSION(:), ALLOCATABLE         ::Ap, Aps
COMPLEX(KIND(0.0d0))                                    ::beta
!
REAL(KIND(0.0d0))                                       ::tol,res, n2b, n2r0, rel_res
!
INTEGER                                                 ::n,i,j,k, maxit
!////////////////////////////////////////////////////////////////////////

!----------------------------------------------------------
n=2
ALLOCATE(A(n,n))
ALLOCATE(b(n))

A(1,1)=CMPLX(-0.73492,7.11486)
A(1,2)=CMPLX(0.024839,4.12154)
A(2,1)=CMPLX(0.274492957,3.7885537)
A(2,2)=CMPLX(-0.632557864,1.95397735)

b(1)=CMPLX(0.289619736,0.895562183)
b(2)=CMPLX(-0.28475616,-0.892163111)

!----------------------------------------------------------

ALLOCATE(x0(n))
ALLOCATE(x0s(n))

!Use all zeros initial guess
x0(:)=CMPLX(0.0d0,0.0d0)
DO i=1,n
x0s(i)=CONJG(x0(i))
END DO

ALLOCATE(Ax(n))
ALLOCATE(ATx(n))
ALLOCATE(x(n))
ALLOCATE(xs(n))

! Multiply matrix A with vector x0
DO i=1,n
Ax(i)=CMPLX(0.0,0.0)
DO j=1,n
Ax(i)=Ax(i)+A(i,j)*x0(j) !==Ax=A*x0
END DO
END DO

! Multiply matrix A^T with vector x0
DO i=1,n
ATx(i)=CMPLX(0.0,0.0)
DO j=1,n
ATx(i)=ATx(i)+CONJG(A(j,i))*x0s(j) !==A^Tx=A^T*x0
END DO
END DO

res=0.0d0
n2b=0.0d0
x=x0

ALLOCATE(r(n))
ALLOCATE(rs(n))
ALLOCATE(p(n))
ALLOCATE(ps(n))

!Initialise
DO i=1,n
r(i)=b(i)-Ax(i)
rs(i)=CONJG(b(i))-ATx(i)
p(i)=r(i) !p0=r0
ps(i)=rs(i) !p0s=r0s
END DO

DO i=1,n
n2b=n2b+(b(i)*CONJG(b(i)))
res=res+(r(i)*CONJG(r(i))) !== inner prod(r,r)
END DO
n2b=SQRT(n2b)
res=SQRT(res)/n2b

!Check that inner prod(r,rs) =/= 0
n2r0=0.0d0
DO i=1,n
n2r0=n2r0+r(i)*CONJG(rs(i))
END DO

IF (n2r0==0) THEN
res=1d-20 !set tol so that loop doesn't run (i.e. already smaller than tol)
PRINT*, "Inner product of r, rs == 0"
END IF
WRITE(*,*) "n2r0=", n2r0

!----------------------------------------------------------
ALLOCATE(Ap(n))
ALLOCATE(Aps(n))
ALLOCATE(res_vec(n))

tol=1d-6
maxit=50 !for n=720

k=0
!Main loop:
main: DO WHILE ((res>tol).AND.(k<maxit))

k=k+1
! Multiply matrix A with vector p
DO i=1,n
Ap(i)=CMPLX(0.0,0.0)
DO j=1,n
Ap(i)=Ap(i)+A(i,j)*p(j)
END DO
END DO

! Multiply matrix A^T with vector p
! N.B. transpose is also conjg.
DO i=1,n
Aps(i)=CMPLX(0.0,0.0)
DO j=1,n
Aps(i)=Aps(i)+CONJG(A(j,i))*ps(j)
END DO
END DO

rho0=CMPLX(0.0d0,0.0d0)
DO i=1,n
rho0=rho0+(r(i)*CONJG(rs(i)))
END DO
WRITE(*,*) "rho0=", rho0

rho1=CMPLX(0.0d0,0.0d0)
DO i=1,n
rho1=rho1+(Ap(i)*CONJG(ps(i)))
END DO
WRITE(*,*) "rho1=", rho1

!Calculate alpha:
alpha=rho0/rho1
WRITE(*,*) "alpha=", alpha

!Update solution
DO i=1,n
x(i)=x(i)+alpha*p(i)
END DO

!Update residual:
DO i=1,n
r(i)=r(i)-alpha*Ap(i)
END DO

!Update second residual:
DO i=1,n
rs(i)=rs(i)-alpha*Aps(i)
END DO

!Calculate beta:
r_rs=CMPLX(0.0d0,0.0d0)
DO i=1,n
r_rs=r_rs+(r(i)*CONJG(rs(i)))
END DO
beta=r_rs/rho0

!Update direction vectors:
DO i=1,n
p(i)=r(i)+beta*p(i)
END DO

DO i=1,n
ps(i)=rs(i)+beta*ps(i)
END DO

!Calculate residual for convergence check
!   res=0.0d0
!   DO i=1,n
!      res=res+(r(i)*CONJG(r(i))) !== inner prod(r,r)
!   END DO
!----------------------------------------------------------
!Calculate updated residual "res_vec=b-A*x" relative to current x
DO i=1,n
Ax(i)=CMPLX(0.0d0, 0.0d0)
DO j=1,n
Ax(i)=Ax(i)+A(i,j)*x(j)
END DO
END DO

DO i=1,n
res_vec(i)=b(i)-Ax(i)
END DO

DO i=1,n
rel_res=rel_res+(res_vec(i)*CONJG(res_vec(i)))
END DO
res=SQRT(res)/REAL(n2b)
WRITE(*,*) "res=",res
WRITE(*,*) " "

END DO main
!----------------------------------------------------------
!Output message
IF (k<maxit) THEN
WRITE(*,*) "Converged in",k,"iterations"
ELSE
WRITE(*,*) "STOPPED after",k, "iterations because max no. of iterations was reached"
END IF

!Output solution vector:
WRITE(*,*) "x_sol="
DO i=1,n
WRITE(*,*) x(i)
END DO

!----------------------------------------------------------
DEALLOCATE(x0,x0s, Ax, ATx, x, xs, p, ps ,r, rs, Ap, Aps, res_vec)
DEALLOCATE(A,b)
!
END PROGRAM
!
!////////////////////////////////////////////////////////////////////////
``````

RESULTS: The results to my script are given as:

``````      STOPPED after          50 iterations because max no. of iterations was reached
x_sol=
(-2.88435711452590705E-002,-0.43229898544084933     )
( 0.11755325208241280     , 0.73895038053993978     )
``````

while the actual results are given using MATLAB's built in bicg.m function as:

``````       -0.3700 - 0.6702i
0.7295 + 1.1571i
``````
-

Here are some blemishes on your program. Whether they are errors or not is somewhat subjective and it's entirely up to you whether you modify your code.

1. In this line

``````IF (n2r0==0) THEN
``````

you test whether the result of a (possibly long running) loop sums to exactly 0. This is always a bad idea with floating-point numbers. If you do not know this, review the many, many questions here on SO with the tag `floating-point` which arise from widespread imprecision in understanding of what it is reasonable to expect from f-p arithmetic. I don't think your use of a real number on the left and an integer on the right of the comparison makes matters worse, but it doesn't make them any better.

2. In at least two places in your code you calculate matrix-vector products. You could replace those loops with calls to the intrinsic `matmul` routine (I think, I haven't checked your code as closely as I'm sure you have). This might actually slow your code, but that's not the problem at this stage. Calling a well-tested library routine rather than rolling your own will (a) reduce the amount of code you have to maintain/test/fix and (b) be more likely to deliver a right-first-time solution. Once you have the code working then, if you must, worry about performance.

3. You declare many real and complex variables with double precision but initialise them with statements like:

``````A(1,1)=CMPLX(-0.73492,7.11486)
``````

A double precision variable has about 15 decimal digits available, but here you provide values for only the first 6 of them. You cannot rely on the compiler to set the other digits to any particular values. Instead, initialise like this:

``````A(1,1)=CMPLX(-0.73492_dp,7.11486_dp)
``````

which will result in those values being initialised to the double precision numbers closest to `-0.73492` and `7.11486`. Of course, you have to have previously written something like `dp = kind(0d0)`, and there are other ways of enforcing the precision of literal constants, but this is the way I usually do it. If you have a modern Fortran compiler which provides the intrinsic `iso_fortran_env` module you could replace the `_dp` with the now-standard `_real64`.

4. This block of code

``````x0(:)=CMPLX(0.0d0,0.0d0)
DO i=1,n
x0s(i)=CONJG(x0(i))
END DO
``````

could be replaced by

``````x0  = CMPLX(0.0d0,0.0d0)
x0s = x0
``````

It seems a little peculiar to use the array syntax to zero the first array, then a loop to zero the second; it seems even more peculiar to call `CONJG` repeatedly when `CONJG(0,0)==(0,0)`.

5. This block of code

``````  DO i=1,n
n2b=n2b+(b(i)*CONJG(b(i)))
res=res+(r(i)*CONJG(r(i))) !== inner prod(r,r)
END DO
n2b=SQRT(n2b)
res=SQRT(res)/n2b
``````

can, if I understand correctly, be replaced by

`````` n2b = sqrt(dot_product(b,b))
res = sqrt(dot_product(r,r))/n2b
``````

I don't actually see anything wrong with your code here, but using the intrinsics cuts down the number of lines you need to write and to maintain as in the case of `matmul` above.

There may be other, less immediately evident, blemishes, but this lot should get you started.

-