gcc/testsuite/gfortran.dg/norm2_3.f90 - gcc - Git at Google

 ! { dg-do run }
 ! { dg-require-effective-target fortran_large_real }
 !
 !
 ! PR fortran/33197
 !
 ! Check implementation of L2 norm (Euclidean vector norm)
 !
 implicit none

 integer,parameter :: qp = selected_real_kind (precision (0.0d0)+1)

 real(qp) :: a(3) = [real(qp) :: 1, 2, huge(3.0_qp)]
 real(qp) :: b(3) = [real(qp) :: 1, 2, 3]
 real(qp) :: c(4) = [real(qp) :: 1, 2, 3, -1]
 real(qp) :: e(0) = [real(qp) :: ]
 real(qp) :: f(4) = [real(qp) :: 0, 0, 3, 0 ]

 real(qp) :: d(4,1) = RESHAPE ([real(qp) :: 1, 2, 3, -1], [4,1])
 real(qp) :: g(4,1) = RESHAPE ([real(qp) :: 0, 0, 4, -1], [4,1])

 ! Check compile-time version

 if (abs (NORM2 ([real(qp) :: 1, 2, huge(3.0_qp)])   - huge(3.0_qp)) &
     > epsilon(0.0_qp)*huge(3.0_qp)) STOP 1

 if (abs (SNORM2([real(qp) :: 1, 2, huge(3.0_qp)],3) - huge(3.0_qp)) &
     > epsilon(0.0_qp)*huge(3.0_qp)) STOP 2

 if (abs (SNORM2([real(qp) :: 1, 2, 3],3) - NORM2([real(qp) :: 1, 2, 3])) &
     > epsilon(0.0_qp)*SNORM2([real(qp) :: 1, 2, 3],3)) STOP 3

 if (NORM2([real(qp) :: ]) /= 0.0_qp) STOP 4
 if (abs (NORM2([real(qp) :: 0, 0, 3, 0]) - 3.0_qp) > epsilon(0.0_qp)) STOP 5

 ! Check TREE version

 if (abs (NORM2 (a)   - huge(3.0_qp)) &
     > epsilon(0.0_qp)*huge(3.0_qp)) STOP 6

 if (abs (SNORM2(b,3) - NORM2(b)) &
     > epsilon(0.0_qp)*SNORM2(b,3)) STOP 7

 if (abs (SNORM2(c,4) - NORM2(c)) &
     > epsilon(0.0_qp)*SNORM2(c,4)) STOP 8

 if (ANY (abs (abs(d(:,1)) - NORM2(d, 2)) &
     > epsilon(0.0_qp))) STOP 9

 ! Check libgfortran version

 if (ANY (abs (SNORM2(d,4) - NORM2(d, 1)) &
     > epsilon(0.0_qp)*SNORM2(d,4))) STOP 10

 if (abs (SNORM2(f,4) - NORM2(f, 1)) &
     > epsilon(0.0_qp)*SNORM2(d,4)) STOP 11

 if (ANY (abs (abs(g(:,1)) - NORM2(g, 2)) &
     > epsilon(0.0_qp))) STOP 12

 contains
    ! NORM2 algorithm based on BLAS, cf.
    ! http://www.netlib.org/blas/snrm2.f
    REAL(qp) FUNCTION SNORM2 (X,n)
       INTEGER, INTENT(IN) :: n
       REAL(qp), INTENT(IN) :: X(n)

       REAL(qp) :: absXi, scale, SSQ
       INTEGER :: i

       INTRINSIC :: ABS, SQRT

       IF (N < 1) THEN
         snorm2 = 0.0_qp
       ELSE IF (N == 1) THEN
         snorm2 = ABS(X(1))
       ELSE
           scale = 0.0_qp
           SSQ = 1.0_qp

           DO i = 1, N
               IF (X(i) /= 0.0_qp) THEN
                   absXi = ABS(X(i))
                   IF (scale < absXi) THEN
                       SSQ = 1.0_qp + SSQ * (scale/absXi)**2
                       scale = absXi
                   ELSE
                       SSQ = SSQ + (absXi/scale)**2
                   END IF
               END IF
           END DO
           snorm2 = scale * SQRT(SSQ)
       END IF
    END FUNCTION SNORM2
 end
	! { dg-do run }
	! { dg-require-effective-target fortran_large_real }
	!
	!
	! PR fortran/33197
	!
	! Check implementation of L2 norm (Euclidean vector norm)
	!
	implicit none

	integer,parameter :: qp = selected_real_kind (precision (0.0d0)+1)

	real(qp) :: a(3) = [real(qp) :: 1, 2, huge(3.0_qp)]
	real(qp) :: b(3) = [real(qp) :: 1, 2, 3]
	real(qp) :: c(4) = [real(qp) :: 1, 2, 3, -1]
	real(qp) :: e(0) = [real(qp) :: ]
	real(qp) :: f(4) = [real(qp) :: 0, 0, 3, 0 ]

	real(qp) :: d(4,1) = RESHAPE ([real(qp) :: 1, 2, 3, -1], [4,1])
	real(qp) :: g(4,1) = RESHAPE ([real(qp) :: 0, 0, 4, -1], [4,1])

	! Check compile-time version

	if (abs (NORM2 ([real(qp) :: 1, 2, huge(3.0_qp)]) - huge(3.0_qp)) &
	> epsilon(0.0_qp)*huge(3.0_qp)) STOP 1

	if (abs (SNORM2([real(qp) :: 1, 2, huge(3.0_qp)],3) - huge(3.0_qp)) &
	> epsilon(0.0_qp)*huge(3.0_qp)) STOP 2

	if (abs (SNORM2([real(qp) :: 1, 2, 3],3) - NORM2([real(qp) :: 1, 2, 3])) &
	> epsilon(0.0_qp)*SNORM2([real(qp) :: 1, 2, 3],3)) STOP 3

	if (NORM2([real(qp) :: ]) /= 0.0_qp) STOP 4
	if (abs (NORM2([real(qp) :: 0, 0, 3, 0]) - 3.0_qp) > epsilon(0.0_qp)) STOP 5

	! Check TREE version

	if (abs (NORM2 (a) - huge(3.0_qp)) &
	> epsilon(0.0_qp)*huge(3.0_qp)) STOP 6

	if (abs (SNORM2(b,3) - NORM2(b)) &
	> epsilon(0.0_qp)*SNORM2(b,3)) STOP 7

	if (abs (SNORM2(c,4) - NORM2(c)) &
	> epsilon(0.0_qp)*SNORM2(c,4)) STOP 8

	if (ANY (abs (abs(d(:,1)) - NORM2(d, 2)) &
	> epsilon(0.0_qp))) STOP 9

	! Check libgfortran version

	if (ANY (abs (SNORM2(d,4) - NORM2(d, 1)) &
	> epsilon(0.0_qp)*SNORM2(d,4))) STOP 10

	if (abs (SNORM2(f,4) - NORM2(f, 1)) &
	> epsilon(0.0_qp)*SNORM2(d,4)) STOP 11

	if (ANY (abs (abs(g(:,1)) - NORM2(g, 2)) &
	> epsilon(0.0_qp))) STOP 12

	contains
	! NORM2 algorithm based on BLAS, cf.
	! http://www.netlib.org/blas/snrm2.f
	REAL(qp) FUNCTION SNORM2 (X,n)
	INTEGER, INTENT(IN) :: n
	REAL(qp), INTENT(IN) :: X(n)

	REAL(qp) :: absXi, scale, SSQ
	INTEGER :: i

	INTRINSIC :: ABS, SQRT

	IF (N < 1) THEN
	snorm2 = 0.0_qp
	ELSE IF (N == 1) THEN
	snorm2 = ABS(X(1))
	ELSE
	scale = 0.0_qp
	SSQ = 1.0_qp

	DO i = 1, N
	IF (X(i) /= 0.0_qp) THEN
	absXi = ABS(X(i))
	IF (scale < absXi) THEN
	SSQ = 1.0_qp + SSQ * (scale/absXi)**2
	scale = absXi
	ELSE
	SSQ = SSQ + (absXi/scale)**2
	END IF
	END IF
	END DO
	snorm2 = scale * SQRT(SSQ)
	END IF
	END FUNCTION SNORM2
	end