dlasq2.f
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dlasq2.f
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	*> \brief \b DLASQ2 computes all the eigenvalues of the symmetric positive definite tridiagonal matrix associated with the qd Array Z to high relative accuracy. Used by sbdsqr and sstegr.
	*
	* =========== DOCUMENTATION ===========
	*
	* Online html documentation available at
	* http://www.netlib.org/lapack/explore-html/
	*
	*> \htmlonly
	*> Download DLASQ2 + dependencies
	*> <a href="http://www.netlib.org/cgi-bin/netlibfiles.tgz?format=tgz&filename=/lapack/lapack_routine/dlasq2.f">
	*> [TGZ]</a>
	*> <a href="http://www.netlib.org/cgi-bin/netlibfiles.zip?format=zip&filename=/lapack/lapack_routine/dlasq2.f">
	*> [ZIP]</a>
	*> <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/dlasq2.f">
	*> [TXT]</a>
	*> \endhtmlonly
	*
	* Definition:
	* ===========
	*
	* SUBROUTINE DLASQ2( N, Z, INFO )
	*
	* .. Scalar Arguments ..
	* INTEGER INFO, N
	* ..
	* .. Array Arguments ..
	* DOUBLE PRECISION Z( * )
	* ..
	*
	*
	*> \par Purpose:
	* =============
	*>
	*> \verbatim
	*>
	*> DLASQ2 computes all the eigenvalues of the symmetric positive
	*> definite tridiagonal matrix associated with the qd array Z to high
	*> relative accuracy are computed to high relative accuracy, in the
	*> absence of denormalization, underflow and overflow.
	*>
	*> To see the relation of Z to the tridiagonal matrix, let L be a
	*> unit lower bidiagonal matrix with subdiagonals Z(2,4,6,,..) and
	*> let U be an upper bidiagonal matrix with 1's above and diagonal
	> Z(1,3,5,,..). The tridiagonal is LU or, if you prefer, the
	*> symmetric tridiagonal to which it is similar.
	*>
	*> Note : DLASQ2 defines a logical variable, IEEE, which is true
	*> on machines which follow ieee-754 floating-point standard in their
	*> handling of infinities and NaNs, and false otherwise. This variable
	*> is passed to DLASQ3.
	*> \endverbatim
	*
	* Arguments:
	* ==========
	*
	*> \param[in] N
	*> \verbatim
	*> N is INTEGER
	*> The number of rows and columns in the matrix. N >= 0.
	*> \endverbatim
	*>
	*> \param[in,out] Z
	*> \verbatim
	> Z is DOUBLE PRECISION array, dimension ( 4N )
	*> On entry Z holds the qd array. On exit, entries 1 to N hold
	> the eigenvalues in decreasing order, Z( 2N+1 ) holds the
	> trace, and Z( 2N+2 ) holds the sum of the eigenvalues. If
	> N > 2, then Z( 2N+3 ) holds the iteration count, Z( 2*N+4 )
	> holds NDIVS/NIN^2, and Z( 2N+5 ) holds the percentage of
	*> shifts that failed.
	*> \endverbatim
	*>
	*> \param[out] INFO
	*> \verbatim
	*> INFO is INTEGER
	*> = 0: successful exit
	*> < 0: if the i-th argument is a scalar and had an illegal
	*> value, then INFO = -i, if the i-th argument is an
	*> array and the j-entry had an illegal value, then
	> INFO = -(i100+j)
	*> > 0: the algorithm failed
	*> = 1, a split was marked by a positive value in E
	> = 2, current block of Z not diagonalized after 100N
	*> iterations (in inner while loop). On exit Z holds
	*> a qd array with the same eigenvalues as the given Z.
	*> = 3, termination criterion of outer while loop not met
	*> (program created more than N unreduced blocks)
	*> \endverbatim
	*
	* Authors:
	* ========
	*
	*> \author Univ. of Tennessee
	*> \author Univ. of California Berkeley
	*> \author Univ. of Colorado Denver
	*> \author NAG Ltd.
	*
	*> \date September 2012
	*
	*> \ingroup auxOTHERcomputational
	*
	*> \par Further Details:
	* =====================
	*>
	*> \verbatim
	*>
	*> Local Variables: I0:N0 defines a current unreduced segment of Z.
	*> The shifts are accumulated in SIGMA. Iteration count is in ITER.
	*> Ping-pong is controlled by PP (alternates between 0 and 1).
	*> \endverbatim
	*>
	* =====================================================================
	SUBROUTINE DLASQ2( N, Z, INFO )
	*
	* -- LAPACK computational routine (version 3.4.2) --
	* -- LAPACK is a software package provided by Univ. of Tennessee, --
	* -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--
	* September 2012
	*
	* .. Scalar Arguments ..
	INTEGER INFO, N
	* ..
	* .. Array Arguments ..
	DOUBLE PRECISION Z( * )
	* ..
	*
	* =====================================================================
	*
	* .. Parameters ..
	DOUBLE PRECISION CBIAS
	PARAMETER ( CBIAS = 1.50D0 )
	DOUBLE PRECISION ZERO, HALF, ONE, TWO, FOUR, HUNDRD
	PARAMETER ( ZERO = 0.0D0, HALF = 0.5D0, ONE = 1.0D0,
	$ TWO = 2.0D0, FOUR = 4.0D0, HUNDRD = 100.0D0 )
	* ..
	* .. Local Scalars ..
	LOGICAL IEEE
	INTEGER I0, I1, I4, IINFO, IPN4, ITER, IWHILA, IWHILB,
	$ K, KMIN, N0, N1, NBIG, NDIV, NFAIL, PP, SPLT,
	$ TTYPE
	DOUBLE PRECISION D, DEE, DEEMIN, DESIG, DMIN, DMIN1, DMIN2, DN,
	$ DN1, DN2, E, EMAX, EMIN, EPS, G, OLDEMN, QMAX,
	$ QMIN, S, SAFMIN, SIGMA, T, TAU, TEMP, TOL,
	$ TOL2, TRACE, ZMAX, TEMPE, TEMPQ
	* ..
	* .. External Subroutines ..
	EXTERNAL DLASQ3, DLASRT, XERBLA
	* ..
	* .. External Functions ..
	INTEGER ILAENV
	DOUBLE PRECISION DLAMCH
	EXTERNAL DLAMCH, ILAENV
	* ..
	* .. Intrinsic Functions ..
	INTRINSIC ABS, DBLE, MAX, MIN, SQRT
	* ..
	* .. Executable Statements ..
	*
	* Test the input arguments.
	* (in case DLASQ2 is not called by DLASQ1)
	*
	INFO = 0
	EPS = DLAMCH( 'Precision' )
	SAFMIN = DLAMCH( 'Safe minimum' )
	TOL = EPS*HUNDRD
	TOL2 = TOL**2
	*
	IF( N.LT.0 ) THEN
	INFO = -1
	CALL XERBLA( 'DLASQ2', 1 )
	RETURN
	ELSE IF( N.EQ.0 ) THEN
	RETURN
	ELSE IF( N.EQ.1 ) THEN
	*
	* 1-by-1 case.
	*
	IF( Z( 1 ).LT.ZERO ) THEN
	INFO = -201
	CALL XERBLA( 'DLASQ2', 2 )
	END IF
	RETURN
	ELSE IF( N.EQ.2 ) THEN
	*
	* 2-by-2 case.
	*
	IF( Z( 2 ).LT.ZERO .OR. Z( 3 ).LT.ZERO ) THEN
	INFO = -2
	CALL XERBLA( 'DLASQ2', 2 )
	RETURN
	ELSE IF( Z( 3 ).GT.Z( 1 ) ) THEN
	D = Z( 3 )
	Z( 3 ) = Z( 1 )
	Z( 1 ) = D
	END IF
	Z( 5 ) = Z( 1 ) + Z( 2 ) + Z( 3 )
	IF( Z( 2 ).GT.Z( 3 )*TOL2 ) THEN
	T = HALF*( ( Z( 1 )-Z( 3 ) )+Z( 2 ) )
	S = Z( 3 )*( Z( 2 ) / T )
	IF( S.LE.T ) THEN
	S = Z( 3 )( Z( 2 ) / ( T( ONE+SQRT( ONE+S / T ) ) ) )
	ELSE
	S = Z( 3 )( Z( 2 ) / ( T+SQRT( T )SQRT( T+S ) ) )
	END IF
	T = Z( 1 ) + ( S+Z( 2 ) )
	Z( 3 ) = Z( 3 )*( Z( 1 ) / T )
	Z( 1 ) = T
	END IF
	Z( 2 ) = Z( 3 )
	Z( 6 ) = Z( 2 ) + Z( 1 )
	RETURN
	END IF
	*
	* Check for negative data and compute sums of q's and e's.
	*
	Z( 2*N ) = ZERO
	EMIN = Z( 2 )
	QMAX = ZERO
	ZMAX = ZERO
	D = ZERO
	E = ZERO
	*
	DO 10 K = 1, 2*( N-1 ), 2
	IF( Z( K ).LT.ZERO ) THEN
	INFO = -( 200+K )
	CALL XERBLA( 'DLASQ2', 2 )
	RETURN
	ELSE IF( Z( K+1 ).LT.ZERO ) THEN
	INFO = -( 200+K+1 )
	CALL XERBLA( 'DLASQ2', 2 )
	RETURN
	END IF
	D = D + Z( K )
	E = E + Z( K+1 )
	QMAX = MAX( QMAX, Z( K ) )
	EMIN = MIN( EMIN, Z( K+1 ) )
	ZMAX = MAX( QMAX, ZMAX, Z( K+1 ) )
	10 CONTINUE
	IF( Z( 2*N-1 ).LT.ZERO ) THEN
	INFO = -( 200+2*N-1 )
	CALL XERBLA( 'DLASQ2', 2 )
	RETURN
	END IF
	D = D + Z( 2*N-1 )
	QMAX = MAX( QMAX, Z( 2*N-1 ) )
	ZMAX = MAX( QMAX, ZMAX )
	*
	* Check for diagonality.
	*
	IF( E.EQ.ZERO ) THEN
	DO 20 K = 2, N
	Z( K ) = Z( 2*K-1 )
	20 CONTINUE
	CALL DLASRT( 'D', N, Z, IINFO )
	Z( 2*N-1 ) = D
	RETURN
	END IF
	*
	TRACE = D + E
	*
	* Check for zero data.
	*
	IF( TRACE.EQ.ZERO ) THEN
	Z( 2*N-1 ) = ZERO
	RETURN
	END IF
	*
	* Check whether the machine is IEEE conformable.
	*
	IEEE = ILAENV( 10, 'DLASQ2', 'N', 1, 2, 3, 4 ).EQ.1 .AND.
	$ ILAENV( 11, 'DLASQ2', 'N', 1, 2, 3, 4 ).EQ.1
	*
	* Rearrange data for locality: Z=(q1,qq1,e1,ee1,q2,qq2,e2,ee2,...).
	*
	DO 30 K = 2*N, 2, -2
	Z( 2*K ) = ZERO
	Z( 2*K-1 ) = Z( K )
	Z( 2*K-2 ) = ZERO
	Z( 2*K-3 ) = Z( K-1 )
	30 CONTINUE
	*
	I0 = 1
	N0 = N
	*
	* Reverse the qd-array, if warranted.
	*
	IF( CBIASZ( 4I0-3 ).LT.Z( 4*N0-3 ) ) THEN
	IPN4 = 4*( I0+N0 )
	DO 40 I4 = 4I0, 2( I0+N0-1 ), 4
	TEMP = Z( I4-3 )
	Z( I4-3 ) = Z( IPN4-I4-3 )
	Z( IPN4-I4-3 ) = TEMP
	TEMP = Z( I4-1 )
	Z( I4-1 ) = Z( IPN4-I4-5 )
	Z( IPN4-I4-5 ) = TEMP
	40 CONTINUE
	END IF
	*
	* Initial split checking via dqd and Li's test.
	*
	PP = 0
	*
	DO 80 K = 1, 2
	*
	D = Z( 4*N0+PP-3 )
	DO 50 I4 = 4( N0-1 ) + PP, 4I0 + PP, -4
	IF( Z( I4-1 ).LE.TOL2*D ) THEN
	Z( I4-1 ) = -ZERO
	D = Z( I4-3 )
	ELSE
	D = Z( I4-3 )*( D / ( D+Z( I4-1 ) ) )
	END IF
	50 CONTINUE
	*
	* dqd maps Z to ZZ plus Li's test.
	*
	EMIN = Z( 4*I0+PP+1 )
	D = Z( 4*I0+PP-3 )
	DO 60 I4 = 4I0 + PP, 4( N0-1 ) + PP, 4
	Z( I4-2*PP-2 ) = D + Z( I4-1 )
	IF( Z( I4-1 ).LE.TOL2*D ) THEN
	Z( I4-1 ) = -ZERO
	Z( I4-2*PP-2 ) = D
	Z( I4-2*PP ) = ZERO
	D = Z( I4+1 )
	ELSE IF( SAFMINZ( I4+1 ).LT.Z( I4-2PP-2 ) .AND.
	$ SAFMINZ( I4-2PP-2 ).LT.Z( I4+1 ) ) THEN
	TEMP = Z( I4+1 ) / Z( I4-2*PP-2 )
	Z( I4-2PP ) = Z( I4-1 )TEMP
	D = D*TEMP
	ELSE
	Z( I4-2PP ) = Z( I4+1 )( Z( I4-1 ) / Z( I4-2*PP-2 ) )
	D = Z( I4+1 )( D / Z( I4-2PP-2 ) )
	END IF
	EMIN = MIN( EMIN, Z( I4-2*PP ) )
	60 CONTINUE
	Z( 4*N0-PP-2 ) = D
	*
	* Now find qmax.
	*
	QMAX = Z( 4*I0-PP-2 )
	DO 70 I4 = 4I0 - PP + 2, 4N0 - PP - 2, 4
	QMAX = MAX( QMAX, Z( I4 ) )
	70 CONTINUE
	*
	* Prepare for the next iteration on K.
	*
	PP = 1 - PP
	80 CONTINUE
	*
	* Initialise variables to pass to DLASQ3.
	*
	TTYPE = 0
	DMIN1 = ZERO
	DMIN2 = ZERO
	DN = ZERO
	DN1 = ZERO
	DN2 = ZERO
	G = ZERO
	TAU = ZERO
	*
	ITER = 2
	NFAIL = 0
	NDIV = 2*( N0-I0 )
	*
	DO 160 IWHILA = 1, N + 1
	IF( N0.LT.1 )
	$ GO TO 170
	*
	* While array unfinished do
	*
	* E(N0) holds the value of SIGMA when submatrix in I0:N0
	* splits from the rest of the array, but is negated.
	*
	DESIG = ZERO
	IF( N0.EQ.N ) THEN
	SIGMA = ZERO
	ELSE
	SIGMA = -Z( 4*N0-1 )
	END IF
	IF( SIGMA.LT.ZERO ) THEN
	INFO = 1
	RETURN
	END IF
	*
	* Find last unreduced submatrix's top index I0, find QMAX and
	* EMIN. Find Gershgorin-type bound if Q's much greater than E's.
	*
	EMAX = ZERO
	IF( N0.GT.I0 ) THEN
	EMIN = ABS( Z( 4*N0-5 ) )
	ELSE
	EMIN = ZERO
	END IF
	QMIN = Z( 4*N0-3 )
	QMAX = QMIN
	DO 90 I4 = 4*N0, 8, -4
	IF( Z( I4-5 ).LE.ZERO )
	$ GO TO 100
	IF( QMIN.GE.FOUR*EMAX ) THEN
	QMIN = MIN( QMIN, Z( I4-3 ) )
	EMAX = MAX( EMAX, Z( I4-5 ) )
	END IF
	QMAX = MAX( QMAX, Z( I4-7 )+Z( I4-5 ) )
	EMIN = MIN( EMIN, Z( I4-5 ) )
	90 CONTINUE
	I4 = 4
	*
	100 CONTINUE
	I0 = I4 / 4
	PP = 0
	*
	IF( N0-I0.GT.1 ) THEN
	DEE = Z( 4*I0-3 )
	DEEMIN = DEE
	KMIN = I0
	DO 110 I4 = 4I0+1, 4N0-3, 4
	DEE = Z( I4 )*( DEE /( DEE+Z( I4-2 ) ) )
	IF( DEE.LE.DEEMIN ) THEN
	DEEMIN = DEE
	KMIN = ( I4+3 )/4
	END IF
	110 CONTINUE
	IF( (KMIN-I0)*2.LT.N0-KMIN .AND.
	$ DEEMIN.LE.HALFZ(4N0-3) ) THEN
	IPN4 = 4*( I0+N0 )
	PP = 2
	DO 120 I4 = 4I0, 2( I0+N0-1 ), 4
	TEMP = Z( I4-3 )
	Z( I4-3 ) = Z( IPN4-I4-3 )
	Z( IPN4-I4-3 ) = TEMP
	TEMP = Z( I4-2 )
	Z( I4-2 ) = Z( IPN4-I4-2 )
	Z( IPN4-I4-2 ) = TEMP
	TEMP = Z( I4-1 )
	Z( I4-1 ) = Z( IPN4-I4-5 )
	Z( IPN4-I4-5 ) = TEMP
	TEMP = Z( I4 )
	Z( I4 ) = Z( IPN4-I4-4 )
	Z( IPN4-I4-4 ) = TEMP
	120 CONTINUE
	END IF
	END IF
	*
	* Put -(initial shift) into DMIN.
	*
	DMIN = -MAX( ZERO, QMIN-TWOSQRT( QMIN )SQRT( EMAX ) )
	*
	* Now I0:N0 is unreduced.
	* PP = 0 for ping, PP = 1 for pong.
	* PP = 2 indicates that flipping was applied to the Z array and
	* and that the tests for deflation upon entry in DLASQ3
	* should not be performed.
	*
	NBIG = 100*( N0-I0+1 )
	DO 140 IWHILB = 1, NBIG
	IF( I0.GT.N0 )
	$ GO TO 150
	*
	* While submatrix unfinished take a good dqds step.
	*
	CALL DLASQ3( I0, N0, Z, PP, DMIN, SIGMA, DESIG, QMAX, NFAIL,
	$ ITER, NDIV, IEEE, TTYPE, DMIN1, DMIN2, DN, DN1,
	$ DN2, G, TAU )
	*
	PP = 1 - PP
	*
	* When EMIN is very small check for splits.
	*
	IF( PP.EQ.0 .AND. N0-I0.GE.3 ) THEN
	IF( Z( 4N0 ).LE.TOL2QMAX .OR.
	$ Z( 4N0-1 ).LE.TOL2SIGMA ) THEN
	SPLT = I0 - 1
	QMAX = Z( 4*I0-3 )
	EMIN = Z( 4*I0-1 )
	OLDEMN = Z( 4*I0 )
	DO 130 I4 = 4I0, 4( N0-3 ), 4
	IF( Z( I4 ).LE.TOL2*Z( I4-3 ) .OR.
	$ Z( I4-1 ).LE.TOL2*SIGMA ) THEN
	Z( I4-1 ) = -SIGMA
	SPLT = I4 / 4
	QMAX = ZERO
	EMIN = Z( I4+3 )
	OLDEMN = Z( I4+4 )
	ELSE
	QMAX = MAX( QMAX, Z( I4+1 ) )
	EMIN = MIN( EMIN, Z( I4-1 ) )
	OLDEMN = MIN( OLDEMN, Z( I4 ) )
	END IF
	130 CONTINUE
	Z( 4*N0-1 ) = EMIN
	Z( 4*N0 ) = OLDEMN
	I0 = SPLT + 1
	END IF
	END IF
	*
	140 CONTINUE
	*
	INFO = 2
	*
	* Maximum number of iterations exceeded, restore the shift
	* SIGMA and place the new d's and e's in a qd array.
	* This might need to be done for several blocks
	*
	I1 = I0
	N1 = N0
	145 CONTINUE
	TEMPQ = Z( 4*I0-3 )
	Z( 4I0-3 ) = Z( 4I0-3 ) + SIGMA
	DO K = I0+1, N0
	TEMPE = Z( 4*K-5 )
	Z( 4K-5 ) = Z( 4K-5 ) * (TEMPQ / Z( 4*K-7 ))
	TEMPQ = Z( 4*K-3 )
	Z( 4K-3 ) = Z( 4K-3 ) + SIGMA + TEMPE - Z( 4*K-5 )
	END DO
	*
	* Prepare to do this on the previous block if there is one
	*
	IF( I1.GT.1 ) THEN
	N1 = I1-1
	DO WHILE( ( I1.GE.2 ) .AND. ( Z(4*I1-5).GE.ZERO ) )
	I1 = I1 - 1
	END DO
	SIGMA = -Z(4*N1-1)
	GO TO 145
	END IF

	DO K = 1, N
	Z( 2K-1 ) = Z( 4K-3 )
	*
	* Only the block 1..N0 is unfinished. The rest of the e's
	* must be essentially zero, although sometimes other data
	* has been stored in them.
	*
	IF( K.LT.N0 ) THEN
	Z( 2K ) = Z( 4K-1 )
	ELSE
	Z( 2*K ) = 0
	END IF
	END DO
	RETURN
	*
	* end IWHILB
	*
	150 CONTINUE
	*
	160 CONTINUE
	*
	INFO = 3
	RETURN
	*
	* end IWHILA
	*
	170 CONTINUE
	*
	* Move q's to the front.
	*
	DO 180 K = 2, N
	Z( K ) = Z( 4*K-3 )
	180 CONTINUE
	*
	* Sort and compute sum of eigenvalues.
	*
	CALL DLASRT( 'D', N, Z, IINFO )
	*
	E = ZERO
	DO 190 K = N, 1, -1
	E = E + Z( K )
	190 CONTINUE
	*
	* Store trace, sum(eigenvalues) and information on performance.
	*
	Z( 2*N+1 ) = TRACE
	Z( 2*N+2 ) = E
	Z( 2*N+3 ) = DBLE( ITER )
	Z( 2N+4 ) = DBLE( NDIV ) / DBLE( N*2 )
	Z( 2N+5 ) = HUNDRDNFAIL / DBLE( ITER )
	RETURN
	*
	* End of DLASQ2
	*
	END

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