```      SUBROUTINE SLASY2( LTRANL, LTRANR, ISGN, N1, N2, TL, LDTL, TR,
\$                   LDTR, B, LDB, SCALE, X, LDX, XNORM, INFO )
*
*  -- LAPACK auxiliary routine (version 3.1) --
*     Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd..
*     November 2006
*
*     .. Scalar Arguments ..
LOGICAL            LTRANL, LTRANR
INTEGER            INFO, ISGN, LDB, LDTL, LDTR, LDX, N1, N2
REAL               SCALE, XNORM
*     ..
*     .. Array Arguments ..
REAL               B( LDB, * ), TL( LDTL, * ), TR( LDTR, * ),
\$                   X( LDX, * )
*     ..
*
*  Purpose
*  =======
*
*  SLASY2 solves for the N1 by N2 matrix X, 1 <= N1,N2 <= 2, in
*
*         op(TL)*X + ISGN*X*op(TR) = SCALE*B,
*
*  where TL is N1 by N1, TR is N2 by N2, B is N1 by N2, and ISGN = 1 or
*  -1.  op(T) = T or T', where T' denotes the transpose of T.
*
*  Arguments
*  =========
*
*  LTRANL  (input) LOGICAL
*          On entry, LTRANL specifies the op(TL):
*             = .FALSE., op(TL) = TL,
*             = .TRUE., op(TL) = TL'.
*
*  LTRANR  (input) LOGICAL
*          On entry, LTRANR specifies the op(TR):
*            = .FALSE., op(TR) = TR,
*            = .TRUE., op(TR) = TR'.
*
*  ISGN    (input) INTEGER
*          On entry, ISGN specifies the sign of the equation
*          as described before. ISGN may only be 1 or -1.
*
*  N1      (input) INTEGER
*          On entry, N1 specifies the order of matrix TL.
*          N1 may only be 0, 1 or 2.
*
*  N2      (input) INTEGER
*          On entry, N2 specifies the order of matrix TR.
*          N2 may only be 0, 1 or 2.
*
*  TL      (input) REAL array, dimension (LDTL,2)
*          On entry, TL contains an N1 by N1 matrix.
*
*  LDTL    (input) INTEGER
*          The leading dimension of the matrix TL. LDTL >= max(1,N1).
*
*  TR      (input) REAL array, dimension (LDTR,2)
*          On entry, TR contains an N2 by N2 matrix.
*
*  LDTR    (input) INTEGER
*          The leading dimension of the matrix TR. LDTR >= max(1,N2).
*
*  B       (input) REAL array, dimension (LDB,2)
*          On entry, the N1 by N2 matrix B contains the right-hand
*          side of the equation.
*
*  LDB     (input) INTEGER
*          The leading dimension of the matrix B. LDB >= max(1,N1).
*
*  SCALE   (output) REAL
*          On exit, SCALE contains the scale factor. SCALE is chosen
*          less than or equal to 1 to prevent the solution overflowing.
*
*  X       (output) REAL array, dimension (LDX,2)
*          On exit, X contains the N1 by N2 solution.
*
*  LDX     (input) INTEGER
*          The leading dimension of the matrix X. LDX >= max(1,N1).
*
*  XNORM   (output) REAL
*          On exit, XNORM is the infinity-norm of the solution.
*
*  INFO    (output) INTEGER
*          On exit, INFO is set to
*             0: successful exit.
*             1: TL and TR have too close eigenvalues, so TL or
*                TR is perturbed to get a nonsingular equation.
*          NOTE: In the interests of speed, this routine does not
*                check the inputs for errors.
*
* =====================================================================
*
*     .. Parameters ..
REAL               ZERO, ONE
PARAMETER          ( ZERO = 0.0E+0, ONE = 1.0E+0 )
REAL               TWO, HALF, EIGHT
PARAMETER          ( TWO = 2.0E+0, HALF = 0.5E+0, EIGHT = 8.0E+0 )
*     ..
*     .. Local Scalars ..
LOGICAL            BSWAP, XSWAP
INTEGER            I, IP, IPIV, IPSV, J, JP, JPSV, K
REAL               BET, EPS, GAM, L21, SGN, SMIN, SMLNUM, TAU1,
\$                   TEMP, U11, U12, U22, XMAX
*     ..
*     .. Local Arrays ..
LOGICAL            BSWPIV( 4 ), XSWPIV( 4 )
INTEGER            JPIV( 4 ), LOCL21( 4 ), LOCU12( 4 ),
\$                   LOCU22( 4 )
REAL               BTMP( 4 ), T16( 4, 4 ), TMP( 4 ), X2( 2 )
*     ..
*     .. External Functions ..
INTEGER            ISAMAX
REAL               SLAMCH
EXTERNAL           ISAMAX, SLAMCH
*     ..
*     .. External Subroutines ..
EXTERNAL           SCOPY, SSWAP
*     ..
*     .. Intrinsic Functions ..
INTRINSIC          ABS, MAX
*     ..
*     .. Data statements ..
DATA               LOCU12 / 3, 4, 1, 2 / , LOCL21 / 2, 1, 4, 3 / ,
\$                   LOCU22 / 4, 3, 2, 1 /
DATA               XSWPIV / .FALSE., .FALSE., .TRUE., .TRUE. /
DATA               BSWPIV / .FALSE., .TRUE., .FALSE., .TRUE. /
*     ..
*     .. Executable Statements ..
*
*     Do not check the input parameters for errors
*
INFO = 0
*
*     Quick return if possible
*
IF( N1.EQ.0 .OR. N2.EQ.0 )
\$   RETURN
*
*     Set constants to control overflow
*
EPS = SLAMCH( 'P' )
SMLNUM = SLAMCH( 'S' ) / EPS
SGN = ISGN
*
K = N1 + N1 + N2 - 2
GO TO ( 10, 20, 30, 50 )K
*
*     1 by 1: TL11*X + SGN*X*TR11 = B11
*
10 CONTINUE
TAU1 = TL( 1, 1 ) + SGN*TR( 1, 1 )
BET = ABS( TAU1 )
IF( BET.LE.SMLNUM ) THEN
TAU1 = SMLNUM
BET = SMLNUM
INFO = 1
END IF
*
SCALE = ONE
GAM = ABS( B( 1, 1 ) )
IF( SMLNUM*GAM.GT.BET )
\$   SCALE = ONE / GAM
*
X( 1, 1 ) = ( B( 1, 1 )*SCALE ) / TAU1
XNORM = ABS( X( 1, 1 ) )
RETURN
*
*     1 by 2:
*     TL11*[X11 X12] + ISGN*[X11 X12]*op[TR11 TR12]  = [B11 B12]
*                                       [TR21 TR22]
*
20 CONTINUE
*
SMIN = MAX( EPS*MAX( ABS( TL( 1, 1 ) ), ABS( TR( 1, 1 ) ),
\$       ABS( TR( 1, 2 ) ), ABS( TR( 2, 1 ) ), ABS( TR( 2, 2 ) ) ),
\$       SMLNUM )
TMP( 1 ) = TL( 1, 1 ) + SGN*TR( 1, 1 )
TMP( 4 ) = TL( 1, 1 ) + SGN*TR( 2, 2 )
IF( LTRANR ) THEN
TMP( 2 ) = SGN*TR( 2, 1 )
TMP( 3 ) = SGN*TR( 1, 2 )
ELSE
TMP( 2 ) = SGN*TR( 1, 2 )
TMP( 3 ) = SGN*TR( 2, 1 )
END IF
BTMP( 1 ) = B( 1, 1 )
BTMP( 2 ) = B( 1, 2 )
GO TO 40
*
*     2 by 1:
*          op[TL11 TL12]*[X11] + ISGN* [X11]*TR11  = [B11]
*            [TL21 TL22] [X21]         [X21]         [B21]
*
30 CONTINUE
SMIN = MAX( EPS*MAX( ABS( TR( 1, 1 ) ), ABS( TL( 1, 1 ) ),
\$       ABS( TL( 1, 2 ) ), ABS( TL( 2, 1 ) ), ABS( TL( 2, 2 ) ) ),
\$       SMLNUM )
TMP( 1 ) = TL( 1, 1 ) + SGN*TR( 1, 1 )
TMP( 4 ) = TL( 2, 2 ) + SGN*TR( 1, 1 )
IF( LTRANL ) THEN
TMP( 2 ) = TL( 1, 2 )
TMP( 3 ) = TL( 2, 1 )
ELSE
TMP( 2 ) = TL( 2, 1 )
TMP( 3 ) = TL( 1, 2 )
END IF
BTMP( 1 ) = B( 1, 1 )
BTMP( 2 ) = B( 2, 1 )
40 CONTINUE
*
*     Solve 2 by 2 system using complete pivoting.
*     Set pivots less than SMIN to SMIN.
*
IPIV = ISAMAX( 4, TMP, 1 )
U11 = TMP( IPIV )
IF( ABS( U11 ).LE.SMIN ) THEN
INFO = 1
U11 = SMIN
END IF
U12 = TMP( LOCU12( IPIV ) )
L21 = TMP( LOCL21( IPIV ) ) / U11
U22 = TMP( LOCU22( IPIV ) ) - U12*L21
XSWAP = XSWPIV( IPIV )
BSWAP = BSWPIV( IPIV )
IF( ABS( U22 ).LE.SMIN ) THEN
INFO = 1
U22 = SMIN
END IF
IF( BSWAP ) THEN
TEMP = BTMP( 2 )
BTMP( 2 ) = BTMP( 1 ) - L21*TEMP
BTMP( 1 ) = TEMP
ELSE
BTMP( 2 ) = BTMP( 2 ) - L21*BTMP( 1 )
END IF
SCALE = ONE
IF( ( TWO*SMLNUM )*ABS( BTMP( 2 ) ).GT.ABS( U22 ) .OR.
\$    ( TWO*SMLNUM )*ABS( BTMP( 1 ) ).GT.ABS( U11 ) ) THEN
SCALE = HALF / MAX( ABS( BTMP( 1 ) ), ABS( BTMP( 2 ) ) )
BTMP( 1 ) = BTMP( 1 )*SCALE
BTMP( 2 ) = BTMP( 2 )*SCALE
END IF
X2( 2 ) = BTMP( 2 ) / U22
X2( 1 ) = BTMP( 1 ) / U11 - ( U12 / U11 )*X2( 2 )
IF( XSWAP ) THEN
TEMP = X2( 2 )
X2( 2 ) = X2( 1 )
X2( 1 ) = TEMP
END IF
X( 1, 1 ) = X2( 1 )
IF( N1.EQ.1 ) THEN
X( 1, 2 ) = X2( 2 )
XNORM = ABS( X( 1, 1 ) ) + ABS( X( 1, 2 ) )
ELSE
X( 2, 1 ) = X2( 2 )
XNORM = MAX( ABS( X( 1, 1 ) ), ABS( X( 2, 1 ) ) )
END IF
RETURN
*
*     2 by 2:
*     op[TL11 TL12]*[X11 X12] +ISGN* [X11 X12]*op[TR11 TR12] = [B11 B12]
*       [TL21 TL22] [X21 X22]        [X21 X22]   [TR21 TR22]   [B21 B22]
*
*     Solve equivalent 4 by 4 system using complete pivoting.
*     Set pivots less than SMIN to SMIN.
*
50 CONTINUE
SMIN = MAX( ABS( TR( 1, 1 ) ), ABS( TR( 1, 2 ) ),
\$       ABS( TR( 2, 1 ) ), ABS( TR( 2, 2 ) ) )
SMIN = MAX( SMIN, ABS( TL( 1, 1 ) ), ABS( TL( 1, 2 ) ),
\$       ABS( TL( 2, 1 ) ), ABS( TL( 2, 2 ) ) )
SMIN = MAX( EPS*SMIN, SMLNUM )
BTMP( 1 ) = ZERO
CALL SCOPY( 16, BTMP, 0, T16, 1 )
T16( 1, 1 ) = TL( 1, 1 ) + SGN*TR( 1, 1 )
T16( 2, 2 ) = TL( 2, 2 ) + SGN*TR( 1, 1 )
T16( 3, 3 ) = TL( 1, 1 ) + SGN*TR( 2, 2 )
T16( 4, 4 ) = TL( 2, 2 ) + SGN*TR( 2, 2 )
IF( LTRANL ) THEN
T16( 1, 2 ) = TL( 2, 1 )
T16( 2, 1 ) = TL( 1, 2 )
T16( 3, 4 ) = TL( 2, 1 )
T16( 4, 3 ) = TL( 1, 2 )
ELSE
T16( 1, 2 ) = TL( 1, 2 )
T16( 2, 1 ) = TL( 2, 1 )
T16( 3, 4 ) = TL( 1, 2 )
T16( 4, 3 ) = TL( 2, 1 )
END IF
IF( LTRANR ) THEN
T16( 1, 3 ) = SGN*TR( 1, 2 )
T16( 2, 4 ) = SGN*TR( 1, 2 )
T16( 3, 1 ) = SGN*TR( 2, 1 )
T16( 4, 2 ) = SGN*TR( 2, 1 )
ELSE
T16( 1, 3 ) = SGN*TR( 2, 1 )
T16( 2, 4 ) = SGN*TR( 2, 1 )
T16( 3, 1 ) = SGN*TR( 1, 2 )
T16( 4, 2 ) = SGN*TR( 1, 2 )
END IF
BTMP( 1 ) = B( 1, 1 )
BTMP( 2 ) = B( 2, 1 )
BTMP( 3 ) = B( 1, 2 )
BTMP( 4 ) = B( 2, 2 )
*
*     Perform elimination
*
DO 100 I = 1, 3
XMAX = ZERO
DO 70 IP = I, 4
DO 60 JP = I, 4
IF( ABS( T16( IP, JP ) ).GE.XMAX ) THEN
XMAX = ABS( T16( IP, JP ) )
IPSV = IP
JPSV = JP
END IF
60       CONTINUE
70    CONTINUE
IF( IPSV.NE.I ) THEN
CALL SSWAP( 4, T16( IPSV, 1 ), 4, T16( I, 1 ), 4 )
TEMP = BTMP( I )
BTMP( I ) = BTMP( IPSV )
BTMP( IPSV ) = TEMP
END IF
IF( JPSV.NE.I )
\$      CALL SSWAP( 4, T16( 1, JPSV ), 1, T16( 1, I ), 1 )
JPIV( I ) = JPSV
IF( ABS( T16( I, I ) ).LT.SMIN ) THEN
INFO = 1
T16( I, I ) = SMIN
END IF
DO 90 J = I + 1, 4
T16( J, I ) = T16( J, I ) / T16( I, I )
BTMP( J ) = BTMP( J ) - T16( J, I )*BTMP( I )
DO 80 K = I + 1, 4
T16( J, K ) = T16( J, K ) - T16( J, I )*T16( I, K )
80       CONTINUE
90    CONTINUE
100 CONTINUE
IF( ABS( T16( 4, 4 ) ).LT.SMIN )
\$   T16( 4, 4 ) = SMIN
SCALE = ONE
IF( ( EIGHT*SMLNUM )*ABS( BTMP( 1 ) ).GT.ABS( T16( 1, 1 ) ) .OR.
\$    ( EIGHT*SMLNUM )*ABS( BTMP( 2 ) ).GT.ABS( T16( 2, 2 ) ) .OR.
\$    ( EIGHT*SMLNUM )*ABS( BTMP( 3 ) ).GT.ABS( T16( 3, 3 ) ) .OR.
\$    ( EIGHT*SMLNUM )*ABS( BTMP( 4 ) ).GT.ABS( T16( 4, 4 ) ) ) THEN
SCALE = ( ONE / EIGHT ) / MAX( ABS( BTMP( 1 ) ),
\$           ABS( BTMP( 2 ) ), ABS( BTMP( 3 ) ), ABS( BTMP( 4 ) ) )
BTMP( 1 ) = BTMP( 1 )*SCALE
BTMP( 2 ) = BTMP( 2 )*SCALE
BTMP( 3 ) = BTMP( 3 )*SCALE
BTMP( 4 ) = BTMP( 4 )*SCALE
END IF
DO 120 I = 1, 4
K = 5 - I
TEMP = ONE / T16( K, K )
TMP( K ) = BTMP( K )*TEMP
DO 110 J = K + 1, 4
TMP( K ) = TMP( K ) - ( TEMP*T16( K, J ) )*TMP( J )
110    CONTINUE
120 CONTINUE
DO 130 I = 1, 3
IF( JPIV( 4-I ).NE.4-I ) THEN
TEMP = TMP( 4-I )
TMP( 4-I ) = TMP( JPIV( 4-I ) )
TMP( JPIV( 4-I ) ) = TEMP
END IF
130 CONTINUE
X( 1, 1 ) = TMP( 1 )
X( 2, 1 ) = TMP( 2 )
X( 1, 2 ) = TMP( 3 )
X( 2, 2 ) = TMP( 4 )
XNORM = MAX( ABS( TMP( 1 ) )+ABS( TMP( 3 ) ),
\$        ABS( TMP( 2 ) )+ABS( TMP( 4 ) ) )
RETURN
*
*     End of SLASY2
*
END

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