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SUBROUTINE SLAEXC( WANTQ, N, T, LDT, Q, LDQ, J1, N1, N2, WORK,
$ INFO ) * * -- LAPACK auxiliary routine (version 3.2) -- * -- LAPACK is a software package provided by Univ. of Tennessee, -- * -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..-- * November 2006 * * .. Scalar Arguments .. LOGICAL WANTQ INTEGER INFO, J1, LDQ, LDT, N, N1, N2 * .. * .. Array Arguments .. REAL Q( LDQ, * ), T( LDT, * ), WORK( * ) * .. * * Purpose * ======= * * SLAEXC swaps adjacent diagonal blocks T11 and T22 of order 1 or 2 in * an upper quasi-triangular matrix T by an orthogonal similarity * transformation. * * T must be in Schur canonical form, that is, block upper triangular * with 1-by-1 and 2-by-2 diagonal blocks; each 2-by-2 diagonal block * has its diagonal elemnts equal and its off-diagonal elements of * opposite sign. * * Arguments * ========= * * WANTQ (input) LOGICAL * = .TRUE. : accumulate the transformation in the matrix Q; * = .FALSE.: do not accumulate the transformation. * * N (input) INTEGER * The order of the matrix T. N >= 0. * * T (input/output) REAL array, dimension (LDT,N) * On entry, the upper quasi-triangular matrix T, in Schur * canonical form. * On exit, the updated matrix T, again in Schur canonical form. * * LDT (input) INTEGER * The leading dimension of the array T. LDT >= max(1,N). * * Q (input/output) REAL array, dimension (LDQ,N) * On entry, if WANTQ is .TRUE., the orthogonal matrix Q. * On exit, if WANTQ is .TRUE., the updated matrix Q. * If WANTQ is .FALSE., Q is not referenced. * * LDQ (input) INTEGER * The leading dimension of the array Q. * LDQ >= 1; and if WANTQ is .TRUE., LDQ >= N. * * J1 (input) INTEGER * The index of the first row of the first block T11. * * N1 (input) INTEGER * The order of the first block T11. N1 = 0, 1 or 2. * * N2 (input) INTEGER * The order of the second block T22. N2 = 0, 1 or 2. * * WORK (workspace) REAL array, dimension (N) * * INFO (output) INTEGER * = 0: successful exit * = 1: the transformed matrix T would be too far from Schur * form; the blocks are not swapped and T and Q are * unchanged. * * ===================================================================== * * .. Parameters .. REAL ZERO, ONE PARAMETER ( ZERO = 0.0E+0, ONE = 1.0E+0 ) REAL TEN PARAMETER ( TEN = 1.0E+1 ) INTEGER LDD, LDX PARAMETER ( LDD = 4, LDX = 2 ) * .. * .. Local Scalars .. INTEGER IERR, J2, J3, J4, K, ND REAL CS, DNORM, EPS, SCALE, SMLNUM, SN, T11, T22, $ T33, TAU, TAU1, TAU2, TEMP, THRESH, WI1, WI2, $ WR1, WR2, XNORM * .. * .. Local Arrays .. REAL D( LDD, 4 ), U( 3 ), U1( 3 ), U2( 3 ), $ X( LDX, 2 ) * .. * .. External Functions .. REAL SLAMCH, SLANGE EXTERNAL SLAMCH, SLANGE * .. * .. External Subroutines .. EXTERNAL SLACPY, SLANV2, SLARFG, SLARFX, SLARTG, SLASY2, $ SROT * .. * .. Intrinsic Functions .. INTRINSIC ABS, MAX * .. * .. Executable Statements .. * INFO = 0 * * Quick return if possible * IF( N.EQ.0 .OR. N1.EQ.0 .OR. N2.EQ.0 ) $ RETURN IF( J1+N1.GT.N ) $ RETURN * J2 = J1 + 1 J3 = J1 + 2 J4 = J1 + 3 * IF( N1.EQ.1 .AND. N2.EQ.1 ) THEN * * Swap two 1-by-1 blocks. * T11 = T( J1, J1 ) T22 = T( J2, J2 ) * * Determine the transformation to perform the interchange. * CALL SLARTG( T( J1, J2 ), T22-T11, CS, SN, TEMP ) * * Apply transformation to the matrix T. * IF( J3.LE.N ) $ CALL SROT( N-J1-1, T( J1, J3 ), LDT, T( J2, J3 ), LDT, CS, $ SN ) CALL SROT( J1-1, T( 1, J1 ), 1, T( 1, J2 ), 1, CS, SN ) * T( J1, J1 ) = T22 T( J2, J2 ) = T11 * IF( WANTQ ) THEN * * Accumulate transformation in the matrix Q. * CALL SROT( N, Q( 1, J1 ), 1, Q( 1, J2 ), 1, CS, SN ) END IF * ELSE * * Swapping involves at least one 2-by-2 block. * * Copy the diagonal block of order N1+N2 to the local array D * and compute its norm. * ND = N1 + N2 CALL SLACPY( 'Full', ND, ND, T( J1, J1 ), LDT, D, LDD ) DNORM = SLANGE( 'Max', ND, ND, D, LDD, WORK ) * * Compute machine-dependent threshold for test for accepting * swap. * EPS = SLAMCH( 'P' ) SMLNUM = SLAMCH( 'S' ) / EPS THRESH = MAX( TEN*EPS*DNORM, SMLNUM ) * * Solve T11*X - X*T22 = scale*T12 for X. * CALL SLASY2( .FALSE., .FALSE., -1, N1, N2, D, LDD, $ D( N1+1, N1+1 ), LDD, D( 1, N1+1 ), LDD, SCALE, X, $ LDX, XNORM, IERR ) * * Swap the adjacent diagonal blocks. * K = N1 + N1 + N2 - 3 GO TO ( 10, 20, 30 )K * 10 CONTINUE * * N1 = 1, N2 = 2: generate elementary reflector H so that: * * ( scale, X11, X12 ) H = ( 0, 0, * ) * U( 1 ) = SCALE U( 2 ) = X( 1, 1 ) U( 3 ) = X( 1, 2 ) CALL SLARFG( 3, U( 3 ), U, 1, TAU ) U( 3 ) = ONE T11 = T( J1, J1 ) * * Perform swap provisionally on diagonal block in D. * CALL SLARFX( 'L', 3, 3, U, TAU, D, LDD, WORK ) CALL SLARFX( 'R', 3, 3, U, TAU, D, LDD, WORK ) * * Test whether to reject swap. * IF( MAX( ABS( D( 3, 1 ) ), ABS( D( 3, 2 ) ), ABS( D( 3, $ 3 )-T11 ) ).GT.THRESH )GO TO 50 * * Accept swap: apply transformation to the entire matrix T. * CALL SLARFX( 'L', 3, N-J1+1, U, TAU, T( J1, J1 ), LDT, WORK ) CALL SLARFX( 'R', J2, 3, U, TAU, T( 1, J1 ), LDT, WORK ) * T( J3, J1 ) = ZERO T( J3, J2 ) = ZERO T( J3, J3 ) = T11 * IF( WANTQ ) THEN * * Accumulate transformation in the matrix Q. * CALL SLARFX( 'R', N, 3, U, TAU, Q( 1, J1 ), LDQ, WORK ) END IF GO TO 40 * 20 CONTINUE * * N1 = 2, N2 = 1: generate elementary reflector H so that: * * H ( -X11 ) = ( * ) * ( -X21 ) = ( 0 ) * ( scale ) = ( 0 ) * U( 1 ) = -X( 1, 1 ) U( 2 ) = -X( 2, 1 ) U( 3 ) = SCALE CALL SLARFG( 3, U( 1 ), U( 2 ), 1, TAU ) U( 1 ) = ONE T33 = T( J3, J3 ) * * Perform swap provisionally on diagonal block in D. * CALL SLARFX( 'L', 3, 3, U, TAU, D, LDD, WORK ) CALL SLARFX( 'R', 3, 3, U, TAU, D, LDD, WORK ) * * Test whether to reject swap. * IF( MAX( ABS( D( 2, 1 ) ), ABS( D( 3, 1 ) ), ABS( D( 1, $ 1 )-T33 ) ).GT.THRESH )GO TO 50 * * Accept swap: apply transformation to the entire matrix T. * CALL SLARFX( 'R', J3, 3, U, TAU, T( 1, J1 ), LDT, WORK ) CALL SLARFX( 'L', 3, N-J1, U, TAU, T( J1, J2 ), LDT, WORK ) * T( J1, J1 ) = T33 T( J2, J1 ) = ZERO T( J3, J1 ) = ZERO * IF( WANTQ ) THEN * * Accumulate transformation in the matrix Q. * CALL SLARFX( 'R', N, 3, U, TAU, Q( 1, J1 ), LDQ, WORK ) END IF GO TO 40 * 30 CONTINUE * * N1 = 2, N2 = 2: generate elementary reflectors H(1) and H(2) so * that: * * H(2) H(1) ( -X11 -X12 ) = ( * * ) * ( -X21 -X22 ) ( 0 * ) * ( scale 0 ) ( 0 0 ) * ( 0 scale ) ( 0 0 ) * U1( 1 ) = -X( 1, 1 ) U1( 2 ) = -X( 2, 1 ) U1( 3 ) = SCALE CALL SLARFG( 3, U1( 1 ), U1( 2 ), 1, TAU1 ) U1( 1 ) = ONE * TEMP = -TAU1*( X( 1, 2 )+U1( 2 )*X( 2, 2 ) ) U2( 1 ) = -TEMP*U1( 2 ) - X( 2, 2 ) U2( 2 ) = -TEMP*U1( 3 ) U2( 3 ) = SCALE CALL SLARFG( 3, U2( 1 ), U2( 2 ), 1, TAU2 ) U2( 1 ) = ONE * * Perform swap provisionally on diagonal block in D. * CALL SLARFX( 'L', 3, 4, U1, TAU1, D, LDD, WORK ) CALL SLARFX( 'R', 4, 3, U1, TAU1, D, LDD, WORK ) CALL SLARFX( 'L', 3, 4, U2, TAU2, D( 2, 1 ), LDD, WORK ) CALL SLARFX( 'R', 4, 3, U2, TAU2, D( 1, 2 ), LDD, WORK ) * * Test whether to reject swap. * IF( MAX( ABS( D( 3, 1 ) ), ABS( D( 3, 2 ) ), ABS( D( 4, 1 ) ), $ ABS( D( 4, 2 ) ) ).GT.THRESH )GO TO 50 * * Accept swap: apply transformation to the entire matrix T. * CALL SLARFX( 'L', 3, N-J1+1, U1, TAU1, T( J1, J1 ), LDT, WORK ) CALL SLARFX( 'R', J4, 3, U1, TAU1, T( 1, J1 ), LDT, WORK ) CALL SLARFX( 'L', 3, N-J1+1, U2, TAU2, T( J2, J1 ), LDT, WORK ) CALL SLARFX( 'R', J4, 3, U2, TAU2, T( 1, J2 ), LDT, WORK ) * T( J3, J1 ) = ZERO T( J3, J2 ) = ZERO T( J4, J1 ) = ZERO T( J4, J2 ) = ZERO * IF( WANTQ ) THEN * * Accumulate transformation in the matrix Q. * CALL SLARFX( 'R', N, 3, U1, TAU1, Q( 1, J1 ), LDQ, WORK ) CALL SLARFX( 'R', N, 3, U2, TAU2, Q( 1, J2 ), LDQ, WORK ) END IF * 40 CONTINUE * IF( N2.EQ.2 ) THEN * * Standardize new 2-by-2 block T11 * CALL SLANV2( T( J1, J1 ), T( J1, J2 ), T( J2, J1 ), $ T( J2, J2 ), WR1, WI1, WR2, WI2, CS, SN ) CALL SROT( N-J1-1, T( J1, J1+2 ), LDT, T( J2, J1+2 ), LDT, $ CS, SN ) CALL SROT( J1-1, T( 1, J1 ), 1, T( 1, J2 ), 1, CS, SN ) IF( WANTQ ) $ CALL SROT( N, Q( 1, J1 ), 1, Q( 1, J2 ), 1, CS, SN ) END IF * IF( N1.EQ.2 ) THEN * * Standardize new 2-by-2 block T22 * J3 = J1 + N2 J4 = J3 + 1 CALL SLANV2( T( J3, J3 ), T( J3, J4 ), T( J4, J3 ), $ T( J4, J4 ), WR1, WI1, WR2, WI2, CS, SN ) IF( J3+2.LE.N ) $ CALL SROT( N-J3-1, T( J3, J3+2 ), LDT, T( J4, J3+2 ), $ LDT, CS, SN ) CALL SROT( J3-1, T( 1, J3 ), 1, T( 1, J4 ), 1, CS, SN ) IF( WANTQ ) $ CALL SROT( N, Q( 1, J3 ), 1, Q( 1, J4 ), 1, CS, SN ) END IF * END IF RETURN * * Exit with INFO = 1 if swap was rejected. * 50 INFO = 1 RETURN * * End of SLAEXC * END |