REAL FUNCTION SOPAUX( SUBNAM, M, N, KL, KU, NB ) * * -- LAPACK timing routine (version 3.0) -- * Univ. of Tennessee, Univ. of California Berkeley, NAG Ltd., * Courant Institute, Argonne National Lab, and Rice University * March 31, 1993 * * .. Scalar Arguments .. CHARACTER*6 SUBNAM INTEGER KL, KU, M, N, NB * .. * * Purpose * ======= * * SOPAUX computes an approximation of the number of floating point * operations used by the subroutine SUBNAM with the given values * of the parameters M, N, KL, KU, and NB. * * This version counts operations for the LAPACK auxiliary routines. * * Arguments * ========= * * SUBNAM (input) CHARACTER*6 * The name of the subroutine. * * M (input) INTEGER * The number of rows of the coefficient matrix. M >= 0. * * N (input) INTEGER * The number of columns of the coefficient matrix. * If the matrix is square (such as in a solve routine) then * N is the number of right hand sides. N >= 0. * * KL (input) INTEGER * The lower band width of the coefficient matrix. * If needed, 0 <= KL <= M-1. * * KU (input) INTEGER * The upper band width of the coefficient matrix. * If needed, 0 <= KU <= N-1. * * NB (input) INTEGER * The block size. If needed, NB >= 1. * * ===================================================================== * * .. Local Scalars .. CHARACTER C1 CHARACTER*2 C2 CHARACTER*3 C3 REAL ADDFAC, ADDS, EK, EM, EN, ENB, MULFAC, MULTS * .. * .. External Functions .. LOGICAL LSAME, LSAMEN EXTERNAL LSAME, LSAMEN * .. * .. Executable Statements .. * SOPAUX = 0 MULTS = 0 ADDS = 0 C1 = SUBNAM( 1: 1 ) C2 = SUBNAM( 2: 3 ) C3 = SUBNAM( 4: 6 ) IF( M.LE.0 .OR. $ .NOT.( LSAME( C1, 'S' ) .OR. LSAME( C1, 'D' ) .OR. $ LSAME( C1, 'C' ) .OR. LSAME( C1, 'Z' ) ) ) THEN RETURN END IF IF( LSAME( C1, 'S' ) .OR. LSAME( C1, 'D' ) ) THEN MULFAC = 1 ADDFAC = 1 ELSE MULFAC = 6 ADDFAC = 2 END IF EM = M EN = N ENB = NB * IF( LSAMEN( 2, C2, 'LA' ) ) THEN * * xLAULM: N => M * IF( LSAMEN( 3, C3, 'ULM' ) .OR. LSAMEN( 3, C3, 'UL2' ) ) THEN MULTS = ( 1./3. )*EM*( -1.+EM*EM ) ADDS = EM*( 1./6.+EM*( -1./2.+EM*( 1./3. ) ) ) * * xLAUUM: N => M * ELSE IF( LSAMEN( 3, C3, 'UUM' ) .OR. LSAMEN( 3, C3, 'UU2' ) ) $ THEN MULTS = EM*( 1./3.+EM*( 1./2.+EM*( 1./6. ) ) ) ADDS = ( 1./6. )*EM*( -1.+EM*EM ) * * xLACON: N => M * ELSE IF( LSAMEN( 3, C3, 'CON' ) ) THEN MULTS = 3.*EM + 3. ADDS = 4.*EM - 3. * * xLARF: M, N => M, N * ELSE IF( LSAMEN( 3, C3, 'RF ' ) ) THEN MULTS = 2.*EM*EN + EN ADDS = 2.*EM*EN * * xLARFB: M, N, SIDE, NB => M, N, KL, NB * where KL <= 0 indicates SIDE = 'L' * and KL > 0 indicates SIDE = 'R' * ELSE IF( LSAMEN( 3, C3, 'RFB' ) ) THEN * * KL <= 0: Code requiring local array * IF( KL.LE.0 ) THEN MULTS = EN*ENB*( 2.*EM+( ENB+1. )/2. ) ADDS = EN*ENB*( 2.*EM+( ENB-1. )/2. ) * * KL > 0: Code not requiring local array * ELSE MULTS = EN*ENB*( 2.*EM+( -ENB/2.+5./2. ) ) ADDS = EN*ENB*( 2.*EM+( -ENB/2.-1./2. ) ) END IF * * xLARFG: N => M * ELSE IF( LSAMEN( 3, C3, 'RFG' ) ) THEN MULTS = 2.*EM + 4. ADDS = EM + 1. * * xLARFT: M, NB => M, N * ELSE IF( LSAMEN( 3, C3, 'RFT' ) ) THEN MULTS = EN*( ( -5./6.+EN*( 1.+EN*( -1./6. ) ) )+( EM/2. )* $ ( EN-1. ) ) ADDS = EN*( ( 1./6. )*( 1.-EN*EN )+( EM/2. )*( EN-1. ) ) * * xLATRD: N, K => M, N * ELSE IF( LSAMEN( 3, C3, 'TRD' ) ) THEN EK = N MULTS = EK*( ( 25./6.-EK*( 3./2.+( 5./3. )*EK ) )+EM* $ ( 2.+2.*EK+EM ) ) ADDS = EK*( ( -1./3.-( 5./3. )*EK*EK )+EM*( -1.+2.*EK+EM ) ) END IF * END IF * SOPAUX = MULFAC*MULTS + ADDFAC*ADDS * RETURN * * End of SOPAUX * END