| @@ -23,7 +23,7 @@ C> \brief \b CGEQRF VARIANT: left-looking Level 3 BLAS version of the algorithm. | |||||
| C>\details \b Purpose: | C>\details \b Purpose: | ||||
| C>\verbatim | C>\verbatim | ||||
| C> | C> | ||||
| C> CGEQRF computes a QR factorization of a real M-by-N matrix A: | |||||
| C> CGEQRF computes a QR factorization of a complex M-by-N matrix A: | |||||
| C> A = Q * R. | C> A = Q * R. | ||||
| C> | C> | ||||
| C> This is the left-looking Level 3 BLAS version of the algorithm. | C> This is the left-looking Level 3 BLAS version of the algorithm. | ||||
| @@ -172,12 +172,11 @@ C> | |||||
| EXTERNAL CGEQR2, CLARFB, CLARFT, XERBLA | EXTERNAL CGEQR2, CLARFB, CLARFT, XERBLA | ||||
| * .. | * .. | ||||
| * .. Intrinsic Functions .. | * .. Intrinsic Functions .. | ||||
| INTRINSIC MAX, MIN | |||||
| INTRINSIC CEILING, MAX, MIN, REAL | |||||
| * .. | * .. | ||||
| * .. External Functions .. | * .. External Functions .. | ||||
| INTEGER ILAENV | INTEGER ILAENV | ||||
| REAL SCEIL | |||||
| EXTERNAL ILAENV, SCEIL | |||||
| EXTERNAL ILAENV | |||||
| * .. | * .. | ||||
| * .. Executable Statements .. | * .. Executable Statements .. | ||||
| @@ -205,13 +204,13 @@ C> | |||||
| * | * | ||||
| * So here 4 x 4 is the last T stored in the workspace | * So here 4 x 4 is the last T stored in the workspace | ||||
| * | * | ||||
| NT = K-SCEIL(REAL(K-NX)/REAL(NB))*NB | |||||
| NT = K-CEILING(REAL(K-NX)/REAL(NB))*NB | |||||
| * | * | ||||
| * optimal workspace = space for dlarfb + space for normal T's + space for the last T | * optimal workspace = space for dlarfb + space for normal T's + space for the last T | ||||
| * | * | ||||
| LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | ||||
| LLWORK = SCEIL(REAL(LLWORK)/REAL(NB)) | |||||
| LLWORK = CEILING(REAL(LLWORK)/REAL(NB)) | |||||
| IF( K.EQ.0 ) THEN | IF( K.EQ.0 ) THEN | ||||
| @@ -230,7 +229,7 @@ C> | |||||
| ELSE | ELSE | ||||
| LBWORK = SCEIL(REAL(K)/REAL(NB))*NB | |||||
| LBWORK = CEILING(REAL(K)/REAL(NB))*NB | |||||
| LWKOPT = (LBWORK+LLWORK-NB)*NB | LWKOPT = (LBWORK+LLWORK-NB)*NB | ||||
| WORK( 1 ) = LWKOPT | WORK( 1 ) = LWKOPT | ||||
| @@ -172,12 +172,11 @@ C> | |||||
| EXTERNAL DGEQR2, DLARFB, DLARFT, XERBLA | EXTERNAL DGEQR2, DLARFB, DLARFT, XERBLA | ||||
| * .. | * .. | ||||
| * .. Intrinsic Functions .. | * .. Intrinsic Functions .. | ||||
| INTRINSIC MAX, MIN | |||||
| INTRINSIC CEILING, MAX, MIN, REAL | |||||
| * .. | * .. | ||||
| * .. External Functions .. | * .. External Functions .. | ||||
| INTEGER ILAENV | INTEGER ILAENV | ||||
| REAL SCEIL | |||||
| EXTERNAL ILAENV, SCEIL | |||||
| EXTERNAL ILAENV | |||||
| * .. | * .. | ||||
| * .. Executable Statements .. | * .. Executable Statements .. | ||||
| @@ -205,13 +204,13 @@ C> | |||||
| * | * | ||||
| * So here 4 x 4 is the last T stored in the workspace | * So here 4 x 4 is the last T stored in the workspace | ||||
| * | * | ||||
| NT = K-SCEIL(REAL(K-NX)/REAL(NB))*NB | |||||
| NT = K-CEILING(REAL(K-NX)/REAL(NB))*NB | |||||
| * | * | ||||
| * optimal workspace = space for dlarfb + space for normal T's + space for the last T | * optimal workspace = space for dlarfb + space for normal T's + space for the last T | ||||
| * | * | ||||
| LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | ||||
| LLWORK = SCEIL(REAL(LLWORK)/REAL(NB)) | |||||
| LLWORK = CEILING(REAL(LLWORK)/REAL(NB)) | |||||
| IF( K.EQ.0 ) THEN | IF( K.EQ.0 ) THEN | ||||
| @@ -230,7 +229,7 @@ C> | |||||
| ELSE | ELSE | ||||
| LBWORK = SCEIL(REAL(K)/REAL(NB))*NB | |||||
| LBWORK = CEILING(REAL(K)/REAL(NB))*NB | |||||
| LWKOPT = (LBWORK+LLWORK-NB)*NB | LWKOPT = (LBWORK+LLWORK-NB)*NB | ||||
| WORK( 1 ) = LWKOPT | WORK( 1 ) = LWKOPT | ||||
| @@ -172,12 +172,11 @@ C> | |||||
| EXTERNAL SGEQR2, SLARFB, SLARFT, XERBLA | EXTERNAL SGEQR2, SLARFB, SLARFT, XERBLA | ||||
| * .. | * .. | ||||
| * .. Intrinsic Functions .. | * .. Intrinsic Functions .. | ||||
| INTRINSIC MAX, MIN | |||||
| INTRINSIC CEILING, MAX, MIN, REAL | |||||
| * .. | * .. | ||||
| * .. External Functions .. | * .. External Functions .. | ||||
| INTEGER ILAENV | INTEGER ILAENV | ||||
| REAL SCEIL | |||||
| EXTERNAL ILAENV, SCEIL | |||||
| EXTERNAL ILAENV | |||||
| * .. | * .. | ||||
| * .. Executable Statements .. | * .. Executable Statements .. | ||||
| @@ -205,13 +204,13 @@ C> | |||||
| * | * | ||||
| * So here 4 x 4 is the last T stored in the workspace | * So here 4 x 4 is the last T stored in the workspace | ||||
| * | * | ||||
| NT = K-SCEIL(REAL(K-NX)/REAL(NB))*NB | |||||
| NT = K-CEILING(REAL(K-NX)/REAL(NB))*NB | |||||
| * | * | ||||
| * optimal workspace = space for dlarfb + space for normal T's + space for the last T | * optimal workspace = space for dlarfb + space for normal T's + space for the last T | ||||
| * | * | ||||
| LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | ||||
| LLWORK = SCEIL(REAL(LLWORK)/REAL(NB)) | |||||
| LLWORK = CEILING(REAL(LLWORK)/REAL(NB)) | |||||
| IF( K.EQ.0 ) THEN | IF( K.EQ.0 ) THEN | ||||
| @@ -230,7 +229,7 @@ C> | |||||
| ELSE | ELSE | ||||
| LBWORK = SCEIL(REAL(K)/REAL(NB))*NB | |||||
| LBWORK = CEILING(REAL(K)/REAL(NB))*NB | |||||
| LWKOPT = (LBWORK+LLWORK-NB)*NB | LWKOPT = (LBWORK+LLWORK-NB)*NB | ||||
| WORK( 1 ) = LWKOPT | WORK( 1 ) = LWKOPT | ||||
| @@ -23,7 +23,7 @@ C> \brief \b ZGEQRF VARIANT: left-looking Level 3 BLAS of the algorithm. | |||||
| C>\details \b Purpose: | C>\details \b Purpose: | ||||
| C>\verbatim | C>\verbatim | ||||
| C> | C> | ||||
| C> ZGEQRF computes a QR factorization of a real M-by-N matrix A: | |||||
| C> ZGEQRF computes a QR factorization of a complex M-by-N matrix A: | |||||
| C> A = Q * R. | C> A = Q * R. | ||||
| C> | C> | ||||
| C> This is the left-looking Level 3 BLAS version of the algorithm. | C> This is the left-looking Level 3 BLAS version of the algorithm. | ||||
| @@ -172,12 +172,11 @@ C> | |||||
| EXTERNAL ZGEQR2, ZLARFB, ZLARFT, XERBLA | EXTERNAL ZGEQR2, ZLARFB, ZLARFT, XERBLA | ||||
| * .. | * .. | ||||
| * .. Intrinsic Functions .. | * .. Intrinsic Functions .. | ||||
| INTRINSIC MAX, MIN | |||||
| INTRINSIC CEILING, MAX, MIN, REAL | |||||
| * .. | * .. | ||||
| * .. External Functions .. | * .. External Functions .. | ||||
| INTEGER ILAENV | INTEGER ILAENV | ||||
| REAL SCEIL | |||||
| EXTERNAL ILAENV, SCEIL | |||||
| EXTERNAL ILAENV | |||||
| * .. | * .. | ||||
| * .. Executable Statements .. | * .. Executable Statements .. | ||||
| @@ -205,13 +204,13 @@ C> | |||||
| * | * | ||||
| * So here 4 x 4 is the last T stored in the workspace | * So here 4 x 4 is the last T stored in the workspace | ||||
| * | * | ||||
| NT = K-SCEIL(REAL(K-NX)/REAL(NB))*NB | |||||
| NT = K-CEILING(REAL(K-NX)/REAL(NB))*NB | |||||
| * | * | ||||
| * optimal workspace = space for dlarfb + space for normal T's + space for the last T | * optimal workspace = space for dlarfb + space for normal T's + space for the last T | ||||
| * | * | ||||
| LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | LLWORK = MAX (MAX((N-M)*K, (N-M)*NB), MAX(K*NB, NB*NB)) | ||||
| LLWORK = SCEIL(REAL(LLWORK)/REAL(NB)) | |||||
| LLWORK = CEILING(REAL(LLWORK)/REAL(NB)) | |||||
| IF( K.EQ.0 ) THEN | IF( K.EQ.0 ) THEN | ||||
| @@ -230,7 +229,7 @@ C> | |||||
| ELSE | ELSE | ||||
| LBWORK = SCEIL(REAL(K)/REAL(NB))*NB | |||||
| LBWORK = CEILING(REAL(K)/REAL(NB))*NB | |||||
| LWKOPT = (LBWORK+LLWORK-NB)*NB | LWKOPT = (LBWORK+LLWORK-NB)*NB | ||||
| WORK( 1 ) = LWKOPT | WORK( 1 ) = LWKOPT | ||||