Visible to Intel only — GUID: GUID-83026634-3CE7-4682-A658-91385E6C2165
Visible to Intel only — GUID: GUID-83026634-3CE7-4682-A658-91385E6C2165
?unmhr
Multiplies an arbitrary complex matrix C by the complex unitary matrix Q determined by ?gehrd.
lapack_int LAPACKE_cunmhr (int matrix_layout, char side, char trans, lapack_int m, lapack_int n, lapack_int ilo, lapack_int ihi, const lapack_complex_float* a, lapack_int lda, const lapack_complex_float* tau, lapack_complex_float* c, lapack_int ldc);
lapack_int LAPACKE_zunmhr (int matrix_layout, char side, char trans, lapack_int m, lapack_int n, lapack_int ilo, lapack_int ihi, const lapack_complex_double* a, lapack_int lda, const lapack_complex_double* tau, lapack_complex_double* c, lapack_int ldc);
- mkl.h
The routine multiplies a matrix C by the unitary matrix Q that has been determined by a preceding call to cgehrd/zgehrd. (The routine ?gehrd reduces a real general matrix A to upper Hessenberg form H by an orthogonal similarity transformation, A = Q*H*QH, and represents the matrix Q as a product of ihi-ilo elementary reflectors. Here ilo and ihi are values determined by cgebal/zgebal when balancing the matrix; if the matrix has not been balanced, ilo = 1 and ihi = n.)
With ?unmhr, you can form one of the matrix products Q*C, QH*C, C*Q, or C*QH, overwriting the result on C (which may be any complex rectangular matrix). A common application of this routine is to transform a matrix V of eigenvectors of H to the matrix QV of eigenvectors of A.
- matrix_layout
-
Specifies whether matrix storage layout is row major (LAPACK_ROW_MAJOR) or column major (LAPACK_COL_MAJOR).
- side
-
Must be 'L' or 'R'.
If side = 'L', then the routine forms Q*C or QH*C.
If side = 'R', then the routine forms C*Q or C*QH.
- trans
-
Must be 'N' or 'C'.
If trans = 'N', then Q is applied to C.
If trans = 'T', then QH is applied to C.
- m
-
The number of rows in C (m≥ 0).
- n
-
The number of columns in C (n≥ 0).
- ilo, ihi
-
These must be the same parameters ilo and ihi, respectively, as supplied to ?gehrd .
If m > 0 and side = 'L', then 1 ≤ilo≤ihi≤m.
If m = 0 and side = 'L', then ilo = 1 and ihi = 0.
If n > 0 and side = 'R', then 1 ≤ilo≤ihi≤n.
If n = 0 and side = 'R', then ilo =1 and ihi = 0.
- a, tau, c
-
Arrays:
a(size max(1,lda*n) for side='R' and size max(1,lda*m) for side='L') contains details of the vectors which define the elementary reflectors, as returned by ?gehrd.
tau contains further details of the elementary reflectors, as returned by ?gehrd.
The dimension of tau must be at least max (1, m-1)
if side = 'L' and at least max (1, n-1) if side = 'R'.
c(size max(1, ldc*n) for column major layout and max(1, ldc*m for row major layout) contains the m-by-n matrix C.
- lda
-
The leading dimension of a; at least max(1, m) if side = 'L' and at least max (1, n) if side = 'R'.
- ldc
-
The leading dimension of c; at least max(1, m) for column major layout and at least max(1, n) for row major layout.
- c
-
C is overwritten by Q*C, or QH*C, or C*QH, or C*Q as specified by side and trans.
This function returns a value info.
If info=0, the execution is successful.
If info = -i, the i-th parameter had an illegal value.
The computed matrix Q differs from the exact result by a matrix E such that ||E||2 = O(ε)*||C||2, where ε is the machine precision.
The approximate number of floating-point operations is
8n(ihi-ilo)2 if side = 'L';
8m(ihi-ilo)2 if side = 'R'.
The real counterpart of this routine is ormhr.