DLAMSH(1) send multiple shifts through a small (single node) matrix to see how consecutive small subdiagonal elements are modified by subsequent shifts in an effort to maximize the number of bulges that can be sent through

SYNOPSIS

SUBROUTINE DLAMSH
( S, LDS, NBULGE, JBLK, H, LDH, N, ULP )

    
INTEGER LDS, NBULGE, JBLK, LDH, N

    
DOUBLE PRECISION ULP

    
DOUBLE PRECISION S(LDS,*), H(LDH,*)

PURPOSE

DLAMSH sends multiple shifts through a small (single node) matrix to
   see how consecutive small subdiagonal elements are modified by 
   subsequent shifts in an effort to maximize the number of bulges 
   that can be sent through. DLAMSH should only be called when there are multiple shifts/bulges
   (NBULGE > 1) and the first shift is starting in the middle of an
   unreduced Hessenberg matrix because of two or more consecutive small
   subdiagonal elements.

ARGUMENTS

S (local input/output) DOUBLE PRECISION array, (LDS,*)
On entry, the matrix of shifts. Only the 2x2 diagonal of S is referenced. It is assumed that S has JBLK double shifts (size 2). On exit, the data is rearranged in the best order for applying.
LDS (local input) INTEGER
On entry, the leading dimension of S. Unchanged on exit. 1 < NBULGE <= JBLK <= LDS/2
NBULGE (local input/output) INTEGER
On entry, the number of bulges to send through H ( >1 ). NBULGE should be less than the maximum determined (JBLK). 1 < NBULGE <= JBLK <= LDS/2 On exit, the maximum number of bulges that can be sent through.
JBLK (local input) INTEGER
On entry, the number of shifts determined for S. Unchanged on exit.
H (local input/output) DOUBLE PRECISION array (LDH,N)
On entry, the local matrix to apply the shifts on. H should be aligned so that the starting row is 2. On exit, the data is destroyed.
LDS (local input) INTEGER
On entry, the leading dimension of S. Unchanged on exit.
N (local input) INTEGER
On entry, the size of H. If all the bulges are expected to go through, N should be at least 4*NBULGE+2. Otherwise, NBULGE may be reduced by this routine.
ULP (local input) DOUBLE PRECISION
On entry, machine precision Unchanged on exit.

Implemented by: G. Henry, May 1, 1997