YET

PCHEEVD()

jobz    (input) character*1
= 'n':  compute eigenvalues only;    (not implemented YET

PCLARZB()

reflectors
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PCLARZT()

multiplied to form the block reflector:
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PCTREVC()

substitution.  it is the hope that scaling would be used to make the
the code robust against possible overflow.  but scaling has not YET
the triangular systems.  pclattrs just calls pctrsv.

PDLARZB()

reflectors
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PDLARZT()

multiplied to form the block reflector:
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PDLASRT()

= 'i': sort d in increasing order;
= 'd': sort d in decreasing order. (not implemented YET
n       (global input) integer

PDSTEDC()

compz   (input) character*1
= 'n':  compute eigenvalues only.    (not implemented YET
= 'v':  compute eigenvectors of original dense symmetric

PDSYEVD()

jobz    (input) character*1
= 'n':  compute eigenvalues only;     (not implemented YET

PSLARZB()

reflectors
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PSLARZT()

multiplied to form the block reflector:
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PSLASRT()

= 'i': sort d in increasing order;
= 'd': sort d in decreasing order. (not implemented YET
n       (global input) integer

PSSTEDC()

compz   (input) character*1
= 'n':  compute eigenvalues only.    (not implemented YET
= 'v':  compute eigenvectors of original dense symmetric

PSSYEVD()

jobz    (input) character*1
= 'n':  compute eigenvalues only;     (not implemented YET

PZHEEVD()

jobz    (input) character*1
= 'n':  compute eigenvalues only;    (not implemented YET

PZLARZB()

reflectors
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PZLARZT()

multiplied to form the block reflector:
= 'f': h = h(1) h(2) . . . h(k) (forward, not supported YET

PZTREVC()

substitution.  it is the hope that scaling would be used to make the
the code robust against possible overflow.  but scaling has not YET
the triangular systems.  pzlattrs just calls pztrsv.

yields

PCHEEVX()

abstol  (global input) real
if jobz='v', setting abstol to pslamch( context, 'u') yields

PCHEGVX()

abstol  (global input) real
if jobz='v', setting abstol to pslamch( context, 'u') yields

PCLACONSB()

m       (global output) integer
on exit, this yields the starting location of the qr doubl

PCLASMSUB()

k       (global output) integer
on exit, this yields the bottom portion of the unreduce

PDLACONSB()

m       (global output) integer
on exit, this yields the starting location of the qr doubl

PDLASMSUB()

k       (global output) integer
on exit, this yields the bottom portion of the unreduce

PDSYEVX()

abstol  (global input) double precision
if jobz='v', setting abstol to pdlamch( context, 'u') yields

PDSYGVX()

abstol  (global input) double precision
if jobz='v', setting abstol to pdlamch( context, 'u') yields

PSLACONSB()

m       (global output) integer
on exit, this yields the starting location of the qr doubl

PSLASMSUB()

k       (global output) integer
on exit, this yields the bottom portion of the unreduce

PSSYEVX()

abstol  (global input) real
if jobz='v', setting abstol to pslamch( context, 'u') yields

PSSYGVX()

abstol  (global input) real
if jobz='v', setting abstol to pslamch( context, 'u') yields

PZHEEVX()

abstol  (global input) double precision
if jobz='v', setting abstol to pdlamch( context, 'u') yields

PZHEGVX()

abstol  (global input) double precision
if jobz='v', setting abstol to pdlamch( context, 'u') yields

PZLACONSB()

m       (global output) integer
on exit, this yields the starting location of the qr doubl

PZLASMSUB()

k       (global output) integer
on exit, this yields the bottom portion of the unreduce

you

PCHEEVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lrwork:

PCHEGVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lrwork:

PCLASWP()

also note that this routine will only work for k1-k2 being in the
same mb (or nb) block.  if you want to pivot a full matrix, us

PDLASWP()

also note that this routine will only work for k1-k2 being in the
same mb (or nb) block.  if you want to pivot a full matrix, us

PDSYEVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lwork:

PDSYGVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lwork:

PSLASWP()

also note that this routine will only work for k1-k2 being in the
same mb (or nb) block.  if you want to pivot a full matrix, us

PSSYEVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lwork:

PSSYGVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lwork:

PZHEEVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lrwork:

PZHEGVX()

minimal workspace is supplied and orfac is too small.
if you want to guarantee orthogonality (at the cos
the following to lrwork:

PZLASWP()

also note that this routine will only work for k1-k2 being in the
same mb (or nb) block.  if you want to pivot a full matrix, us

your

PDSTEBZ()

used was incorrect. no eigenvalues were computed.
probable cause: your machine has sloppy floatin
cure: increase the parameter "fudge", recompile,

PSSTEBZ()

used was incorrect. no eigenvalues were computed.
probable cause: your machine has sloppy floatin
cure: increase the parameter "fudge", recompile,