<div dir="ltr"><div class="gmail_quote"><div dir="ltr">On Tue, Sep 18, 2018 at 11:53 AM Jan Grießer <<a href="mailto:griesser.jan@googlemail.com">griesser.jan@googlemail.com</a>> wrote:<br></div><blockquote class="gmail_quote" style="margin:0 0 0 .8ex;border-left:1px #ccc solid;padding-left:1ex"><div dir="ltr"><div dir="ltr"><div dir="ltr">But i'am still struggling a little bit with copying the vector entries from the processes to one sequentiel proces. I tried to use the comment with Scatter().toZero() in Python and tried the following code:<div><div>vecs = np.zeros((69999,nconv))</div><div><span style="white-space:pre-wrap"> </span>for i in range(nconv):</div><div><span style="white-space:pre-wrap"> </span>val = E.getEigenpair(i, vr, vi)</div><div><span style="white-space:pre-wrap"> </span>scatter, vec_full = PETSc.Scatter().toZero(vr)</div><div><span style="white-space:pre-wrap"> </span>scatter.scatter(vr, vec_full, False, PETSc.ScatterMode.FORWARD)</div><div><span style="white-space:pre-wrap"> </span>if rank == 0:</div><div><span style="white-space:pre-wrap"> </span>vecs[:,i] = vec_full.getArray()<span style="white-space:pre-wrap"> </span></div></div><div>but when i take a look at the eigenvectors there are some entries which are strange, because in this exampled i printed 4 eigenvalues and vectors and get nconv=4, but when i print the vectors i get lines </div><div>with 4 entries but they are all zero and also get lines with strange entries e.g.</div><div><div>6.386079897185445800e-05 3.675310683411162830e-04 9.068495707804999221e-06 7.43627600.000000000000000000e+00 0.000000000000000000e+00 0.000000000000000000e+00 0.000000000000000000e+00</div></div><div>where i have more than 4 entries. Can somebody explain to me why this happens or what is wrong with the code. (Sorry for asking such beginner questions, but i just started to work with PETSc and SLEPc)</div></div></div></div></blockquote><div><br></div><div>We can definitely figure that out. However, can you try</div><div><br></div><div> vr.view(PETSC_VIEWER_STDOUT_WORLD)</div><div><br></div><div>just to check your vectors initially?</div><div><br></div><div> Thanks,</div><div><br></div><div> Matt</div><div> </div><blockquote class="gmail_quote" style="margin:0 0 0 .8ex;border-left:1px #ccc solid;padding-left:1ex"><div class="gmail_quote"><div dir="ltr">Am Di., 18. Sep. 2018 um 09:26 Uhr schrieb Jan Grießer <<a href="mailto:griesser.jan@googlemail.com" target="_blank">griesser.jan@googlemail.com</a>>:<br></div><blockquote class="gmail_quote" style="margin:0 0 0 .8ex;border-left:1px #ccc solid;padding-left:1ex"><div dir="ltr">Now it works. Thank you very much!</div><br><div class="gmail_quote"><div dir="ltr">Am Mo., 17. Sep. 2018 um 10:54 Uhr schrieb Jose E. Roman <<a href="mailto:jroman@dsic.upv.es" target="_blank">jroman@dsic.upv.es</a>>:<br></div><blockquote class="gmail_quote" style="margin:0 0 0 .8ex;border-left:1px #ccc solid;padding-left:1ex">For this you have to set a number of partitions equal to the number of MPI processes. If you get this error it is because these values are different.<br>
Jose<br>
<br>
<br>
> El 17 sept 2018, a las 10:50, Jan Grießer <<a href="mailto:griesser.jan@googlemail.com" target="_blank">griesser.jan@googlemail.com</a>> escribió:<br>
> <br>
> Is this relly necessary, because in the last sentences of the chapter it states that:<br>
> An additional benefit of multi-communicator support is that it enables parallel spectrum slicing runs without the need to install a parallel direct solver (MUMPS). The following commandline example uses sequential linear solves in 4 partitions, one process each:<br>
> Therefore i assumed that it is not necessary to compile PETsc4py with an external solver e.g. MUMPS<br>
> <br>
> Am Mo., 17. Sep. 2018 um 10:47 Uhr schrieb Jose E. Roman <<a href="mailto:jroman@dsic.upv.es" target="_blank">jroman@dsic.upv.es</a>>:<br>
> You need a parallel direct solver such as MUMPS. This is explained in section 3.4.5.<br>
> Jose<br>
> <br>
> <br>
> > El 17 sept 2018, a las 10:41, Jan Grießer <<a href="mailto:griesser.jan@googlemail.com" target="_blank">griesser.jan@googlemail.com</a>> escribió:<br>
> > <br>
> > def solve_eigensystem(DynMatrix_nn, Unity_nn, Dimension, LowerLimit, UpperLimit):<br>
> > # Create the EPS solver <br>
> > E = SLEPc.EPS().create()<br>
> > <br>
> > # Create the preconditioner and set it to Cholesky<br>
> > pc = PETSc.PC().create()<br>
> > pc.setType(pc.Type.CHOLESKY)<br>
> > <br>
> > # Create the KSP object<br>
> > ksp = PETSc.KSP().create()<br>
> > ksp.setType(ksp.Type.PREONLY)<br>
> > ksp.setPC(pc)<br>
> > <br>
> > # Set up the spectral transformations <br>
> > st = SLEPc.ST().create()<br>
> > st.setType("sinvert")<br>
> > st.setKSP(ksp)<br>
> > # Setup spectral transformation <br>
> > E.setST(st)<br>
> > <br>
> > # Eigenvalues should be real, therefore we start to order them from the smallest real value |l.real|<br>
> > E.setWhichEigenpairs(E.Which.ALL)<br>
> > # Set the interval of spectrum slicing<br>
> > E.setInterval(LowerLimit, UpperLimit)<br>
> > # Since the dynamical matrix is symmetric and real it is hermitian. Use GHEP for the spectrum slicing. Operatormatrix B is just a unit matrix <br>
> > E.setProblemType(SLEPc.EPS.ProblemType.GHEP)<br>
> > # Use the Krylov Schur method to solve the eigenvalue problem<br>
> > E.setType(E.Type.KRYLOVSCHUR)<br>
> > # Partition the Krylov schnur problem in npart procceses<br>
> > E.setKrylovSchurPartitions(10)<br>
> > # Set the convergence criterion to relative to the eigenvalue and the maximal number of iterations<br>
> > E.setConvergenceTest(E.Conv.REL)<br>
> > E.setTolerances(tol = 1e-7, max_it = 1000)<br>
> > # Set the matrix in order to solve <br>
> > E.setOperators(DynMatrix_nn, Unity_nn)<br>
> > # Sets EPS options from the options database. <br>
> > E.setFromOptions()<br>
> > # Sets up all the internal data structures necessary for the execution of the eigensolver.<br>
> > E.setUp()<br>
> > <br>
> > # Solve eigenvalue problem <br>
> > startClock = time.clock()<br>
> > startTime = time.time()<br>
> > E.solve()<br>
> > <br>
> > Has maybe one of you any idea why this happens and where the problem is ? <br>
> > <br>
> > Am Mo., 17. Sep. 2018 um 10:40 Uhr schrieb Jan Grießer <<a href="mailto:griesser.jan@googlemail.com" target="_blank">griesser.jan@googlemail.com</a>>:<br>
> > I am aware that SLEPc is not supposed to calculate all eigenvalues and eigenvectors, my problem is simply that i want for a physical large enough system all of them before i can make the transition to go to the smallest ones. <br>
> > Competitiveness is of secondary importance at the moment. <br>
> > But ihave a problem connected with spectrum slicing. I followed the instructions in the manual of Chap. 3.4.5 Spectrum Slicing and converted them to the python package. <br>
> > But now i get the following error. It appears to me that it is not able to find the ksp object, but i actually do not know why this is the case. <br>
> > aceback (most recent call last):<br>
> > File "Eigensolver_spectrum_slicing.py", line 216, in <module><br>
> > solve_eigensystem(DynMatrix_nn, Unity_nn, D_nn.shape, opt_dict.LowLimit, opt_dict.UpperLimit)<br>
> > File "Eigensolver_spectrum_slicing.py", line 121, in solve_eigensystem<br>
> > E.setUp()<br>
> > File "SLEPc/EPS.pyx", line 1099, in slepc4py.SLEPc.EPS.setUp<br>
> > petsc4py.PETSc.Error: error code 92<br>
> > [14] EPSSetUp() line 165 in /tmp/pip-install-golhudw7/slepc/src/eps/interface/epssetup.c<br>
> > [14] EPSSetUp_KrylovSchur() line 146 in /tmp/pip-install-golhudw7/slepc/src/eps/impls/krylov/krylovschur/krylovschur.c<br>
> > [14] EPSSetUp_KrylovSchur_Slice() line 410 in /tmp/pip-install-golhudw7/slepc/src/eps/impls/krylov/krylovschur/ks-slice.c<br>
> > [14] EPSSliceGetEPS() line 300 in /tmp/pip-install-golhudw7/slepc/src/eps/impls/krylov/krylovschur/ks-slice.c<br>
> > [14] EPSSetUp() line 165 in /tmp/pip-install-golhudw7/slepc/src/eps/interface/epssetup.c<br>
> > [14] EPSSetUp_KrylovSchur() line 146 in /tmp/pip-install-golhudw7/slepc/src/eps/impls/krylov/krylovschur/krylovschur.c<br>
> > [14] EPSSetUp_KrylovSchur_Slice() line 461 in /tmp/pip-install-golhudw7/slepc/src/eps/impls/krylov/krylovschur/ks-slice.c<br>
> > [14] EPSSliceGetInertia() line 331 in /tmp/pip-install-golhudw7/slepc/src/eps/impls/krylov/krylovschur/ks-slice.c<br>
> > [14] STSetUp() line 271 in /tmp/pip-install-golhudw7/slepc/src/sys/classes/st/interface/stsolve.c<br>
> > [14] STSetUp_Sinvert() line 132 in /tmp/pip-install-golhudw7/slepc/src/sys/classes/st/impls/sinvert/sinvert.c<br>
> > [14] KSPSetUp() line 381 in /tmp/pip-install-xmiaat2t/petsc/src/ksp/ksp/interface/itfunc.c<br>
> > [14] PCSetUp() line 923 in /tmp/pip-install-xmiaat2t/petsc/src/ksp/pc/interface/precon.c<br>
> > [14] PCSetUp_Cholesky() line 86 in /tmp/pip-install-xmiaat2t/petsc/src/ksp/pc/impls/factor/cholesky/cholesky.c<br>
> > [14] MatGetFactor() line 4318 in /tmp/pip-install-xmiaat2t/petsc/src/mat/interface/matrix.c<br>
> > [14] See <a href="http://www.mcs.anl.gov/petsc/documentation/linearsolvertable.html" rel="noreferrer" target="_blank">http://www.mcs.anl.gov/petsc/documentation/linearsolvertable.html</a> for possible LU and Cholesky solvers<br>
> > [14] Could not locate a solver package. Perhaps you must ./configure with --download-<package><br>
> > <br>
> > The code i used to solve the problem is <br>
> > <br>
> > Am Fr., 14. Sep. 2018 um 18:34 Uhr schrieb Matthew Knepley <<a href="mailto:knepley@gmail.com" target="_blank">knepley@gmail.com</a>>:<br>
> > On Fri, Sep 14, 2018 at 12:19 PM Jose E. Roman <<a href="mailto:jroman@dsic.upv.es" target="_blank">jroman@dsic.upv.es</a>> wrote:<br>
> > El 14 sept 2018, a las 17:45, Jan Grießer <<a href="mailto:griesser.jan@googlemail.com" target="_blank">griesser.jan@googlemail.com</a>> escribió:<br>
> > <br>
> >> Hey there,<br>
> >> first i want to say thanks to Satish and Matt for helping with with my last problem with the mpi compilation. I have two questions related to solving a big, hermitian, standard eigenvalue problem using SLEPc4py., compiled with Intel MKL and Intel MPI. <br>
> >> <br>
> >> - I am using slepc4py with <br>
> >> mpi and run it with around -n 20 cores at the moment and how i wanted to ask if there is an easy way to retrieve the eigenvectors? When i run my code and print for i in range(nconv):<br>
> >> for i in range(nconv):<br>
> >> <br>
> >> val = E.<br>
> >> getEigenpair(i, vr<br>
> >> , vi)<br>
> >> Print(<br>
> >> vr.getArray())<br>
> >> i get the parts of the eigenvectors according to the partition of the matrix. Is there any easy way to put them together in an array and write them to file ? (I am struggling a little bit with the building them in the correct order)<br>
> > <br>
> > You need VecScatterCreateToZero. There must be an equivalent in python.<br>
> > <br>
> > An alternative to this which you should consider, because it is simpler, is to write the vector to a file<br>
> > using some format that PETSc understands, Then you just need vr.view(viewer) for a viewer like<br>
> > the binary viewer or some ASCII format you like.<br>
> > <br>
> > Thanks,<br>
> > <br>
> > Matt<br>
> >> - I need to solve eigenvalue problems up to a dimension of 100000 degrees of freedom and i need all eigenvalues and eigenvectors. I think solving all eigenvalues in one process is far too much and i thought about if it is possible to apply the spectrum slicing described in Chap. 3.4.5. Due to the nature of my problem, i am able to simulate smaller systems of 10000 DOF and extract the biggest eigenvalue, which will be the same for larger systems sizes. Is this in general possible since i have a standard HEP problem or is there a better and faster possibility to do this?<br>
> > <br>
> > In general, SLEPc is not intended for computing the whole spectrum. You can try with spectrum slicing but this will be competitive if computing just a percentage of eigenvalues, 50% say. <br>
> > <br>
> > Jose<br>
> > <br>
> >> <br>
> >> Thank you very much!<br>
> > <br>
> > <br>
> > -- <br>
> > What most experimenters take for granted before they begin their experiments is infinitely more interesting than any results to which their experiments lead.<br>
> > -- Norbert Wiener<br>
> > <br>
> > <a href="https://www.cse.buffalo.edu/~knepley/" rel="noreferrer" target="_blank">https://www.cse.buffalo.edu/~knepley/</a><br>
> <br>
<br>
</blockquote></div>
</blockquote></div>
</blockquote></div><br clear="all"><div><br></div>-- <br><div dir="ltr" class="gmail_signature" data-smartmail="gmail_signature"><div dir="ltr"><div><div dir="ltr"><div><div dir="ltr"><div>What most experimenters take for granted before they begin their experiments is infinitely more interesting than any results to which their experiments lead.<br>-- Norbert Wiener</div><div><br></div><div><a href="http://www.cse.buffalo.edu/~knepley/" target="_blank">https://www.cse.buffalo.edu/~knepley/</a><br></div></div></div></div></div></div></div></div>