diff --git a/Cassiopee/KCore/test/compareSessionLogs.py b/Cassiopee/KCore/test/compareSessionLogs.py index d492adc1f..c0661743e 100644 --- a/Cassiopee/KCore/test/compareSessionLogs.py +++ b/Cassiopee/KCore/test/compareSessionLogs.py @@ -154,7 +154,7 @@ def stringify(test='', ref='', new=''): compStr += stringify(*diffTest(test, refDict[test], newDict[test])) if len(compStr): compStr = commonTestsHeader + compStr - baseState = 'FAIL' + baseState = 'FAILED' else: compStr = commonTestsHeader + "[none]\n" newTestsHeader = "\nNew tests:\n{}\n".format('-'*9) @@ -170,7 +170,7 @@ def stringify(test='', ref='', new=''): compStr += deletedTestsHeader for test in deletedTests: compStr += stringify(test) - baseState = 'FAIL' + baseState = 'FAILED' else: compStr += deletedTestsHeader + "[none]\n" failedTestsHeader = "\nReminder - Failed tests:\n{}\n".format('-'*23) @@ -203,16 +203,15 @@ def stringify(test='', ref='', new=''): if baseState in ['OK', 'NEW ADDITIONS'] and 'REF-' in script_args.logs[0]: if os.access(script_args.logs[0], os.W_OK): import shutil - shutil.copyfile(script_args.logs[0], - script_args.logs[0].replace('REF-', '')) + os.remove(script_args.logs[0]) newRef = os.path.join(os.path.dirname(script_args.logs[1]), 'REF-' + os.path.basename(script_args.logs[1])) shutil.copyfile(script_args.logs[1], newRef) else: exitStatus = 2 + prod = getProd(script_args.logs[1]) tlog, tlog2 = getTimeFromLog(script_args.logs[1]) if script_args.email: - prod = getProd(script_args.logs[1]) if baseStateMsg: baseStateMsg = '\n\n'+baseStateMsg try: from KCore.notify import notify @@ -227,4 +226,20 @@ def stringify(test='', ref='', new=''): if os.access('./', os.W_OK): print("Writing comparison to {}".format(filename)) with open(filename, 'w') as f: f.write(header + compStr + baseStateMsg) + + # Amend state of the base in logs/validation_status.txt + logAllValids = "/stck/cassiope/git/logs/validation_status.txt" + entry = "{} - {} - {}\n".format(prod, tlog2, baseState) + if os.access(os.path.dirname(logAllValids), os.W_OK): + with open(logAllValids, 'r') as f: contents = f.readlines() + prodFound = False + for i, line in enumerate(contents): + if line.startswith(prod): + contents[i] = entry + prodFound = True + break + + if not prodFound: contents.append(entry) + with open(logAllValids, 'w') as f: f.writelines(contents) + sys.exit(exitStatus) diff --git a/Cassiopee/KCore/test/notifyValid.py b/Cassiopee/KCore/test/notifyValid.py new file mode 100644 index 000000000..325a8ec51 --- /dev/null +++ b/Cassiopee/KCore/test/notifyValid.py @@ -0,0 +1,48 @@ +# Send a notification by email to a list of recipients about the validation +# status of different prods. Please set the environment variable CASSIOPEE_EMAIL +# Usage: python notifyValid.py --recipients='a.b@onera.fr c.d@onera.fr' +import os +import sys +from time import strptime, strftime + +# Parse command-line arguments +def parseArgs(): + import argparse + # Create argument parser + parser = argparse.ArgumentParser() + parser.add_argument("-r", "--recipients", type=str, default='', + help="Single-quoted space-separated list of recipients") + # Parse arguments + return parser.parse_args() + +# Main +if __name__ == '__main__': + script_args = parseArgs() + recipients = script_args.recipients.split(' ') + if not recipients[0]: recipients = [] + + # Check valid status + log_entries = [] + with open('/stck/cassiope/git/logs/validation_status.txt', 'r') as f: + for line in f: + log_entries.append(line.strip().split(' - ')) + log_entries.sort(key=lambda x: x[1], reverse=True) + + vnvState = 'OK' + messageText = "Non-regression testing of Cassiopee, Fast and all PModules:\n{}\n\n".format(58*'-') + for log_machine in log_entries: + prod = log_machine[0] + date = strptime(log_machine[1], "%y%m%d-%H%M%S") + date = strftime("%d/%m/%y at %T", date) + status = log_machine[2] + messageText += '{:>20} | {} | {:>10}\n'.format(prod, date, status) + if 'FAILED' in log_machine: vnvState = 'FAILED' + + try: + from KCore.notify import notify + notify(recipients=recipients, + messageSubject="[V&V Cassiopee] State: {}".format(vnvState), + messageText=messageText) + except ImportError: + print("Error: KCore is required to import notify.") + sys.exit() diff --git a/Cassiopee/Transform/Transform/subzone.cpp b/Cassiopee/Transform/Transform/subzone.cpp index 0d9cf86d0..3ca743f1f 100644 --- a/Cassiopee/Transform/Transform/subzone.cpp +++ b/Cassiopee/Transform/Transform/subzone.cpp @@ -792,7 +792,7 @@ PyObject* K_TRANSFORM::subzoneElements(PyObject* self, PyObject* args) vector neltspc(nc+1), neltspc2(nc), nvpe(nc); char* eltType2 = new char[50]; strcpy(eltType2, ""); - std::vector eltTypes; + vector eltTypes; K_ARRAY::extractVars(eltType, eltTypes); // Compute the cumulative number of elements per connectivity, @@ -809,7 +809,7 @@ PyObject* K_TRANSFORM::subzoneElements(PyObject* self, PyObject* args) } // Bin input elements - std::vector > binnedEltList(nc); + vector > binnedEltList(nc); for (E_Int i = 0; i < n; i++) { E_Int noe = eltList[i]; @@ -1110,7 +1110,7 @@ PyObject* K_TRANSFORM::subzoneElementsBoth(PyObject* self, PyObject* args) vector neltspc(nc+1), neltspc2(nc), nvpe(nc); char* eltType2 = new char[50]; strcpy(eltType2, ""); - std::vector eltTypes; + vector eltTypes; K_ARRAY::extractVars(eltType, eltTypes); // Compute the cumulative number of elements per connectivity, @@ -1127,7 +1127,7 @@ PyObject* K_TRANSFORM::subzoneElementsBoth(PyObject* self, PyObject* args) } // Bin input elements - std::vector > binnedEltList(nc); + vector > binnedEltList(nc); for (E_Int i = 0; i < n; i++) { E_Int noe = eltList[i]; @@ -1268,166 +1268,29 @@ PyObject* K_TRANSFORM::subzoneFaces(PyObject* self, PyObject* args) { PyErr_SetString(PyExc_TypeError, "subzone: cannot be used on a structured array."); - RELEASESHAREDS(array,f); return NULL; + RELEASESHAREDS(array, f); return NULL; } E_Int n = faceList.getSize(); E_Int* faceListp = faceList.begin(); - E_Int nf, nt2; - - char eltTypeFaces[10]; - int fBAR[] = { - 1, - 2 }; - int fTRI[] = { - 1, 2, - 2, 3, - 3, 1 }; - int fQUAD[] = { - 1, 2, - 2, 3, - 3, 4, - 4, 1 }; - int fTETRA[] = { - 1, 3, 2, - 1, 2, 4, - 2, 3, 4, - 3, 1, 4 }; - int fPENTA[] = { - 1, 2, 5, 4, - 2, 3, 6, 5, - 3, 1, 4, 6, - 1, 3, 2, 1, - 4, 5, 6, 4 - }; - int fPYRA[] = { - 1, 4, 3, 2, - 1, 2, 5, 5, - 2, 3, 5, 2, - 3, 4, 5, 3, - 4, 1, 5, 4 - }; - int fHEXA[] = { - 1, 4, 3, 2, - 1, 2, 6, 5, - 2, 3, 7, 6, - 3, 4, 8, 7, - 1, 5, 8, 4, - 5, 6, 7, 8 }; - - int* fPtr = NULL; E_Int type = 0; - nt2 = 0; nf = 0; - // nf: nbre de face de l'element d'entree - // eltTypeFaces: type de l'element de sortie (face de l'elt d'entree) - // nt2: nbre de noeuds de l'element de sortie - // type=0 (les faces de sortie sont a elements basiques - // type=1 (entree: elements basiques, sortie: NGON) - if (K_STRING::cmp(eltType, "BAR") == 0) - { - type = 0; nf = 2; strcpy(eltTypeFaces, "NODE"); nt2 = 1; fPtr = fBAR; - } - else if (K_STRING::cmp(eltType, "TRI") == 0) - { - type = 0; nf = 3; strcpy(eltTypeFaces, "BAR"); nt2 = 2; fPtr = fTRI; - } - else if (K_STRING::cmp(eltType, "QUAD") == 0) - { - type = 0; nf = 4; strcpy(eltTypeFaces, "BAR"); nt2 = 2; fPtr = fQUAD; - } - else if (K_STRING::cmp(eltType, "TETRA") == 0) - { - type = 0; nf = 4; strcpy(eltTypeFaces, "TRI"); nt2 = 3; fPtr = fTETRA; - } - else if (K_STRING::cmp(eltType, "HEXA") == 0) - { - type = 0; nf = 6; strcpy(eltTypeFaces, "QUAD"); nt2 = 4; fPtr = fHEXA; - } - else if (K_STRING::cmp(eltType, "PENTA") == 0) - { - type = 0; nf = 5; strcpy(eltTypeFaces, "QUAD"); nt2 = 4; fPtr = fPENTA; - } - else if (K_STRING::cmp(eltType, "PYRA") == 0) - { - type = 0; nf = 5; strcpy(eltTypeFaces, "QUAD"); nt2 = 4; fPtr = fPYRA; - } - else if (K_STRING::cmp(eltType, "NGON") == 0) - { - type = 2; strcpy(eltTypeFaces, "NGON"); - } - else - { - PyErr_SetString(PyExc_TypeError, - "subzone: element type not taken into account."); - RELEASESHAREDU(array, f, cn); return NULL; - } E_Int nfld = f->getNfld(); E_Int npts = f->getSize(); - if (type == 0) // Basic faces - { - FldArrayI* c2n = new FldArrayI(n,nt2); - // Selectionne les faces subzonees - FldArrayI indirNodes(npts); indirNodes.setAllValuesAt(-1); - E_Int* indirNp = indirNodes.begin(); + E_Int api = f->getApi(); - E_Int ind, indElt, nof, indnode, indnodef; - indnodef = 0; - for (E_Int i = 0; i < n; i++) - { - ind = faceListp[i]-1; - indElt = ind / nf; - nof = ind - indElt*nf; - // printf("elt=%d face=%d\n", indElt, nof); - for (E_Int v = 1; v <= nt2; v++) - { - indnode = (*cn)(indElt, fPtr[nof*nt2+v-1])-1; - if (indirNp[indnode] == -1) - { - indnodef += 1; - indirNp[indnode] = indnodef; - (*c2n)(i,v) = indnodef; - } - else - (*c2n)(i,v) = indirNp[indnode]; - } - } - - FldArrayF* f2 = new FldArrayF(indnodef, nfld); - E_Int indf; - for(E_Int eq = 1; eq <= nfld; eq++) - { - E_Float* fp = f->begin(eq); - E_Float* fnp = f2->begin(eq); - for (E_Int ind = 0; ind < npts; ind++) - { - indf = indirNp[ind]-1; - if (indf > -1) fnp[indf] = fp[ind]; - } - } - // Build array - PyObject* tpl = K_ARRAY::buildArray(*f2, varString, - *c2n, -1, eltTypeFaces); - RELEASESHAREDU(array,f, cn); - delete f2; delete c2n; - return tpl; - } - else if (type == 2) // IN: NGON, OUT: NGON + if (K_STRING::cmp(eltType, "NGON") == 0) // IN: NGON, OUT: NGON { E_Int nbnodes, fidx; - E_Int indvertn = 1, indedgen = 1; - E_Int sizeEF2 = 0; + E_Int indedgen = 1; + E_Int npts2 = 0; E_Int sizeEF2 = 0; // Acces non universel sur les ptrs E_Int* ngon = cn->getNGon(); E_Int* indPG = cn->getIndPG(); - E_Int shift = 1; E_Int api = f->getApi(); + E_Int shift = 1; if (api == 3) shift = 0; // Calcul du nombre de points et aretes uniques dans la nouvelle // connectivite vector indirVertices(npts, -1); - // Les vertices sont mappes pour construire une table d'indirection: leur - // nombre n'est pas connu a priori et ils ne sont pas parcourus - // dans l'ordre. - std::unordered_map vertexMap; // Les aretes sont hashees pour determiner le nombre unique d'aretes et // construire la nouvelle connectivite 2D vector edge(2); @@ -1448,15 +1311,10 @@ PyObject* K_TRANSFORM::subzoneFaces(PyObject* self, PyObject* args) edge[0] = face[j]-1; edge[1] = face[(j+1)%nbnodes]-1; E.set(edge.data(), 2); - // Increment the value associated with the first vertex. - // If it is 1, then first time this vertex is encountered - // The second vertex will be dealt with when considering the next edge - auto resV = vertexMap.insert(std::make_pair(edge[0], 0)); - if (++resV.first->second == 1) - { - indirVertices[edge[0]] = indvertn; - indvertn++; - } + // If indirection table is -1 for the first vertex, then first time + // this vertex is encountered. The second vertex will be dealt with + // when considering the next edge + if (indirVertices[edge[0]] == -1) indirVertices[edge[0]] = ++npts2; // If the value associated with E is -1, then first time this edge // is encountered, set to current unique edge count @@ -1470,7 +1328,6 @@ PyObject* K_TRANSFORM::subzoneFaces(PyObject* self, PyObject* args) } // Construction des nouvelles connectivites Elmt/Faces et Face/Noeuds - E_Int npts2 = vertexMap.size(); E_Int nfaces2 = edgeMap.size(); E_Int sizeFN2 = (2+shift)*nfaces2; E_Int nelts2 = n; @@ -1724,7 +1581,8 @@ PyObject* K_TRANSFORM::subzoneFacesBoth(PyObject* self, PyObject* args) E_Int im, jm, km; FldArrayF* f; FldArrayI* cn; char* varString; char* eltType; - E_Int res = K_ARRAY::getFromArray(arrayNodes, varString, f, im, jm, km, cn, eltType, true); + E_Int res = K_ARRAY::getFromArray3(arrayNodes, varString, f, + im, jm, km, cn, eltType); if (res != 1 && res != 2) { PyErr_SetString(PyExc_TypeError, @@ -1735,14 +1593,15 @@ PyObject* K_TRANSFORM::subzoneFacesBoth(PyObject* self, PyObject* args) { PyErr_SetString(PyExc_TypeError, "subzone: cannot be used on a structured array."); - RELEASESHAREDS(arrayNodes,f); return NULL; + RELEASESHAREDS(arrayNodes, f); return NULL; } // Check array of centers E_Int imc, jmc, kmc; FldArrayF* fc; FldArrayI* cnc; char* varStringc; char* eltTypec; - E_Int resc = K_ARRAY::getFromArray(arrayCenters, varStringc, fc, imc, jmc, kmc, cnc, eltTypec, true); + E_Int resc = K_ARRAY::getFromArray3(arrayCenters, varStringc, fc, + imc, jmc, kmc, cnc, eltTypec); if (resc != 1 && resc != 2) { PyErr_SetString(PyExc_TypeError, @@ -1753,7 +1612,7 @@ PyObject* K_TRANSFORM::subzoneFacesBoth(PyObject* self, PyObject* args) { PyErr_SetString(PyExc_TypeError, "subzone: cannot be used on a structured array."); - RELEASESHAREDU(arrayNodes, f, cn); RELEASESHAREDS(arrayCenters,fc); return NULL; + RELEASESHAREDU(arrayNodes, f, cn); RELEASESHAREDS(arrayCenters, fc); return NULL; } E_Int n = faceList.getSize(); @@ -2161,6 +2020,6 @@ PyObject* K_TRANSFORM::subzoneFacesBoth(PyObject* self, PyObject* args) return l; } - RELEASESHAREDU(arrayNodes,f, cn); RELEASESHAREDU(arrayCenters, fc, cnc); + RELEASESHAREDU(arrayNodes, f, cn); RELEASESHAREDU(arrayCenters, fc, cnc); return NULL; -} \ No newline at end of file +}