void mesh_deform_bind(Scene *scene, MeshDeformModifierData *mmd, float *vertexcos, int totvert, float cagemat[][4]) { MeshDeformBind mdb; MVert *mvert; int a; waitcursor(1); start_progress_bar(); memset(&mdb, 0, sizeof(MeshDeformBind)); /* get mesh and cage mesh */ mdb.vertexcos= MEM_callocN(sizeof(float)*3*totvert, "MeshDeformCos"); mdb.totvert= totvert; mdb.cagedm= mesh_create_derived_no_deform(scene, mmd->object, NULL, CD_MASK_BAREMESH); mdb.totcagevert= mdb.cagedm->getNumVerts(mdb.cagedm); mdb.cagecos= MEM_callocN(sizeof(*mdb.cagecos)*mdb.totcagevert, "MeshDeformBindCos"); copy_m4_m4(mdb.cagemat, cagemat); mvert= mdb.cagedm->getVertArray(mdb.cagedm); for(a=0; a<mdb.totcagevert; a++) copy_v3_v3(mdb.cagecos[a], mvert[a].co); for(a=0; a<mdb.totvert; a++) mul_v3_m4v3(mdb.vertexcos[a], mdb.cagemat, vertexcos + a*3); /* solve */ #if 0 if(mmd->mode == MOD_MDEF_VOLUME) harmonic_coordinates_bind(scene, mmd, &mdb); else heat_weighting_bind(scene, dm, mmd, &mdb); #else harmonic_coordinates_bind(scene, mmd, &mdb); #endif /* assign bind variables */ mmd->bindcagecos= (float*)mdb.cagecos; mmd->totvert= mdb.totvert; mmd->totcagevert= mdb.totcagevert; copy_m4_m4(mmd->bindmat, mmd->object->obmat); /* transform bindcagecos to world space */ for(a=0; a<mdb.totcagevert; a++) mul_m4_v3(mmd->object->obmat, mmd->bindcagecos+a*3); /* free */ mdb.cagedm->release(mdb.cagedm); MEM_freeN(mdb.vertexcos); /* compact weights */ modifier_mdef_compact_influences((ModifierData*)mmd); end_progress_bar(); waitcursor(0); }
int fluidsimBake(bContext *C, ReportList *reports, Object *ob) { Scene *scene= CTX_data_scene(C); FILE *fileCfg; int i; Object *fsDomain = NULL; FluidsimSettings *domainSettings; Object *obit = NULL; /* object iterator */ Base *base; int origFrame = scene->r.cfra; char debugStrBuffer[256]; int dirExist = 0; int gridlevels = 0; int simAborted = 0; // was the simulation aborted by user? int doExportOnly = 0; char *exportEnvStr = "BLENDER_ELBEEMEXPORTONLY"; const char *strEnvName = "BLENDER_ELBEEMDEBUG"; // from blendercall.cpp //char *channelNames[3] = { "translation","rotation","scale" }; char *suffixConfig = "fluidsim.cfg"; char *suffixSurface = "fluidsurface"; char newSurfdataPath[FILE_MAXDIR+FILE_MAXFILE]; // modified output settings char targetDir[FILE_MAXDIR+FILE_MAXFILE]; // store & modify output settings char targetFile[FILE_MAXDIR+FILE_MAXFILE]; // temp. store filename from targetDir for access int outStringsChanged = 0; // modified? copy back before baking int haveSomeFluid = 0; // check if any fluid objects are set // config vars, inited before either export or run... double calcViscosity = 0.0; int noFrames; double aniFrameTime; float aniFrlen; int channelObjCount; float *bbStart = NULL; float *bbSize = NULL; float domainMat[4][4]; float invDomMat[4][4]; // channel data int allchannelSize; // fixed by no. of frames int startFrame = 1; // dont use scene->r.sfra here, always start with frame 1 // easy frame -> sim time calc float *timeAtFrame=NULL, *timeAtIndex=NULL; // domain float *channelDomainTime = NULL; float *channelDomainViscosity = NULL; float *channelDomainGravity = NULL; // objects (currently max. 256 objs) float *channelObjMove[256][3]; // object movments , 0=trans, 1=rot, 2=scale float *channelObjInivel[256]; // initial velocities float *channelObjActive[256]; // obj active channel /* fluid control channels */ float *channelAttractforceStrength[256]; float *channelAttractforceRadius[256]; float *channelVelocityforceStrength[256]; float *channelVelocityforceRadius[256]; FluidsimModifierData *fluidmd = NULL; Mesh *mesh = NULL; if(getenv(strEnvName)) { int dlevel = atoi(getenv(strEnvName)); elbeemSetDebugLevel(dlevel); snprintf(debugStrBuffer,256,"fluidsimBake::msg: Debug messages activated due to envvar '%s'\n",strEnvName); elbeemDebugOut(debugStrBuffer); } if(getenv(exportEnvStr)) { doExportOnly = atoi(getenv(exportEnvStr)); snprintf(debugStrBuffer,256,"fluidsimBake::msg: Exporting mode set to '%d' due to envvar '%s'\n",doExportOnly, exportEnvStr); elbeemDebugOut(debugStrBuffer); } // make sure it corresponds to startFrame setting // old: noFrames = scene->r.efra - scene->r.sfra +1; noFrames = scene->r.efra - 0; if(noFrames<=0) { BKE_report(reports, RPT_ERROR, "No frames to export - check your animation range settings."); return 0; } /* no object pointer, find in selected ones.. */ if(!ob) { for(base=scene->base.first; base; base= base->next) { if ((base)->flag & SELECT) { FluidsimModifierData *fluidmdtmp = (FluidsimModifierData *)modifiers_findByType(base->object, eModifierType_Fluidsim); if(fluidmdtmp && (base->object->type==OB_MESH)) { if(fluidmdtmp->fss->type == OB_FLUIDSIM_DOMAIN) { ob = base->object; break; } } } } // no domains found? if(!ob) return 0; } channelObjCount = 0; for(base=scene->base.first; base; base= base->next) { FluidsimModifierData *fluidmdtmp = (FluidsimModifierData *)modifiers_findByType(base->object, eModifierType_Fluidsim); obit = base->object; if( fluidmdtmp && (obit->type==OB_MESH) && (fluidmdtmp->fss->type != OB_FLUIDSIM_DOMAIN) && // if has to match 3 places! // CHECKMATCH (fluidmdtmp->fss->type != OB_FLUIDSIM_PARTICLE) ) { channelObjCount++; } } if (channelObjCount>=255) { BKE_report(reports, RPT_ERROR, "Cannot bake with more then 256 objects."); return 0; } /* check if there's another domain... */ for(base=scene->base.first; base; base= base->next) { FluidsimModifierData *fluidmdtmp = (FluidsimModifierData *)modifiers_findByType(base->object, eModifierType_Fluidsim); obit = base->object; if( fluidmdtmp &&(obit->type==OB_MESH)) { if(fluidmdtmp->fss->type == OB_FLUIDSIM_DOMAIN) { if(obit != ob) { BKE_report(reports, RPT_ERROR, "There should be only one domain object."); return 0; } } } } // check if theres any fluid // abort baking if not... for(base=scene->base.first; base; base= base->next) { FluidsimModifierData *fluidmdtmp = (FluidsimModifierData *)modifiers_findByType(base->object, eModifierType_Fluidsim); obit = base->object; if( fluidmdtmp && (obit->type==OB_MESH) && ((fluidmdtmp->fss->type == OB_FLUIDSIM_FLUID) || (fluidmdtmp->fss->type == OB_FLUIDSIM_INFLOW) )) { haveSomeFluid = 1; break; } } if(!haveSomeFluid) { BKE_report(reports, RPT_ERROR, "No fluid objects in scene."); return 0; } /* these both have to be valid, otherwise we wouldnt be here */ /* dont use ob here after...*/ fsDomain = ob; fluidmd = (FluidsimModifierData *)modifiers_findByType(ob, eModifierType_Fluidsim); domainSettings = fluidmd->fss; ob = NULL; mesh = fsDomain->data; // calculate bounding box fluid_get_bb(mesh->mvert, mesh->totvert, fsDomain->obmat, domainSettings->bbStart, domainSettings->bbSize); // reset last valid frame domainSettings->lastgoodframe = -1; /* rough check of settings... */ if(domainSettings->previewresxyz > domainSettings->resolutionxyz) { snprintf(debugStrBuffer,256,"fluidsimBake::warning - Preview (%d) >= Resolution (%d)... setting equal.\n", domainSettings->previewresxyz , domainSettings->resolutionxyz); elbeemDebugOut(debugStrBuffer); domainSettings->previewresxyz = domainSettings->resolutionxyz; } // set adaptive coarsening according to resolutionxyz // this should do as an approximation, with in/outflow // doing this more accurate would be overkill // perhaps add manual setting? if(domainSettings->maxRefine <0) { if(domainSettings->resolutionxyz>128) { gridlevels = 2; } else if(domainSettings->resolutionxyz>64) { gridlevels = 1; } else { gridlevels = 0; } } else { gridlevels = domainSettings->maxRefine; } snprintf(debugStrBuffer,256,"fluidsimBake::msg: Baking %s, refine: %d\n", fsDomain->id.name , gridlevels ); elbeemDebugOut(debugStrBuffer); // prepare names... strncpy(targetDir, domainSettings->surfdataPath, FILE_MAXDIR); strncpy(newSurfdataPath, domainSettings->surfdataPath, FILE_MAXDIR); BLI_convertstringcode(targetDir, G.sce); // fixed #frame-no strcpy(targetFile, targetDir); strcat(targetFile, suffixConfig); if(!doExportOnly) { strcat(targetFile,".tmp"); } // dont overwrite/delete original file // make sure all directories exist // as the bobjs use the same dir, this only needs to be checked // for the cfg output BLI_make_existing_file(targetFile); // check selected directory // simply try to open cfg file for writing to test validity of settings fileCfg = fopen(targetFile, "w"); if(fileCfg) { dirExist = 1; fclose(fileCfg); // remove cfg dummy from directory test if(!doExportOnly) { BLI_delete(targetFile, 0,0); } } if((strlen(targetDir)<1) || (!dirExist)) { char blendDir[FILE_MAXDIR+FILE_MAXFILE], blendFile[FILE_MAXDIR+FILE_MAXFILE]; // invalid dir, reset to current/previous strcpy(blendDir, G.sce); BLI_splitdirstring(blendDir, blendFile); if(strlen(blendFile)>6){ int len = strlen(blendFile); if( (blendFile[len-6]=='.')&& (blendFile[len-5]=='b')&& (blendFile[len-4]=='l')&& (blendFile[len-3]=='e')&& (blendFile[len-2]=='n')&& (blendFile[len-1]=='d') ){ blendFile[len-6] = '\0'; } } // todo... strip .blend ? snprintf(newSurfdataPath,FILE_MAXFILE+FILE_MAXDIR,"//fluidsimdata/%s_%s_", blendFile, fsDomain->id.name); snprintf(debugStrBuffer,256,"fluidsimBake::error - warning resetting output dir to '%s'\n", newSurfdataPath); elbeemDebugOut(debugStrBuffer); outStringsChanged=1; } // check if modified output dir is ok if(outStringsChanged) { char dispmsg[FILE_MAXDIR+FILE_MAXFILE+256]; int selection=0; strcpy(dispmsg,"Output settings set to: '"); strcat(dispmsg, newSurfdataPath); strcat(dispmsg, "'%t|Continue with changed settings%x1|Discard and abort%x0"); // ask user if thats what he/she wants... selection = pupmenu(dispmsg); if(selection<1) return 0; // 0 from menu, or -1 aborted strcpy(targetDir, newSurfdataPath); strncpy(domainSettings->surfdataPath, newSurfdataPath, FILE_MAXDIR); BLI_convertstringcode(targetDir, G.sce); // fixed #frame-no } // -------------------------------------------------------------------------------------------- // dump data for start frame // CHECK more reasonable to number frames according to blender? // dump data for frame 0 scene->r.cfra = startFrame; ED_update_for_newframe(C, 1); // init common export vars for both file export and run for(i=0; i<256; i++) { channelObjMove[i][0] = channelObjMove[i][1] = channelObjMove[i][2] = NULL; channelObjInivel[i] = NULL; channelObjActive[i] = NULL; channelAttractforceStrength[i] = NULL; channelAttractforceRadius[i] = NULL; channelVelocityforceStrength[i] = NULL; channelVelocityforceRadius[i] = NULL; } allchannelSize = scene->r.efra; // always use till last frame aniFrameTime = (domainSettings->animEnd - domainSettings->animStart)/(double)noFrames; // blender specific - scale according to map old/new settings in anim panel: aniFrlen = scene->r.framelen; if(domainSettings->viscosityMode==1) { /* manual mode, visc=value/(10^-vexp) */ calcViscosity = (1.0/pow(10.0,domainSettings->viscosityExponent)) * domainSettings->viscosityValue; } else { calcViscosity = fluidsimViscosityPreset[ domainSettings->viscosityMode ]; } bbStart = domainSettings->bbStart; bbSize = domainSettings->bbSize; // always init { int timeIcu[1] = { FLUIDSIM_TIME }; float timeDef[1] = { 1. }; int gravIcu[3] = { FLUIDSIM_GRAV_X, FLUIDSIM_GRAV_Y, FLUIDSIM_GRAV_Z }; float gravDef[3]; int viscIcu[1] = { FLUIDSIM_VISC }; float viscDef[1] = { 1. }; gravDef[0] = domainSettings->gravx; gravDef[1] = domainSettings->gravy; gravDef[2] = domainSettings->gravz; // time channel is a bit special, init by hand... timeAtIndex = MEM_callocN( (allchannelSize+1)*1*sizeof(float), "fluidsiminit_timeatindex"); for(i=0; i<=scene->r.efra; i++) { timeAtIndex[i] = (float)(i-startFrame); } fluidsimInitChannel(scene, &channelDomainTime, allchannelSize, timeAtIndex, timeIcu,timeDef, domainSettings->ipo, CHANNEL_FLOAT ); // NDEB // time channel is a multiplicator for aniFrameTime if(channelDomainTime) { for(i=0; i<allchannelSize; i++) { channelDomainTime[i*2+0] = aniFrameTime * channelDomainTime[i*2+0]; if(channelDomainTime[i*2+0]<0.) channelDomainTime[i*2+0] = 0.; } } timeAtFrame = MEM_callocN( (allchannelSize+1)*1*sizeof(float), "fluidsiminit_timeatframe"); timeAtFrame[0] = timeAtFrame[1] = domainSettings->animStart; // start at index 1 if(channelDomainTime) { for(i=2; i<=allchannelSize; i++) { timeAtFrame[i] = timeAtFrame[i-1]+channelDomainTime[(i-1)*2+0]; } } else { for(i=2; i<=allchannelSize; i++) { timeAtFrame[i] = timeAtFrame[i-1]+aniFrameTime; } } fluidsimInitChannel(scene, &channelDomainViscosity, allchannelSize, timeAtFrame, viscIcu,viscDef, domainSettings->ipo, CHANNEL_FLOAT ); // NDEB if(channelDomainViscosity) { for(i=0; i<allchannelSize; i++) { channelDomainViscosity[i*2+0] = calcViscosity * channelDomainViscosity[i*2+0]; } } fluidsimInitChannel(scene, &channelDomainGravity, allchannelSize, timeAtFrame, gravIcu,gravDef, domainSettings->ipo, CHANNEL_VEC ); } // domain channel init // init obj movement channels channelObjCount=0; for(base=scene->base.first; base; base= base->next) { FluidsimModifierData *fluidmdtmp = (FluidsimModifierData *)modifiers_findByType(base->object, eModifierType_Fluidsim); obit = base->object; if( fluidmdtmp && (obit->type==OB_MESH) && (fluidmdtmp->fss->type != OB_FLUIDSIM_DOMAIN) && // if has to match 3 places! // CHECKMATCH (fluidmdtmp->fss->type != OB_FLUIDSIM_PARTICLE) ) { // cant use fluidsimInitChannel for obj channels right now, due // to the special DXXX channels, and the rotation specialities IpoCurve *icuex[3][3]; //IpoCurve *par_icuex[3][3]; #if 0 int icuIds[3][3] = { {OB_LOC_X, OB_LOC_Y, OB_LOC_Z}, {OB_ROT_X, OB_ROT_Y, OB_ROT_Z}, {OB_SIZE_X, OB_SIZE_Y, OB_SIZE_Z} }; int icudIds[3][3] = { {OB_DLOC_X, OB_DLOC_Y, OB_DLOC_Z}, {OB_DROT_X, OB_DROT_Y, OB_DROT_Z}, {OB_DSIZE_X, OB_DSIZE_Y, OB_DSIZE_Z} }; #endif // relative ipos IpoCurve *icudex[3][3]; //IpoCurve *par_icudex[3][3]; int j,k; float vals[3] = {0.0,0.0,0.0}; int o = channelObjCount; int inivelIcu[3] = { FLUIDSIM_VEL_X, FLUIDSIM_VEL_Y, FLUIDSIM_VEL_Z }; float inivelDefs[3]; int activeIcu[1] = { FLUIDSIM_ACTIVE }; float activeDefs[1] = { 1 }; // default to on inivelDefs[0] = fluidmdtmp->fss->iniVelx; inivelDefs[1] = fluidmdtmp->fss->iniVely; inivelDefs[2] = fluidmdtmp->fss->iniVelz; // check & init loc,rot,size for(j=0; j<3; j++) { for(k=0; k<3; k++) { // XXX prevent invalid memory access until this works icuex[j][k]= NULL; icudex[j][k]= NULL; // XXX icuex[j][k] = find_ipocurve(obit->ipo, icuIds[j][k] ); // XXX icudex[j][k] = find_ipocurve(obit->ipo, icudIds[j][k] ); // XXX lines below were already disabled! //if(obit->parent) { //par_icuex[j][k] = find_ipocurve(obit->parent->ipo, icuIds[j][k] ); //par_icudex[j][k] = find_ipocurve(obit->parent->ipo, icudIds[j][k] ); //} } } for(j=0; j<3; j++) { channelObjMove[o][j] = MEM_callocN( allchannelSize*4*sizeof(float), "fluidsiminit_objmovchannel"); for(i=1; i<=allchannelSize; i++) { for(k=0; k<3; k++) { if(icuex[j][k]) { // IPO exists, use it ... // XXX calc_icu(icuex[j][k], aniFrlen*((float)i) ); vals[k] = icuex[j][k]->curval; if(obit->parent) { // add parent transform, multiply scaling, add trafo&rot //calc_icu(par_icuex[j][k], aniFrlen*((float)i) ); //if(j==2) { vals[k] *= par_icuex[j][k]->curval; } //else { vals[k] += par_icuex[j][k]->curval; } } } else { // use defaults from static values float setval=0.0; if(j==0) { setval = obit->loc[k]; if(obit->parent){ setval += obit->parent->loc[k]; } } else if(j==1) { setval = ( 180.0*obit->rot[k] )/( 10.0*M_PI ); if(obit->parent){ setval = ( 180.0*(obit->rot[k]+obit->parent->rot[k]) )/( 10.0*M_PI ); } } else { setval = obit->size[k]; if(obit->parent){ setval *= obit->parent->size[k]; } } vals[k] = setval; } if(icudex[j][k]) { // XXX calc_icu(icudex[j][k], aniFrlen*((float)i) ); //vals[k] += icudex[j][k]->curval; // add transform, multiply scaling, add trafo&rot if(j==2) { vals[k] *= icudex[j][k]->curval; } else { vals[k] += icudex[j][k]->curval; } if(obit->parent) { // add parent transform, multiply scaling, add trafo&rot //calc_icu(par_icuex[j][k], aniFrlen*((float)i) ); //if(j==2) { vals[k] *= par_icudex[j][k]->curval; } //else { vals[k] += par_icudex[j][k]->curval; } } } } // k for(k=0; k<3; k++) { float set = vals[k]; if(j==1) { // rot is downscaled by 10 for ipo !? set = 360.0 - (10.0*set); } channelObjMove[o][j][(i-1)*4 + k] = set; } // k channelObjMove[o][j][(i-1)*4 + 3] = timeAtFrame[i]; } } { int attrFSIcu[1] = { FLUIDSIM_ATTR_FORCE_STR }; int attrFRIcu[1] = { FLUIDSIM_ATTR_FORCE_RADIUS }; int velFSIcu[1] = { FLUIDSIM_VEL_FORCE_STR }; int velFRIcu[1] = { FLUIDSIM_VEL_FORCE_RADIUS }; float attrFSDefs[1]; float attrFRDefs[1]; float velFSDefs[1]; float velFRDefs[1]; attrFSDefs[0] = fluidmdtmp->fss->attractforceStrength; attrFRDefs[0] = fluidmdtmp->fss->attractforceRadius; velFSDefs[0] = fluidmdtmp->fss->velocityforceStrength; velFRDefs[0] = fluidmdtmp->fss->velocityforceRadius; fluidsimInitChannel(scene, &channelAttractforceStrength[o], allchannelSize, timeAtFrame, attrFSIcu,attrFSDefs, fluidmdtmp->fss->ipo, CHANNEL_FLOAT ); fluidsimInitChannel(scene, &channelAttractforceRadius[o], allchannelSize, timeAtFrame, attrFRIcu,attrFRDefs, fluidmdtmp->fss->ipo, CHANNEL_FLOAT ); fluidsimInitChannel(scene, &channelVelocityforceStrength[o], allchannelSize, timeAtFrame, velFSIcu,velFSDefs, fluidmdtmp->fss->ipo, CHANNEL_FLOAT ); fluidsimInitChannel(scene, &channelVelocityforceRadius[o], allchannelSize, timeAtFrame, velFRIcu,velFRDefs, fluidmdtmp->fss->ipo, CHANNEL_FLOAT ); } fluidsimInitChannel(scene, &channelObjInivel[o], allchannelSize, timeAtFrame, inivelIcu,inivelDefs, fluidmdtmp->fss->ipo, CHANNEL_VEC ); fluidsimInitChannel(scene, &channelObjActive[o], allchannelSize, timeAtFrame, activeIcu,activeDefs, fluidmdtmp->fss->ipo, CHANNEL_FLOAT ); channelObjCount++; } } // init trafo matrix Mat4CpyMat4(domainMat, fsDomain->obmat); if(!Mat4Invert(invDomMat, domainMat)) { snprintf(debugStrBuffer,256,"fluidsimBake::error - Invalid obj matrix?\n"); elbeemDebugOut(debugStrBuffer); BKE_report(reports, RPT_ERROR, "Invalid object matrix."); // FIXME add fatal msg FS_FREE_CHANNELS; return 0; } // -------------------------------------------------------------------------------------------- // start writing / exporting strcpy(targetFile, targetDir); strcat(targetFile, suffixConfig); if(!doExportOnly) { strcat(targetFile,".tmp"); } // dont overwrite/delete original file // make sure these directories exist as well if(outStringsChanged) { BLI_make_existing_file(targetFile); } if(!doExportOnly) { ListBase threads; // perform simulation with El'Beem api and threads elbeemSimulationSettings fsset; elbeemResetSettings(&fsset); fsset.version = 1; // setup global settings for(i=0 ; i<3; i++) fsset.geoStart[i] = bbStart[i]; for(i=0 ; i<3; i++) fsset.geoSize[i] = bbSize[i]; // simulate with 50^3 fsset.resolutionxyz = (int)domainSettings->resolutionxyz; fsset.previewresxyz = (int)domainSettings->previewresxyz; // 10cm water domain fsset.realsize = domainSettings->realsize; fsset.viscosity = calcViscosity; // earth gravity fsset.gravity[0] = domainSettings->gravx; fsset.gravity[1] = domainSettings->gravy; fsset.gravity[2] = domainSettings->gravz; // simulate 5 frames, each 0.03 seconds, output to ./apitest_XXX.bobj.gz fsset.animStart = domainSettings->animStart; fsset.aniFrameTime = aniFrameTime; fsset.noOfFrames = noFrames; // is otherwise subtracted in parser strcpy(targetFile, targetDir); strcat(targetFile, suffixSurface); // defaults for compressibility and adaptive grids fsset.gstar = domainSettings->gstar; fsset.maxRefine = domainSettings->maxRefine; // check <-> gridlevels fsset.generateParticles = domainSettings->generateParticles; fsset.numTracerParticles = domainSettings->generateTracers; fsset.surfaceSmoothing = domainSettings->surfaceSmoothing; fsset.surfaceSubdivs = domainSettings->surfaceSubdivs; fsset.farFieldSize = domainSettings->farFieldSize; strcpy( fsset.outputPath, targetFile); // domain channels fsset.channelSizeFrameTime = fsset.channelSizeViscosity = fsset.channelSizeGravity = allchannelSize; fsset.channelFrameTime = channelDomainTime; fsset.channelViscosity = channelDomainViscosity; fsset.channelGravity = channelDomainGravity; fsset.runsimCallback = &runSimulationCallback; fsset.runsimUserData = &fsset; if( (domainSettings->typeFlags&OB_FSBND_NOSLIP)) fsset.domainobsType = FLUIDSIM_OBSTACLE_NOSLIP; else if((domainSettings->typeFlags&OB_FSBND_PARTSLIP)) fsset.domainobsType = FLUIDSIM_OBSTACLE_PARTSLIP; else if((domainSettings->typeFlags&OB_FSBND_FREESLIP)) fsset.domainobsType = FLUIDSIM_OBSTACLE_FREESLIP; fsset.domainobsPartslip = domainSettings->partSlipValue; fsset.generateVertexVectors = (domainSettings->domainNovecgen==0); // init blender trafo matrix // fprintf(stderr,"elbeemInit - mpTrafo:\n"); { int j; for(i=0; i<4; i++) { for(j=0; j<4; j++) { fsset.surfaceTrafo[i*4+j] = invDomMat[j][i]; // fprintf(stderr,"elbeemInit - mpTrafo %d %d = %f (%d) \n", i,j, fsset.surfaceTrafo[i*4+j] , (i*4+j) ); } } } // init solver with settings elbeemInit(); elbeemAddDomain(&fsset); // init objects channelObjCount = 0; for(base=scene->base.first; base; base= base->next) { FluidsimModifierData *fluidmdtmp = (FluidsimModifierData *)modifiers_findByType(base->object, eModifierType_Fluidsim); obit = base->object; //{ snprintf(debugStrBuffer,256,"DEBUG object name=%s, type=%d ...\n", obit->id.name, obit->type); elbeemDebugOut(debugStrBuffer); } // DEBUG if( fluidmdtmp && // if has to match 3 places! // CHECKMATCH (obit->type==OB_MESH) && (fluidmdtmp->fss->type != OB_FLUIDSIM_DOMAIN) && (fluidmdtmp->fss->type != OB_FLUIDSIM_PARTICLE)) { float *verts=NULL; int *tris=NULL; int numVerts=0, numTris=0; int o = channelObjCount; int deform = (fluidmdtmp->fss->domainNovecgen); // misused value // todo - use blenderInitElbeemMesh int modifierIndex = modifiers_indexInObject(obit, (ModifierData *)fluidmdtmp); elbeemMesh fsmesh; elbeemResetMesh( &fsmesh ); fsmesh.type = fluidmdtmp->fss->type; // get name of object for debugging solver fsmesh.name = obit->id.name; initElbeemMesh(scene, obit, &numVerts, &verts, &numTris, &tris, 0, modifierIndex); fsmesh.numVertices = numVerts; fsmesh.numTriangles = numTris; fsmesh.vertices = verts; fsmesh.triangles = tris; fsmesh.channelSizeTranslation = fsmesh.channelSizeRotation = fsmesh.channelSizeScale = fsmesh.channelSizeInitialVel = fsmesh.channelSizeActive = allchannelSize; fsmesh.channelTranslation = channelObjMove[o][0]; fsmesh.channelRotation = channelObjMove[o][1]; fsmesh.channelScale = channelObjMove[o][2]; fsmesh.channelActive = channelObjActive[o]; if( (fsmesh.type == OB_FLUIDSIM_FLUID) || (fsmesh.type == OB_FLUIDSIM_INFLOW)) { fsmesh.channelInitialVel = channelObjInivel[o]; fsmesh.localInivelCoords = ((fluidmdtmp->fss->typeFlags&OB_FSINFLOW_LOCALCOORD)?1:0); } if( (fluidmdtmp->fss->typeFlags&OB_FSBND_NOSLIP)) fsmesh.obstacleType = FLUIDSIM_OBSTACLE_NOSLIP; else if((fluidmdtmp->fss->typeFlags&OB_FSBND_PARTSLIP)) fsmesh.obstacleType = FLUIDSIM_OBSTACLE_PARTSLIP; else if((fluidmdtmp->fss->typeFlags&OB_FSBND_FREESLIP)) fsmesh.obstacleType = FLUIDSIM_OBSTACLE_FREESLIP; fsmesh.obstaclePartslip = fluidmdtmp->fss->partSlipValue; fsmesh.volumeInitType = fluidmdtmp->fss->volumeInitType; fsmesh.obstacleImpactFactor = fluidmdtmp->fss->surfaceSmoothing; // misused value if(fsmesh.type == OB_FLUIDSIM_CONTROL) { // control fluids will get exported as whole deform = 1; fsmesh.cpsTimeStart = fluidmdtmp->fss->cpsTimeStart; fsmesh.cpsTimeEnd = fluidmdtmp->fss->cpsTimeEnd; fsmesh.cpsQuality = fluidmdtmp->fss->cpsQuality; fsmesh.obstacleType = (fluidmdtmp->fss->flag & OB_FLUIDSIM_REVERSE); fsmesh.channelSizeAttractforceRadius = fsmesh.channelSizeVelocityforceStrength = fsmesh.channelSizeVelocityforceRadius = fsmesh.channelSizeAttractforceStrength = allchannelSize; fsmesh.channelAttractforceStrength = channelAttractforceStrength[o]; fsmesh.channelAttractforceRadius = channelAttractforceRadius[o]; fsmesh.channelVelocityforceStrength = channelVelocityforceStrength[o]; fsmesh.channelVelocityforceRadius = channelVelocityforceRadius[o]; } else { // set channels to 0 fsmesh.channelAttractforceStrength = fsmesh.channelAttractforceRadius = fsmesh.channelVelocityforceStrength = fsmesh.channelVelocityforceRadius = NULL; } // animated meshes if(deform) { fsmesh.channelSizeVertices = allchannelSize; fluidsimInitMeshChannel(C, &fsmesh.channelVertices, allchannelSize, obit, numVerts, timeAtFrame, modifierIndex); scene->r.cfra = startFrame; ED_update_for_newframe(C, 1); // remove channels fsmesh.channelTranslation = fsmesh.channelRotation = fsmesh.channelScale = NULL; } elbeemAddMesh(&fsmesh); if(verts) MEM_freeN(verts); if(tris) MEM_freeN(tris); if(fsmesh.channelVertices) MEM_freeN(fsmesh.channelVertices); channelObjCount++; } // valid mesh } // objects //domainSettings->type = OB_FLUIDSIM_DOMAIN; // enable for bake display again // set to neutral, -1 means user abort, -2 means init error globalBakeState = 0; globalBakeFrame = 0; BLI_init_threads(&threads, fluidsimSimulateThread, 1); BLI_insert_thread(&threads, targetFile); { int done = 0; float noFramesf = (float)noFrames; float percentdone = 0.0; int lastRedraw = -1; g_break= 0; G.afbreek= 0; /* blender_test_break uses this global */ start_progress_bar(); while(done==0) { char busy_mess[80]; waitcursor(1); // lukep we add progress bar as an interim mesure percentdone = globalBakeFrame / noFramesf; sprintf(busy_mess, "baking fluids %d / %d |||", globalBakeFrame, (int) noFramesf); progress_bar(percentdone, busy_mess ); // longer delay to prevent frequent redrawing PIL_sleep_ms(2000); BLI_lock_thread(LOCK_CUSTOM1); if(globalBakeState != 0) done = 1; // 1=ok, <0=error/abort BLI_unlock_thread(LOCK_CUSTOM1); if (!G.background) { g_break= blender_test_break(); if(g_break) { // abort... BLI_lock_thread(LOCK_CUSTOM1); if(domainSettings) domainSettings->lastgoodframe = startFrame+globalBakeFrame; done = -1; globalBakeFrame = 0; globalBakeState = -1; simAborted = 1; BLI_unlock_thread(LOCK_CUSTOM1); break; } } // redraw the 3D for showing progress once in a while... if(lastRedraw!=globalBakeFrame) { #if 0 ScrArea *sa; scene->r.cfra = startFrame+globalBakeFrame; lastRedraw = globalBakeFrame; ED_update_for_newframe(C, 1); sa= G.curscreen->areabase.first; while(sa) { if(sa->spacetype == SPACE_VIEW3D) { scrarea_do_windraw(sa); } sa= sa->next; } screen_swapbuffers(); #endif } // redraw } end_progress_bar(); } BLI_end_threads(&threads); } // El'Beem API init, thread creation // -------------------------------------------------------------------------------------------- else { // write config file to be run with command line simulator BKE_report(reports, RPT_WARNING, "Config file export not supported."); } // config file export done! // -------------------------------------------------------------------------------------------- FS_FREE_CHANNELS; // go back to "current" blender time waitcursor(0); if(globalBakeState >= 0) { if(domainSettings) domainSettings->lastgoodframe = startFrame+globalBakeFrame; } scene->r.cfra = origFrame; ED_update_for_newframe(C, 1); if(!simAborted) { char elbeemerr[256]; // check if some error occurred if(globalBakeState==-2) { elbeemGetErrorString(elbeemerr); BKE_reportf(reports, RPT_ERROR, "Failed to initialize [Msg: %s]", elbeemerr); return 0; } // init error } // elbeemFree(); return 1; }