Line data Source code
1 : // -*- C++ -*-
2 : //# MultiThreadedVisResample.cc: Implementation of the MultiThreadedVisibilityResampler class
3 : //# Copyright (C) 1997,1998,1999,2000,2001,2002,2003
4 : //# Associated Universities, Inc. Washington DC, USA.
5 : //#
6 : //# This library is free software; you can redistribute it and/or modify it
7 : //# under the terms of the GNU Library General Public License as published by
8 : //# the Free Software Foundation; either version 2 of the License, or (at your
9 : //# option) any later version.
10 : //#
11 : //# This library is distributed in the hope that it will be useful, but WITHOUT
12 : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 : //# FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library General Public
14 : //# License for more details.
15 : //#
16 : //# You should have received a copy of the GNU Library General Public License
17 : //# along with this library; if not, write to the Free Software Foundation,
18 : //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
19 : //#
20 : //# Correspondence concerning AIPS++ should be addressed as follows:
21 : //# Internet email: aips2-request@nrao.edu.
22 : //# Postal address: AIPS++ Project Office
23 : //# National Radio Astronomy Observatory
24 : //# 520 Edgemont Road
25 : //# Charlottesville, VA 22903-2475 USA
26 : //#
27 : //# $Id$
28 :
29 : #include <synthesis/TransformMachines/SynthesisError.h>
30 : #include <synthesis/Utilities/ThreadCoordinator.h>
31 : //#include <msvis/MSVis/UtilJ.h>
32 : #include <synthesis/TransformMachines/Utils.h>
33 : #include <synthesis/TransformMachines/VisibilityResampler.h>
34 : #include <synthesis/MeasurementComponents/MultiThreadedVisResampler.h>
35 : #include <synthesis/MeasurementComponents/ResamplerWorklet.h>
36 : #include <synthesis/TransformMachines/AWVisResampler.h>
37 : #include <synthesis/MeasurementComponents/MThWorkIDEnum.h>
38 : #include <fstream>
39 :
40 : using namespace casacore;
41 : namespace casa{
42 : template
43 : void MultiThreadedVisibilityResampler::DataToGridImpl_p(Array<Complex>& griddedData,
44 : VBStore& vbs,
45 : Matrix<Double>& sumwt,
46 : const Bool& dopsf,
47 : Bool useConjFreqCF);
48 : template
49 : void MultiThreadedVisibilityResampler::DataToGridImpl_p(Array<DComplex>& griddedData,
50 : VBStore& vbs,
51 : Matrix<Double>& sumwt,
52 : const Bool& dopsf,
53 : Bool useConjFreqCF);
54 : //
55 : //---------------------------------------------------------------------------------------
56 : //
57 0 : MultiThreadedVisibilityResampler::MultiThreadedVisibilityResampler(const Bool& doublePrecision,
58 : CountedPtr<VisibilityResamplerBase>& visResampler,
59 0 : const Int& n):
60 : resamplers_p(), doubleGriddedData_p(), singleGriddedData_p(), sumwt_p(), gridderWorklets_p(),
61 : vbsVec_p(), threadClerk_p(),threadStarted_p(false), visResamplerCtor_p(visResampler),
62 0 : whoLoadedVB_p(MThWorkID::NOONE), currentVBS_p(0)
63 : {
64 0 : if (n < 0) nelements_p = SynthesisUtils::getenv(FTMachineNumThreadsEnvVar, n);
65 0 : if (nelements_p < 0) nelements_p = 1;
66 0 : init(doublePrecision);
67 : // t4G_p=Timers::getTime();
68 : // t4DG_p=Timers::getTime();
69 0 : }
70 : //
71 : //---------------------------------------------------------------------------------------
72 : //
73 0 : MultiThreadedVisibilityResampler::MultiThreadedVisibilityResampler(const Bool& doublePrecision,
74 0 : const Int& n):
75 : resamplers_p(), doubleGriddedData_p(), singleGriddedData_p(), sumwt_p(), gridderWorklets_p(),
76 : vbsVec_p(), threadClerk_p(),threadStarted_p(false), visResamplerCtor_p(),
77 0 : whoLoadedVB_p(MThWorkID::NOONE),currentVBS_p(0)
78 : {
79 0 : if (n < 0) nelements_p = SynthesisUtils::getenv(FTMachineNumThreadsEnvVar, n);
80 0 : if (nelements_p < 0) nelements_p = 1;
81 0 : init(doublePrecision);
82 : // t4G_p=Timers::getTime();
83 : // t4DG_p=Timers::getTime();
84 0 : }
85 : //
86 : //---------------------------------------------------------------------------------------
87 : //
88 0 : void MultiThreadedVisibilityResampler::copy(const MultiThreadedVisibilityResampler& other)
89 : {
90 0 : resamplers_p.assign(other.resamplers_p);
91 0 : gridderWorklets_p.assign(other.gridderWorklets_p);
92 0 : vbsVec_p.assign(other.vbsVec_p);
93 :
94 0 : doubleGriddedData_p.assign(other.doubleGriddedData_p);
95 0 : singleGriddedData_p.assign(other.singleGriddedData_p);
96 0 : sumwt_p.assign(other.sumwt_p);
97 : // doubleGriddedData_p.reference(other.doubleGriddedData_p);
98 : // singleGriddedData_p.reference(other.singleGriddedData_p);
99 : // sumwt_p.reference(other.sumwt_p);
100 :
101 0 : nelements_p = other.nelements_p;
102 0 : doublePrecision_p = other.doublePrecision_p;
103 0 : threadClerk_p = other.threadClerk_p;
104 0 : threadStarted_p = other.threadStarted_p;
105 0 : whoLoadedVB_p = other.whoLoadedVB_p;
106 0 : currentVBS_p = other.currentVBS_p;
107 : // t4G_p=other.t4G_p;
108 : // t4DG_p=other.t4DG_p;
109 0 : }
110 : //
111 : //---------------------------------------------------------------------------------------
112 : //
113 : MultiThreadedVisibilityResampler&
114 0 : MultiThreadedVisibilityResampler::operator=(const MultiThreadedVisibilityResampler& other)
115 0 : { copy(other); return *this;}
116 : //
117 : //---------------------------------------------------------------------------------------
118 : //
119 0 : void MultiThreadedVisibilityResampler::init(const Bool& doublePrecision)
120 : {
121 0 : LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler","init"));
122 0 : doublePrecision_p=doublePrecision;
123 0 : allocateBuffers();
124 0 : }
125 : //
126 : //---------------------------------------------------------------------------------------
127 : //
128 0 : void MultiThreadedVisibilityResampler::cleanup()
129 : {
130 : // if ((nelements() > 1) && (threadClerk_p->nThreads() > 0))
131 0 : if (threadClerk_p->nThreads() > 0)
132 : {
133 : // threadClerk_p->getToWork(NULL); // Signal the threads to quit
134 0 : threadClerk_p->giveWorkToWorkers(NULL); // Signal the threads to quit
135 0 : threadClerk_p->setNThreads(0);
136 : // if (!threadClerk_p.null()) {delete &(*threadClerk_p);}
137 0 : vbsVec_p.resize(0,0);
138 0 : resamplers_p.resize(0);
139 : // for(Int i=0; i<gridderWorklets_p.nelements(); i++) delete &(*gridderWorklets_p[i]);
140 0 : gridderWorklets_p.resize(0);
141 0 : sumwt_p.resize(0);
142 0 : doubleGriddedData_p.resize(0);
143 0 : singleGriddedData_p.resize(0);
144 0 : nelements_p=0;
145 0 : whoLoadedVB_p = MThWorkID::NOONE;
146 0 : currentVBS_p=0;
147 : // delete mutexForResamplers_p;
148 : }
149 0 : }
150 : //
151 : //---------------------------------------------------------------------------------------
152 : //
153 0 : void MultiThreadedVisibilityResampler::releaseBuffers()
154 : {
155 : // for (Int i=0;i<nelements();i++)
156 : // {
157 : // // if (!resamplers_p[i].null()) delete &(*resamplers_p[i]);
158 : // // if (!gridderWorklets_p[i].null()) delete &(*gridderWorklets_p[i]);
159 : // if (doublePrecision_p)
160 : // if (!doubleGriddedData_p[i].null()) delete &(*doubleGriddedData_p[i]);
161 : // else if (!singleGriddedData_p[i].null()) delete &(*singleGriddedData_p[i]);
162 : // if (!sumwt_p[i].null()) delete &(*sumwt_p[i]);
163 : // }
164 : // resamplers_p.resize(0);
165 : // gridderWorklets_p.resize(0);
166 0 : doubleGriddedData_p.resize(0);
167 0 : singleGriddedData_p.resize(0);
168 0 : sumwt_p.resize(0);
169 0 : }
170 : //
171 : //---------------------------------------------------------------------------------------
172 : //
173 0 : void MultiThreadedVisibilityResampler::makeInfrastructureContainers()
174 : {
175 : //
176 : // Fill the various containers (allocate buffers)
177 : //----------------------------------------------------------------
178 0 : if (threadClerk_p.null()) threadClerk_p = new ThreadCoordinator<Int>(nelements());
179 0 : for (Int i=0;i<nelements();i++)
180 : {
181 0 : resamplers_p[i] = visResamplerCtor_p->clone();
182 0 : gridderWorklets_p[i] = new ResamplerWorklet();
183 : }
184 0 : }
185 : //
186 : //---------------------------------------------------------------------------------------
187 : //
188 0 : Double MultiThreadedVisibilityResampler::allocateDataBuffers()
189 : {
190 0 : Int totalMem=0;
191 0 : for (Int i=0;i<nelements();i++)
192 : {
193 : //
194 : // *GriddedData and sumwt are the target complex grids
195 : // *(for gridding) and accumulating sum-of-weights (also
196 : // *during gridding). These may or may not be shared.
197 : //
198 0 : if (doublePrecision_p) doubleGriddedData_p[i] = new Array<DComplex>;
199 0 : else singleGriddedData_p[i] = new Array<Complex>;
200 0 : sumwt_p[i] = new Matrix<Double>;
201 0 : if (!threadStarted_p)
202 : {
203 0 : if (doublePrecision_p) totalMem += (*doubleGriddedData_p[i]).size()*sizeof(DComplex);
204 0 : else totalMem += (*singleGriddedData_p[i]).size()*sizeof(Complex);
205 0 : totalMem += (*sumwt_p[i]).size()*sizeof(Double);
206 : // (*gridderWorklets_p[i]).initThread(i, threadClerk_p,
207 : // &(*resamplers_p[i]));
208 : // (*gridderWorklets_p[i]).startThread();
209 : }
210 : }
211 0 : return totalMem;
212 : }
213 : //
214 : //---------------------------------------------------------------------------------------
215 : //
216 0 : void MultiThreadedVisibilityResampler::startThreads()
217 : {
218 0 : if (!threadStarted_p)
219 0 : for (Int i=0;i<nelements();i++)
220 : {
221 0 : (*gridderWorklets_p[i]).initThread(i, threadClerk_p,
222 0 : &(*resamplers_p[i]));
223 0 : (*gridderWorklets_p[i]).startThread();
224 : }
225 0 : threadStarted_p=true;
226 0 : }
227 : //
228 : //---------------------------------------------------------------------------------------
229 : //
230 0 : void MultiThreadedVisibilityResampler::allocateBuffers(Bool /*newDataBuffers*/)
231 : {
232 0 : LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler","allocateBuffers"));
233 0 : Double totalMem=0;
234 : // if (nelements() > 1)
235 : {
236 0 : if (visResamplerCtor_p.null())
237 0 : log_p << "Internal Error: VisResampler Ctor not initialized" << LogIO::EXCEPTION;
238 :
239 0 : log_p << "Allocating buffers per thread. No. of threads = " << nelements() << endl;
240 : // mutexForResamplers_p = new async::Mutex;
241 :
242 : //
243 : // Resize the containers
244 : //----------------------------------------------------------------
245 0 : if (doublePrecision_p) doubleGriddedData_p.resize(nelements());
246 0 : else singleGriddedData_p.resize(nelements());
247 :
248 0 : resamplers_p.resize(nelements());
249 0 : sumwt_p.resize(nelements());
250 0 : gridderWorklets_p.resize(nelements());
251 0 : vbsVec_p.resize(nelements(),1);
252 : //----------------------------------------------------------------
253 :
254 0 : makeInfrastructureContainers();
255 0 : totalMem=allocateDataBuffers();
256 0 : startThreads();
257 : //----------------------------------------------------------------
258 : }
259 : // else
260 : // {
261 : // resamplers_p.resize(1);
262 : // // resamplers_p[0] = new VisibilityResampler();
263 : // // resamplers_p[0] = visResamplerCtor_p;
264 : // resamplers_p[0] = visResamplerCtor_p->clone();
265 : // vbsVec_p.resize(1,1);
266 : // cerr << "#@%@%@%#$@#$"<< endl;
267 : // gridderWorklets_p.resize(1);
268 : // gridderWorklets_p[0] = new ResamplerWorklet();
269 : // singleGriddedData_p.resize(1);
270 : // sumwt_p.resize(1);
271 : // if (doublePrecision_p) doubleGriddedData_p[0] = new Array<DComplex>;
272 : // else singleGriddedData_p[0] = new Array<Complex>;
273 : // sumwt_p[0] = new Matrix<Double>;
274 : // }
275 0 : if (totalMem > 0)
276 0 : log_p << "Total memory used in buffers for multi-threading: " << totalMem/(1024*1024) << " MB" << LogIO::POST;
277 0 : }
278 : //
279 : //---------------------------------------------------------------------------------------
280 : //
281 0 : void MultiThreadedVisibilityResampler::setParams(const Vector<Double>& uvwScale,
282 : const Vector<Double>& offset,
283 : const Vector<Double>& dphase)
284 0 : {for (Int i=0;i < nelements(); i++) resamplers_p[i]->setParams(uvwScale, offset, dphase);}
285 : //
286 : //---------------------------------------------------------------------------------------
287 : //
288 0 : void MultiThreadedVisibilityResampler::setMaps(const Vector<Int>& chanMap,
289 : const Vector<Int>& polMap)
290 0 : {for (Int i=0;i < nelements(); i++) resamplers_p[i]->setMaps(chanMap, polMap);};
291 : //
292 : //---------------------------------------------------------------------------------------
293 : //
294 0 : void MultiThreadedVisibilityResampler::setCFMaps(const Vector<Int>& cfMap,
295 : const Vector<Int>& conjCFMap)
296 0 : {for (Int i=0;i < nelements(); i++) resamplers_p[i]->setCFMaps(cfMap, conjCFMap);};
297 : //
298 : //---------------------------------------------------------------------------------------
299 : //
300 0 : void MultiThreadedVisibilityResampler::setConvFunc(const CFStore& cfs)
301 0 : {for (Int i=0;i < nelements(); i++) resamplers_p[i]->setConvFunc(cfs);};
302 : //
303 : //---------------------------------------------------------------------------------------
304 : //
305 0 : void MultiThreadedVisibilityResampler::setFreqMaps(const Matrix<Double>& spwChanFreqs, const Matrix<Double>& spwChanConjFreqs)
306 0 : {for (Int i=0;i < nelements(); i++) resamplers_p[i]->setFreqMaps(spwChanFreqs,spwChanConjFreqs);}
307 : //
308 : //---------------------------------------------------------------------------------------
309 : //
310 0 : void MultiThreadedVisibilityResampler::scatter(Matrix<VBStore>& vbStores,const VBStore& vbs)
311 : {
312 0 : Int nRows=vbs.nRow_p, nr,br=0;
313 0 : nr=(Int)(nRows/nelements())+1;
314 :
315 0 : for(Int i=0; i < nelements(); i++)
316 : {
317 0 : vbStores(i,currentVBS_p).reference(vbs);
318 0 : vbStores(i,currentVBS_p).beginRow_p = min(br,nRows);
319 0 : vbStores(i,currentVBS_p).endRow_p = min(br+nr,nRows);
320 0 : br = vbStores(i,currentVBS_p).endRow_p;
321 : }
322 0 : }
323 : //
324 : //---------------------------------------------------------------------------------------
325 : //
326 0 : void MultiThreadedVisibilityResampler::GatherGrids(Array<DComplex>& griddedData,
327 : Matrix<Double>& sumwt)
328 : {
329 0 : LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler(Double)","GatherGrids"));
330 : // if (nelements() > 1)
331 : {
332 : // log_p << "Deleting thread clerk" << LogIO::POST;
333 : // delete threadClerk_p; threadClerk_p=NULL;
334 0 : log_p << "Gathering grids..." << LogIO::POST;
335 : // cerr << "Gridded data shape = " << griddedData.shape() << " " << sumwt.shape() << endl;
336 : // for (Int i=0;i<nelements();i++)
337 : // cerr << "Gridded buffer shape = "
338 : // << (*doubleGriddedData_p[i]).shape() << " "
339 : // << (*sumwt_p[i]).shape() << endl;
340 0 : for(Int i=0;i<nelements(); i++)
341 : {
342 0 : griddedData += *(doubleGriddedData_p[i]);
343 0 : sumwt += *(sumwt_p[i]);
344 : }
345 : }
346 : log_p << "Gridder timing: "
347 0 : << "Setup = " << tSetupG.formatAverage().c_str() << " "
348 0 : << "SendData = " << tSendDataG.formatAverage().c_str() << " "
349 0 : << "WaitForWork = " << tWaitForWorkG.formatAverage().c_str()
350 0 : << "Outside = " << tOutsideG.formatAverage().c_str()
351 0 : << LogIO::POST;
352 : // log_p << "DGridder timing: "
353 : // << "Setup = " << tSetupDG.formatAverage().c_str() << " "
354 : // << "SendData = " << tSendDataDG.formatAverage().c_str() << " "
355 : // << "WaitForWork = " << tWaitForWorkDG.formatAverage().c_str()
356 : // << "Outside = " << tOutsideDG.formatAverage().c_str()
357 : // << LogIO::POST;
358 0 : }
359 : //
360 : //---------------------------------------------------------------------------------------
361 : //
362 0 : void MultiThreadedVisibilityResampler::GatherGrids(Array<Complex>& griddedData,
363 : Matrix<Double>& sumwt)
364 : {
365 0 : LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler(Single)","GatherGrids"));
366 : // if (nelements() > 1)
367 : {
368 0 : log_p << "Gathering grids..." << LogIO::POST;
369 0 : for(Int i=0;i<nelements(); i++)
370 : {
371 0 : griddedData += *(singleGriddedData_p[i]);
372 0 : sumwt += *(sumwt_p[i]);
373 : }
374 : }
375 : log_p << "Gridder timing: "
376 0 : << "Setup = " << tSetupG.formatAverage().c_str() << " "
377 0 : << "SendData = " << tSendDataG.formatAverage().c_str() << " "
378 0 : << "WaitForWork = " << tWaitForWorkG.formatAverage().c_str()
379 0 : << "Outside = " << tOutsideG.formatAverage().c_str()
380 0 : << LogIO::POST;
381 0 : }
382 : //
383 : //---------------------------------------------------------------------------------------
384 : //
385 0 : void MultiThreadedVisibilityResampler::initializePutBuffers(const Array<DComplex>& griddedData,
386 : const Matrix<Double>& sumwt)
387 : {
388 0 : LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler","initializeBuffers"));
389 : // if ((nelements() > 1))
390 : {
391 : // if (threadClerk_p) {delete threadClerk_p; threadClerk_p=NULL;}
392 0 : Double totalMem=0;
393 : // if (!threadClerk_p) threadClerk_p = new ThreadCoordinator<Int>(nelements());
394 0 : for(Int i=0; i<nelements(); i++)
395 : {
396 : // Resize and copy The following commented code attempts
397 : // to defeat the problem of false sharing, should it be
398 : // the bottlenec.
399 : // {
400 : // Vector<Array<DComplex>* > tmp(5);
401 : // for (Int j=0;j<5;j++)
402 : // {
403 : // (tmp[j]) = new Array<DComplex>;
404 : // (tmp[j])->assign(griddedData);
405 : // }
406 : // (*doubleGriddedData_p[i]).assign(griddedData);
407 : // for (Int j=0;j<5;j++) delete tmp[j];
408 : // }
409 :
410 : // The following code relies on system memalloc
411 0 : (*doubleGriddedData_p[i]).assign(griddedData);
412 0 : (*sumwt_p[i]).assign(sumwt);
413 0 : if (!threadStarted_p)
414 : {
415 0 : totalMem += (*doubleGriddedData_p[i]).size()*sizeof(DComplex);
416 0 : totalMem += (*sumwt_p[i]).size()*sizeof(Double);
417 : }
418 : }
419 0 : if (!threadStarted_p)
420 0 : log_p << "Total memory used in buffers:" << totalMem/(1024*1024) << " MB" << LogIO::POST;
421 : // for (Int i=0;i<nelements(); i++)
422 : // log_p << "Activating worklet "
423 : // << "# " << (*gridderWorklets_p[i]).getID() << ". "
424 : // << "PID = " << (*gridderWorklets_p[i]).getPID() << " "
425 : // << "TID = " << (*gridderWorklets_p[i]).getTID()
426 : // << LogIO::POST;
427 : // threadStarted_p = true;
428 : }
429 0 : }
430 : //
431 : //---------------------------------------------------------------------------------------
432 : //
433 0 : void MultiThreadedVisibilityResampler::initializePutBuffers(const Array<Complex>& griddedData,
434 : const Matrix<Double>& sumwt)
435 : {
436 0 : LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler", "initializePutBuffers(Single)"));
437 : // if (nelements() > 1)
438 : {
439 0 : for(Int i=0; i<nelements(); i++)
440 : {
441 0 : (*singleGriddedData_p[i]).assign(griddedData);
442 0 : (*sumwt_p[i]).assign(sumwt);
443 : }
444 : }
445 0 : }
446 : //
447 : //------------------------------------------------------------------------------
448 : //
449 : // Re-sample the griddedData on the VisBuffer (a.k.a gridding).
450 : //
451 : // Make the following four methods via templated implementation.
452 : template <class T>
453 0 : void MultiThreadedVisibilityResampler::DataToGridImpl_p(Array<T>& /*griddedData*/,
454 : VBStore& vbs,
455 : Matrix<Double>& /*sumwt*/,
456 : const Bool& dopsf,
457 : Bool /*useConjFreqCF*/)
458 : {
459 : // LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler", "DataToGridImpl_p"));
460 0 : if (whoLoadedVB_p == MThWorkID::DATATOGRID) {/*scatter(vbsVec_p,vbs); */whoLoadedVB_p = MThWorkID::DATATOGRID;}
461 0 : scatter(vbsVec_p,vbs);
462 :
463 : // if (nelements() == 1)
464 : // resamplers_p[0]->DataToGrid(griddedData, vbsVec_p(0,currentVBS_p), sumwt, dopsf);
465 : // // resamplers_p[0]->DataToGrid(*singleGriddedData_p[0], vbsVec_p(0,currentVBS_p),*sumwt_p[0] , dopsf);
466 : // else
467 : {
468 : // Int workRequestDataToGrid=1;
469 0 : Int workRequestDataToGrid=MThWorkID::DATATOGRID;
470 0 : casa::utilj::ThreadTimes t1=casa::utilj::ThreadTimes::getTime();
471 0 : for(Int i=0; i < nelements(); i++)
472 : {
473 0 : vbsVec_p(i,currentVBS_p).dopsf_p = dopsf;
474 0 : if (doublePrecision_p)
475 0 : (*gridderWorklets_p[i]).initToSky(&vbsVec_p(i,currentVBS_p),
476 0 : &(*doubleGriddedData_p[i]),
477 0 : &(*sumwt_p[i]));
478 : else
479 : {
480 : // cerr << &(*gridderWorklets_p[i]) << " "
481 : // << &(*singleGriddedData_p[i]) << " "
482 : // << &(*sumwt_p[i]) << " " << i << endl;
483 : // if(gridderWorklets_p[i].null()) cerr << "worklet null" << endl;
484 : // if (singleGriddedData_p[i].null()) cerr << "data null" << endl;
485 : // if (sumwt_p[i].null()) cerr << "wt null" << endl;
486 0 : (*gridderWorklets_p[i]).initToSky(&vbsVec_p(i,currentVBS_p),
487 0 : &(*singleGriddedData_p[i]),
488 0 : &(*sumwt_p[i]));
489 : }
490 : }
491 :
492 0 : casa::utilj::ThreadTimes t2=casa::utilj::ThreadTimes::getTime();
493 : // threadClerk_p->getToWork(&workRequestDataToGrid);
494 0 : threadClerk_p->giveWorkToWorkers(&workRequestDataToGrid);
495 0 : casa::utilj::ThreadTimes t3=casa::utilj::ThreadTimes::getTime();
496 0 : threadClerk_p->waitForWorkersToFinishTask();
497 0 : casa::utilj::ThreadTimes t4=casa::utilj::ThreadTimes::getTime();
498 :
499 0 : tSetupG += t2-t1;
500 0 : tSendDataG += t3-t2;
501 0 : tWaitForWorkG += t4-t3;
502 0 : tOutsideG += t1-t4G_p;
503 : }
504 0 : t4G_p = casa::utilj::ThreadTimes::getTime();
505 0 : }
506 : //
507 : //------------------------------------------------------------------------------
508 : //
509 : // Re-sample VisBuffer to a regular grid (griddedData) (a.k.a. de-gridding)
510 : // Still single threaded...
511 0 : void MultiThreadedVisibilityResampler::GridToData(VBStore& vbs, const Array<Complex>& griddedData)
512 : {
513 : // LogIO log_p(LogOrigin("MultiThreadedVisibilityResampler", "GridToData"));
514 0 : if (whoLoadedVB_p == MThWorkID::GRIDTODATA) {/*scatter(vbsVec_p,vbs);*/ whoLoadedVB_p = MThWorkID::GRIDTODATA;}
515 0 : scatter(vbsVec_p,vbs);
516 :
517 : // if (nelements() == 1)
518 : // resamplers_p[0]->GridToData(vbsVec_p(0,currentVBS_p),griddedData);
519 : // else
520 : {
521 : // Int workRequestDataToGrid=0;
522 0 : Int workRequestDataToGrid=MThWorkID::GRIDTODATA;
523 : // Timers t1=Timers::getTime();
524 0 : for(Int i=0; i < nelements(); i++)
525 : {
526 0 : (*gridderWorklets_p[i]).initToVis(&vbsVec_p(i,currentVBS_p),&griddedData);
527 : }
528 : // Timers t2=Timers::getTime();
529 : // threadClerk_p->getToWork(&workRequestDataToGrid);
530 0 : threadClerk_p->giveWorkToWorkers(&workRequestDataToGrid);
531 : // Timers t3=Timers::getTime();
532 0 : threadClerk_p->waitForWorkersToFinishTask();
533 : // Timers t4=Timers::getTime();
534 : // tSetupDG += t2-t1;
535 : // tSendDataDG += t3-t2;
536 : // tWaitForWorkDG += t4-t3;
537 : // tOutsideDG += t1-t4DG_p;
538 : }
539 : // t4DG_p = Timers::getTime();
540 0 : }
541 : //
542 : //------------------------------------------------------------------------------
543 : //
544 0 : void MultiThreadedVisibilityResampler::ComputeResiduals(VBStore& vbs)
545 : {
546 0 : if (whoLoadedVB_p == MThWorkID::RESIDUALCALC) {/*scatter(vbsVec_p,vbs);*/ whoLoadedVB_p = MThWorkID::RESIDUALCALC;}
547 0 : scatter(vbsVec_p,vbs);
548 :
549 : // if (nelements() == 1)
550 : // resamplers_p[0]->ComputeResiduals(vbsVec_p(0,currentVBS_p));
551 : // else
552 : {
553 : // Int workRequested=2;
554 0 : Int workRequested=MThWorkID::RESIDUALCALC;
555 0 : for (Int i=0; i<nelements(); i++)
556 0 : (*gridderWorklets_p[i]).initToVis(&vbsVec_p(i,currentVBS_p),NULL);
557 0 : threadClerk_p->giveWorkToWorkers(&workRequested);
558 0 : threadClerk_p->waitForWorkersToFinishTask();
559 : }
560 0 : }
561 :
562 : };
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