-
Notifications
You must be signed in to change notification settings - Fork 83
/
lulesh.h
645 lines (502 loc) · 19.7 KB
/
lulesh.h
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
#if !defined(USE_MPI)
# error "You should specify USE_MPI=0 or USE_MPI=1 on the compile line"
#endif
#if USE_MPI
#include <mpi.h>
/*
define one of these three symbols:
SEDOV_SYNC_POS_VEL_NONE
SEDOV_SYNC_POS_VEL_EARLY
SEDOV_SYNC_POS_VEL_LATE
*/
#define SEDOV_SYNC_POS_VEL_EARLY 1
#endif
#include <math.h>
#include <stdlib.h>
#include <stdint.h>
#include <vector>
//**************************************************
// Allow flexibility for arithmetic representations
//**************************************************
#define MAX(a, b) ( ((a) > (b)) ? (a) : (b))
// Precision specification
typedef float real4 ;
typedef double real8 ;
typedef long double real10 ; // 10 bytes on x86
typedef int32_t Int4_t ;
typedef int64_t Int8_t ;
typedef Int4_t Index_t ; // array subscript and loop index
typedef real8 Real_t ; // floating point representation
typedef Int4_t Int_t ; // integer representation
enum { VolumeError = -1, QStopError = -2 } ;
inline real4 SQRT(real4 arg) { return sqrtf(arg) ; }
inline real8 SQRT(real8 arg) { return sqrt(arg) ; }
inline real10 SQRT(real10 arg) { return sqrtl(arg) ; }
inline real4 CBRT(real4 arg) { return cbrtf(arg) ; }
inline real8 CBRT(real8 arg) { return cbrt(arg) ; }
inline real10 CBRT(real10 arg) { return cbrtl(arg) ; }
inline real4 FABS(real4 arg) { return fabsf(arg) ; }
inline real8 FABS(real8 arg) { return fabs(arg) ; }
inline real10 FABS(real10 arg) { return fabsl(arg) ; }
// Stuff needed for boundary conditions
// 2 BCs on each of 6 hexahedral faces (12 bits)
#define XI_M 0x00007
#define XI_M_SYMM 0x00001
#define XI_M_FREE 0x00002
#define XI_M_COMM 0x00004
#define XI_P 0x00038
#define XI_P_SYMM 0x00008
#define XI_P_FREE 0x00010
#define XI_P_COMM 0x00020
#define ETA_M 0x001c0
#define ETA_M_SYMM 0x00040
#define ETA_M_FREE 0x00080
#define ETA_M_COMM 0x00100
#define ETA_P 0x00e00
#define ETA_P_SYMM 0x00200
#define ETA_P_FREE 0x00400
#define ETA_P_COMM 0x00800
#define ZETA_M 0x07000
#define ZETA_M_SYMM 0x01000
#define ZETA_M_FREE 0x02000
#define ZETA_M_COMM 0x04000
#define ZETA_P 0x38000
#define ZETA_P_SYMM 0x08000
#define ZETA_P_FREE 0x10000
#define ZETA_P_COMM 0x20000
// MPI Message Tags
#define MSG_COMM_SBN 1024
#define MSG_SYNC_POS_VEL 2048
#define MSG_MONOQ 3072
#define MAX_FIELDS_PER_MPI_COMM 6
// Assume 128 byte coherence
// Assume Real_t is an "integral power of 2" bytes wide
#define CACHE_COHERENCE_PAD_REAL (128 / sizeof(Real_t))
#define CACHE_ALIGN_REAL(n) \
(((n) + (CACHE_COHERENCE_PAD_REAL - 1)) & ~(CACHE_COHERENCE_PAD_REAL-1))
/*********************************/
/* Data structure implementation */
/*********************************/
/* might want to add access methods so that memory can be */
/* better managed, as in luleshFT */
template <typename T>
T *Allocate(size_t size)
{
return static_cast<T *>(malloc(sizeof(T)*size)) ;
}
template <typename T>
void Release(T **ptr)
{
if (*ptr != NULL) {
free(*ptr) ;
*ptr = NULL ;
}
}
//////////////////////////////////////////////////////
// Primary data structure
//////////////////////////////////////////////////////
/*
* The implementation of the data abstraction used for lulesh
* resides entirely in the Domain class below. You can change
* grouping and interleaving of fields here to maximize data layout
* efficiency for your underlying architecture or compiler.
*
* For example, fields can be implemented as STL objects or
* raw array pointers. As another example, individual fields
* m_x, m_y, m_z could be budled into
*
* struct { Real_t x, y, z ; } *m_coord ;
*
* allowing accessor functions such as
*
* "Real_t &x(Index_t idx) { return m_coord[idx].x ; }"
* "Real_t &y(Index_t idx) { return m_coord[idx].y ; }"
* "Real_t &z(Index_t idx) { return m_coord[idx].z ; }"
*/
class Domain {
public:
// Constructor
Domain(Int_t numRanks, Index_t colLoc,
Index_t rowLoc, Index_t planeLoc,
Index_t nx, Int_t tp, Int_t nr, Int_t balance, Int_t cost);
// Destructor
~Domain();
//
// ALLOCATION
//
void AllocateNodePersistent(Int_t numNode) // Node-centered
{
m_x.resize(numNode); // coordinates
m_y.resize(numNode);
m_z.resize(numNode);
m_xd.resize(numNode); // velocities
m_yd.resize(numNode);
m_zd.resize(numNode);
m_xdd.resize(numNode); // accelerations
m_ydd.resize(numNode);
m_zdd.resize(numNode);
m_fx.resize(numNode); // forces
m_fy.resize(numNode);
m_fz.resize(numNode);
m_nodalMass.resize(numNode); // mass
}
void AllocateElemPersistent(Int_t numElem) // Elem-centered
{
m_nodelist.resize(8*numElem);
// elem connectivities through face
m_lxim.resize(numElem);
m_lxip.resize(numElem);
m_letam.resize(numElem);
m_letap.resize(numElem);
m_lzetam.resize(numElem);
m_lzetap.resize(numElem);
m_elemBC.resize(numElem);
m_e.resize(numElem);
m_p.resize(numElem);
m_q.resize(numElem);
m_ql.resize(numElem);
m_qq.resize(numElem);
m_v.resize(numElem);
m_volo.resize(numElem);
m_delv.resize(numElem);
m_vdov.resize(numElem);
m_arealg.resize(numElem);
m_ss.resize(numElem);
m_elemMass.resize(numElem);
m_vnew.resize(numElem) ;
}
void AllocateGradients(Int_t numElem, Int_t allElem)
{
// Position gradients
m_delx_xi = Allocate<Real_t>(numElem) ;
m_delx_eta = Allocate<Real_t>(numElem) ;
m_delx_zeta = Allocate<Real_t>(numElem) ;
// Velocity gradients
m_delv_xi = Allocate<Real_t>(allElem) ;
m_delv_eta = Allocate<Real_t>(allElem);
m_delv_zeta = Allocate<Real_t>(allElem) ;
}
void DeallocateGradients()
{
Release(&m_delx_zeta);
Release(&m_delx_eta) ;
Release(&m_delx_xi) ;
Release(&m_delv_zeta);
Release(&m_delv_eta) ;
Release(&m_delv_xi) ;
}
void AllocateStrains(Int_t numElem)
{
m_dxx = Allocate<Real_t>(numElem) ;
m_dyy = Allocate<Real_t>(numElem) ;
m_dzz = Allocate<Real_t>(numElem) ;
}
void DeallocateStrains()
{
Release(&m_dzz) ;
Release(&m_dyy) ;
Release(&m_dxx) ;
}
//
// ACCESSORS
//
// Node-centered
// Nodal coordinates
Real_t& x(Index_t idx) { return m_x[idx] ; }
Real_t& y(Index_t idx) { return m_y[idx] ; }
Real_t& z(Index_t idx) { return m_z[idx] ; }
// Nodal velocities
Real_t& xd(Index_t idx) { return m_xd[idx] ; }
Real_t& yd(Index_t idx) { return m_yd[idx] ; }
Real_t& zd(Index_t idx) { return m_zd[idx] ; }
// Nodal accelerations
Real_t& xdd(Index_t idx) { return m_xdd[idx] ; }
Real_t& ydd(Index_t idx) { return m_ydd[idx] ; }
Real_t& zdd(Index_t idx) { return m_zdd[idx] ; }
// Nodal forces
Real_t& fx(Index_t idx) { return m_fx[idx] ; }
Real_t& fy(Index_t idx) { return m_fy[idx] ; }
Real_t& fz(Index_t idx) { return m_fz[idx] ; }
// Nodal mass
Real_t& nodalMass(Index_t idx) { return m_nodalMass[idx] ; }
// Nodes on symmertry planes
Index_t symmX(Index_t idx) { return m_symmX[idx] ; }
Index_t symmY(Index_t idx) { return m_symmY[idx] ; }
Index_t symmZ(Index_t idx) { return m_symmZ[idx] ; }
bool symmXempty() { return m_symmX.empty(); }
bool symmYempty() { return m_symmY.empty(); }
bool symmZempty() { return m_symmZ.empty(); }
//
// Element-centered
//
Index_t& regElemSize(Index_t idx) { return m_regElemSize[idx] ; }
Index_t& regNumList(Index_t idx) { return m_regNumList[idx] ; }
Index_t* regNumList() { return &m_regNumList[0] ; }
Index_t* regElemlist(Int_t r) { return m_regElemlist[r] ; }
Index_t& regElemlist(Int_t r, Index_t idx) { return m_regElemlist[r][idx] ; }
Index_t* nodelist(Index_t idx) { return &m_nodelist[Index_t(8)*idx] ; }
// elem connectivities through face
Index_t& lxim(Index_t idx) { return m_lxim[idx] ; }
Index_t& lxip(Index_t idx) { return m_lxip[idx] ; }
Index_t& letam(Index_t idx) { return m_letam[idx] ; }
Index_t& letap(Index_t idx) { return m_letap[idx] ; }
Index_t& lzetam(Index_t idx) { return m_lzetam[idx] ; }
Index_t& lzetap(Index_t idx) { return m_lzetap[idx] ; }
// elem face symm/free-surface flag
Int_t& elemBC(Index_t idx) { return m_elemBC[idx] ; }
// Principal strains - temporary
Real_t& dxx(Index_t idx) { return m_dxx[idx] ; }
Real_t& dyy(Index_t idx) { return m_dyy[idx] ; }
Real_t& dzz(Index_t idx) { return m_dzz[idx] ; }
// New relative volume - temporary
Real_t& vnew(Index_t idx) { return m_vnew[idx] ; }
// Velocity gradient - temporary
Real_t& delv_xi(Index_t idx) { return m_delv_xi[idx] ; }
Real_t& delv_eta(Index_t idx) { return m_delv_eta[idx] ; }
Real_t& delv_zeta(Index_t idx) { return m_delv_zeta[idx] ; }
// Position gradient - temporary
Real_t& delx_xi(Index_t idx) { return m_delx_xi[idx] ; }
Real_t& delx_eta(Index_t idx) { return m_delx_eta[idx] ; }
Real_t& delx_zeta(Index_t idx) { return m_delx_zeta[idx] ; }
// Energy
Real_t& e(Index_t idx) { return m_e[idx] ; }
// Pressure
Real_t& p(Index_t idx) { return m_p[idx] ; }
// Artificial viscosity
Real_t& q(Index_t idx) { return m_q[idx] ; }
// Linear term for q
Real_t& ql(Index_t idx) { return m_ql[idx] ; }
// Quadratic term for q
Real_t& qq(Index_t idx) { return m_qq[idx] ; }
// Relative volume
Real_t& v(Index_t idx) { return m_v[idx] ; }
Real_t& delv(Index_t idx) { return m_delv[idx] ; }
// Reference volume
Real_t& volo(Index_t idx) { return m_volo[idx] ; }
// volume derivative over volume
Real_t& vdov(Index_t idx) { return m_vdov[idx] ; }
// Element characteristic length
Real_t& arealg(Index_t idx) { return m_arealg[idx] ; }
// Sound speed
Real_t& ss(Index_t idx) { return m_ss[idx] ; }
// Element mass
Real_t& elemMass(Index_t idx) { return m_elemMass[idx] ; }
Index_t nodeElemCount(Index_t idx)
{ return m_nodeElemStart[idx+1] - m_nodeElemStart[idx] ; }
Index_t *nodeElemCornerList(Index_t idx)
{ return &m_nodeElemCornerList[m_nodeElemStart[idx]] ; }
// Parameters
// Cutoffs
Real_t u_cut() const { return m_u_cut ; }
Real_t e_cut() const { return m_e_cut ; }
Real_t p_cut() const { return m_p_cut ; }
Real_t q_cut() const { return m_q_cut ; }
Real_t v_cut() const { return m_v_cut ; }
// Other constants (usually are settable via input file in real codes)
Real_t hgcoef() const { return m_hgcoef ; }
Real_t qstop() const { return m_qstop ; }
Real_t monoq_max_slope() const { return m_monoq_max_slope ; }
Real_t monoq_limiter_mult() const { return m_monoq_limiter_mult ; }
Real_t ss4o3() const { return m_ss4o3 ; }
Real_t qlc_monoq() const { return m_qlc_monoq ; }
Real_t qqc_monoq() const { return m_qqc_monoq ; }
Real_t qqc() const { return m_qqc ; }
Real_t eosvmax() const { return m_eosvmax ; }
Real_t eosvmin() const { return m_eosvmin ; }
Real_t pmin() const { return m_pmin ; }
Real_t emin() const { return m_emin ; }
Real_t dvovmax() const { return m_dvovmax ; }
Real_t refdens() const { return m_refdens ; }
// Timestep controls, etc...
Real_t& time() { return m_time ; }
Real_t& deltatime() { return m_deltatime ; }
Real_t& deltatimemultlb() { return m_deltatimemultlb ; }
Real_t& deltatimemultub() { return m_deltatimemultub ; }
Real_t& stoptime() { return m_stoptime ; }
Real_t& dtcourant() { return m_dtcourant ; }
Real_t& dthydro() { return m_dthydro ; }
Real_t& dtmax() { return m_dtmax ; }
Real_t& dtfixed() { return m_dtfixed ; }
Int_t& cycle() { return m_cycle ; }
Index_t& numRanks() { return m_numRanks ; }
Index_t& colLoc() { return m_colLoc ; }
Index_t& rowLoc() { return m_rowLoc ; }
Index_t& planeLoc() { return m_planeLoc ; }
Index_t& tp() { return m_tp ; }
Index_t& sizeX() { return m_sizeX ; }
Index_t& sizeY() { return m_sizeY ; }
Index_t& sizeZ() { return m_sizeZ ; }
Index_t& numReg() { return m_numReg ; }
Int_t& cost() { return m_cost ; }
Index_t& numElem() { return m_numElem ; }
Index_t& numNode() { return m_numNode ; }
Index_t& maxPlaneSize() { return m_maxPlaneSize ; }
Index_t& maxEdgeSize() { return m_maxEdgeSize ; }
//
// MPI-Related additional data
//
#if USE_MPI
// Communication Work space
Real_t *commDataSend ;
Real_t *commDataRecv ;
// Maximum number of block neighbors
MPI_Request recvRequest[26] ; // 6 faces + 12 edges + 8 corners
MPI_Request sendRequest[26] ; // 6 faces + 12 edges + 8 corners
#endif
private:
void BuildMesh(Int_t nx, Int_t edgeNodes, Int_t edgeElems);
void SetupThreadSupportStructures();
void CreateRegionIndexSets(Int_t nreg, Int_t balance);
void SetupCommBuffers(Int_t edgeNodes);
void SetupSymmetryPlanes(Int_t edgeNodes);
void SetupElementConnectivities(Int_t edgeElems);
void SetupBoundaryConditions(Int_t edgeElems);
//
// IMPLEMENTATION
//
/* Node-centered */
std::vector<Real_t> m_x ; /* coordinates */
std::vector<Real_t> m_y ;
std::vector<Real_t> m_z ;
std::vector<Real_t> m_xd ; /* velocities */
std::vector<Real_t> m_yd ;
std::vector<Real_t> m_zd ;
std::vector<Real_t> m_xdd ; /* accelerations */
std::vector<Real_t> m_ydd ;
std::vector<Real_t> m_zdd ;
std::vector<Real_t> m_fx ; /* forces */
std::vector<Real_t> m_fy ;
std::vector<Real_t> m_fz ;
std::vector<Real_t> m_nodalMass ; /* mass */
std::vector<Index_t> m_symmX ; /* symmetry plane nodesets */
std::vector<Index_t> m_symmY ;
std::vector<Index_t> m_symmZ ;
// Element-centered
// Region information
Int_t m_numReg ;
Int_t m_cost; //imbalance cost
Index_t *m_regElemSize ; // Size of region sets
Index_t *m_regNumList ; // Region number per domain element
Index_t **m_regElemlist ; // region indexset
std::vector<Index_t> m_nodelist ; /* elemToNode connectivity */
std::vector<Index_t> m_lxim ; /* element connectivity across each face */
std::vector<Index_t> m_lxip ;
std::vector<Index_t> m_letam ;
std::vector<Index_t> m_letap ;
std::vector<Index_t> m_lzetam ;
std::vector<Index_t> m_lzetap ;
std::vector<Int_t> m_elemBC ; /* symmetry/free-surface flags for each elem face */
Real_t *m_dxx ; /* principal strains -- temporary */
Real_t *m_dyy ;
Real_t *m_dzz ;
Real_t *m_delv_xi ; /* velocity gradient -- temporary */
Real_t *m_delv_eta ;
Real_t *m_delv_zeta ;
Real_t *m_delx_xi ; /* coordinate gradient -- temporary */
Real_t *m_delx_eta ;
Real_t *m_delx_zeta ;
std::vector<Real_t> m_e ; /* energy */
std::vector<Real_t> m_p ; /* pressure */
std::vector<Real_t> m_q ; /* q */
std::vector<Real_t> m_ql ; /* linear term for q */
std::vector<Real_t> m_qq ; /* quadratic term for q */
std::vector<Real_t> m_v ; /* relative volume */
std::vector<Real_t> m_volo ; /* reference volume */
std::vector<Real_t> m_vnew ; /* new relative volume -- temporary */
std::vector<Real_t> m_delv ; /* m_vnew - m_v */
std::vector<Real_t> m_vdov ; /* volume derivative over volume */
std::vector<Real_t> m_arealg ; /* characteristic length of an element */
std::vector<Real_t> m_ss ; /* "sound speed" */
std::vector<Real_t> m_elemMass ; /* mass */
// Cutoffs (treat as constants)
const Real_t m_e_cut ; // energy tolerance
const Real_t m_p_cut ; // pressure tolerance
const Real_t m_q_cut ; // q tolerance
const Real_t m_v_cut ; // relative volume tolerance
const Real_t m_u_cut ; // velocity tolerance
// Other constants (usually setable, but hardcoded in this proxy app)
const Real_t m_hgcoef ; // hourglass control
const Real_t m_ss4o3 ;
const Real_t m_qstop ; // excessive q indicator
const Real_t m_monoq_max_slope ;
const Real_t m_monoq_limiter_mult ;
const Real_t m_qlc_monoq ; // linear term coef for q
const Real_t m_qqc_monoq ; // quadratic term coef for q
const Real_t m_qqc ;
const Real_t m_eosvmax ;
const Real_t m_eosvmin ;
const Real_t m_pmin ; // pressure floor
const Real_t m_emin ; // energy floor
const Real_t m_dvovmax ; // maximum allowable volume change
const Real_t m_refdens ; // reference density
// Variables to keep track of timestep, simulation time, and cycle
Real_t m_dtcourant ; // courant constraint
Real_t m_dthydro ; // volume change constraint
Int_t m_cycle ; // iteration count for simulation
Real_t m_dtfixed ; // fixed time increment
Real_t m_time ; // current time
Real_t m_deltatime ; // variable time increment
Real_t m_deltatimemultlb ;
Real_t m_deltatimemultub ;
Real_t m_dtmax ; // maximum allowable time increment
Real_t m_stoptime ; // end time for simulation
Int_t m_numRanks ;
Index_t m_colLoc ;
Index_t m_rowLoc ;
Index_t m_planeLoc ;
Index_t m_tp ;
Index_t m_sizeX ;
Index_t m_sizeY ;
Index_t m_sizeZ ;
Index_t m_numElem ;
Index_t m_numNode ;
Index_t m_maxPlaneSize ;
Index_t m_maxEdgeSize ;
// OMP hack
Index_t *m_nodeElemStart ;
Index_t *m_nodeElemCornerList ;
// Used in setup
Index_t m_rowMin, m_rowMax;
Index_t m_colMin, m_colMax;
Index_t m_planeMin, m_planeMax ;
} ;
typedef Real_t &(Domain::* Domain_member )(Index_t) ;
struct cmdLineOpts {
Int_t its; // -i
Int_t nx; // -s
Int_t numReg; // -r
Int_t numFiles; // -f
Int_t showProg; // -p
Int_t quiet; // -q
Int_t viz; // -v
Int_t cost; // -c
Int_t balance; // -b
};
// Function Prototypes
// lulesh-par
Real_t CalcElemVolume( const Real_t x[8],
const Real_t y[8],
const Real_t z[8]);
// lulesh-util
void ParseCommandLineOptions(int argc, char *argv[],
Int_t myRank, struct cmdLineOpts *opts);
void VerifyAndWriteFinalOutput(Real_t elapsed_time,
Domain& locDom,
Int_t nx,
Int_t numRanks);
// lulesh-viz
void DumpToVisit(Domain& domain, int numFiles, int myRank, int numRanks);
// lulesh-comm
void CommRecv(Domain& domain, Int_t msgType, Index_t xferFields,
Index_t dx, Index_t dy, Index_t dz,
bool doRecv, bool planeOnly);
void CommSend(Domain& domain, Int_t msgType,
Index_t xferFields, Domain_member *fieldData,
Index_t dx, Index_t dy, Index_t dz,
bool doSend, bool planeOnly);
void CommSBN(Domain& domain, Int_t xferFields, Domain_member *fieldData);
void CommSyncPosVel(Domain& domain);
void CommMonoQ(Domain& domain);
// lulesh-init
void InitMeshDecomp(Int_t numRanks, Int_t myRank,
Int_t *col, Int_t *row, Int_t *plane, Int_t *side);