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TEveCalo3DGL.cxx
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1// @(#)root/eve:$Id$
2// Author: Matevz Tadel 2007
3
4/*************************************************************************
5 * Copyright (C) 1995-2007, Rene Brun and Fons Rademakers. *
6 * All rights reserved. *
7 * *
8 * For the licensing terms see $ROOTSYS/LICENSE. *
9 * For the list of contributors see $ROOTSYS/README/CREDITS. *
10 *************************************************************************/
11
12#include "TEveCalo3DGL.h"
13#include "TEveCalo.h"
14
15#include "TMath.h"
16#include "TAxis.h"
17
18#include "TGLRnrCtx.h"
19#include "TGLSelectRecord.h"
20#include "TGLPhysicalShape.h"
21#include "TGLIncludes.h"
22#include "TGLUtil.h"
23#include "TEveRGBAPalette.h"
24#include "TEveUtil.h"
25
26/** \class TEveCalo3DGL
27\ingroup TEve
28OpenGL renderer class for TEveCalo3D.
29*/
30
32
33////////////////////////////////////////////////////////////////////////////////
34/// Constructor.
35
37 TGLObject(), fM(0)
38{
40}
41
42////////////////////////////////////////////////////////////////////////////////
43/// Set model object.
44
46{
47 fM = SetModelDynCast<TEveCalo3D>(obj);
48 return kTRUE;
49}
50
51////////////////////////////////////////////////////////////////////////////////
52/// Set bounding box.
53
55{
56 // !! This ok if master sub-classed from TAttBBox
58}
59
60////////////////////////////////////////////////////////////////////////////////
61/// Override from TGLObject.
62/// To account for large point-sizes we modify the projection matrix
63/// during selection and thus we need a direct draw.
64
66{
67 if (rnrCtx.Highlight() || rnrCtx.Selection()) return kFALSE;
68 return TGLObject::ShouldDLCache(rnrCtx);
69}
70
71////////////////////////////////////////////////////////////////////////////////
72/// Calculate cross-product.
73
74inline void TEveCalo3DGL::CrossProduct(const Float_t a[3], const Float_t b[3],
75 const Float_t c[3], Float_t out[3]) const
76{
77 const Float_t v1[3] = { a[0] - c[0], a[1] - c[1], a[2] - c[2] };
78 const Float_t v2[3] = { b[0] - c[0], b[1] - c[1], b[2] - c[2] };
79
80 out[0] = v1[1] * v2[2] - v1[2] * v2[1];
81 out[1] = v1[2] * v2[0] - v1[0] * v2[2];
82 out[2] = v1[0] * v2[1] - v1[1] * v2[0];
83}
84
85////////////////////////////////////////////////////////////////////////////////
86/// Render end cap grid.
87
89{
90 using namespace TMath;
91
95
96 Float_t etaMin = fM->GetEtaMin();
97 Float_t etaMax = fM->GetEtaMax();
100 Float_t phiMin = fM->GetPhiMin();
101 Float_t phiMax = fM->GetPhiMax();
102
103 TAxis *ax = fM->GetData()->GetEtaBins();
104 Int_t nx = ax->GetNbins();
105 TAxis *ay = fM->GetData()->GetPhiBins();
106 Int_t ny = ay->GetNbins();
107
108
109 Float_t r, z, theta, phiU, phiL, eta;
110
111 // eta slices
112 for (Int_t i=0; i<=nx; ++i)
113 {
114 eta = ax->GetBinUpEdge(i);
115 if (eta >= transF && (eta > etaMin && eta < etaMax))
116 {
117 theta = TEveCaloData::EtaToTheta(eta);
118 r = Abs(zEF*Tan(theta));
119 z = Sign(zEF, ax->GetBinLowEdge(i));
120 for (Int_t j=1; j<=ny; ++j)
121 {
122 phiL = ay->GetBinLowEdge(j);
123 phiU = ay->GetBinUpEdge(j);
124 if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
125 {
126 glVertex3f(r*Cos(phiL), r*Sin(phiL), z);
127 glVertex3f(r*Cos(phiU), r*Sin(phiU), z);
128 }
129 }
130 } else if (eta <= transB && (eta > etaMin && eta < etaMax)) {
131 theta = TEveCaloData::EtaToTheta(eta);
132 r = Abs(zEB*Tan(theta));
133 z = Sign(zEB, ax->GetBinLowEdge(i));
134 for (Int_t j=1; j<=ny; ++j)
135 {
136 phiL = ay->GetBinLowEdge(j);
137 phiU = ay->GetBinUpEdge(j);
138 if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
139 {
140 glVertex3f(r*Cos(phiL), r*Sin(phiL), z);
141 glVertex3f(r*Cos(phiU), r*Sin(phiU), z);
142 }
143 }
144 }
145 }
146
147 Float_t r1, r2;
148 // phi slices front
149 if (etaMax > transF)
150 {
151 r1 = zEF*Tan(TEveCaloData::EtaToTheta(etaMax));
152 if (etaMin < transF)
153 r2 = rB;
154 else
155 r2 = zEF*Tan(TEveCaloData::EtaToTheta(etaMin));
156
157 for (Int_t j=1; j<=ny; ++j)
158 {
159 phiL = ay->GetBinLowEdge(j);
160 phiU = ay->GetBinUpEdge(j);
161 if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
162 {
163 glVertex3f( r1*Cos(phiU), r1*Sin(phiU), zEF);
164 glVertex3f( r2*Cos(phiU), r2*Sin(phiU), zEF);
165 glVertex3f( r1*Cos(phiL), r1*Sin(phiL), zEF);
166 glVertex3f( r2*Cos(phiL), r2*Sin(phiL), zEF);
167 }
168 }
169 }
170
171 // phi slices back
172 if (etaMin < transB)
173 {
174 r1 = zEB*Tan(TEveCaloData::EtaToTheta(etaMin));
175 if (etaMax > transB)
176 r2 = rB;
177 else
178 r2 = zEB*Tan(TEveCaloData::EtaToTheta(etaMax));
179
180 r1 = Abs(r1);
181 r2 = Abs(r2);
182 for (Int_t j=1; j<=ny; ++j)
183 {
184 phiL = ay->GetBinLowEdge(j);
185 phiU = ay->GetBinUpEdge(j);
186 if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
187 {
188 glVertex3f(r1*Cos(phiU), r1*Sin(phiU), zEB);
189 glVertex3f(r2*Cos(phiU), r2*Sin(phiU), zEB);
190 glVertex3f(r1*Cos(phiL), r1*Sin(phiL), zEB);
191 glVertex3f(r2*Cos(phiL), r2*Sin(phiL), zEB);
192 }
193 }
194 }
195}
196
197////////////////////////////////////////////////////////////////////////////////
198/// Render barrel grid.
199
201{
202 using namespace TMath;
203
204 Float_t etaMin = fM->GetEtaMin();
205 Float_t etaMax = fM->GetEtaMax();
208 Float_t phiMin = fM->GetPhiMin();
209 Float_t phiMax = fM->GetPhiMax();
210
211 Float_t rB = fM->GetBarrelRadius();
212 TAxis *ax = fM->GetData()->GetEtaBins();
213 Int_t nx = ax->GetNbins();
214 TAxis *ay = fM->GetData()->GetPhiBins();
215 Int_t ny = ay->GetNbins();
216
217 Float_t z, theta, phiL, phiU, eta, x, y;
218
219 // eta slices
220 for(Int_t i=0; i<=nx; i++)
221 {
222 eta = ax->GetBinUpEdge(i);
223 if (eta<=transF && eta>=transB && (etaMin < eta && eta < etaMax))
224 {
225 theta = TEveCaloData::EtaToTheta(eta);
226 z = rB/Tan(theta);
227 for (Int_t j=1; j<=ny; j++)
228 {
229 phiU = ay->GetBinUpEdge(j);
230 phiL = ay->GetBinLowEdge(j);
231 if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
232 {
233 glVertex3f(rB*Cos(phiL), rB*Sin(phiL), z);
234 glVertex3f(rB*Cos(phiU), rB*Sin(phiU), z);
235 }
236 }
237 }
238 }
239
240 // phi slices
241 Float_t zF, zB;
242
243 if (etaMin > transB)
244 zB = rB/Tan(TEveCaloData::EtaToTheta(etaMin));
245 else
246 zB = fM->GetBackwardEndCapPos();
247
248
249 if (etaMax < transF)
250 zF = rB/Tan(TEveCaloData::EtaToTheta(etaMax));
251 else
252 zF = fM->GetForwardEndCapPos();
253
254 for (Int_t j=1; j<=ny; j++)
255 {
256 phiU = ay->GetBinUpEdge(j);
257 phiL = ay->GetBinLowEdge(j);
258 if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
259 {
260 x = rB * Cos(phiL);
261 y = rB * Sin(phiL);
262 glVertex3f(x, y, zB);
263 glVertex3f(x, y, zF);
264 x = rB * Cos(phiU);
265 y = rB * Sin(phiU);
266 glVertex3f(x, y, zB);
267 glVertex3f(x, y, zF);
268 }
269 }
270}
271
272////////////////////////////////////////////////////////////////////////////////
273/// Draw frame reading eta, phi axis.
274
276{
277 if (rnrCtx.Highlight() || rnrCtx.Selection() || rnrCtx.IsDrawPassOutlineLine()) return;
278
279 Bool_t transparent_p = fM->fFrameTransparency > 0;
280
281 if (transparent_p)
282 {
283 glPushAttrib(GL_ENABLE_BIT | GL_DEPTH_BUFFER_BIT);
284
285 glDepthMask(GL_FALSE);
286 glEnable(GL_BLEND);
287 glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
288
290 }
291
292 TGLCapabilitySwitch lights_off(GL_LIGHTING, kFALSE);
293
295 glBegin(GL_LINES);
296
297 Float_t etaMin = fM->GetEtaMin();
298 Float_t etaMax = fM->GetEtaMax();
299
302 if (fM->GetRnrBarrelFrame() && (etaMin < transF && etaMax > transB))
303 {
305 }
306
307 if (fM->GetRnrEndCapFrame() && (etaMax > transF || etaMin < transB))
308 {
310 }
311
312 glEnd();
313
314 if (transparent_p)
315 {
316 glPopAttrib();
317 }
318}
319
320////////////////////////////////////////////////////////////////////////////////
321/// Render box with given points.
322/// ~~~ {.cpp}
323/// z
324/// |
325/// |
326/// |________y
327/// / 6-------7
328/// / /| /|
329/// x 5-------4 |
330/// | 2-----|-3
331/// |/ |/
332/// 1-------0
333/// ~~~
334
335void TEveCalo3DGL::RenderBox(const Float_t pnts[8]) const
336{
337 const Float_t *p = pnts;
338 Float_t cross[3];
339
340 // bottom: 0123
341 glBegin(GL_POLYGON);
342 CrossProduct(p+3, p+9, p, cross);
343 glNormal3fv(cross);
344 glVertex3fv(p);
345 glVertex3fv(p+3);
346 glVertex3fv(p+6);
347 glVertex3fv(p+9);
348 glEnd();
349 // top: 7654
350 glBegin(GL_POLYGON);
351 CrossProduct(p+21, p+15, p+12, cross);
352 glNormal3fv(cross);
353 glVertex3fv(p+21);
354 glVertex3fv(p+18);
355 glVertex3fv(p+15);
356 glVertex3fv(p+12);
357 glEnd();
358 // back: 0451
359 glBegin(GL_POLYGON);
360 CrossProduct(p+12, p+3, p, cross);
361 glNormal3fv(cross);
362 glVertex3fv(p);
363 glVertex3fv(p+12);
364 glVertex3fv(p+15);
365 glVertex3fv(p+3);
366 glEnd();
367 //front : 3267
368 glBegin(GL_POLYGON);
369 CrossProduct(p+6, p+21, p+9, cross);
370 glNormal3fv(cross);
371 glVertex3fv(p+9);
372 glVertex3fv(p+6);
373 glVertex3fv(p+18);
374 glVertex3fv(p+21);
375 glEnd();
376 // left: 0374
377 glBegin(GL_POLYGON);
378 CrossProduct(p+21, p, p+9, cross);
379 glNormal3fv(cross);
380 glVertex3fv(p);
381 glVertex3fv(p+9);
382 glVertex3fv(p+21);
383 glVertex3fv(p+12);
384 glEnd();
385 // right: 1562
386 glBegin(GL_POLYGON);
387 CrossProduct(p+15, p+6, p+3, cross);
388 glNormal3fv(cross);
389 glVertex3fv(p+3);
390 glVertex3fv(p+15);
391 glVertex3fv(p+18);
392 glVertex3fv(p+6);
393 glEnd();
394}
395
396////////////////////////////////////////////////////////////////////////////////
397/// Render barrel cell.
398
400{
401 using namespace TMath;
402
404 Float_t r2 = r1 + towerH*Sin(cellData.ThetaMin());
405 Float_t z1In, z1Out, z2In, z2Out;
406
407 z1In = r1/Tan(cellData.ThetaMax());
408 z1Out = r2/Tan(cellData.ThetaMax());
409 z2In = r1/Tan(cellData.ThetaMin());
410 z2Out = r2/Tan(cellData.ThetaMin());
411
412 Float_t cos1 = Cos(cellData.PhiMin());
413 Float_t sin1 = Sin(cellData.PhiMin());
414 Float_t cos2 = Cos(cellData.PhiMax());
415 Float_t sin2 = Sin(cellData.PhiMax());
416
417 Float_t box[24];
418 Float_t* pnts = box;
419 // 0
420 pnts[0] = r1*cos2;
421 pnts[1] = r1*sin2;
422 pnts[2] = z1In;
423 pnts += 3;
424 // 1
425 pnts[0] = r1*cos1;
426 pnts[1] = r1*sin1;
427 pnts[2] = z1In;
428 pnts += 3;
429 // 2
430 pnts[0] = r1*cos1;
431 pnts[1] = r1*sin1;
432 pnts[2] = z2In;
433 pnts += 3;
434 // 3
435 pnts[0] = r1*cos2;
436 pnts[1] = r1*sin2;
437 pnts[2] = z2In;
438 pnts += 3;
439 //---------------------------------------------------
440 // 4
441 pnts[0] = r2*cos2;
442 pnts[1] = r2*sin2;
443 pnts[2] = z1Out;
444 pnts += 3;
445 // 5
446 pnts[0] = r2*cos1;
447 pnts[1] = r2*sin1;
448 pnts[2] = z1Out;
449 pnts += 3;
450 // 6
451 pnts[0] = r2*cos1;
452 pnts[1] = r2*sin1;
453 pnts[2] = z2Out;
454 pnts += 3;
455 // 7
456 pnts[0] = r2*cos2;
457 pnts[1] = r2*sin2;
458 pnts[2] = z2Out;
459
460 RenderBox(box);
461
462 offset += towerH*Sin(cellData.ThetaMin());
463
464}// end RenderBarrelCell
465
466////////////////////////////////////////////////////////////////////////////////
467/// Render an endcap cell.
468
470{
471 using namespace TMath;
472 Float_t z1, r1In, r1Out, z2, r2In, r2Out;
473
474 z1 = (cellData.EtaMin()<0) ? fM->fEndCapPosB - offset : fM->fEndCapPosF + offset;
475 z2 = z1 + TMath::Sign(towerH, cellData.EtaMin());
476
477 r1In = z1*Tan(cellData.ThetaMin());
478 r2In = z2*Tan(cellData.ThetaMin());
479 r1Out = z1*Tan(cellData.ThetaMax());
480 r2Out = z2*Tan(cellData.ThetaMax());
481
482 Float_t cos2 = Cos(cellData.PhiMin());
483 Float_t sin2 = Sin(cellData.PhiMin());
484 Float_t cos1 = Cos(cellData.PhiMax());
485 Float_t sin1 = Sin(cellData.PhiMax());
486
487 Float_t box[24];
488 Float_t* pnts = box;
489 // 0
490 pnts[0] = r1In*cos1;
491 pnts[1] = r1In*sin1;
492 pnts[2] = z1;
493 pnts += 3;
494 // 1
495 pnts[0] = r1In*cos2;
496 pnts[1] = r1In*sin2;
497 pnts[2] = z1;
498 pnts += 3;
499 // 2
500 pnts[0] = r2In*cos2;
501 pnts[1] = r2In*sin2;
502 pnts[2] = z2;
503 pnts += 3;
504 // 3
505 pnts[0] = r2In*cos1;
506 pnts[1] = r2In*sin1;
507 pnts[2] = z2;
508 pnts += 3;
509 //---------------------------------------------------
510 // 4
511 pnts[0] = r1Out*cos1;
512 pnts[1] = r1Out*sin1;
513 pnts[2] = z1;
514 pnts += 3;
515 // 5
516 pnts[0] = r1Out*cos2;
517 pnts[1] = r1Out*sin2;
518 pnts[2] = z1;
519 pnts += 3;
520 // 6
521 pnts[0] = r2Out*cos2;
522 pnts[1] = r2Out*sin2;
523 pnts[2] = z2;
524 pnts += 3;
525 // 7
526 pnts[0] = r2Out*cos1;
527 pnts[1] = r2Out*sin1;
528 pnts[2] = z2;
529
530 RenderBox(box);
531
532 offset += towerH;
533
534} // end RenderEndCapCell
535
536////////////////////////////////////////////////////////////////////////////////
537/// GL rendering.
538
540{
542
543 // check if eta phi range has changed
544 if (fM->fCellIdCacheOK == kFALSE)
546
547 glPushAttrib(GL_ENABLE_BIT | GL_LINE_BIT | GL_POLYGON_BIT);
548 glEnable(GL_LIGHTING);
549 glEnable(GL_NORMALIZE);
550 glEnable(GL_BLEND);
551 glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
552
554 Float_t towerH = 0;
555 Int_t tower = 0;
556 Int_t prevTower = -1;
557 Float_t offset = 0;
558 Int_t cellID = 0;
559
560 if (rnrCtx.SecSelection()) glPushName(0);
561
562 fOffset.assign(fM->fCellList.size(), 0);
563 for (TEveCaloData::vCellId_i i = fM->fCellList.begin(); i != fM->fCellList.end(); ++i)
564 {
565 fM->fData->GetCellData((*i), cellData);
566 tower = i->fTower;
567 if (tower != prevTower)
568 {
569 offset = 0;
570 prevTower = tower;
571 }
572 fOffset[cellID] = offset;
573 fM->SetupColorHeight(cellData.Value(fM->fPlotEt), (*i).fSlice, towerH);
574
575 if (rnrCtx.SecSelection()) glLoadName(cellID);
576
577 if ((cellData.Eta() > 0 && cellData.Eta() < fM->GetTransitionEtaForward()) ||
578 (cellData.Eta() < 0 && cellData.Eta() > fM->GetTransitionEtaBackward()))
579 {
580 RenderBarrelCell(cellData, towerH, offset);
581 }
582 else
583 {
584 RenderEndCapCell(cellData, towerH, offset);
585 }
586 ++cellID;
587 }
588
589 if (rnrCtx.SecSelection()) glPopName();
590
591 RenderGrid(rnrCtx);
592
593 glPopAttrib();
594}
595
596////////////////////////////////////////////////////////////////////////////////
597/// Draw polygons in highlight mode.
598
599void TEveCalo3DGL::DrawHighlight(TGLRnrCtx & rnrCtx, const TGLPhysicalShape* /*pshp*/, Int_t /*lvl*/) const
600{
601 if (fM->fData->GetCellsSelected().empty() && fM->fData->GetCellsHighlighted().empty())
602 {
603 return;
604 }
605
606 glPushAttrib(GL_ENABLE_BIT | GL_LINE_BIT | GL_POLYGON_BIT);
607 glDisable(GL_LIGHTING);
608 glDisable(GL_CULL_FACE);
609 glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
610
613
614 if (!fM->fData->GetCellsHighlighted().empty())
615 {
616 glColor4ubv(rnrCtx.ColorSet().Selection(3).CArr());
618 }
619 if (!fM->fData->GetCellsSelected().empty())
620 {
621 Float_t dr[2];
622 glGetFloatv(GL_DEPTH_RANGE,dr);
623 glColor4ubv(rnrCtx.ColorSet().Selection(1).CArr());
624 glDepthRange(dr[0], 0.8*dr[1]);
626 glDepthRange(dr[0], dr[1]);
627 }
628
630 glPopAttrib();
631}
632
633////////////////////////////////////////////////////////////////////////////////
634
636{
638 Float_t towerH = 0;
639
640 for (TEveCaloData::vCellId_i i = cells.begin(); i != cells.end(); i++)
641 {
642 fM->fData->GetCellData(*i, cellData);
643 fM->SetupColorHeight(cellData.Value(fM->fPlotEt), (*i).fSlice, towerH);
644
645 // find tower with offsets
646 Float_t offset = 0;
647 for (Int_t j = 0; j < (Int_t) fM->fCellList.size(); ++j)
648 {
649 if (fM->fCellList[j].fTower == i->fTower && fM->fCellList[j].fSlice == i->fSlice )
650 {
651 offset = fOffset[j];
652 break;
653 }
654 }
655
656 if (fM->CellInEtaPhiRng(cellData))
657 {
658 if (cellData.Eta() < fM->GetTransitionEtaForward() && cellData.Eta() > fM->GetTransitionEtaBackward())
659 RenderBarrelCell(cellData, towerH, offset);
660 else
661 RenderEndCapCell(cellData, towerH, offset);
662 }
663 }
664}
665
666////////////////////////////////////////////////////////////////////////////////
667/// Processes tower selection.
668/// Virtual function from TGLogicalShape. Called from TGLViewer.
669
671{
673 if (rec.GetN() > 1)
674 {
675 sel.push_back(fM->fCellList[rec.GetItem(1)]);
676 }
678}
#define GL_LINES
Definition GL_glu.h:284
#define GL_FALSE
Definition GL_glu.h:261
#define GL_POLYGON
Definition GL_glu.h:292
#define b(i)
Definition RSha256.hxx:100
#define c(i)
Definition RSha256.hxx:101
#define a(i)
Definition RSha256.hxx:99
int Int_t
Definition RtypesCore.h:45
float Float_t
Definition RtypesCore.h:57
constexpr Bool_t kFALSE
Definition RtypesCore.h:101
constexpr Bool_t kTRUE
Definition RtypesCore.h:100
const char Option_t
Definition RtypesCore.h:66
#define ClassImp(name)
Definition Rtypes.h:377
winID h TVirtualViewer3D TVirtualGLPainter p
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t winding char text const char depth char const char Int_t count const char ColorStruct_t color const char Pixmap_t Pixmap_t PictureAttributes_t attr const char char ret_data h unsigned char height h Atom_t Int_t ULong_t ULong_t unsigned char prop_list Atom_t sel
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t winding char text const char depth char const char Int_t count const char ColorStruct_t color const char Pixmap_t Pixmap_t PictureAttributes_t attr const char char ret_data h unsigned char height h offset
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t r
Class to manage histogram axis.
Definition TAxis.h:31
virtual Double_t GetBinLowEdge(Int_t bin) const
Return low edge of bin.
Definition TAxis.cxx:518
Int_t GetNbins() const
Definition TAxis.h:125
virtual Double_t GetBinUpEdge(Int_t bin) const
Return up edge of bin.
Definition TAxis.cxx:528
OpenGL renderer class for TEveCalo3D.
void SetBBox() override
Set bounding box.
std::vector< Float_t > fOffset
void RenderBarrelCell(const TEveCaloData::CellGeom_t &cell, Float_t towerH, Float_t &offset) const
Render barrel cell.
TEveCalo3D * fM
void RenderBox(const Float_t pnts[8]) const
Render box with given points.
void DirectDraw(TGLRnrCtx &rnrCtx) const override
GL rendering.
TEveCalo3DGL()
Constructor.
void RenderGrid(TGLRnrCtx &rnrCtx) const
Draw frame reading eta, phi axis.
void RenderGridEndCap() const
Render end cap grid.
void ProcessSelection(TGLRnrCtx &rnrCtx, TGLSelectRecord &rec) override
Processes tower selection.
void DrawHighlight(TGLRnrCtx &rnrCtx, const TGLPhysicalShape *ps, Int_t lvl=-1) const override
Draw polygons in highlight mode.
void DrawSelectedCells(TEveCaloData::vCellId_t cells) const
void CrossProduct(const Float_t a[3], const Float_t b[3], const Float_t c[3], Float_t out[3]) const
Calculate cross-product.
Bool_t ShouldDLCache(const TGLRnrCtx &rnrCtx) const override
Override from TGLObject.
void RenderGridBarrel() const
Render barrel grid.
Bool_t SetModel(TObject *obj, const Option_t *opt=nullptr) override
Set model object.
void RenderEndCapCell(const TEveCaloData::CellGeom_t &cell, Float_t towerH, Float_t &offset) const
Render an endcap cell.
Visualization of a calorimeter event data in 3D.
Definition TEveCalo.h:158
TEveCaloData::vCellId_t fCellList
Definition TEveCalo.h:165
Bool_t GetRnrBarrelFrame() const
Definition TEveCalo.h:189
Float_t GetFrameWidth() const
Definition TEveCalo.h:182
Color_t fFrameColor
Definition TEveCalo.h:171
void BuildCellIdCache() override
Build list of drawn cell IDs. See TEveCalo3DGL::DirectDraw().
Definition TEveCalo.cxx:459
Char_t fFrameTransparency
Definition TEveCalo.h:172
Bool_t GetRnrEndCapFrame() const
Definition TEveCalo.h:188
std::vector< CellId_t > vCellId_t
static Float_t EtaToTheta(Float_t eta)
void ProcessSelection(vCellId_t &sel_cells, TGLSelectRecord &rec)
Process newly selected cells with given select-record.
virtual void GetCellData(const CellId_t &id, CellData_t &data) const =0
virtual TAxis * GetEtaBins() const
vCellId_t & GetCellsHighlighted()
virtual TAxis * GetPhiBins() const
vCellId_t & GetCellsSelected()
std::vector< CellId_t >::iterator vCellId_i
Float_t fEndCapPosF
Definition TEveCalo.h:52
Float_t GetEtaMin() const
Definition TEveCalo.h:137
Float_t fPlotEt
Definition TEveCalo.h:55
Float_t GetTransitionEtaBackward() const
Get transition eta between barrel and backward end-cap cells.
Definition TEveCalo.cxx:227
Float_t GetBarrelRadius() const
Definition TEveCalo.h:100
Float_t GetBackwardEndCapPos() const
Definition TEveCalo.h:104
Float_t GetForwardEndCapPos() const
Definition TEveCalo.h:103
TEveCaloData * GetData() const
Definition TEveCalo.h:87
TEveRGBAPalette * AssertPalette()
Make sure the TEveRGBAPalette pointer is not null.
Definition TEveCalo.cxx:378
Bool_t fCellIdCacheOK
Definition TEveCalo.h:41
Float_t GetEtaMax() const
Definition TEveCalo.h:138
TEveCaloData * fData
Definition TEveCalo.h:40
Float_t fEndCapPosB
Definition TEveCalo.h:53
Float_t GetTransitionEtaForward() const
Get transition eta between barrel and forward end-cap cells.
Definition TEveCalo.cxx:209
Float_t GetPhiMax() const
Definition TEveCalo.h:146
Bool_t CellInEtaPhiRng(TEveCaloData::CellData_t &) const
Returns true if given cell is in the ceta phi range.
Definition TEveCalo.cxx:307
Bool_t GetValueIsColor() const
Definition TEveCalo.h:129
Float_t GetPhiMin() const
Definition TEveCalo.h:145
void SetupColorHeight(Float_t value, Int_t slice, Float_t &height) const
Set color and height for a given value and slice using slice color or TEveRGBAPalette.
Definition TEveCalo.cxx:415
static Bool_t IsU1IntervalContainedByMinMax(Float_t minM, Float_t maxM, Float_t minQ, Float_t maxQ)
Return true if interval Q is contained within interval M for U1 variables.
Definition TEveUtil.cxx:342
TGLColor & Selection(Int_t i)
Definition TGLUtil.h:855
const UChar_t * CArr() const
Definition TGLUtil.h:800
TObject * fExternalObj
first replica
Base-class for direct OpenGL renderers.
Definition TGLObject.h:22
Bool_t fMultiColor
Definition TGLObject.h:28
void SetAxisAlignedBBox(Float_t xmin, Float_t xmax, Float_t ymin, Float_t ymax, Float_t zmin, Float_t zmax)
Set axis-aligned bounding-box.
Definition TGLObject.cxx:86
Bool_t ShouldDLCache(const TGLRnrCtx &rnrCtx) const override
Decide if display-list should be used for this pass rendering, as determined by rnrCtx.
Definition TGLObject.cxx:41
Concrete physical shape - a GL drawable.
The TGLRnrCtx class aggregates data for a given redering context as needed by various parts of the RO...
Definition TGLRnrCtx.h:41
Bool_t SecSelection() const
Definition TGLRnrCtx.h:224
TGLColorSet & ColorSet()
Return reference to current color-set (top of the stack).
Bool_t IsDrawPassOutlineLine() const
Definition TGLRnrCtx.h:207
Bool_t Highlight() const
Definition TGLRnrCtx.h:218
Bool_t Selection() const
Definition TGLRnrCtx.h:222
Standard selection record including information about containing scene and details ob out selected ob...
static UInt_t LockColor()
Prevent further color changes.
Definition TGLUtil.cxx:1669
static void ColorTransparency(Color_t color_index, Char_t transparency=0)
Set color from color_index and ROOT-style transparency (default 0).
Definition TGLUtil.cxx:1741
static UInt_t UnlockColor()
Allow color changes.
Definition TGLUtil.cxx:1677
static Float_t LineWidth()
Get the line-width, taking the global scaling into account.
Definition TGLUtil.cxx:1943
Mother of all ROOT objects.
Definition TObject.h:41
void box(Int_t pat, Double_t x1, Double_t y1, Double_t x2, Double_t y2)
Definition fillpatterns.C:1
Double_t y[n]
Definition legend1.C:17
Double_t x[n]
Definition legend1.C:17
TMath.
Definition TMathBase.h:35
T1 Sign(T1 a, T2 b)
Returns a value with the magnitude of a and the sign of b.
Definition TMathBase.h:175
Cell data inner structure.
Float_t Value(Bool_t) const
Return energy value associated with the cell, usually Et.
Cell geometry inner structure.
Float_t ThetaMin() const
Float_t ThetaMax() const
Float_t PhiMin() const
Float_t PhiMax() const
Float_t EtaMin() const