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source: Sophya/trunk/Cosmo/SimLSS/genefluct3d.cc@ 3347

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Last change on this file since 3347 was 3331, checked in by cmv, 18 years ago
mise en place evolution seulement sur distance au plan Z , cmv 02/10/2007
File size: 47.7 KB

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1	#include "machdefs.h"
2	#include <iostream>
3	#include <stdlib.h>
4	#include <stdio.h>
5	#include <string.h>
6	#include <math.h>
7	#include <unistd.h>
8
9	#include "tarray.h"
10	#include "pexceptions.h"
11	#include "perandom.h"
12	#include "srandgen.h"
13
14	#include "fabtcolread.h"
15	#include "fabtwriter.h"
16	#include "fioarr.h"
17
18	#include "arrctcast.h"
19
20	#include "constcosmo.h"
21	#include "geneutils.h"
22	#include "schechter.h"
23
24	#include "genefluct3d.h"
25
26	#define FFTW_THREAD
27
28	#define MODULE2(_x_) ((double)((_x_).real()(_x_).real() + (_x_).imag()(_x_).imag()))
29
30	namespace SOPHYA {
31
32	//-------------------------------------------------------
33	GeneFluct3D::GeneFluct3D(TArray< complex<r_8 > >& T)
34	: Nx_(0) , Ny_(0) , Nz_(0)
35	, lp_(0)
36	, array_allocated_(false) , T_(T)
37	, cosmo_(NULL) , growth_(NULL)
38	, redsh_ref_(-999.), kredsh_ref_(0.), dred_ref_(-999.)
39	, loscom_ref_(-999.), dtrc_ref_(-999.), dlum_ref_(-999.), dang_ref_(-999.)
40	, nu_ref_(-999.), dnu_ref_ (-999.)
41	, loscom_min_(-999.), loscom_max_(-999.)
42	, loscom2zred_min_(0.) , loscom2zred_max_(0.)
43	{
44	xobs_[0] = xobs_[1] = xobs_[2] = 0.;
45	zred_.resize(0);
46	loscom_.resize(0);
47	loscom2zred_.resize(0);
48	SetNThread();
49	}
50
51	GeneFluct3D::~GeneFluct3D(void)
52	{
53	fftw_destroy_plan(pf_);
54	fftw_destroy_plan(pb_);
55	#ifdef FFTW_THREAD
56	if(nthread_>0) fftw_cleanup_threads();
57	#endif
58	}
59
60	//-------------------------------------------------------
61	void GeneFluct3D::SetSize(long nx,long ny,long nz,double dx,double dy,double dz)
62	{
63	setsize(nx,ny,nz,dx,dy,dz);
64	setalloc();
65	setpointers(false);
66	init_fftw();
67	}
68
69	void GeneFluct3D::SetObservator(double redshref,double kredshref)
70	// L'observateur est au redshift z=0
71	// est situe sur la "perpendiculaire" a la face x,y
72	// issue du centre de cette face
73	// Il faut positionner le cube sur l'axe des z cad des redshifts:
74	// redshref = redshift de reference
75	// Si redshref<0 alors redshref=0
76	// kredshref = indice (en double) correspondant a ce redshift
77	// Si kredshref<0 alors kredshref=nz/2 (milieu du cube)
78	// Exemple: redshref=1.5 kredshref=250.75
79	// -> Le pixel i=nx/2 j=ny/2 k=250.75 est au redshift 1.5
80	{
81	if(redshref<0.) redshref = 0.;
82	if(kredshref<0.) {
83	if(Nz_<=0) {
84	char *bla = "GeneFluct3D::SetObservator_Error: for kredsh_ref<0 SetSize should be called first";
85	cout<<bla<<endl; throw ParmError(bla);
86	}
87	kredshref = Nz_/2.;
88	}
89	redsh_ref_ = redshref;
90	kredsh_ref_ = kredshref;
91	if(lp_>0)
92	cout<<"--- GeneFluct3D::SetObservator zref="<<redsh_ref_<<" kref="<<kredsh_ref_<<endl;
93	}
94
95	void GeneFluct3D::SetCosmology(CosmoCalc& cosmo)
96	{
97	cosmo_ = &cosmo;
98	if(lp_>1) cosmo_->Print();
99	}
100
101	void GeneFluct3D::SetGrowthFactor(GrowthFactor& growth)
102	{
103	growth_ = &growth;
104	}
105
106	void GeneFluct3D::setsize(long nx,long ny,long nz,double dx,double dy,double dz)
107	{
108	if(lp_>1) cout<<"--- GeneFluct3D::setsize: N="<<nx<<","<<ny<<","<<nz
109	<<" D="<<dx<<","<<dy<<","<<dz<<endl;
110	if(nx<=0 \|\| dx<=0.) {
111	char *bla = "GeneFluct3D::setsize_Error: bad value(s) for nn/dx";
112	cout<<bla<<endl; throw ParmError(bla);
113	}
114
115	// Les tailles des tableaux
116	Nx_ = nx;
117	Ny_ = ny; if(Ny_ <= 0) Ny_ = Nx_;
118	Nz_ = nz; if(Nz_ <= 0) Nz_ = Nx_;
119	N_.resize(0); N_.push_back(Nx_); N_.push_back(Ny_); N_.push_back(Nz_);
120	NRtot_ = Nx_Ny_Nz_; // nombre de pixels dans le survey
121	NCz_ = Nz_/2 +1;
122	NTz_ = 2*NCz_;
123
124	// le pas dans l'espace (Mpc)
125	Dx_ = dx;
126	Dy_ = dy; if(Dy_ <= 0.) Dy_ = Dx_;
127	Dz_ = dz; if(Dz_ <= 0.) Dz_ = Dx_;
128	D_.resize(0); D_.push_back(Dx_); D_.push_back(Dy_); D_.push_back(Dz_);
129	dVol_ = Dx_Dy_Dz_;
130	Vol_ = (Nx_Dx_)(Ny_Dy_)(Nz_*Dz_);
131
132	// Le pas dans l'espace de Fourier (Mpc^-1)
133	Dkx_ = 2.M_PI/(Nx_Dx_);
134	Dky_ = 2.M_PI/(Ny_Dy_);
135	Dkz_ = 2.M_PI/(Nz_Dz_);
136	Dk_.resize(0); Dk_.push_back(Dkx_); Dk_.push_back(Dky_); Dk_.push_back(Dkz_);
137	Dk3_ = Dkx_Dky_Dkz_;
138
139	// La frequence de Nyquist en k (Mpc^-1)
140	Knyqx_ = M_PI/Dx_;
141	Knyqy_ = M_PI/Dy_;
142	Knyqz_ = M_PI/Dz_;
143	Knyq_.resize(0); Knyq_.push_back(Knyqx_); Knyq_.push_back(Knyqy_); Knyq_.push_back(Knyqz_);
144	}
145
146	void GeneFluct3D::setalloc(void)
147	{
148	if(lp_>1) cout<<"--- GeneFluct3D::setalloc ---"<<endl;
149	// Dimensionnement du tableau complex<r_8>
150	// ATTENTION: TArray adresse en memoire a l'envers du C
151	// Tarray(n1,n2,n3) == Carray[n3][n2][n1]
152	sa_size_t SzK_[3] = {NCz_,Ny_,Nx_}; // a l'envers
153	try {
154	T_.ReSize(3,SzK_);
155	array_allocated_ = true;
156	if(lp_>1) cout<<" allocating: "<<T_.Size()*sizeof(complex<r_8>)/1.e6<<" Mo"<<endl;
157	} catch (...) {
158	cout<<"GeneFluct3D::setalloc_Error: Problem allocating T_"<<endl;
159	}
160	T_.SetMemoryMapping(BaseArray::CMemoryMapping);
161	}
162
163	void GeneFluct3D::setpointers(bool from_real)
164	{
165	if(lp_>1) cout<<"--- GeneFluct3D::setpointers ---"<<endl;
166	if(from_real) T_ = ArrCastR2C(R_);
167	else R_ = ArrCastC2R(T_);
168	// On remplit les pointeurs
169	fdata_ = (fftw_complex *) (&T_(0,0,0));
170	data_ = (double *) (&R_(0,0,0));
171	}
172
173	void GeneFluct3D::check_array_alloc(void)
174	// Pour tester si le tableau T_ est alloue
175	{
176	if(array_allocated_) return;
177	char bla[90];
178	sprintf(bla,"GeneFluct3D::check_array_alloc_Error: array is not allocated");
179	cout<<bla<<endl; throw ParmError(bla);
180	}
181
182	void GeneFluct3D::init_fftw(void)
183	{
184	// --- Initialisation de fftw3 (attention data est sur-ecrit a l'init)
185	if(lp_>1) cout<<"--- GeneFluct3D::init_fftw ---"<<endl;
186	#ifdef FFTW_THREAD
187	if(nthread_>0) {
188	cout<<"...Computing with "<<nthread_<<" threads"<<endl;
189	fftw_init_threads();
190	fftw_plan_with_nthreads(nthread_);
191	}
192	#endif
193	if(lp_>1) cout<<"...forward plan"<<endl;
194	pf_ = fftw_plan_dft_r2c_3d(Nx_,Ny_,Nz_,data_,fdata_,FFTW_ESTIMATE);
195	if(lp_>1) cout<<"...backward plan"<<endl;
196	pb_ = fftw_plan_dft_c2r_3d(Nx_,Ny_,Nz_,fdata_,data_,FFTW_ESTIMATE);
197	}
198
199	//-------------------------------------------------------
200	long GeneFluct3D::LosComRedshift(double zinc,long npoints)
201	// Given a position of the cube relative to the observer
202	// and a cosmology
203	// (SetObservator() and SetCosmology() should have been called !)
204	// This routine filled:
205	// the vector "zred_" of scanned redshift (by zinc increments)
206	// the vector "loscom_" of corresponding los comoving distance
207	// -- Input:
208	// zinc : redshift increment for computation
209	// npoints : number of points required for inverting loscom -> zred
210	//
211	{
212	if(lp_>0) cout<<"--- LosComRedshift: zinc="<<zinc<<" , npoints="<<npoints<<endl;
213
214	if(cosmo_ == NULL \|\| redsh_ref_<0.) {
215	char *bla = "GeneFluct3D::LosComRedshift_Error: set Observator and Cosmology first";
216	cout<<bla<<endl; throw ParmError(bla);
217	}
218
219	// La distance angulaire/luminosite/Dnu au pixel de reference
220	dred_ref_ = Dz_/(cosmo_->Dhubble()/cosmo_->E(redsh_ref_));
221	loscom_ref_ = cosmo_->Dloscom(redsh_ref_);
222	dtrc_ref_ = cosmo_->Dtrcom(redsh_ref_);
223	dlum_ref_ = cosmo_->Dlum(redsh_ref_);
224	dang_ref_ = cosmo_->Dang(redsh_ref_);
225	nu_ref_ = Fr_HyperFin_Par/(1.+redsh_ref_); // GHz
226	dnu_ref_ = Fr_HyperFin_Par *dred_ref_/pow(1.+redsh_ref_,2.); // GHz
227	if(lp_>0) {
228	cout<<"...reference pixel redshref="<<redsh_ref_
229	<<", dredref="<<dred_ref_
230	<<", nuref="<<nu_ref_ <<" GHz"
231	<<", dnuref="<<dnu_ref_ <<" GHz"<<endl
232	<<" dlosc="<<loscom_ref_<<" Mpc com"
233	<<", dtrc="<<dtrc_ref_<<" Mpc com"
234	<<", dlum="<<dlum_ref_<<" Mpc"
235	<<", dang="<<dang_ref_<<" Mpc"<<endl;
236	}
237
238	// On calcule les coordonnees de l'observateur dans le repere du cube
239	// cad dans le repere ou l'origine est au centre du pixel i=j=l=0.
240	// L'observateur est sur un axe centre sur le milieu de la face Oxy
241	xobs_[0] = Nx_/2.*Dx_;
242	xobs_[1] = Ny_/2.*Dy_;
243	xobs_[2] = kredsh_ref_*Dz_ - loscom_ref_;
244
245	// L'observateur est-il dans le cube?
246	bool obs_in_cube = false;
247	if(xobs_[2]>=0. && xobs_[2]<=Nz_*Dz_) obs_in_cube = true;
248
249	// Find MINIMUM los com distance to the observer:
250	// c'est le centre de la face a k=0
251	// (ou zero si l'observateur est dans le cube)
252	loscom_min_ = 0.;
253	if(!obs_in_cube) loscom_min_ = -xobs_[2];
254
255	// TO BE FIXED TO BE FIXED TO BE FIXED TO BE FIXED TO BE FIXED TO BE FIXED
256	if(loscom_min_<=1.e-50)
257	for(int i=0;i<50;i++)
258	cout<<"ATTENTION TOUTES LES PARTIES DU CODE NE MARCHENT PAS POUR UN OBSERVATEUR DANS LE CUBE"<<endl;
259	// TO BE FIXED TO BE FIXED TO BE FIXED TO BE FIXED TO BE FIXED TO BE FIXED
260
261
262	// Find MAXIMUM los com distance to the observer:
263	// ou que soit positionne l'observateur, la distance
264	// maximal est sur un des coins du cube
265	loscom_max_ = 0.;
266	for(long i=0;i<=1;i++) {
267	double dx2 = DXcom(i(Nx_-1)); dx2 = dx2;
268	for(long j=0;j<=1;j++) {
269	double dy2 = DYcom(j(Ny_-1)); dy2 = dy2;
270	for(long k=0;k<=1;k++) {
271	double dz2 = DZcom(k(Nz_-1)); dz2 = dz2;
272	dz2 = sqrt(dx2+dy2+dz2);
273	if(dz2>loscom_max_) loscom_max_ = dz2;
274	}
275	}
276	}
277	if(lp_>0) {
278	cout<<"...zref="<<redsh_ref_<<" kzref="<<kredsh_ref_<<" losref="<<loscom_ref_<<" Mpc\n"
279	<<" xobs="<<xobs_[0]<<" , "<<xobs_[1]<<" , "<<xobs_[2]<<" Mpc "
280	<<" in_cube="<<obs_in_cube
281	<<" loscom_min="<<loscom_min_<<" loscom_max="<<loscom_max_<<" Mpc (com)"<<endl;
282	}
283
284	// Fill the corresponding vectors for loscom and zred
285	// Be shure to have one dlc <loscom_min and one >loscom_max
286	if(zinc<=0.) zinc = 0.01;
287	for(double z=0.; ; z+=zinc) {
288	double dlc = cosmo_->Dloscom(z);
289	if(dlc<loscom_min_) {zred_.resize(0); loscom_.resize(0);}
290	zred_.push_back(z);
291	loscom_.push_back(dlc);
292	z += zinc;
293	if(dlc>loscom_max_) break; // on sort apres avoir stoque un dlc>dlcmax
294	}
295
296	if(lp_>0) {
297	long n = zred_.size();
298	cout<<"...zred/loscom tables[zinc="<<zinc<<"]: n="<<n;
299	if(n>0) cout<<" z="<<zred_[0]<<" -> d="<<loscom_[0];
300	if(n>1) cout<<" , z="<<zred_[n-1]<<" -> d="<<loscom_[n-1];
301	cout<<endl;
302	}
303
304	// Compute the parameters and tables needed for inversion loscom->zred
305	if(npoints<3) npoints = zred_.size();
306	InverseFunc invfun(zred_,loscom_);
307	invfun.ComputeParab(npoints,loscom2zred_);
308	loscom2zred_min_ = invfun.YMin();
309	loscom2zred_max_ = invfun.YMax();
310
311	if(lp_>0) {
312	long n = loscom2zred_.size();
313	cout<<"...loscom -> zred[npoints="<<npoints<<"]: n="<<n
314	<<" los_min="<<loscom2zred_min_
315	<<" los_max="<<loscom2zred_max_
316	<<" -> zred=[";
317	if(n>0) cout<<loscom2zred_[0];
318	cout<<",";
319	if(n>1) cout<<loscom2zred_[n-1];
320	cout<<"]"<<endl;
321	if(lp_>1 && n>0)
322	for(int i=0;i<n;i++)
323	if(i<2 \|\| abs(i-n/2)<2 \|\| i>=n-2)
324	cout<<" i="<<i
325	<<" d="<<loscom2zred_min_+i*(loscom2zred_max_-loscom2zred_min_)/(n-1.)
326	<<" Mpc z="<<loscom2zred_[i]<<endl;
327	}
328
329	return zred_.size();
330	}
331
332	//-------------------------------------------------------
333	void GeneFluct3D::WriteFits(string cfname,int bitpix)
334	{
335	cout<<"--- GeneFluct3D::WriteFits: Writing Cube to "<<cfname<<endl;
336	try {
337	FitsImg3DWriter fwrt(cfname.c_str(),bitpix,5);
338	fwrt.WriteKey("NX",Nx_," axe transverse 1");
339	fwrt.WriteKey("NY",Ny_," axe transverse 2");
340	fwrt.WriteKey("NZ",Nz_," axe longitudinal (redshift)");
341	fwrt.WriteKey("DX",Dx_," Mpc");
342	fwrt.WriteKey("DY",Dy_," Mpc");
343	fwrt.WriteKey("DZ",Dz_," Mpc");
344	fwrt.WriteKey("DKX",Dkx_," Mpc^-1");
345	fwrt.WriteKey("DKY",Dky_," Mpc^-1");
346	fwrt.WriteKey("DKZ",Dkz_," Mpc^-1");
347	fwrt.WriteKey("ZREF",redsh_ref_," reference redshift");
348	fwrt.WriteKey("KZREF",kredsh_ref_," reference redshift on z axe");
349	fwrt.Write(R_);
350	} catch (PThrowable & exc) {
351	cout<<"Exception : "<<(string)typeid(exc).name()
352	<<" - Msg= "<<exc.Msg()<<endl;
353	return;
354	} catch (...) {
355	cout<<" some other exception was caught !"<<endl;
356	return;
357	}
358	}
359
360	void GeneFluct3D::ReadFits(string cfname)
361	{
362	cout<<"--- GeneFluct3D::ReadFits: Reading Cube from "<<cfname<<endl;
363	try {
364	FitsImg3DRead fimg(cfname.c_str(),0,5);
365	fimg.Read(R_);
366	long nx = fimg.ReadKeyL("NX");
367	long ny = fimg.ReadKeyL("NY");
368	long nz = fimg.ReadKeyL("NZ");
369	double dx = fimg.ReadKey("DX");
370	double dy = fimg.ReadKey("DY");
371	double dz = fimg.ReadKey("DZ");
372	double zref = fimg.ReadKey("ZREF");
373	double kzref = fimg.ReadKey("KZREF");
374	setsize(nx,ny,nz,dx,dy,dz);
375	setpointers(true);
376	init_fftw();
377	SetObservator(zref,kzref);
378	array_allocated_ = true;
379	} catch (PThrowable & exc) {
380	cout<<"Exception : "<<(string)typeid(exc).name()
381	<<" - Msg= "<<exc.Msg()<<endl;
382	return;
383	} catch (...) {
384	cout<<" some other exception was caught !"<<endl;
385	return;
386	}
387	}
388
389	void GeneFluct3D::WritePPF(string cfname,bool write_real)
390	// On ecrit soit le TArray<r_8> ou le TArray<complex <r_8> >
391	{
392	cout<<"--- GeneFluct3D::WritePPF: Writing Cube (real="<<write_real<<") to "<<cfname<<endl;
393	try {
394	R_.Info()["NX"] = (int_8)Nx_;
395	R_.Info()["NY"] = (int_8)Ny_;
396	R_.Info()["NZ"] = (int_8)Nz_;
397	R_.Info()["DX"] = (r_8)Dx_;
398	R_.Info()["DY"] = (r_8)Dy_;
399	R_.Info()["DZ"] = (r_8)Dz_;
400	R_.Info()["ZREF"] = (r_8)redsh_ref_;
401	R_.Info()["KZREF"] = (r_8)kredsh_ref_;
402	POutPersist pos(cfname.c_str());
403	if(write_real) pos << PPFNameTag("rgen") << R_;
404	else pos << PPFNameTag("pkgen") << T_;
405	} catch (PThrowable & exc) {
406	cout<<"Exception : "<<(string)typeid(exc).name()
407	<<" - Msg= "<<exc.Msg()<<endl;
408	return;
409	} catch (...) {
410	cout<<" some other exception was caught !"<<endl;
411	return;
412	}
413	}
414
415	void GeneFluct3D::ReadPPF(string cfname)
416	{
417	cout<<"--- GeneFluct3D::ReadPPF: Reading Cube from "<<cfname<<endl;
418	try {
419	bool from_real = true;
420	PInPersist pis(cfname.c_str());
421	string name_tag_k = "pkgen";
422	bool found_tag_k = pis.GotoNameTag("pkgen");
423	if(found_tag_k) {
424	cout<<" ...reading spectrum into TArray<complex <r_8> >"<<endl;
425	pis >> PPFNameTag("pkgen") >> T_;
426	from_real = false;
427	} else {
428	cout<<" ...reading space into TArray<r_8>"<<endl;
429	pis >> PPFNameTag("rgen") >> R_;
430	}
431	setpointers(from_real); // a mettre ici pour relire les DVInfo
432	int_8 nx = R_.Info()["NX"];
433	int_8 ny = R_.Info()["NY"];
434	int_8 nz = R_.Info()["NZ"];
435	r_8 dx = R_.Info()["DX"];
436	r_8 dy = R_.Info()["DY"];
437	r_8 dz = R_.Info()["DZ"];
438	r_8 zref = R_.Info()["ZREF"];
439	r_8 kzref = R_.Info()["KZREF"];
440	setsize(nx,ny,nz,dx,dy,dz);
441	init_fftw();
442	SetObservator(zref,kzref);
443	array_allocated_ = true;
444	} catch (PThrowable & exc) {
445	cout<<"Exception : "<<(string)typeid(exc).name()
446	<<" - Msg= "<<exc.Msg()<<endl;
447	return;
448	} catch (...) {
449	cout<<" some other exception was caught !"<<endl;
450	return;
451	}
452	}
453
454	void GeneFluct3D::WriteSlicePPF(string cfname)
455	// On ecrit 3 tranches du cube selon chaque axe
456	{
457	cout<<"--- GeneFluct3D::WriteSlicePPF: Writing Cube Slices "<<cfname<<endl;
458	try {
459
460	POutPersist pos(cfname.c_str());
461	TMatrix<r_4> S;
462	char str[16];
463	long i,j,l;
464
465	// Tranches en Z
466	for(int s=0;s<3;s++) {
467	S.ReSize(Nx_,Ny_);
468	if(s==0) l=0; else if(s==1) l=(Nz_+1)/2; else l=Nz_-1;
469	sprintf(str,"z%ld",l);
470	for(i=0;i<Nx_;i++) for(j=0;j<Ny_;j++) S(i,j)=data_[IndexR(i,j,l)];
471	pos<<PPFNameTag(str)<<S; S.RenewObjId();
472	}
473
474	// Tranches en Y
475	for(int s=0;s<3;s++) {
476	S.ReSize(Nz_,Nx_);
477	if(s==0) j=0; else if(s==1) j=(Ny_+1)/2; else j=Ny_-1;
478	sprintf(str,"y%ld",j);
479	for(i=0;i<Nx_;i++) for(l=0;l<Nz_;l++) S(l,i)=data_[IndexR(i,j,l)];
480	pos<<PPFNameTag(str)<<S; S.RenewObjId();
481	}
482
483	// Tranches en X
484	for(int s=0;s<3;s++) {
485	S.ReSize(Nz_,Ny_);
486	if(s==0) i=0; else if(s==1) i=(Nx_+1)/2; else i=Nx_-1;
487	sprintf(str,"x%ld",i);
488	for(j=0;j<Ny_;j++) for(l=0;l<Nz_;l++) S(l,j)=data_[IndexR(i,j,l)];
489	pos<<PPFNameTag(str)<<S; S.RenewObjId();
490	}
491
492	} catch (PThrowable & exc) {
493	cout<<"Exception : "<<(string)typeid(exc).name()
494	<<" - Msg= "<<exc.Msg()<<endl;
495	return;
496	} catch (...) {
497	cout<<" some other exception was caught !"<<endl;
498	return;
499	}
500	}
501
502	//-------------------------------------------------------
503	void GeneFluct3D::Print(void)
504	{
505	cout<<"GeneFluct3D(T_alloc="<<array_allocated_<<"):"<<endl;
506	cout<<"Space Size : nx="<<Nx_<<" ny="<<Ny_<<" nz="<<Nz_<<" ("<<NTz_<<") size="
507	<<NRtot_<<endl;
508	cout<<" Resol: dx="<<Dx_<<" dy="<<Dy_<<" dz="<<Dz_<<" Mpc"
509	<<", dVol="<<dVol_<<", Vol="<<Vol_<<" Mpc^3"<<endl;
510	cout<<"Fourier Size : nx="<<Nx_<<" ny="<<Ny_<<" nz="<<NCz_<<endl;
511	cout<<" Resol: dkx="<<Dkx_<<" dky="<<Dky_<<" dkz="<<Dkz_<<" Mpc^-1"
512	<<", Dk3="<<Dk3_<<" Mpc^-3"<<endl;
513	cout<<" (2Pi/k: "<<2.M_PI/Dkx_<<" "<<2.M_PI/Dky_<<" "<<2.*M_PI/Dkz_<<" Mpc)"<<endl;
514	cout<<" Nyquist: kx="<<Knyqx_<<" ky="<<Knyqy_<<" kz="<<Knyqz_<<" Mpc^-1"
515	<<", Kmax="<<GetKmax()<<" Mpc^-1"<<endl;
516	cout<<" (2Pi/k: "<<2.M_PI/Knyqx_<<" "<<2.M_PI/Knyqy_<<" "<<2.*M_PI/Knyqz_<<" Mpc)"<<endl;
517	cout<<"Redshift "<<redsh_ref_<<" for z axe at k="<<kredsh_ref_<<endl;
518	}
519
520	//-------------------------------------------------------
521	void GeneFluct3D::ComputeFourier0(GenericFunc& pk_at_z)
522	// cf ComputeFourier() mais avec autre methode de realisation du spectre
523	// (attention on fait une fft pour realiser le spectre)
524	{
525
526	// --- realisation d'un tableau de tirage gaussiens
527	if(lp_>0) cout<<"--- ComputeFourier0: before gaussian filling ---"<<endl;
528	// On tient compte du pb de normalisation de FFTW3
529	double sntot = sqrt((double)NRtot_);
530	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
531	int_8 ip = IndexR(i,j,l);
532	data_[ip] = NorRand()/sntot;
533	}
534
535	// --- realisation d'un tableau de tirage gaussiens
536	if(lp_>0) cout<<"...before fft real ---"<<endl;
537	fftw_execute(pf_);
538
539	// --- On remplit avec une realisation
540	if(lp_>0) cout<<"...before Fourier realization filling"<<endl;
541	T_(0,0,0) = complex<r_8>(0.); // on coupe le continue et on l'initialise
542	long lmod = Nx_/10; if(lmod<1) lmod=1;
543	for(long i=0;i<Nx_;i++) {
544	long ii = (i>Nx_/2) ? Nx_-i : i;
545	double kx = iiDkx_; kx = kx;
546	if(lp_>0 && i%lmod==0) cout<<"i="<<i<<" ii="<<ii<<endl;
547	for(long j=0;j<Ny_;j++) {
548	long jj = (j>Ny_/2) ? Ny_-j : j;
549	double ky = jjDky_; ky = ky;
550	for(long l=0;l<NCz_;l++) {
551	double kz = lDkz_; kz = kz;
552	if(i==0 && j==0 && l==0) continue; // Suppression du continu
553	double k = sqrt(kx+ky+kz);
554	// cf normalisation: Peacock, Cosmology, formule 16.38 p504
555	double pk = pk_at_z(k)/Vol_;
556	// ici pas de "/2" a cause de la remarque ci-dessus
557	T_(l,j,i) *= sqrt(pk);
558	}
559	}
560	}
561
562	if(lp_>0) cout<<"...computing power"<<endl;
563	double p = compute_power_carte();
564	if(lp_>0) cout<<"Puissance dans la realisation: "<<p<<endl;
565
566	}
567
568	//-------------------------------------------------------
569	void GeneFluct3D::ComputeFourier(GenericFunc& pk_at_z)
570	// Calcule une realisation du spectre "pk_at_z"
571	// Attention: dans TArray le premier indice varie le + vite
572	// Explication normalisation: see Coles & Lucchin, Cosmology, p264-265
573	// FFTW3: on note N=NxNyNz
574	// f --(FFT)--> F = TF(f) --(FFT^-1)--> fb = TF^-1(F) = TF^-1(TF(f))
575	// sum(f(x_i)^2) = S
576	// sum(F(nu_i)^2) = S*N
577	// sum(fb(x_i)^2) = S*N^2
578	{
579	// --- RaZ du tableau
580	T_ = complex<r_8>(0.);
581
582	// --- On remplit avec une realisation
583	if(lp_>0) cout<<"--- ComputeFourier ---"<<endl;
584	long lmod = Nx_/10; if(lmod<1) lmod=1;
585	for(long i=0;i<Nx_;i++) {
586	long ii = (i>Nx_/2) ? Nx_-i : i;
587	double kx = iiDkx_; kx = kx;
588	if(lp_>0 && i%lmod==0) cout<<"i="<<i<<" ii="<<ii<<endl;
589	for(long j=0;j<Ny_;j++) {
590	long jj = (j>Ny_/2) ? Ny_-j : j;
591	double ky = jjDky_; ky = ky;
592	for(long l=0;l<NCz_;l++) {
593	double kz = lDkz_; kz = kz;
594	if(i==0 && j==0 && l==0) continue; // Suppression du continu
595	double k = sqrt(kx+ky+kz);
596	// cf normalisation: Peacock, Cosmology, formule 16.38 p504
597	double pk = pk_at_z(k)/Vol_;
598	// Explication de la division par 2: voir perandom.cc
599	// ou egalement Coles & Lucchin, Cosmology formula 13.7.2 p279
600	T_(l,j,i) = ComplexGaussRan(sqrt(pk/2.));
601	}
602	}
603	}
604
605	manage_coefficients(); // gros effet pour les spectres que l'on utilise !
606
607	if(lp_>0) cout<<"...computing power"<<endl;
608	double p = compute_power_carte();
609	if(lp_>0) cout<<"Puissance dans la realisation: "<<p<<endl;
610
611	}
612
613	long GeneFluct3D::manage_coefficients(void)
614	// Take into account the real and complexe conjugate coefficients
615	// because we want a realization of a real data in real space
616	{
617	if(lp_>1) cout<<"...managing coefficients"<<endl;
618	check_array_alloc();
619
620	// 1./ Le Continu et Nyquist sont reels
621	long nreal = 0;
622	for(long kk=0;kk<2;kk++) {
623	long k=0; // continu
624	if(kk==1) {if(Nz_%2!=0) continue; else k = Nz_/2;} // Nyquist
625	for(long jj=0;jj<2;jj++) {
626	long j=0;
627	if(jj==1) {if( Ny_%2!=0) continue; else j = Ny_/2;}
628	for(long ii=0;ii<2;ii++) {
629	long i=0;
630	if(ii==1) {if( Nx_%2!=0) continue; else i = Nx_/2;}
631	int_8 ip = IndexC(i,j,k);
632	//cout<<"i="<<i<<" j="<<j<<" k="<<k<<" = ("<<fdata_[ip][0]<<","<<fdata_[ip][1]<<")"<<endl;
633	fdata_[ip][1] = 0.; fdata_[ip][0] *= M_SQRT2;
634	nreal++;
635	}
636	}
637	}
638	if(lp_>1) cout<<"Number of forced real number ="<<nreal<<endl;
639
640	// 2./ Les elements complexe conjugues (tous dans le plan k=0,Nyquist)
641
642	// a./ les lignes et colonnes du continu et de nyquist
643	long nconj1 = 0;
644	for(long kk=0;kk<2;kk++) {
645	long k=0; // continu
646	if(kk==1) {if(Nz_%2!=0) continue; else k = Nz_/2;} // Nyquist
647	for(long jj=0;jj<2;jj++) { // selon j
648	long j=0;
649	if(jj==1) {if( Ny_%2!=0) continue; else j = Ny_/2;}
650	for(long i=1;i<(Nx_+1)/2;i++) {
651	int_8 ip = IndexC(i,j,k);
652	int_8 ip1 = IndexC(Nx_-i,j,k);
653	fdata_[ip1][0] = fdata_[ip][0]; fdata_[ip1][1] = -fdata_[ip][1];
654	nconj1++;
655	}
656	}
657	for(long ii=0;ii<2;ii++) {
658	long i=0;
659	if(ii==1) {if( Nx_%2!=0) continue; else i = Nx_/2;}
660	for(long j=1;j<(Ny_+1)/2;j++) {
661	int_8 ip = IndexC(i,j,k);
662	int_8 ip1 = IndexC(i,Ny_-j,k);
663	fdata_[ip1][0] = fdata_[ip][0]; fdata_[ip1][1] = -fdata_[ip][1];
664	nconj1++;
665	}
666	}
667	}
668	if(lp_>1) cout<<"Number of forced conjugate on cont+nyq ="<<nconj1<<endl;
669
670	// b./ les lignes et colonnes hors continu et de nyquist
671	long nconj2 = 0;
672	for(long kk=0;kk<2;kk++) {
673	long k=0; // continu
674	if(kk==1) {if(Nz_%2!=0) continue; else k = Nz_/2;} // Nyquist
675	for(long j=1;j<(Ny_+1)/2;j++) {
676	if(Ny_%2==0 && j==Ny_/2) continue; // on ne retraite pas nyquist en j
677	for(long i=1;i<Nx_;i++) {
678	if(Nx_%2==0 && i==Nx_/2) continue; // on ne retraite pas nyquist en i
679	int_8 ip = IndexC(i,j,k);
680	int_8 ip1 = IndexC(Nx_-i,Ny_-j,k);
681	fdata_[ip1][0] = fdata_[ip][0]; fdata_[ip1][1] = -fdata_[ip][1];
682	nconj2++;
683	}
684	}
685	}
686	if(lp_>1) cout<<"Number of forced conjugate hors cont+nyq ="<<nconj2<<endl;
687
688	if(lp_>1) cout<<"Check: ddl= "<<NRtot_<<" =?= "<<2(Nx_Ny_*NCz_-nconj1-nconj2)-8<<endl;
689
690	return nreal+nconj1+nconj2;
691	}
692
693	double GeneFluct3D::compute_power_carte(void)
694	// Calcul la puissance de la realisation du spectre Pk
695	{
696	check_array_alloc();
697
698	double s2 = 0.;
699	for(long l=0;l<NCz_;l++)
700	for(long j=0;j<Ny_;j++)
701	for(long i=0;i<Nx_;i++) s2 += MODULE2(T_(l,j,i));
702
703	double s20 = 0.;
704	for(long j=0;j<Ny_;j++)
705	for(long i=0;i<Nx_;i++) s20 += MODULE2(T_(0,j,i));
706
707	double s2n = 0.;
708	if(Nz_%2==0)
709	for(long j=0;j<Ny_;j++)
710	for(long i=0;i<Nx_;i++) s2n += MODULE2(T_(NCz_-1,j,i));
711
712	return 2.*s2 -s20 -s2n;
713	}
714
715	//-------------------------------------------------------------------
716	void GeneFluct3D::FilterByPixel(void)
717	// Filtrage par la fonction fenetre du pixel (parallelepipede)
718	// TF = 1/(dxdydz)*Int[{-dx/2,dx/2},{-dy/2,dy/2},{-dz/2,dz/2}]
719	// e^(ik_xx) e^(ik_yy) e^(ik_z*z) dxdydz
720	// = 2/(k_xdx) sin(k_xdx/2) (idem y) * (idem z)
721	// Gestion divergence en 0: sin(y)/y = 1 - y^2/6*(1-y^2/20)
722	// avec y = k_x*dx/2
723	{
724	if(lp_>0) cout<<"--- FilterByPixel ---"<<endl;
725	check_array_alloc();
726
727	for(long i=0;i<Nx_;i++) {
728	long ii = (i>Nx_/2) ? Nx_-i : i;
729	double kx = iiDkx_ Dx_/2;
730	double pk_x = pixelfilter(kx);
731	for(long j=0;j<Ny_;j++) {
732	long jj = (j>Ny_/2) ? Ny_-j : j;
733	double ky = jjDky_ Dy_/2;
734	double pk_y = pixelfilter(ky);
735	for(long l=0;l<NCz_;l++) {
736	double kz = lDkz_ Dz_/2;
737	double pk_z = pixelfilter(kz);
738	T_(l,j,i) = pk_xpk_y*pk_z;
739	}
740	}
741	}
742
743	}
744
745	//-------------------------------------------------------------------
746	void GeneFluct3D::ApplyGrowthFactor(int type_evol)
747	// Apply Growth to real space
748	// Using the correspondance between redshift and los comoving distance
749	// describe in vector "zred_" "loscom_"
750	// type_evol = 1 : evolution de la puissance du bruit avec la distance a l'observateur
751	// 2 : evolution de la puissance du bruit avec la distance du plan Z
752	// (tous les pixels d'un plan Z sont mis au meme redshift z que celui du milieu)
753	{
754	if(lp_>0) cout<<"--- ApplyGrowthFactor: evol="<<type_evol<<endl;
755	check_array_alloc();
756
757	if(growth_ == NULL) {
758	char *bla = "GeneFluct3D::ApplyGrowthFactor_Error: set GrowthFactor first";
759	cout<<bla<<endl; throw ParmError(bla);
760	}
761	if(type_evol<1 \|\| type_evol>2) {
762	char *bla = "GeneFluct3D::ApplyGrowthFactor_Error: bad type_evol value";
763	cout<<bla<<endl; throw ParmError(bla);
764	}
765
766	InterpFunc interpinv(loscom2zred_min_,loscom2zred_max_,loscom2zred_);
767	unsigned short ok;
768
769	//CHECK: Histo hgr(0.9zred_[0],1.1zred_[n-1],1000);
770	for(long i=0;i<Nx_;i++) {
771	double dx2 = DXcom(i); dx2 *= dx2;
772	for(long j=0;j<Ny_;j++) {
773	double dy2 = DYcom(j); dy2 *= dy2;
774	for(long l=0;l<Nz_;l++) {
775	double dz = DZcom(l);
776	if(type_evol==1) dz = sqrt(dx2+dy2+dz*dz);
777	else dz = fabs(dz); // tous les plans Z au meme redshift
778	double z = interpinv(dz);
779	//CHECK: hgr.Add(z);
780	double dzgr = (*growth_)(z); // interpolation par morceau
781	//double dzgr = growth_->Linear(z,ok); // interpolation lineaire
782	//double dzgr = growth_->Parab(z,ok); // interpolation parabolique
783	int_8 ip = IndexR(i,j,l);
784	data_[ip] *= dzgr;
785	}
786	}
787	}
788
789	//CHECK: {POutPersist pos("applygrowth.ppf"); string tag="hgr"; pos.PutObject(hgr,tag);}
790
791	}
792
793	//-------------------------------------------------------------------
794	void GeneFluct3D::ComputeReal(void)
795	// Calcule une realisation dans l'espace reel
796	{
797	if(lp_>0) cout<<"--- ComputeReal ---"<<endl;
798	check_array_alloc();
799
800	// On fait la FFT
801	fftw_execute(pb_);
802	}
803
804	//-------------------------------------------------------------------
805	void GeneFluct3D::ReComputeFourier(void)
806	{
807	if(lp_>0) cout<<"--- ReComputeFourier ---"<<endl;
808	check_array_alloc();
809
810	// On fait la FFT
811	fftw_execute(pf_);
812	// On corrige du pb de la normalisation de FFTW3
813	double v = (double)NRtot_;
814	for(long i=0;i<Nx_;i++)
815	for(long j=0;j<Ny_;j++)
816	for(long l=0;l<NCz_;l++) T_(l,j,i) /= complex<r_8>(v);
817
818	}
819
820	//-------------------------------------------------------------------
821	int GeneFluct3D::ComputeSpectrum(HistoErr& herr)
822	// Compute spectrum from "T" and fill HistoErr "herr"
823	// T : dans le format standard de GeneFuct3D: T(nz,ny,nx)
824	// cad T(kz,ky,kx) avec 0<kz<kz_nyq -ky_nyq<ky<ky_nyq -kx_nyq<kx<kx_nyq
825	{
826	if(lp_>0) cout<<"--- ComputeSpectrum ---"<<endl;
827	check_array_alloc();
828
829	if(herr.NBins()<0) return -1;
830	herr.Zero();
831
832	// Attention a l'ordre
833	for(long i=0;i<Nx_;i++) {
834	long ii = (i>Nx_/2) ? Nx_-i : i;
835	double kx = iiDkx_; kx = kx;
836	for(long j=0;j<Ny_;j++) {
837	long jj = (j>Ny_/2) ? Ny_-j : j;
838	double ky = jjDky_; ky = ky;
839	for(long l=0;l<NCz_;l++) {
840	double kz = l*Dkz_;
841	double k = sqrt(kx+ky+kz*kz);
842	double pk = MODULE2(T_(l,j,i));
843	herr.Add(k,pk);
844	}
845	}
846	}
847	herr.ToVariance();
848
849	// renormalize to directly compare to original spectrum
850	double norm = Vol_;
851	herr *= norm;
852
853	return 0;
854	}
855
856	int GeneFluct3D::ComputeSpectrum2D(Histo2DErr& herr)
857	{
858	if(lp_>0) cout<<"--- ComputeSpectrum2D ---"<<endl;
859	check_array_alloc();
860
861	if(herr.NBinX()<0 \|\| herr.NBinY()<0) return -1;
862	herr.Zero();
863
864	// Attention a l'ordre
865	for(long i=0;i<Nx_;i++) {
866	long ii = (i>Nx_/2) ? Nx_-i : i;
867	double kx = iiDkx_; kx = kx;
868	for(long j=0;j<Ny_;j++) {
869	long jj = (j>Ny_/2) ? Ny_-j : j;
870	double ky = jjDky_; ky = ky;
871	double kt = sqrt(kx+ky);
872	for(long l=0;l<NCz_;l++) {
873	double kz = l*Dkz_;
874	double pk = MODULE2(T_(l,j,i));
875	herr.Add(kt,kz,pk);
876	}
877	}
878	}
879	herr.ToVariance();
880
881	// renormalize to directly compare to original spectrum
882	double norm = Vol_;
883	herr *= norm;
884
885	return 0;
886	}
887
888	//-------------------------------------------------------------------
889	int GeneFluct3D::ComputeSpectrum(HistoErr& herr,double sigma,bool pixcor)
890	// Compute spectrum from "T" and fill HistoErr "herr"
891	// AVEC la soustraction du niveau de bruit et la correction par filterpixel()
892	// Si on ne fait pas ca, alors on obtient un spectre non-isotrope!
893	//
894	// T : dans le format standard de GeneFuct3D: T(nz,ny,nx)
895	// cad T(kz,ky,kx) avec 0<kz<kz_nyq -ky_nyq<ky<ky_nyq -kx_nyq<kx<kx_nyq
896	{
897	if(lp_>0) cout<<"--- ComputeSpectrum: sigma="<<sigma<<endl;
898	check_array_alloc();
899
900	if(sigma<=0.) sigma = 0.;
901	double sigma2 = sigma*sigma / (double)NRtot_;
902
903	if(herr.NBins()<0) return -1;
904	herr.Zero();
905
906	TVector<r_8> vfz(NCz_);
907	if(pixcor) // kz = l*Dkz_
908	for(long l=0;l<NCz_;l++) {vfz(l)=pixelfilter(lDkz_ Dz_/2); vfz(l)*=vfz(l);}
909
910	// Attention a l'ordre
911	for(long i=0;i<Nx_;i++) {
912	long ii = (i>Nx_/2) ? Nx_-i : i;
913	double kx = ii*Dkx_;
914	double fx = (pixcor) ? pixelfilter(kx*Dx_/2): 1.;
915	kx = kx; fx = fx;
916	for(long j=0;j<Ny_;j++) {
917	long jj = (j>Ny_/2) ? Ny_-j : j;
918	double ky = jj*Dky_;
919	double fy = (pixcor) ? pixelfilter(ky*Dy_/2): 1.;
920	ky = ky; fy = fy;
921	for(long l=0;l<NCz_;l++) {
922	double kz = l*Dkz_;
923	double k = sqrt(kx+ky+kz*kz);
924	double pk = MODULE2(T_(l,j,i)) - sigma2;
925	double fz = (pixcor) ? vfz(l): 1.;
926	double f = fxfyfz;
927	if(f>0.) herr.Add(k,pk/f);
928	}
929	}
930	}
931	herr.ToVariance();
932
933	// renormalize to directly compare to original spectrum
934	double norm = Vol_;
935	herr *= norm;
936
937	return 0;
938	}
939
940	int GeneFluct3D::ComputeSpectrum2D(Histo2DErr& herr,double sigma,bool pixcor)
941	// AVEC la soustraction du niveau de bruit et la correction par filterpixel()
942	{
943	if(lp_>0) cout<<"--- ComputeSpectrum2D: sigma="<<sigma<<endl;
944	check_array_alloc();
945
946	if(sigma<=0.) sigma = 0.;
947	double sigma2 = sigma*sigma / (double)NRtot_;
948
949	if(herr.NBinX()<0 \|\| herr.NBinY()<0) return -1;
950	herr.Zero();
951
952	TVector<r_8> vfz(NCz_);
953	if(pixcor) // kz = l*Dkz_
954	for(long l=0;l<NCz_;l++) {vfz(l)=pixelfilter(lDkz_ Dz_/2); vfz(l)*=vfz(l);}
955
956	// Attention a l'ordre
957	for(long i=0;i<Nx_;i++) {
958	long ii = (i>Nx_/2) ? Nx_-i : i;
959	double kx = ii*Dkx_;
960	double fx = (pixcor) ? pixelfilter(kx*Dx_/2) : 1.;
961	kx = kx; fx = fx;
962	for(long j=0;j<Ny_;j++) {
963	long jj = (j>Ny_/2) ? Ny_-j : j;
964	double ky = jj*Dky_;
965	double fy = (pixcor) ? pixelfilter(ky*Dy_/2) : 1.;
966	ky = ky; fy = fy;
967	double kt = sqrt(kx+ky);
968	for(long l=0;l<NCz_;l++) {
969	double kz = l*Dkz_;
970	double pk = MODULE2(T_(l,j,i)) - sigma2;
971	double fz = (pixcor) ? vfz(l): 1.;
972	double f = fxfyfz;
973	if(f>0.) herr.Add(kt,kz,pk/f);
974	}
975	}
976	}
977	herr.ToVariance();
978
979	// renormalize to directly compare to original spectrum
980	double norm = Vol_;
981	herr *= norm;
982
983	return 0;
984	}
985
986	//-------------------------------------------------------
987	int_8 GeneFluct3D::VarianceFrReal(double R,double& var)
988	// Recompute MASS variance in spherical top-hat (rayon=R)
989	{
990	if(lp_>0) cout<<"--- VarianceFrReal R="<<R<<endl;
991	check_array_alloc();
992
993	long dnx = long(R/Dx_+0.5); if(dnx<=0) dnx = 1;
994	long dny = long(R/Dy_+0.5); if(dny<=0) dny = 1;
995	long dnz = long(R/Dz_+0.5); if(dnz<=0) dnz = 1;
996	if(lp_>0) cout<<"dnx="<<dnx<<" dny="<<dny<<" dnz="<<dnz<<endl;
997
998	double sum=0., sum2=0., r2 = R*R; int_8 nsum=0;
999
1000	for(long i=dnx;i<Nx_-dnx;i+=dnx) {
1001	for(long j=dny;j<Ny_-dny;j+=dny) {
1002	for(long l=dnz;l<Nz_-dnz;l+=dnz) {
1003	double s=0.; int_8 n=0;
1004	for(long ii=i-dnx;ii<=i+dnx;ii++) {
1005	double x = (ii-i)Dx_; x = x;
1006	for(long jj=j-dny;jj<=j+dny;jj++) {
1007	double y = (jj-j)Dy_; y = y;
1008	for(long ll=l-dnz;ll<=l+dnz;ll++) {
1009	double z = (ll-l)Dz_; z = z;
1010	if(x+y+z>r2) continue;
1011	int_8 ip = IndexR(ii,jj,ll);
1012	s += 1.+data_[ip];
1013	n++;
1014	}
1015	}
1016	}
1017	if(n>0) {sum += s; sum2 += s*s; nsum++;}
1018	//cout<<i<<","<<j<<","<<l<<" n="<<n<<" s="<<s<<" sum="<<sum<<" sum2="<<sum2<<endl;
1019	}
1020	}
1021	}
1022
1023	if(nsum<=1) {var=0.; return nsum;}
1024
1025	sum /= nsum;
1026	sum2 = sum2/nsum - sum*sum;
1027	if(lp_>0) cout<<"...nsum="<<nsum<<" <M>="<<sum<<" <(M-<M>)^2>="<<sum2<<endl;
1028
1029	var = sum2/(sum*sum); // <dM>^2/<M>^2
1030	if(lp_>0) cout<<"...sigmaR^2="<<var<<" -> "<<sqrt(var)<<endl;
1031
1032	return nsum;
1033	}
1034
1035	//-------------------------------------------------------
1036	int_8 GeneFluct3D::NumberOfBad(double vmin,double vmax)
1037	// number of pixels outside of ]vmin,vmax[ extremites exclues
1038	// -> vmin and vmax are considered as bad
1039	{
1040	check_array_alloc();
1041
1042	int_8 nbad = 0;
1043	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1044	int_8 ip = IndexR(i,j,l);
1045	double v = data_[ip];
1046	if(v<=vmin \|\| v>=vmax) nbad++;
1047	}
1048
1049	if(lp_>0) cout<<"--- NumberOfBad "<<nbad<<" px out of ]"<<vmin<<","<<vmax<<"["<<endl;
1050	return nbad;
1051	}
1052
1053	int_8 GeneFluct3D::MinMax(double& xmin,double& xmax,double vmin,double vmax)
1054	// Calcul des valeurs xmin et xmax dans le cube reel avec valeurs ]vmin,vmax[ extremites exclues
1055	{
1056	bool tstval = (vmax>vmin)? true: false;
1057	if(lp_>0) {
1058	cout<<"--- MinMax";
1059	if(tstval) cout<<" range=]"<<vmin<<","<<vmax<<"[";
1060	cout<<endl;
1061	}
1062	check_array_alloc();
1063
1064	int_8 n = 0;
1065	xmin = xmax = data_[0];
1066
1067	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1068	int_8 ip = IndexR(i,j,l);
1069	double x = data_[ip];
1070	if(tstval && (x<=vmin \|\| x>=vmax)) continue;
1071	if(x<xmin) xmin = x;
1072	if(x>xmax) xmax = x;
1073	n++;
1074	}
1075
1076	if(lp_>0) cout<<" n="<<n<<" min="<<xmin<<" max="<<xmax<<endl;
1077
1078	return n;
1079	}
1080
1081	int_8 GeneFluct3D::MeanSigma2(double& rm,double& rs2,double vmin,double vmax
1082	,bool useout,double vout)
1083	// Calcul de mean,sigma2 dans le cube reel avec valeurs ]vmin,vmax[ extremites exclues
1084	// useout = false: ne pas utiliser les pixels hors limites pour calculer mean,sigma2
1085	// true : utiliser les pixels hors limites pour calculer mean,sigma2
1086	// en remplacant leurs valeurs par "vout"
1087	{
1088	bool tstval = (vmax>vmin)? true: false;
1089	if(lp_>0) {
1090	cout<<"--- MeanSigma2";
1091	if(tstval) cout<<" range=]"<<vmin<<","<<vmax<<"[";
1092	if(useout) cout<<", useout="<<useout<<" vout="<<vout;
1093	cout<<endl;
1094	}
1095	check_array_alloc();
1096
1097	int_8 n = 0;
1098	rm = rs2 = 0.;
1099
1100	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1101	int_8 ip = IndexR(i,j,l);
1102	double v = data_[ip];
1103	if(tstval) {
1104	if(v<=vmin \|\| v>=vmax) {if(useout) v=vout; else continue;}
1105	}
1106	rm += v;
1107	rs2 += v*v;
1108	n++;
1109	}
1110
1111	if(n>1) {
1112	rm /= (double)n;
1113	rs2 = rs2/(double)n - rm*rm;
1114	}
1115
1116	if(lp_>0) cout<<" n="<<n<<" m="<<rm<<" s2="<<rs2<<" s="<<sqrt(fabs(rs2))<<endl;
1117
1118	return n;
1119	}
1120
1121	int_8 GeneFluct3D::SetToVal(double vmin, double vmax,double val0)
1122	// set to "val0" if out of range ]vmin,vmax[ extremites exclues
1123	// cad set to "val0" if in [vmin,vmax] -> vmin and vmax are set to val0
1124	{
1125	check_array_alloc();
1126
1127	int_8 nbad = 0;
1128	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1129	int_8 ip = IndexR(i,j,l);
1130	double v = data_[ip];
1131	if(v<=vmin \|\| v>=vmax) {data_[ip] = val0; nbad++;}
1132	}
1133
1134	if(lp_>0) cout<<"--- SetToVal "<<nbad<<" px set to="<<val0
1135	<<" because out of range=]"<<vmin<<","<<vmax<<"["<<endl;
1136	return nbad;
1137	}
1138
1139	void GeneFluct3D::ScaleOffset(double scalecube,double offsetcube)
1140	// Replace "V" by "scalecube * ( V + offsetcube )"
1141	{
1142	if(lp_>0) cout<<"--- ScaleCube scale="<<scalecube<<" offset="<<offsetcube<<endl;
1143
1144	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1145	int_8 ip = IndexR(i,j,l);
1146	data_[ip] = scalecube * ( data_[ip] + offsetcube );
1147	}
1148
1149	return;
1150	}
1151
1152	//-------------------------------------------------------
1153	void GeneFluct3D::TurnFluct2Mass(void)
1154	// d_rho/rho -> Mass (add one!)
1155	{
1156	if(lp_>0) cout<<"--- TurnFluct2Mass ---"<<endl;
1157	check_array_alloc();
1158
1159
1160	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1161	int_8 ip = IndexR(i,j,l);
1162	data_[ip] += 1.;
1163	}
1164	}
1165
1166	double GeneFluct3D::TurnMass2HIMass(double m_by_mpc3)
1167	{
1168	if(lp_>0) cout<<"--- TurnMass2HIMass : "<<m_by_mpc3<<" Msol/Mpc^3"<<endl;
1169
1170	double mall=0., mgood=0.;
1171	int_8 nall=0, ngood=0;
1172	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1173	int_8 ip = IndexR(i,j,l);
1174	mall += data_[ip]; nall++;
1175	if(data_[ip]>0.) {mgood += data_[ip]; ngood++;}
1176	}
1177	if(ngood>0) mgood /= (double)ngood;
1178	if(nall>0) mall /= (double)nall;
1179	if(lp_>0) cout<<"...ngood="<<ngood<<" mgood="<<mgood
1180	<<", nall="<<nall<<" mall="<<mall<<endl;
1181	if(ngood<=0 \|\| mall<=0.) {
1182	cout<<"TurnMass2HIMass_Error: ngood="<<ngood<<" <=0 \|\| mall="<<mall<<" <=0"<<endl;
1183	throw RangeCheckError("TurnMass2HIMass_Error: ngood<=0 \|\| mall<=0");
1184	}
1185
1186	// On doit mettre m*Vol masse de HI dans notre survey
1187	// On en met uniquement dans les pixels de masse >0.
1188	// On MET a zero les pixels <0
1189	// On renormalise sur les pixels>0 pour qu'on ait m*Vol masse de HI
1190	// comme on ne prend que les pixels >0, on doit normaliser
1191	// a la moyenne de <1+d_rho/rho> sur ces pixels
1192	// (rappel sur tout les pixels <1+d_rho/rho>=1)
1193	// masse de HI a mettre ds 1 px:
1194	double dm = m_by_mpc3*Vol_/ (mgood/mall) /(double)ngood;
1195	if(lp_>0) cout<<"...HI mass density move from "
1196	<<m_by_mpc3*Vol_/double(NRtot_)<<" to "<<dm<<" / pixel"<<endl;
1197
1198	double sum = 0.;
1199	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1200	int_8 ip = IndexR(i,j,l);
1201	if(data_[ip]<=0.) data_[ip] = 0.;
1202	else {
1203	data_[ip] *= dm; // par coherence on multiplie aussi les <=0
1204	sum += data_[ip]; // mais on ne les compte pas
1205	}
1206	}
1207
1208	if(lp_>0) cout<<sum<<"...mass HI put into survey / "<<m_by_mpc3*Vol_<<endl;
1209
1210	return sum;
1211	}
1212
1213	double GeneFluct3D::TurnMass2MeanNumber(double n_by_mpc3)
1214	// do NOT treate negative or nul values
1215	{
1216	if(lp_>0) cout<<"--- TurnMass2MeanNumber : "<<n_by_mpc3<<" gal/Mpc^3"<<endl;
1217
1218	double mall=0., mgood=0.;
1219	int_8 nall=0, ngood=0;
1220	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1221	int_8 ip = IndexR(i,j,l);
1222	mall += data_[ip]; nall++;
1223	if(data_[ip]>0.) {mgood += data_[ip]; ngood++;}
1224	}
1225	if(ngood>0) mgood /= (double)ngood;
1226	if(nall>0) mall /= (double)nall;
1227	if(lp_>0) cout<<"...ngood="<<ngood<<" mgood="<<mgood
1228	<<", nall="<<nall<<" mall="<<mall<<endl;
1229	if(ngood<=0 \|\| mall<=0.) {
1230	cout<<"TurnMass2MeanNumber_Error: ngood="<<ngood<<" <=0 \|\| mall="<<mall<<" <=0"<<endl;
1231	throw RangeCheckError("TurnMass2MeanNumber_Error: ngood<=0 \|\| mall<=0");
1232	}
1233
1234	// On doit mettre n*Vol galaxies dans notre survey
1235	// On en met uniquement dans les pixels de masse >0.
1236	// On NE met PAS a zero les pixels <0
1237	// On renormalise sur les pixels>0 pour qu'on ait n*Vol galaxies
1238	// comme on ne prend que les pixels >0, on doit normaliser
1239	// a la moyenne de <1+d_rho/rho> sur ces pixels
1240	// (rappel sur tout les pixels <1+d_rho/rho>=1)
1241	// nb de gal a mettre ds 1 px:
1242	double dn = n_by_mpc3*Vol_/ (mgood/mall) /(double)ngood;
1243	if(lp_>0) cout<<"...galaxy density move from "
1244	<<n_by_mpc3*Vol_/double(NRtot_)<<" to "<<dn<<" / pixel"<<endl;
1245
1246	double sum = 0.;
1247	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1248	int_8 ip = IndexR(i,j,l);
1249	data_[ip] *= dn; // par coherence on multiplie aussi les <=0
1250	if(data_[ip]>0.) sum += data_[ip]; // mais on ne les compte pas
1251	}
1252
1253	if(lp_>0) cout<<sum<<"...galaxies put into survey / "<<n_by_mpc3*Vol_<<endl;
1254
1255	return sum;
1256	}
1257
1258	double GeneFluct3D::ApplyPoisson(void)
1259	// do NOT treate negative or nul mass -> let it as it is
1260	{
1261	if(lp_>0) cout<<"--- ApplyPoisson ---"<<endl;
1262	check_array_alloc();
1263
1264	double sum = 0.;
1265	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1266	int_8 ip = IndexR(i,j,l);
1267	double v = data_[ip];
1268	if(v>0.) {
1269	unsigned long dn = PoissRandLimit(v,10.);
1270	data_[ip] = (double)dn;
1271	sum += (double)dn;
1272	}
1273	}
1274	if(lp_>0) cout<<sum<<" galaxies put into survey"<<endl;
1275
1276	return sum;
1277	}
1278
1279	double GeneFluct3D::TurnNGal2Mass(FunRan& massdist,bool axeslog)
1280	// do NOT treate negative or nul mass -> let it as it is
1281	// INPUT:
1282	// massdist : distribution de masse (m*dn/dm)
1283	// axeslog = false : retourne la masse
1284	// = true : retourne le log10(mass)
1285	// RETURN la masse totale
1286	{
1287	if(lp_>0) cout<<"--- TurnNGal2Mass ---"<<endl;
1288	check_array_alloc();
1289
1290	double sum = 0.;
1291	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1292	int_8 ip = IndexR(i,j,l);
1293	double v = data_[ip];
1294	if(v>0.) {
1295	long ngal = long(v+0.1);
1296	data_[ip] = 0.;
1297	for(long i=0;i<ngal;i++) {
1298	double m = massdist.RandomInterp(); // massdist.Random();
1299	if(axeslog) m = pow(10.,m);
1300	data_[ip] += m;
1301	}
1302	sum += data_[ip];
1303	}
1304	}
1305	if(lp_>0) cout<<sum<<" MSol HI mass put into survey"<<endl;
1306
1307	return sum;
1308	}
1309
1310	double GeneFluct3D::TurnNGal2MassQuick(SchechterMassDist& schmdist)
1311	// idem TurnNGal2Mass mais beaucoup plus rapide
1312	{
1313	if(lp_>0) cout<<"--- TurnNGal2MassQuick ---"<<endl;
1314	check_array_alloc();
1315
1316	double sum = 0.;
1317	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) for(long l=0;l<Nz_;l++) {
1318	int_8 ip = IndexR(i,j,l);
1319	double v = data_[ip];
1320	if(v>0.) {
1321	long ngal = long(v+0.1);
1322	data_[ip] = schmdist.TirMass(ngal);
1323	sum += data_[ip];
1324	}
1325	}
1326	if(lp_>0) cout<<sum<<" MSol HI mass put into survey"<<endl;
1327
1328	return sum;
1329	}
1330
1331	void GeneFluct3D::AddAGN(double lfjy,double lsigma,double powlaw)
1332	// Add AGN flux into simulation:
1333	// --- Procedure:
1334	// 1. lancer "cmvdefsurv" avec les parametres du survey
1335	// (au redshift de reference du survey)
1336	// et recuperer l'angle solide "angsol sr" du pixel elementaire
1337	// au centre du cube.
1338	// 2. lancer "cmvtstagn" pour cet angle solide -> cmvtstagn.ppf
1339	// 3. regarder l'histo "hlfang" et en deduire un equivalent gaussienne
1340	// cad une moyenne <log10(S)> et un sigma "sig"
1341	// Attention: la distribution n'est pas gaussienne les "mean,sigma"
1342	// de l'histo ne sont pas vraiment ce que l'on veut
1343	// --- Limitations actuelle du code:
1344	// . les AGN sont supposes evoluer avec la meme loi de puissance pour tout theta,phi
1345	// . le flux des AGN est mis dans une colonne Oz (indice k) et pas sur la ligne de visee
1346	// . la distribution est approximee a une gaussienne
1347	// ... C'est une approximation pour un observateur loin du centre du cube
1348	// et pour un cube peu epais / distance observateur
1349	// --- Parametres de la routine:
1350	// llfy : c'est le <log10(S)> du flux depose par les AGN
1351	// dans l'angle solide du pixel elementaire de reference du cube
1352	// lsigma : c'est le sigma de la distribution des log10(S)
1353	// powlaw : c'est la pente de la distribution cad que le flux "lmsol"
1354	// et considere comme le flux a 1.4GHz et qu'on suppose une loi
1355	// F(nu) = (1.4GHz/nu)^powlaw * F(1.4GHz)
1356	// - Comme on est en echelle log10():
1357	// on tire log10(Msol) + X
1358	// ou X est une realisation sur une gaussienne de variance "sig^2"
1359	// La masse realisee est donc: Msol*10^X
1360	// - Pas de probleme de pixel negatif car on a une multiplication!
1361	{
1362	if(lp_>0) cout<<"--- AddAGN: <log10(S Jy)> = "<<lfjy<<" , sigma = "<<lsigma<<endl;
1363	check_array_alloc();
1364
1365	if(cosmo_ == NULL \|\| redsh_ref_<0.\| loscom2zred_.size()<1) {
1366	char *bla = "GeneFluct3D::AddAGN_Error: set Observator and Cosmology first";
1367	cout<<bla<<endl; throw ParmError(bla);
1368	}
1369
1370	// Le flux des AGN en Jy et en mass solaire
1371	double fagnref = pow(10.,lfjy)(dnu_ref_1.e9); // Jy.Hz = W/m^2
1372	double magnref = FluxHI2Msol(fagnref*Jansky2Watt_cst,dlum_ref_); // Msol
1373	if(lp_>0)
1374	cout<<"Au pixel de ref: fagnref="<<fagnref
1375	<<" Jy.Hz (a 1.4GHz), magnref="<<magnref<<" Msol"<<endl;
1376
1377	if(powlaw!=0.) {
1378	// F(nu) = F(1.4GHz)(nu GHz/1.4 Ghz)^p = F(1.4GHz)(1/(1+z))^p , car nu = 1.4 GHz/(1+z)
1379	magnref *= pow(1/(1.+redsh_ref_),powlaw);
1380	if(lp_>0) cout<<" powlaw="<<powlaw<<" -> change magnref to "<<magnref<<" Msol"<<endl;
1381	}
1382
1383	// Les infos en fonction de l'indice "l" selon Oz
1384	vector<double> correction;
1385	InterpFunc interpinv(loscom2zred_min_,loscom2zred_max_,loscom2zred_);
1386	long nzmod = ((Nz_>10)?Nz_/10:1);
1387	for(long l=0;l<Nz_;l++) {
1388	double z = fabs(DZcom(l));
1389	double zred = interpinv(z);
1390	double dtrc = cosmo_->Dtrcom(zred); // pour variation angle solide
1391	double dlum = cosmo_->Dlum(zred); // pour variation conversion mass HI
1392	double dred = Dz_/(cosmo_->Dhubble()/cosmo_->E(zred));
1393	double dnu = Fr_HyperFin_Par *dred/pow(1.+zred,2.); // pour variation dNu
1394	// on a: Mass ~ DNu * Dlum^2 / Dtrcom^2
1395	double corr = dnu/dnu_ref_pow(dtrc_ref_/dtrcdlum/dlum_ref_,2.);
1396	// F(nu) = F(1.4GHz)(nu GHz/1.4 Ghz)^p = F(1.4GHz)(1/(1+z))^p , car nu = 1.4 GHz/(1+z)
1397	if(powlaw!=0.) corr *= pow((1.+redsh_ref_)/(1.+zred),powlaw);
1398	correction.push_back(corr);
1399	if(lp_>0 && (l==0 \|\| l==Nz_-1 \|\| l%nzmod==0)) {
1400	cout<<"l="<<l<<" z="<<z<<" red="<<zred<<" dred="<<dred<<" dnu="<<dnu
1401	<<" dtrc="<<dtrc<<" dlum="<<dlum
1402	<<" -> cor="<<corr<<endl;
1403	}
1404	}
1405
1406	double sum=0., sum2=0., nsum=0.;
1407	for(long i=0;i<Nx_;i++) for(long j=0;j<Ny_;j++) {
1408	double a = lsigma*NorRand();
1409	a = magnref*pow(10.,a);
1410	// On met le meme tirage le long de Oz (indice k)
1411	for(long l=0;l<Nz_;l++) {
1412	int_8 ip = IndexR(i,j,l);
1413	data_[ip] += a*correction[l];
1414	}
1415	sum += a; sum2 += a*a; nsum += 1.;
1416	}
1417
1418	if(lp_>0 && nsum>1.) {
1419	sum /= nsum;
1420	sum2 = sum2/nsum - sum*sum;
1421	cout<<"...Mean mass="<<sum<<" Msol , s^2="<<sum2<<" s="<<sqrt(fabs(sum2))<<endl;
1422	}
1423
1424	}
1425
1426	void GeneFluct3D::AddNoise2Real(double snoise,int type_evol)
1427	// add noise to every pixels (meme les <=0 !)
1428	// type_evol = 0 : pas d'evolution de la puissance du bruit
1429	// 1 : evolution de la puissance du bruit avec la distance a l'observateur
1430	// 2 : evolution de la puissance du bruit avec la distance du plan Z
1431	// (tous les plans Z sont mis au meme redshift z de leur milieu)
1432	{
1433	if(lp_>0) cout<<"--- AddNoise2Real: snoise = "<<snoise<<" evol="<<type_evol<<endl;
1434	check_array_alloc();
1435
1436	if(type_evol<0) type_evol = 0;
1437	if(type_evol>2) {
1438	char *bla = "GeneFluct3D::AddNoise2Real_Error: bad type_evol value";
1439	cout<<bla<<endl; throw ParmError(bla);
1440	}
1441
1442	vector<double> correction;
1443	InterpFunc *intercor = NULL;
1444
1445	if(type_evol>0) {
1446	// Sigma_Noise(en mass) :
1447	// Slim ~ 1/sqrt(DNu) * sqrt(nlobe) en W/m^2Hz
1448	// Flim ~ sqrt(DNu) * sqrt(nlobe) en W/m^2
1449	// Mlim ~ sqrt(DNu) * (Dlum)^2 * sqrt(nlobe) en Msol
1450	// nlobe ~ 1/Dtrcom^2
1451	// Mlim ~ sqrt(DNu) * (Dlum)^2 / Dtrcom
1452	if(cosmo_ == NULL \|\| redsh_ref_<0.\| loscom2zred_.size()<1) {
1453	char *bla = "GeneFluct3D::AddNoise2Real_Error: set Observator and Cosmology first";
1454	cout<<bla<<endl; throw ParmError(bla);
1455	}
1456	InterpFunc interpinv(loscom2zred_min_,loscom2zred_max_,loscom2zred_);
1457	long nsz = loscom2zred_.size(), nszmod=((nsz>10)? nsz/10: 1);
1458	for(long i=0;i<nsz;i++) {
1459	double d = interpinv.X(i);
1460	double zred = interpinv(d);
1461	double dtrc = cosmo_->Dtrcom(zred); // pour variation angle solide
1462	double dlum = cosmo_->Dlum(zred); // pour variation conversion mass HI
1463	double dred = Dz_/(cosmo_->Dhubble()/cosmo_->E(zred));
1464	double dnu = Fr_HyperFin_Par *dred/pow(1.+zred,2.); // pour variation dNu
1465	double corr = sqrt(dnu/dnu_ref_) * pow(dlum/dlum_ref_,2.) * dtrc_ref_/dtrc;
1466	if(lp_>0 && (i==0 \|\| i==nsz-1 \|\| i%nszmod==0))
1467	cout<<"i="<<i<<" d="<<d<<" red="<<zred<<" dred="<<dred<<" dnu="<<dnu
1468	<<" dtrc="<<dtrc<<" dlum="<<dlum<<" -> cor="<<corr<<endl;
1469	correction.push_back(corr);
1470	}
1471	intercor = new InterpFunc(loscom2zred_min_,loscom2zred_max_,correction);
1472	}
1473
1474	double corrlim[2] = {1.,1.};
1475	for(long i=0;i<Nx_;i++) {
1476	double dx2 = DXcom(i); dx2 *= dx2;
1477	for(long j=0;j<Ny_;j++) {
1478	double dy2 = DYcom(j); dy2 *= dy2;
1479	for(long l=0;l<Nz_;l++) {
1480	double corr = 1.;
1481	if(type_evol>0) {
1482	double dz = DZcom(l);
1483	if(type_evol==1) dz = sqrt(dx2+dy2+dz*dz);
1484	else dz = fabs(dz); // tous les plans Z au meme redshift
1485	corr = (*intercor)(dz);
1486	if(corr<corrlim[0]) corrlim[0]=corr; else if(corr>corrlim[1]) corrlim[1]=corr;
1487	}
1488	int_8 ip = IndexR(i,j,l);
1489	data_[ip] += snoisecorrNorRand();
1490	}
1491	}
1492	}
1493	if(type_evol>0)
1494	cout<<"correction factor range: ["<<corrlim[0]<<","<<corrlim[1]<<"]"<<endl;
1495
1496	if(intercor!=NULL) delete intercor;
1497	}
1498
1499	} // Fin namespace SOPHYA

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