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R1448 Lenstool-HPC
structure.h
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#ifndef STRUCTURE_H
#define STRUCTURE_H
#include "dimension.h"
#include<gsl/gsl_matrix.h>
// Parameter constants
#define CX 0
#define CY 1
#define EPOT 2
#define EMASS 3
#define THETA 4
#define PHI 5
#define RC 6
#define B0 7
#define ALPHA 8
#define BETA 9
#define RCUT 10
#define MASSE 11
#define ZLENS 12
#define RCSLOPE 13
#define PMASS 14
#define OMEGAM 15
#define OMEGAX 16
#define WX 17
#define WA 18
#define SCX 19
#define SCY 20
#define SA 21
#define SB 22
#define SEPS 23
#define STHETA 24
#define SINDEX 25
#define SFLUX 26
#define VFCX 27
#define VFCY 28
#define VFVT 29
#define VFRT 30
#define VFI 31
#define VFTHETA 32
#define VFLCENT 33
#define VFSIGMA 34
/*
* structure definition
*/
/*****************************************************************/
/* */
/* Definition de type */
/* */
/*****************************************************************/
typedef
struct
{
double
re
;
double
im
;
}
complex
;
/*****************************************************************/
/* */
/* structure point */
/* */
/*****************************************************************/
struct
point
{
double
x
;
double
y
;
};
/*****************************************************************/
/* */
/* structure lens-data */
/* */
/*****************************************************************/
typedef
struct
{
double
alpha_now
,
x_now
,
kappa
,
dpl
;
}
lensdata
;
/*****************************************************************/
/* */
/* Definition des structures de controle */
/* */
/*****************************************************************/
struct
g_observ
{
int
bruit
;
int
setbin
;
int
bin
;
int
setseeing
;
int
filtre
;
double
seeing
;
double
seeing_a
;
double
seeing_b
;
double
seeing_angle
;
char
psffile
[
FILENAME_SIZE
];
double
r0st
;
double
r0st_a
;
double
r0st_b
;
double
prec
;
double
SKY
;
double
gain
;
int
idum
;
};
struct
g_mode
{
int
verbose
;
int
sort
;
int
grille
;
int
ngrille
;
double
zgrille
;
int
inverse
;
/* mode inversion de la lentille */
int
itmax
;
/* iter. max lors de l'optimisation*/
double
rate
;
/* rate in the bayesian optimisation*/
double
minchi0
;
/* minimal chi2 for the optimisation*/
int
ichi2
;
/* compute the chi2 with the given model and constraints*/
int
image
;
/* flag pour fichier d'images */
char
imafile
[
FILENAME_SIZE
];
int
source
;
/* flag pour fichier de sources */
char
sourfile
[
FILENAME_SIZE
];
/* from an image file compute only the source catalogue */
int
sof
;
/* flag pour fichier de sources */
char
imsfile
[
FILENAME_SIZE
];
char
sfile
[
FILENAME_SIZE
];
/* correlate shear with model */
int
icorshear
;
/* flag pour fichier de correlation */
char
corshfile
[
FILENAME_SIZE
];
/* etude pour le comportement local des image */
int
local
;
/* flag d'etude de e_i dans le repere local */
char
localfile
[
FILENAME_SIZE
];
/* etude pour l'inversion des arclets en fonction du redshift */
int
study
;
/* flag d'etude de e_s en fonction de z_s */
char
studyfile
[
FILENAME_SIZE
];
int
fake
;
int
mean
;
double
seeing
;
/* etude pour le calcul du amplification du plan image */
int
iampli
;
int
nampli
;
double
zampli
;
char
amplifile
[
FILENAME_SIZE
];
/* etude pour le calcul du poten du plan image */
int
ipoten
;
int
npoten
;
double
zpoten
;
char
potenfile
[
FILENAME_SIZE
];
/* etude pour le calcul du mass du plan image */
int
imass
;
int
nmass
;
double
zmass
;
char
massfile
[
FILENAME_SIZE
];
/* etude pour le calcul du dpl du plan image */
int
idpl
;
int
ndpl
;
double
zdpl
;
char
dplxfile
[
FILENAME_SIZE
];
char
dplyfile
[
FILENAME_SIZE
];
/* etude pour le calcul du curvature du plan image */
int
icurv
;
int
ncurv
;
double
zcurv
;
char
cxxfile
[
FILENAME_SIZE
];
char
cxyfile
[
FILENAME_SIZE
];
char
cyyfile
[
FILENAME_SIZE
];
/* etude pour le calcul du shear-field du plan image */
int
ishearf
;
double
zshearf
;
char
shearffile
[
FILENAME_SIZE
];
int
nshearf
;
/* etude pour le calcul du amplification-field du plan image */
int
iamplif
;
double
zamplif
;
char
ampliffile
[
FILENAME_SIZE
];
/* etude pour le calcul du shear du plan image */
int
ishear
;
int
nshear
;
double
zshear
;
char
shearfile
[
FILENAME_SIZE
];
/* etude pour le calcul du time_delay du plan image */
int
itime
;
int
ntime
;
double
ztime
;
char
timefile
[
FILENAME_SIZE
];
/* etude pour le calcul des props du plan image */
int
prop
;
int
nprop
;
double
zprop
;
char
propfile
[
FILENAME_SIZE
];
double
radius
;
double
masse
;
/* visualisation pixelise du champ */
int
pixel
;
int
npixel
;
char
pixelfile
[
FILENAME_SIZE
];
/* datacube */
int
cube
;
int
nslices
;
char
cubefile
[
FILENAME_SIZE
];
/* Reference absolue */
int
iref
;
double
ref_ra
;
double
ref_dec
;
/* calcul des markers sources de markers images donnes */
int
marker
;
double
zmarker
;
char
markfile
[
FILENAME_SIZE
];
/* etude d'une coupe des props du plan image */
int
radial
;
double
zradial
;
double
theta
;
/* visualisation pixelise du plan source */
int
iclean
;
double
zclean
;
/* center of multiple images file */
char
centerfile
[
FILENAME_SIZE
];
};
/* potfile parameters */
struct
g_pot
{
int
potid
;
// 1: pot P, 2: pot Q
int
ftype
;
char
potfile
[
FILENAME_SIZE
];
int
type
;
double
zlens
;
double
core
;
double
corekpc
;
double
mag0
;
int
select
;
int
ircut
;
double
cut
,
cut1
,
cut2
;
double
cutkpc1
,
cutkpc2
;
int
isigma
;
double
sigma
,
sigma1
,
sigma2
;
int
islope
;
double
slope
,
slope1
,
slope2
;
int
ivdslope
;
double
vdslope
,
vdslope1
,
vdslope2
;
int
ivdscat
;
double
vdscat
,
vdscat1
,
vdscat2
;
int
ircutscat
;
double
rcutscat
,
rcutscat1
,
rcutscat2
;
int
ia
;
// scaling relation of msm200
double
a
,
a1
,
a2
;
int
ib
;
// scaling relation of msm200
double
b
,
b1
,
b2
;
};
/* dynfile parameters */
struct
g_dyn
{
int
dyntype
;
int
dynnumber
;
double
dynvel
;
double
dynevel
;
double
indmass
;
double
indemass
;
double
refradius
;
};
// parameters of an image in pixels with WCS coordinates
struct
g_pixel
{
int
column
;
int
ech
;
int
format
;
char
pixfile
[
FILENAME_SIZE
];
int
ncont
;
char
outfile
[
FILENAME_SIZE
];
char
contfile
[
10
][
FILENAME_SIZE
];
double
pixelx
;
double
pixely
;
int
header
;
double
xmin
;
double
xmax
;
double
ymin
;
double
ymax
;
int
nx
;
int
ny
;
double
meanFlux
;
struct
WorldCoor
*
wcsinfo
;
};
struct
g_cube
{
int
format
;
char
pixfile
[
FILENAME_SIZE
];
double
xmin
;
double
xmax
;
double
ymin
;
double
ymax
;
double
lmin
;
double
lmax
;
double
pixelx
;
double
pixely
;
double
pixelz
;
int
nx
;
int
ny
;
int
nz
;
int
header
;
double
meanFlux
;
struct
WorldCoor
*
wcsinfo
;
};
struct
g_image
{
int
random
;
int
nzlim
;
int
npcl
;
/* shear map parameteres */
int
shmap
;
double
zsh
,
dl0ssh
,
dossh
,
drsh
;
char
shfile
[
FILENAME_SIZE
];
/* arclets parameteres */
int
stat
;
int
statmode
;
char
arclet
[
FILENAME_SIZE
];
char
nza
[
10
];
/*index of the redshift known arclet in z_arclet*/
double
zarclet
;
double
drarclet
;
double
sigell
,
dsigell
;
// ellipticity of sources and associated error
double
sig2ell
;
// source plane fitting
int
srcfit
;
// boolean yes/no
long
int
nsrcfit
;
// number of points in srcfit global variable
char
srcfitFile
[
FILENAME_SIZE
];
// name of the srcfit catalog of points
char
srcfitMethod
[
50
];
// source plane fitting method
/* multiple arcs parameteres */
int
forme
;
int
n_mult
;
int
mult_abs
;
int
mult
[
NFMAX
];
char
multfile
[
FILENAME_SIZE
];
double
sig2pos
[
NFMAX
][
NIMAX
];
// position error per system
double
**
weight
;
// inverse of covariance matrix
double
detCov
;
// determinant of the covariance matrix
double
sig2amp
;
double
Dmag
;
int
adjust
;
char
Afile
[
FILENAME_SIZE
];
int
Anx
;
int
Any
;
int
Abin
;
int
Anfilt
;
int
Anpixseeing
;
double
Apixel
;
double
Aseeing
;
double
Axmin
;
double
Axmax
;
double
Aymin
;
double
Aymax
;
double
Amean
;
double
Adisp
;
};
struct
g_source
{
int
grid
;
int
rand
;
long
int
ns
;
int
distz
;
double
emax
;
double
zs
;
double
zsmin
;
double
zsmax
;
double
par1
;
// for Smail et al. distrib
double
par2
;
double
par3
;
double
taille
;
double
lfalpha
;
double
lfm_star
;
double
lfm_min
;
double
lfm_max
;
};
struct
g_grille
{
int
ngrid
;
// number of cells in source-image plane inversion
int
pol
;
// boolean : 0 regular grid, 1 polar grid
long
int
nlens
;
// size of lens[] list
long
int
nplens
[
NPOTFILE
+
1
];
// array of potfile starting indexes in lens[]
int
npot
;
// number of potfiles
long
int
nlens_crit
;
// number of lens for which the critical lines have to be computed
long
int
no_lens
;
// individual clump to optimise index in lens[]
long
int
nmsgrid
;
// multi-scale grid final index in lens[]
char
splinefile
[
FILENAME_SIZE
];
double
xmin
;
double
xmax
;
double
ymin
;
double
ymax
;
double
dx
;
double
dy
;
int
nx
;
int
ny
;
int
echant
;
double
exc
;
double
excmin
;
double
**
invmat
;
// msgrid transformation matrix between vector Sigma and sig2
};
// Multi-scale grid definition
struct
g_msgrid
{
double
threshold
;
// splitting threshold
int
levels
;
// number of splitting
double
param
;
// for PIEMD grid : rcut/rcore
char
gridfile
[
FILENAME_SIZE
];
// file containing the description of a grid
};
struct
g_cline
{
int
nplan
;
double
cz
[
NPZMAX
];
int
zone
;
int
npzone
;
char
zonefile
[
FILENAME_SIZE
];
double
cpas
;
// minimum size of the squares in MARCHINGSQUARES or initial step size in SNAKE
double
dmax
;
char
algorithm
[
20
];
//SNAKE or MARCHINGSQUARES algorithm for critical lines search
double
limitHigh
;
// maximum size of the squares in MARCHINGSQUARES algorithm
};
struct
g_frame
{
double
xmin
;
double
xmax
;
double
ymin
;
double
ymax
;
double
lmin
;
double
lmax
;
double
rmax
;
};
struct
g_large
{
double
dlarge
;
char
iname
[
50
];
int
vitesse
;
int
iso
;
int
nmaxiso
;
double
scale
;
double
zonex
;
double
zoney
;
int
profil
;
int
pt
;
int
ncourbe
;
int
npt
;
};
struct
g_cosmo
{
//function g_cosmo_equal make comparison of two g_cosmo structures
//see distcosmo2_cash.c
int
model
;
//TV
double
omegaM
;
double
omegaX
;
double
kcourb
;
double
wX
;
double
wa
;
double
H0
;
double
h
;
};
/*****************************************************************/
/* */
/* Definition des types */
/* */
/*****************************************************************/
struct
polar
{
double
r
;
double
theta
;
};
struct
segment
{
double
dist
;
int
k
;
};
struct
matrix
{
double
a
;
double
b
;
double
c
;
double
d
;
};
struct
vecteur
{
double
x
;
double
y
;
};
struct
biline
{
int
i
;
struct
point
I
;
struct
point
S
;
};
struct
ellipse
{
double
a
;
double
b
;
double
theta
;
};
struct
pointgal
{
int
n
;
struct
point
C
;
double
z
;
};
struct
pointell
{
struct
point
C
;
struct
ellipse
E
;
};
struct
shear
{
int
n
;
struct
point
C
;
double
mx
;
double
my
;
double
dx
;
double
dy
;
double
err
;
};
//"class" for cashing results of distcosmo2 (see cosmoratio.c )
struct
distcosmo2_cash
{
//you should initialise distcosmo2_cash before using
//set z1 = 0 z2 = 0 dsl=0 (or run distcosmo2_cash_init)
//or define it as global variables which will set zero automatically
//Of course, in c++ life is easy and we simple could write constructor
struct
g_cosmo
C
;
//cosmologe for which dls = distcosmo2(z1,z2) was calculated
double
z1
,
z2
;
double
dls
;
//cashing value
};
//"members" of "class" distcosmo2_cash
//you should run distcosmo2_cash_init after creatig distcosmo2_hash
void
distcosmo2_cash_init
(
struct
distcosmo2_cash
*
cash
);
//calculate distcosmo2(z1,z2) and store result in the case
//or get value from the cash if we've already calculated it
double
distcosmo2_cash_request
(
struct
distcosmo2_cash
*
cash
,
double
z1
,
double
z2
);
struct
galaxie
{
char
n
[
IDSIZE
];
struct
point
C
;
struct
point
Grad
;
// total deflection with all clumps
struct
ellipse
E
;
char
c
;
int
type
;
double
magabs
;
double
mag
;
double
flux
;
double
mu
;
double
I0
;
double
z
;
double
dl0s
;
// DLS distcosmo2 between lens[0] and z
double
dos
;
// DOS distance to z
double
dr
;
// ratio dl0s/dos
double
q
;
double
eps
;
double
tau
;
double
dis
;
double
A
;
double
ep
;
double
tp
;
double
dp
;
double
thp
;
double
taux
;
double
tauy
;
double
time
;
double
kappa
;
double
gamma1
;
double
gamma2
;
double
var1
;
// multipurpose variable1
double
var2
;
// multipurpose variable2
struct
point
grad
;
// deflection due to the not optimised clumps
struct
matrix
grad2
;
// absolute projected potential of the not optimised clumps
struct
point
*
np_grad
;
// deflection due to non parametric clumps with b0=1
double
*
np_grad2a
;
// laplacian due to non parametric clumps with b0=1
double
*
np_grad2b
;
// laplacian due to non parametric clumps with b0=1
double
*
np_grad2c
;
// laplacian due to non parametric clumps with b0=1
struct
distcosmo2_cash
dls_cash
;
//cash of distcosmo2 result
struct
point
(
*
gsource
)[
NGGMAX
][
NGGMAX
];
//we use it only for single image families!
//(see chi2SglImage function in o_chi.c)
//gsource is a 2D map of G.ngrid^2 points in the source plane defined
//by dlsds. Each point in gsource is linked to a single point in the
//gimage global variable. Those 2 maps define a kind of bijection
//between the source and the image planes.
double
grid_dr
;
//dlsds ratio for the grid used from source to image plane
};
struct
gal_pol
{
int
n
;
struct
polar
C
;
struct
ellipse
E
;
double
z
;
};
struct
z_lim
{
int
opt
;
char
n
[
128
];
int
bk
;
int
bk0
;
// opt_mc stuff golse2002
double
percent
;
// opt_mc stuff golse2002
double
min
;
double
max
;
double
err
;
double
ddmin
;
double
ddmax
;
double
dderr
;
double
excu
;
double
excd
;
};
struct
sigposStr
{
int
bk
;
double
min
;
double
max
;
double
prec
;
double
excu
;
double
excd
;
};
struct
propertie
{
int
n
;
struct
point
P
;
double
k
;
double
s
;
double
e
;
double
t
;
double
q
;
double
theta
;
double
d
;
double
A
;
double
g
;
};
struct
ligne
{
double
i
;
double
e
;
double
theta
;
};
struct
line
{
double
e
;
double
theta
;
double
i
;
double
phi
;
};
struct
cline
{
int
n
;
struct
point
C
;
double
phi
;
double
dl
;
double
z
;
double
dos
;
// distcosmo1 to redshift z
double
dl0s
;
// distcosmo2 between lens[0] and z
double
dlsds
;
// ratio of dl0s/dos
};
struct
pot
{
int
type
;
char
n
[
IDSIZE
];
struct
point
C
;
double
epot
;
double
emass
;
double
theta
;
double
phi
;
// triaxiality
double
sigma
;
double
rc
;
double
rckpc
;
double
rcut
;
double
rcutkpc
;
double
alpha
;
double
beta
;
double
rcslope
;
double
z
;
double
dlsds
;
/*ratio D(LS)/D(OS) angular distances*/
double
psicut
;
double
psimcut
;
double
psiccut
;
double
b0
;
double
masse
;
double
pmass
;
double
cr
;
double
ct
;
double
mag
;
double
lum
;
double
mtol
;
double
effradius
;
// double omegaM;
// double omegaX;
// double wX;
};
struct
ipot
{
int
pmax
;
int
map
;
int
map_z
;
int
lens
[
10
];
int
para
[
10
];
int
lens_z
[
10
];
int
para_z
[
10
];
int
zlim
[
2
];
int
extend
;
int
masse
;
};
struct
triplet
{
struct
point
a
;
struct
point
b
;
struct
point
c
;
};
struct
bitriplet
{
struct
triplet
i
;
struct
triplet
s
;
};
struct
chaine
{
struct
triplet
S
;
struct
triplet
I
;
struct
chaine
*
F
;
};
struct
arbre
{
struct
galaxie
*
N
;
struct
arbre
*
FG
;
struct
arbre
*
FD
;
};
struct
variation
{
struct
point
C
;
double
elip
;
double
theta
;
};
struct
pixlist
{
double
i
;
double
j
;
double
flux
;
};
struct
MCarlo
{
int
optMC
;
int
n_MonteCarlo
;
int
iterations
;
int
squares_par
;
int
tosses_sq
;
};
//velocity field
struct
vfield
{
double
vt
;
double
rt
;
struct
point
C
;
double
i
;
double
theta
;
double
lcent
;
double
sigma
;
int
profile
;
};
#endif
// if STRUCTURE_H
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