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R1448 Lenstool-HPC
main.cpp
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/**
* @file main.cpp
* @Author Christoph Schaaefer, EPFL (christophernstrerne.schaefer@epfl.ch)
* @date October 2016
* @brief Benchmark for gradhalo function
*/
#include <iostream>
#include <iomanip>
#include <string.h>
#include <math.h>
#include <sys/time.h>
#include <fstream>
#include <sys/stat.h>
#include <unistd.h>
//
//#include <mm_malloc.h>
#include <omp.h>
//
//#include <cuda_runtime.h>
#include <structure_hpc.hpp>
//#include <cuda.h>
#include "timer.h"
#include "gradient.hpp"
#include "gradient2.hpp"
#include "chi_CPU.hpp"
#include "module_cosmodistances.hpp"
#include "module_readParameters.hpp"
#include "grid_gradient2_CPU.hpp"
#include "grid_amplif_CPU.hpp"
#include "module_writeFits.hpp"
#ifdef __WITH_GPU
#include "grid_gradient_GPU.cuh"
#include "grid_map_GPU.cuh"
#include "grid_gradient2_GPU.cuh"
//#include "gradient_GPU.cuh"
#endif
#ifdef __WITH_LENSTOOL
//#include "setup.hpp"
#warning "linking with libtool..."
#include<fonction.h>
#include<constant.h>
#include<dimension.h>
#include<structure.h>
#include<lt.h>
#include <stdlib.h>
//
//
struct
g_mode
M
;
struct
g_pot
P
[
NPOTFILE
];
struct
g_pixel
imFrame
,
wFrame
,
ps
,
PSF
;
struct
g_cube
cubeFrame
;
struct
g_dyn
Dy
;
// //TV
//
struct
g_source
S
;
struct
g_image
I
;
struct
g_grille
G
;
struct
g_msgrid
H
;
// multi-scale grid
struct
g_frame
F
;
struct
g_large
L
;
struct
g_cosmo
C
;
struct
g_cline
CL
;
struct
g_observ
O
;
struct
pot
lens
[
NLMAX
];
struct
pot
lmin
[
NLMAX
],
lmax
[
NLMAX
],
prec
[
NLMAX
];
struct
g_cosmo
clmin
,
clmax
;
/*cosmological limits*/
struct
galaxie
smin
[
NFMAX
],
smax
[
NFMAX
];
// limits on source parameters
struct
ipot
ip
;
struct
MCarlo
mc
;
struct
vfield
vf
;
struct
vfield
vfmin
,
vfmax
;
// limits on velocity field parameters
struct
cline
cl
[
NIMAX
];
lensdata
*
lens_table
;
//
int
block
[
NLMAX
][
NPAMAX
];
/*switch for the lens optimisation*/
int
cblock
[
NPAMAX
];
/*switch for the cosmological optimisation*/
int
sblock
[
NFMAX
][
NPAMAX
];
/*switch for the source parameters*/
int
vfblock
[
NPAMAX
];
/*switch for the velocity field parameters*/
double
excu
[
NLMAX
][
NPAMAX
];
double
excd
[
NLMAX
][
NPAMAX
];
/* supplments tableaux de valeurs pour fonctions g pour Einasto
* * Ce sont trois variables globales qu'on pourra utiliser dans toutes les fonctions du projet
* */
#define CMAX 20
#define LMAX 80
float
Tab1
[
LMAX
][
CMAX
];
float
Tab2
[
LMAX
][
CMAX
];
float
Tab3
[
LMAX
][
CMAX
];
int
nrline
,
ntline
,
flagr
,
flagt
;
long
int
narclet
;
struct
point
gimage
[
NGGMAX
][
NGGMAX
],
gsource_global
[
NGGMAX
][
NGGMAX
];
struct
biline
radial
[
NMAX
],
tangent
[
NMAX
];
struct
galaxie
arclet
[
NAMAX
],
source
[
NFMAX
],
image
[
NFMAX
][
NIMAX
];
struct
galaxie
cimage
[
NFMAX
];
struct
pointgal
gianti
[
NPMAX
][
NIMAX
];
struct
point
SC
;
double
elix
;
double
alpha_e
;
double
*
v_xx
;
double
*
v_yy
;
double
**
map_p
;
double
**
tmp_p
;
double
**
map_axx
;
double
**
map_ayy
;
#endif
void
gradient_grid_GPU_sorted
(
type_t
*
grid_grad_x
,
type_t
*
grid_grad_y
,
const
struct
grid_param
*
frame
,
const
struct
Potential_SOA
*
lens
,
int
Nlens
,
int
nbgridcells
);
//
//
int
module_readCheckInput_readInput
(
int
argc
,
char
*
argv
[],
std
::
string
*
outdir
)
{
/// check if there is a correct number of arguments, and store the name of the input file in infile
char
*
infile
;
struct
stat
file_stat
;
// If we do not have 3 arguments, stop
if
(
argc
!=
3
)
{
fprintf
(
stderr
,
"
\n
Unexpected number of arguments
\n
"
);
fprintf
(
stderr
,
"
\n
USAGE:
\n
"
);
fprintf
(
stderr
,
"lenstool input_file output_directorypath [-n]
\n\n
"
);
exit
(
-
1
);
}
else
if
(
argc
==
3
)
infile
=
argv
[
1
];
std
::
ifstream
ifile
(
infile
,
std
::
ifstream
::
in
);
// Open the file
int
ts
=
(
int
)
time
(
NULL
);
char
buffer
[
10
];
std
::
stringstream
ss
;
ss
<<
ts
;
std
::
string
trimstamp
=
ss
.
str
();
//
//std::string outdir = argv[2];
*
outdir
=
argv
[
2
];
*
outdir
+=
"-"
;
*
outdir
+=
trimstamp
;
std
::
cout
<<
*
outdir
<<
std
::
endl
;
// check whether the output directory already exists
if
(
stat
(
outdir
->
c_str
(),
&
file_stat
)
<
0
){
mkdir
(
outdir
->
c_str
(),
S_IRUSR
|
S_IWUSR
|
S_IXUSR
|
S_IRGRP
|
S_IWGRP
|
S_IXGRP
|
S_IROTH
);
}
else
{
printf
(
"Error : Directory %s already exists. Specify a non existing directory.
\n
"
,
argv
[
2
]);
exit
(
-
1
);
}
// check whether the input file exists. If it could not be opened (ifile = 0), it does not exist
if
(
ifile
){
ifile
.
close
();
}
else
{
printf
(
"The file %s does not exist, please specify a valid file name
\n
"
,
infile
);
exit
(
-
1
);
}
return
0
;
}
//
//
//
int
main
(
int
argc
,
char
*
argv
[])
{
//
// Setting Up the problem
//
// This module function reads the terminal input when calling LENSTOOL and checks that it is correct
// Otherwise it exits LENSTOOL
//
char
cwd
[
1024
];
if
(
getcwd
(
cwd
,
sizeof
(
cwd
))
!=
NULL
)
fprintf
(
stdout
,
"Current working dir: %s
\n
"
,
cwd
);
//
std
::
string
path
;
module_readCheckInput_readInput
(
argc
,
argv
,
&
path
);
//
// This module function reads the cosmology parameters from the parameter file
// Input: struct cosmologicalparameters cosmology, parameter file
// Output: Initialized cosmology struct
cosmo_param
cosmology
;
// Cosmology struct to store the cosmology data from the file
std
::
string
inputFile
=
argv
[
1
];
// Input file
module_readParameters_readCosmology
(
inputFile
,
cosmology
);
//
// This module function reads the runmode paragraph and the number of sources, arclets, etc. in the parameter file.
// The runmode_param stores the information of what exactly the user wants to do with lenstool.
struct
runmode_param
runmode
;
module_readParameters_readRunmode
(
inputFile
,
&
runmode
);
module_readParameters_debug_cosmology
(
runmode
.
debug
,
cosmology
);
module_readParameters_debug_runmode
(
1
,
runmode
);
//
//=== Declaring variables
//
struct
grid_param
frame
;
struct
galaxy
images
[
runmode
.
nimagestot
];
struct
galaxy
sources
[
runmode
.
nsets
];
struct
Potential
lenses
[
runmode
.
nhalos
+
runmode
.
npotfile
-
1
];
struct
Potential_SOA
lenses_SOA_table
[
NTYPES
];
struct
Potential_SOA
lenses_SOA
;
struct
cline_param
cline
;
struct
potfile_param
potfile
;
struct
Potential
potfilepotentials
[
runmode
.
npotfile
];
struct
potentialoptimization
host_potentialoptimization
[
runmode
.
nhalos
];
int
nImagesSet
[
runmode
.
nsets
];
// Contains the number of images in each set of images
//Bayesmap specific variables
type_t
*
bayespot
;
int
nparam
,
nvalues
;
// This module function reads in the potential form and its parameters (e.g. NFW)
// Input: input file
// Output: Potentials and its parameters
module_readParameters_PotentialSOA_direct
(
inputFile
,
&
lenses_SOA
,
runmode
.
nhalos
,
runmode
.
npotfile
,
cosmology
);
module_readParameters_debug_potential_SOA
(
0
,
lenses_SOA
,
runmode
.
nhalos
);
module_readParameters_limit
(
inputFile
,
host_potentialoptimization
,
runmode
.
nhalos
);
module_readParameters_debug_limit
(
0
,
host_potentialoptimization
[
0
]);
if
(
runmode
.
potfile
==
1
)
{
module_readParameters_readpotfiles_param
(
inputFile
,
&
potfile
,
cosmology
);
module_readParameters_debug_potfileparam
(
1
,
&
potfile
);
module_readParameters_readpotfiles_SOA
(
&
runmode
,
&
cosmology
,
&
potfile
,
&
lenses_SOA
);
module_readParameters_debug_potential_SOA
(
1
,
lenses_SOA
,
runmode
.
nhalos
+
runmode
.
npotfile
);
}
// This module function reads in the grid form and its parameters
// Input: input file
// Output: grid and its parameters
//
module_readParameters_Grid
(
inputFile
,
&
frame
);
//std::cerr <<frame.xmin <<std::endl;
//
std
::
cout
<<
"--------------------------"
<<
std
::
endl
<<
std
::
endl
;
fflush
(
stdout
);
//
double
t_lt
,
t_lt_total
;
int
turn
=
0
;
#if 0
//#ifdef __WITH_LENSTOOL
double **array; // contains the bayes.dat data
int nParam;
long int iVal, nVal; // size of array
char fname[50]; // <map><ival>.fits
char fname2[50]; // <map><ival>.fits
FILE *pFile;
int i;
double *index; // list of bayes.dat lines
int seed; // random seed
int tmp;
printf("Setting up lenstool using %d lenses...", runmode.nhalos+runmode.npotfile); fflush(stdout);
//convert_to_LT(&lenses_SOA, runmode.nhalos+runmode.npotfile);
// Read the .par file
init_grille("m1931.par", 1);
// remove the .fits extension tcpo filename
if( M.imass ) M.massfile[strlen(M.massfile)-5]=0;
if( M.ishear ) M.shearfile[strlen(M.shearfile)-5]=0;
if( M.iampli ) M.amplifile[strlen(M.amplifile)-5]=0;
if( M.idpl )
{
M.dplxfile[strlen(M.dplxfile)-5]=0;
M.dplyfile[strlen(M.dplyfile)-5]=0;
}
if( M.pixel ) M.pixelfile[strlen(M.pixelfile)-5]=0;
if( M.iclean ) ps.pixfile[strlen(ps.pixfile)-5]=0;
// Read catalog of multiple images
readConstraints();
// Initialise the grid
if( G.pol != 0 )
gridp();
else
grid();
// Switch to silent mode
M.verbose = 0;
printf("ok\n");
std::cerr << " Read Bayes models" << std::endl;
// Read the bayes.dat file
array = readBayesModels(&nParam, &nVal);
if( array == NULL )
{
fprintf(stderr, "ERROR: bayes.dat file not found\n");
return -1;
}
// Create the ./tmp directory
i = system("mkdir -p tmp");
// Prepare the index list
index = (double *) malloc((unsigned) nVal*sizeof(double));
for( i = 0 ; i < nVal ; i++ ) index[i]=i;
seed = -2;
std::cerr << " Finished setting up" << std::endl;
//Defining maps
int ampli = 1;
t_lt_total = -myseconds();
// Loop over each line
for( i = 0; i < nVal && i < 2000; i++ )
{
// Randomly draw a line from index array
tmp = (int) floor(d_random(&seed) * (nVal - i));
iVal = index[i+tmp];
// and swap the indexes in the index list
index[i+tmp] = index[i];
// Set the lens parameters from <array>
setBayesModel( iVal, nVal, array );
if( M.iampli != 0 )
{
sprintf( fname, "tmp/%s%ld.fits","Amplif_", iVal );
printf("INFO: Compute file %d/%ld : %s [CTRL-C to interrupt]\n",i+1, nVal,fname);
fflush(stdout);
pFile = fopen( fname, "r" );
if( pFile == NULL )
{
pFile = fopen( fname, "w");
fprintf( pFile, "busy\n" );
fclose(pFile);
std::cerr << runmode.amplif<< runmode.amplif_gridcells<< runmode.z_amplif << std::endl;
t_lt = -myseconds();
g_ampli( M.iampli, M.nampli, M.zampli, fname );
//g_ampli( runmode.amplif, runmode.amplif_gridcells, runmode.z_amplif, fname );
t_lt += myseconds();
//
turn += 1;
std::cout << " Time = " << std::setprecision(15) << t_lt << " " << turn <<std::endl;
}
else
fclose(pFile);
}
}
t_lt_total += myseconds();
#endif
#ifdef __WITH_GPU
double
t_1
,
t_2
;
struct
matrix
*
grid_gradient2_cpu
;
grid_gradient2_cpu
=
(
struct
matrix
*
)
malloc
((
int
)
(
runmode
.
amplif_gridcells
)
*
(
runmode
.
amplif_gridcells
)
*
sizeof
(
struct
matrix
));
// Bayes Map specific functions
////read bayes lines
module_readParameters_preparebayes
(
nparam
,
nvalues
);
//
bayespot
=
(
type_t
*
)
malloc
((
int
)
(
nparam
)
*
(
nvalues
)
*
sizeof
(
type_t
));
module_readParameters_bayesmodels
(
bayespot
,
nparam
,
nvalues
);
////read bayes lines
//
t_1
=
-
myseconds
();
for
(
int
ii
=
0
;
ii
<
nvalues
;
ii
++
){
////set bayes potential
module_readParameters_setbayesmapmodels
(
&
runmode
,
&
cosmology
,
host_potentialoptimization
,
&
potfile
,
&
lenses_SOA
,
bayespot
,
nparam
,
ii
);
module_readParameters_debug_potential_SOA
(
0
,
lenses_SOA
,
runmode
.
nhalos
+
runmode
.
npotfile
);
////calculate maps
std
::
cout
<<
" GPU launching for map "
<<
ii
<<
std
::
endl
;
//Chrono(opt)
t_2
=
-
myseconds
();
if
(
runmode
.
amplif
>
0
){
//Allocation
type_t
*
ampli_GPU
=
(
type_t
*
)
malloc
((
int
)
(
runmode
.
amplif_gridcells
)
*
(
runmode
.
amplif_gridcells
)
*
sizeof
(
type_t
));
//Init
memset
(
ampli_GPU
,
0
,
(
runmode
.
amplif_gridcells
)
*
(
runmode
.
amplif_gridcells
)
*
sizeof
(
type_t
));
//Choosing Function definition
map_gpu_function_t
map_gpu_func
;
map_gpu_func
=
select_map_function
(
"ampli"
,
&
runmode
);
//calculating map using defined function
map_grid_GPU
(
map_gpu_func
,
ampli_GPU
,
&
cosmology
,
&
frame
,
&
lenses_SOA
,
runmode
.
nhalos
+
runmode
.
npotfile
,
runmode
.
amplif_gridcells
,
runmode
.
amplif
,
runmode
.
z_amplif
);
//writing
module_writeFits
(
path
,
runmode
.
amplif_name
,
ii
,
ampli_GPU
,
&
runmode
,
&
frame
,
runmode
.
ref_ra
,
runmode
.
ref_dec
);
//std::cerr << "**" << ampli_GPU[0] << std::endl;
free
(
ampli_GPU
);
}
//
t_2
+=
myseconds
();
std
::
cout
<<
" Time "
<<
std
::
setprecision
(
15
)
<<
t_2
<<
std
::
endl
;
}
t_1
+=
myseconds
();
std
::
cout
<<
"Lenstool Total Time "
<<
std
::
setprecision
(
15
)
<<
t_lt_total
<<
std
::
endl
;
std
::
cout
<<
"HPC Total Time "
<<
std
::
setprecision
(
15
)
<<
t_1
<<
std
::
endl
;
#endif
}
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