PRO dustem_fit_intensity_example,model=model $
                                ,sed_file=sed_file $
                                ,Nitermax=Nitermax $
                                ,postscript=postscript $
                                ,fits_save_and_restore=fits_save_and_restore $
                                 ,help=help $
                                 ,wait=wait $
                                 ,verbose=verbose

;+
; NAME:
;    dustem_fit_intensity_example  
;
; PURPOSE:
; This routine is an example of how to fit an observational SED
; (StokesI only) with DustEM and DustEMWrap. The objective is to
; illustrate how to use DustEMWrap and not to do science -- the fit
; obtained by running this example is likely to be poor.
;  
; For this example, the code uses the SED in the file example_SED_1.xcat,
; which is distributed in the Data/EXAMPLE_OBSDATA/ directory 
;
; The example SED has Stokes I photometric data points from
; IRAC, MIPS and IRAS. Examples illustrating running DustEMWrap to
; fit spectral data, polarisation data and extinction data
; are provided in other _example routines in the src/idl/
; directory. See the DustEMWrap User Guide for more information.
;
; CATEGORY:
;    DustEMWrap, Distributed, High-Level, User Example
;
; CALLING SEQUENCE:
;    dustem_fit_intensity_example[,model=][sed_file=][,postscript=][,Nitermax=][,fits_save_and_restore=][,/help,/wait,/verbose]
;
; INPUTS:
;    None
;
; OPTIONAL INPUT PARAMETERS:
;    None
;
; OUTPUTS:
;    None
;
; OPTIONAL OUTPUT PARAMETERS:
;    Plots, results structure in binary FITS table format
;
; ACCEPTED KEY-WORDS:
;    model = specifies the interstellar dust mixture used by DustEM
;           'MC10' model from Compiegne et al 2010 (default)
;           'DBP90' model from Desert et al 1990
;           'DL01' model from Draine & Li 2001
;           'WD01_RV5p5B' model from Weingartner & Draine 2002 with Rv=5.5
;           'DL07' model from Draine & Li 2007
;           'J13' model from Jones et al 2013, as updated in
;                 Koehler et al 2014
;           'G17_ModelA' model A from Guillet et al (2018). Includes
;                 polarisation. See Tables 2 and 3 of that paper for details.
;           'G17_ModelB' model B from Guillet et al (2018)
;           'G17_ModelC' model C from Guillet et al (2018)
;           'G17_ModelD' model A from Guillet et al (2018)
;    sed_file = string naming the path to text file in .xcat format that
;          describes the observational SED. If not set, the file
;          'Data/EXAMPLE_OBSDATA/example_SED_1.xcat' is used.  
;    postscript = if set, final plot is saved as postscript in the
;                 current working directory
;    Nitermax = maximum number of fit iterations. Default is 5.
;    fits_save_and_restore = if set, save the fit results in a binary
;               FITS file. The code then restore this file and plots
;               the results using the saved results information.
;    help      = if set, print this help
;    wait      = if set, wait this many seconds between each step of
;                the code (for illustration purposes)
;    verbose      = if set, subroutines will run in verbose mode
;
; COMMON BLOCKS:
;    None
;
; SIDE EFFECTS:
;    None
;
; RESTRICTIONS:
;    The DustEM fortran code must be installed
;    The DustEMWrap IDL code must be installed
;
; PROCEDURES AND SUBROUTINES USED:
;    *** COMMENT AH --> is this really NONE? ****
;
; EXAMPLES
;    dustem_fit_intensity_example
;    dustem_fit_intensity_example,Nitermax=1,fits_save_and_restore='/tmp/mysavefile.fits'
;    dustem_fit_intensity_example,model='DBP90'
;
; MODIFICATION HISTORY:
;    Written by JPB Apr-2011
;    Evolution details on the DustEMWrap gitlab.
;    See http://dustemwrap.irap.omp.eu/ for FAQ and help.  
;-

IF keyword_set(help) THEN BEGIN
  doc_library,'dustem_fit_intensity_example'
  goto,the_end
END

IF keyword_set(model) THEN BEGIN
  use_model=strupcase(model)
ENDIF ELSE BEGIN
  use_model='DBP90'    ;Default is the DBP90 model
ENDELSE

known_mdls=['MC10','DBP90','DL01','WD01_RV5P5B','DL07','J13','G17_MODELA','G17_MODELB','G17_MODELC','G17_MODELD'] 
test_model = where(known_mdls eq use_model,ct)
if ct eq 0 then begin
   message,'ISM dust model '+use_model+' unknown',/continue
   message,'Known models are MC10,DBP90,DL01,WD01_RV5P5B,DL07,J13,G17_MODELA,G17_MODELB,G17_MODELC,G17_MODELD',/continue
   stop
end


use_polarization=0   ; initialize Dustemwrap in no polarization mode 
use_window=2          ; default graphics window number to use for plotting the results
use_verbose=0
if keyword_set(verbose) then use_verbose=1
use_Nitermax=5        ; maximum number of iterations for the fit
IF keyword_set(Nitermax) THEN use_Nitermax=Nitermax

dustem_define_la_common

;=== Set the (model-dependent) parameters that you want to fit (pd),
;=== their initial values (iv)
;=== and whether they are bounded (ulimed,llimed,llims,ulims).
;=== Fixed parameters (fpd) and their values (fiv) are also set here.
;=== Refer to the DustEM and DustEMWrap User guides for an explanation
;=== of the physical meaning of dust model and plug-in parameters, and
;=== how to specify them.

;=== Examples are provided for some of the dust models. 
;=== To try them, uncomment the model that you want to try and re-run

;=== AN EXAMPLE FOR DBP90
;=== Here we fit the dust abundances of the DBP90 model, the
;=== intensity of the dust-heating radiation field as well as several plug-ins:
;=== (i) continuum due to a blackbody  
;=== (ii) free-free emission
;=== (iii) synchrotron emission
;=== The free parameters are all lower-bounded at zero.
;use_model='DBP90' ; you should specify this !
pd = [ $
     '(*!dustem_params).G0', $                           ;G0
     '(*!dustem_params).grains(0).mdust_o_mh',$          ;PAH0 mass fraction
     '(*!dustem_params).grains(1).mdust_o_mh',$          ;VSG mass fraction
     '(*!dustem_params).grains(2).mdust_o_mh', $         ;BG mass fraction
     'dustem_plugin_continuum_1', $                      ;Temperature of BB
     'dustem_plugin_continuum_2', $                      ;Intensity of BB continuum
     'dustem_plugin_freefree_1', $                       ;Ionized gas temperature
     'dustem_plugin_freefree_2', $                       ;Free-free amplitude
     'dustem_plugin_synchrotron_1', $                    ;Spectral index of CREs
     'dustem_plugin_synchrotron_2']                      ;Synchrotron amplitude at 10 mm

iv =   [1.0, 1.2e-4, 8.7e-4, 4.4e-4, 1000.,0.001,7500.,0.004, 2.7,0.01]
Npar=n_elements(pd)
ulimed=replicate(0,Npar)
llimed=replicate(1,Npar) 
llims=replicate(0.,Npar)
fpd=[] & fiv=[]


;; ;=== AN EXAMPLE FOR DL01 (or DL07 or WD01_RV5P5B)
;; ;=== Here we fit the dust abundances of the model. The
;; ;=== intensity of the dust-heating radiation field is fixed to 1.2*G0.
;; ;=== The free parameters are all lower-bounded at zero.
;; use_model='DL01' ; you should specify this !
;; pd = [ $
;;         '(*!dustem_params).grains(0).mdust_o_mh',$     ;PAH0 mass fraction
;;         '(*!dustem_params).grains(1).mdust_o_mh',$     ;PAH1 mass fraction
;;         '(*!dustem_params).grains(2).mdust_o_mh', $    ;Gra
;;         '(*!dustem_params).grains(3).mdust_o_mh', $    ;Gra
;;         '(*!dustem_params).grains(4).mdust_o_mh']      ;aSil
;;    iv =   [5.4e-4, 5.4e-4,1.8e-4,2.33e-3,8.27e-3]
;;    Npar=n_elements(pd)
;;    ulimed=replicate(0,Npar)
;;    llimed=replicate(1,Npar)
;;    llims=replicate(0.,Npar)
;;    fpd=['(*!dustem_params).G0']
;;    fiv=[1.2]


;; ;=== AN EXAMPLE FOR MC10
;; ;=== Here we fit the dust abundances of the MC10 model, the
;; ;=== intensity of the dust-heating radiation field as well as a plug-in:
;; ;===  (i) continuum due to a blackbody 
;; ;=== The intensity of the dust-heating radiation field is fixed to
;; ;=== 1.5*G0 and the tmperature of the blackbody is fixed to 1200K
;; ;=== The free parameters in the fit are lower-bounded at zero.
;; use_model='MC10' ; you should specify this !
   ;; pd = [ $
   ;;      '(*!dustem_params).grains(0).mdust_o_mh'$         ;PAH0 mass fraction
   ;;      ,'(*!dustem_params).grains(1).mdust_o_mh' $       ;PAH1 mass fraction
   ;;      ,'(*!dustem_params).grains(2).mdust_o_mh' $       ;amCBEx
   ;;      ,'(*!dustem_params).grains(3).mdust_o_mh' $       ;amCBEx
   ;;      ,'(*!dustem_params).grains(4).mdust_o_mh' $       ;aSilx
   ;;      ,'dustem_plugin_continuum_2' $                    ;Intensity at peak of the continuum
   ;;      ]
   ;; iv =   [ 7.8e-4, 7.8e-4, 1.65e-4, 1.45e-3, 6.7e-3, 0.003]
   ;; Npar=n_elements(pd)
   ;; ulimed=replicate(0,Npar)
   ;; llimed=replicate(1,Npar)
   ;; llims=replicate(0.,Npar)
   ;; fpd=[ $
   ;;     '(*!dustem_params).G0'   $ ; ISRF intensity (multiplicative factor x G0)
   ;;     ,'dustem_plugin_continuum_1' $ ;temperature of blackbody the produces the continuum 
   ;;     ]
   ;; fiv=[1.5, 1200.]

;; ;=== AN EXAMPLE FOR J13
;; ;=== Here we fit the dust abundances of the MC10 model, the
;; ;=== intensity of the dust-heating radiation field as well as two plug-ins:
;; ;=== (i) free-free emission
;; ;=== (ii)continuum due to a blackbody 
;; ;=== The temperature of the blackbody is fixed to 1000K
;; ;=== The free parameters in the fit are all lower-bounded at zero.
;; use_model='J13' ; you should specify this !
;; pd = [ $
;;      '(*!dustem_params).G0' $                                   ;G0
;;      ,'(*!dustem_params).grains(0).mdust_o_mh'$                  ;CM20 -- power law size distribution
;;      ,'(*!dustem_params).grains(1).mdust_o_mh'$                 ;CM20 -- logN size distribution
;;      ,'(*!dustem_params).grains(2).mdust_o_mh' $                ;aPyM5
;;      ,'(*!dustem_params).grains(3).mdust_o_mh' $                ;aOlM5
;;      ,'dustem_plugin_freefree_1' $                              ;ionized gas temperature
;;      ,'dustem_plugin_freefree_2' $                              ;free-free amplitude
;;      ,'dustem_plugin_continuum_2']                              ;Intensity at peak of the BB continuum
;; iv =   [1.2,1.7e-3, 6.3e-4, 2.55e-3, 2.55e-3, 7500., 0.4, 0.001]         
;; Npar=n_elements(pd)
;; ulimed=replicate(0,Npar)
;; llimed=replicate(1,Npar)
;; llims=replicate(0.,Npar)
;; fpd=[ $
;;     'dustem_plugin_continuum_2'] ; Temperature of the BB
;; fiv=[1000.]                       


Nfix=n_elements(fpd)
if n_elements(fiv) ne Nfix then begin
   message,'Number of fixed parameters (fpd) does not equal number of initial values of fixed parameters (fiv)',/info
   stop
end

if keyword_set(wait) then begin
   message,'Finished setting dust model and plug-in parameters: '+use_model,/info
   wait,wait
end

;== INITIALISE DUSTEM
dustem_init,model=use_model,polarization=use_polarization
!dustem_nocatch=1
!dustem_verbose=use_verbose
!dustem_show_plot=1


;=== READ EXAMPLE SED DATA
dir=!dustem_wrap_soft_dir+'/Data/EXAMPLE_OBSDATA/'
file=dir+'example_SED_1.xcat'
IF keyword_set(sed_file) THEN file=sed_file
sed=read_xcat(file,/silent)

if keyword_set(wait) then begin
   message,'Finished reading SED data: '+file,/info
   wait,wait
end

;;=== ADJUST THE UNCERTAINTIES (FOR ILLUSTRATION)
ind=where(sed.sigmaII LT (0.2*sed.StokesI)^2,count)
IF count NE 0 THEN sed[ind].sigmaII=(0.2*sed[ind].StokesI)^2

;== SET THE OBSERVATIONAL STRUCTURE
;== sed is passed twice -- the first occurrence is the SED that you
;== wish to fit, the second occurrence is the SED that you wish to visualise. 
dustem_set_data,sed,sed

;== SET INITIAL VALUES AND LIMITS OF THE PARAMETERS THAT WILL BE
;== ADJUSTED DURING THE FIT
dustem_init_parinfo,pd,iv,up_limited=ulimed,lo_limited=llimed,up_limits=ulims,lo_limits=llims

;== INITIALIZE ANY PLUGINS
dustem_init_plugins,pd,fpd 

;== INITIALIZE ANY FIXED PARAMETERS FOR PLUGINS
if Nfix gt 0 then dustem_init_fixed_params,fpd,fiv

if keyword_set(wait) then begin
   message,'Finished initializing DustEMWrap, including plugins and fixed parameters',/info
   wait,wait
end

;=== INFORMATION TO RUN THE FIT
tol=1.e-16     ;fit tolerence

;=== INFORMATION TO MAKE THE PLOT
yr=[1.00e-4,1.00E2] ; y-axis limits
xr=[1.00E0,6.00e4] ; x-axis limits
tit='FIT INTENSITY EXAMPLE' ; plot title
ytit=textoidl('I_\nu (MJy/sr) for N_H=10^{20} H/cm^2') ; y-axis title
xtit=textoidl('\lambda (\mum)') ; x-axis title

;===  RUN THE FIT
t1=systime(0,/sec)
res=dustem_mpfit_data(tol=tol,Nitermax=use_Nitermax,gtol=gtol $
                      ,/xlog,/ylog,xr=xr,yr=yr,xtit=xtit,ytit=ytit,title=tit $
                      ,legend_xpos=legend_xpos,legend_ypos=legend_ypos $
                      ,errors=errors,chi2=chi2,rchi2=rchi2)
t2=systime(0,/sec)

if keyword_set(wait) then begin
   message,'Finished running DustEMWrap, using Niters: '+strtrim(string(use_Nitermax),2),/info
   message,'Time taken [sec]: '+sigfig(t2-t1,2,/sci),/info
   wait,wait
end

;=== MAKE THE FINAL PLOT
IF keyword_set(postscript) THEN BEGIN
    dir_ps='./'
    set_plot,'PS'
    ps_file=dir_ps+postscript
    device,filename=ps_file,/color
ENDIF
dustemwrap_plot,*(*!dustem_fit).CURRENT_PARAM_VALUES,dummy,xr=xr,/xstyle,yr=yr,/ysty,/ylog,/xlog,title=tit+' (Final fit)'
IF keyword_set(postscript) THEN BEGIN
  set_plot,'X'
  device,/close
  message,'Wrote '+ps_file,/info
ENDIF

if keyword_set(wait) then begin
   message,'Made the plot of the final results',/info
   wait,wait
end

IF keyword_set(fits_save_and_restore) THEN BEGIN
   message,'Writing out results structure: '+fits_save_and_restore,/info
   dustem_write_fits_table,filename=fits_save_and_restore,help=help
;=== At this point, you could erase all dustem system variables, or exit idl... all the
;=== information needed to recover the results and remake the plots has been saved in the FITS table
  dustem_read_fits_table,filename=fits_save_and_restore,dustem_spectra_st=dustem_spectra_st
  ;==== plot result taken from the saved fits table
  res=*(*!dustem_fit).CURRENT_PARAM_VALUES
  dustemwrap_plot,res,dustem_spectra_st,xr=xr,/xstyle,yr=yr,/ysty,/ylog,/xlog,title=tit+' (From Saved FITS file)'
  if keyword_set(wait) then begin
     message,'Saved the results as FITS in the file: '+fits_save_and_restore+', and made a plot using the data in this file',/info
     wait,wait
  end
ENDIF

message,'Finished dustem_fit_intensity_example',/info

stop

the_end:

END