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# Copyright(c) 1986 Association of Universities for Research in Astronomy Inc.
include <math/curfit.h>
include "icfit.h"
include "names.h"
# IC_FVSHOW -- Show fit parameters in verbose mode.
procedure ic_fvshow$t (ic, cv, x, y, wts, npts, fd)
pointer ic # ICFIT pointer
pointer cv # Curfit pointer
PIXEL x[ARB] # Ordinates
PIXEL y[ARB] # Abscissas
PIXEL wts[ARB] # Weights
int npts # Number of data points
int fd # Output descriptor
int i, n, deleted, ncoeffs
PIXEL chisqr, rms
pointer sp, fit, wts1, coeffs, errors
int $tcvstati()
PIXEL ic_rms$t()
begin
# Do the standard ic_show option, then add on the verbose part.
call ic_fshow (ic, fd)
if (npts == 0) {
call eprintf ("# Incomplete output - no data points for fit\n")
return
}
# Determine the number of coefficients and allocate memory.
ncoeffs = $tcvstati (cv, CVNCOEFF)
call smark (sp)
call salloc (coeffs, ncoeffs, TY_PIXEL)
call salloc (errors, ncoeffs, TY_PIXEL)
if (npts == IC_NFIT(ic)) {
# Allocate memory for the fit.
n = npts
call salloc (fit, n, TY_PIXEL)
call salloc (wts1, n, TY_PIXEL)
# Eliminate rejected points and count deleted points.
call amov$t (wts, Mem$t[wts1], n)
if (IC_NREJECT(ic) > 0) {
do i = 1, npts {
if (Memi[IC_REJPTS(ic)+i-1] == YES)
Mem$t[wts1+i-1] = 0.
}
}
deleted = 0
do i = 1, n {
if (wts[i] == 0.)
deleted = deleted + 1
}
# Get the coefficients and compute the errors.
call $tcvvector (cv, x, Mem$t[fit], n)
call $tcvcoeff (cv, Mem$t[coeffs], ncoeffs)
call $tcverrors (cv, y, Mem$t[wts1], Mem$t[fit], n, chisqr,
Mem$t[errors])
rms = ic_rms$t (x, y, Mem$t[fit], Mem$t[wts1], n)
} else {
# Allocate memory for the fit.
n = IC_NFIT(ic)
call salloc (fit, n, TY_PIXEL)
call salloc (wts1, n, TY_PIXEL)
# Eliminate rejected points and count deleted points.
call amov$t (Mem$t[IC_WTSFIT(ic)], Mem$t[wts1], n)
if (IC_NREJECT(ic) > 0) {
do i = 1, npts {
if (Memi[IC_REJPTS(ic)+i-1] == YES)
Mem$t[wts1+i-1] = 0.
}
}
deleted = 0
do i = 1, n {
if (wts[i] == 0.)
deleted = deleted + 1
}
# Get the coefficients and compute the errors.
call $tcvvector (cv, Mem$t[IC_XFIT(ic)], Mem$t[fit], n)
rms = ic_rms$t (Mem$t[IC_XFIT(ic)], Mem$t[IC_YFIT(ic)],
Mem$t[fit], Mem$t[wts1], n)
call $tcvcoeff (cv, Mem$t[coeffs], ncoeffs)
call $tcverrors (cv, Mem$t[IC_YFIT(ic)], Mem$t[wts1], Mem$t[fit],
n, chisqr, Mem$t[errors])
}
# Print the error analysis.
call fprintf (fd, "# total points = %d\n# sample points = %d\n")
call pargi (npts)
call pargi (n)
call fprintf (fd, "# nrejected = %d\n# deleted = %d\n")
call pargi (IC_NREJECT(ic))
call pargi (deleted)
call fprintf (fd, "# RMS = %10.7g\n")
call parg$t (rms)
call fprintf (fd, "# square root of reduced chi square = %10.7g\n")
call parg$t (sqrt (chisqr))
call fprintf (fd, "# \t coefficent\t error\n")
do i = 1, ncoeffs {
call fprintf (fd, "# \t%14.7e\t%14.7e\n")
call parg$t (Mem$t[coeffs+i-1])
call parg$t (Mem$t[errors+i-1])
}
# Free allocated memory.
call sfree (sp)
end
# IC_FXYSHOW -- List data as x, y, fit, weight lines on output.
procedure ic_fxyshow$t (ic, cv, x, y, w, npts, fd)
pointer ic # ICFIT pointer
pointer cv # Pointer to curfit structure
PIXEL x[npts] # Array of x data values
PIXEL y[npts] # Array of y data values
PIXEL w[npts] # Array of weight data values
int npts # Number of data values
int fd # Output file descriptor
int i
PIXEL $tcveval()
begin
# List the data being fit (not necessarily the input data).
call fprintf (fd, "# X Y Y FIT WEIGHT\n")
if (npts == IC_NFIT(ic)) {
do i = 1, npts {
call fprintf (fd, "%8g %8g %8g %8g\n")
call parg$t (x[i])
call parg$t (y[i])
call parg$t ($tcveval (cv, x[i]))
call parg$t (w[i])
}
} else {
do i = 1, IC_NFIT(ic) {
call fprintf (fd, "%8g %8g %8g %8g\n")
call parg$t (Mem$t[IC_XFIT(ic)+i-1])
call parg$t (Mem$t[IC_YFIT(ic)+i-1])
call parg$t ($tcveval (cv, Mem$t[IC_XFIT(ic)+i-1]))
call parg$t (Mem$t[IC_WTSFIT(ic)+i-1])
}
}
end
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