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# Copyright(c) 1986 Association of Universities for Research in Astronomy Inc.
include <math/gsurfit.h>
# GS_DERPOLY -- Evaluate the new polynomial derivative surface.
procedure rgs_derpoly (coeff, x, y, zfit, npts, xterms, xorder, yorder, nxder,
nyder, k1x, k2x, k1y, k2y)
real coeff[ARB] # 1D array of coefficients
real x[npts] # x values of points to be evaluated
real y[npts]
real zfit[npts] # the fitted points
int npts # number of points to be evaluated
int xterms # cross terms ?
int xorder,yorder # order of the polynomials in x and y
int nxder,nyder # order of the derivatives in x and y
real k1x, k2x # normalizing constants
real k1y, k2y
int i, k, cptr, maxorder, xincr
pointer sp, xb, yb, xbptr, ybptr, accum
begin
# allocate temporary space for the basis functions
call smark (sp)
call salloc (xb, xorder * npts, TY_REAL)
call salloc (yb, yorder * npts, TY_REAL)
call salloc (accum, npts, TY_REAL)
# calculate basis functions
call rgs_dpol (x, npts, xorder, nxder, k1x, k2x, Memr[xb])
call rgs_dpol (y, npts, yorder, nyder, k1y, k2y, Memr[yb])
# accumulate the output vector
cptr = 0
call aclrr (zfit, npts)
if (xterms != GS_XNONE) {
maxorder = max (xorder + 1, yorder + 1)
xincr = xorder
ybptr = yb
do i = 1, yorder {
call aclrr (Memr[accum], npts)
xbptr = xb
do k = 1, xincr {
call awsur (Memr[accum], Memr[xbptr], Memr[accum], npts,
1.0, coeff[cptr+k])
xbptr = xbptr + npts
}
call gs_asumvpr (Memr[accum], Memr[ybptr], zfit, zfit, npts)
cptr = cptr + xincr
ybptr = ybptr + npts
switch (xterms) {
case GS_XHALF:
if ((i + xorder + 1) > maxorder)
xincr = xincr - 1
default:
;
}
}
} else {
call amulr (Memr[xb], Memr[yb], zfit, npts)
call amulkr (zfit, coeff[1], zfit, npts)
xbptr = xb + npts
do k = 1, xorder - 1 {
call awsur (zfit, Memr[xbptr], zfit, npts, 1.0, coeff[k+1])
xbptr = xbptr + npts
}
ybptr = yb + npts
do k = 1, yorder - 1 {
call awsur (zfit, Memr[ybptr], zfit, npts, 1.0, coeff[xorder+k])
ybptr = ybptr + npts
}
}
call sfree (sp)
end
# GS_DERCHEB -- Evaluate the new Chebyshev polynomial derivative surface.
procedure rgs_dercheb (coeff, x, y, zfit, npts, xterms, xorder, yorder,
nxder, nyder, k1x, k2x, k1y, k2y)
real coeff[ARB] # 1D array of coefficients
real x[npts] # x values of points to be evaluated
real y[npts]
real zfit[npts] # the fitted points
int npts # number of points to be evaluated
int xterms # cross terms ?
int xorder,yorder # order of the polynomials in x and y
int nxder,nyder # order of the derivatives in x and y
real k1x, k2x # normalizing constants
real k1y, k2y
int i, k, cptr, maxorder, xincr
pointer sp, xb, yb, xbptr, ybptr, accum
begin
# allocate temporary space for the basis functions
call smark (sp)
call salloc (xb, xorder * npts, TY_REAL)
call salloc (yb, yorder * npts, TY_REAL)
call salloc (accum, npts, TY_REAL)
# calculate basis functions
call rgs_dcheb (x, npts, xorder, nxder, k1x, k2x, Memr[xb])
call rgs_dcheb (y, npts, yorder, nyder, k1y, k2y, Memr[yb])
# accumulate thr output vector
cptr = 0
call aclrr (zfit, npts)
if (xterms != GS_XNONE) {
maxorder = max (xorder + 1, yorder + 1)
xincr = xorder
ybptr = yb
do i = 1, yorder {
call aclrr (Memr[accum], npts)
xbptr = xb
do k = 1, xincr {
call awsur (Memr[accum], Memr[xbptr], Memr[accum], npts,
1.0, coeff[cptr+k])
xbptr = xbptr + npts
}
call gs_asumvpr (Memr[accum], Memr[ybptr], zfit, zfit, npts)
cptr = cptr + xincr
ybptr = ybptr + npts
switch (xterms) {
case GS_XHALF:
if ((i + xorder + 1) > maxorder)
xincr = xincr - 1
default:
;
}
}
} else {
call amulr (Memr[xb], Memr[yb], zfit, npts)
call amulkr (zfit, coeff[1], zfit, npts)
xbptr = xb + npts
do k = 1, xorder - 1 {
call awsur (zfit, Memr[xbptr], zfit, npts, 1.0, coeff[k+1])
xbptr = xbptr + npts
}
ybptr = yb + npts
do k = 1, yorder - 1 {
call awsur (zfit, Memr[ybptr], zfit, npts, 1.0, coeff[xorder+k])
ybptr = ybptr + npts
}
}
# free temporary space
call sfree (sp)
end
# GS_DERLEG -- Evaluate the new Legendre polynomial derivative surface.
procedure rgs_derleg (coeff, x, y, zfit, npts, xterms, xorder, yorder,
nxder, nyder, k1x, k2x, k1y, k2y)
real coeff[ARB] # 1D array of coefficients
real x[npts] # x values of points to be evaluated
real y[npts]
real zfit[npts] # the fitted points
int npts # number of points to be evaluated
int xterms # cross terms ?
int xorder,yorder # order of the polynomials in x and y
int nxder,nyder # order of the derivatives in x and y
real k1x, k2x # normalizing constants
real k1y, k2y
int i, k, cptr, maxorder, xincr
pointer sp, xb, yb, accum, xbptr, ybptr
begin
# allocate temporary space for the basis functions
call smark (sp)
call salloc (xb, xorder * npts, TY_REAL)
call salloc (yb, yorder * npts, TY_REAL)
call salloc (accum, npts, TY_REAL)
# calculate basis functions
call rgs_dleg (x, npts, xorder, nxder, k1x, k2x, Memr[xb])
call rgs_dleg (y, npts, yorder, nyder, k1y, k2y, Memr[yb])
cptr = 0
call aclrr (zfit, npts)
if (xterms != GS_XNONE) {
maxorder = max (xorder + 1, yorder + 1)
xincr = xorder
ybptr = yb
do i = 1, yorder {
xbptr = xb
call aclrr (Memr[accum], npts)
do k = 1, xincr {
call awsur (Memr[accum], Memr[xbptr], Memr[accum], npts,
1.0, coeff[cptr+k])
xbptr = xbptr + npts
}
call gs_asumvpr (Memr[accum], Memr[ybptr], zfit, zfit, npts)
cptr = cptr + xincr
ybptr = ybptr + npts
switch (xterms) {
case GS_XHALF:
if ((i + xorder + 1) > maxorder)
xincr = xincr - 1
default:
;
}
}
} else {
call amulr (Memr[xb], Memr[yb], zfit, npts)
call amulkr (zfit, coeff[1], zfit, npts)
xbptr = xb + npts
do k = 1, xorder - 1 {
call awsur (zfit, Memr[xbptr], zfit, npts, 1.0, coeff[k+1])
xbptr = xbptr + npts
}
ybptr = yb + npts
do k = 1, yorder - 1 {
call awsur (zfit, Memr[ybptr], zfit, npts, 1.0, coeff[xorder+k])
ybptr = ybptr + npts
}
}
# free temporary space
call sfree (sp)
end
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