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# Copyright(c) 1986 Association of Universities for Research in Astronomy Inc.
# Simples IMIO test routines.
task mkimage = t_mkimage,
mktest = t_mktest,
cube = t_cube,
maxmin = t_maxmin,
gsubras = t_gsubras,
dump = t_dump
include <imhdr.h>
include <printf.h>
include <ctype.h>
include <mach.h>
define NTYPES 7
# MKIMAGE -- Make a new two dimensional image of a specified size
# and datatype. The image pixels are all set to zero.
procedure t_mkimage()
int dtype
real pixval
int ncols, nlines
char imname[SZ_FNAME]
char title[SZ_LINE]
short ty_code[NTYPES]
real clgetr()
char clgetc(), ch
int clgeti(), stridx()
string types "usilrdx" # Supported pixfile datatypes
data ty_code /TY_USHORT, TY_SHORT, TY_INT, TY_LONG, TY_REAL,
TY_DOUBLE, TY_COMPLEX/
begin
call clgstr ("image", imname, SZ_FNAME)
ncols = clgeti ("ncols")
nlines = clgeti ("nlines")
ch = clgetc ("datatype")
dtype = ty_code[stridx(ch,types)]
pixval = clgetr ("pixval")
call clgstr ("title", title, SZ_LINE)
call immake2 (imname, ncols, nlines, dtype, pixval, title)
end
# IMMAKE2 -- Make a two dimensional image of datatype [usilr] with all pixels
# set to the given value.
procedure immake2 (imname, ncols, nlines, dtype, pixval, title)
char imname[ARB] # name of new image
int ncols, nlines # image size
int dtype # datatype
real pixval # constant pixel value
char title[ARB] # image title
int i
pointer im, buf
pointer immap(), impl2r()
begin
im = immap (imname, NEW_IMAGE, 0)
IM_PIXTYPE(im) = dtype
IM_LEN(im,1) = ncols
IM_LEN(im,2) = nlines
call strcpy (title, IM_TITLE(im), SZ_IMTITLE)
# Write out the lines.
do i = 1, nlines {
buf = impl2r (im, i)
call amovkr (pixval, Memr[buf], ncols)
}
call imunmap (im)
end
# MKTEST -- Make a test image.
procedure t_mktest()
char imname[SZ_FNAME]
int ndim, dim[IM_MAXDIM]
int i, j, k, scalar
long offset
int clgeti(), nscan(), clscan(), stridx()
pointer buf, im, immap(), impl3l()
int dtype
string types "usilrdx" # Supported pixfile datatypes
char ty_code[7], clgetc()
data ty_code /TY_USHORT, TY_SHORT, TY_INT, TY_LONG, TY_REAL,
TY_DOUBLE, TY_COMPLEX, EOS/
begin
call clgstr ("image_name", imname, SZ_FNAME)
dtype = ty_code[stridx (clgetc ("datatype"), types)]
ndim = clgeti ("ndim")
call amovki (1, dim, 3)
if (clscan ("axis_lengths") != EOF) {
do i = 1, ndim
call gargi (dim[i])
if (nscan() < ndim)
call error (1, "Insufficient dimensions")
}
im = immap (imname, NEW_IMAGE, 0)
IM_PIXTYPE(im) = dtype
do i = 1, ndim
IM_LEN(im,i) = dim[i]
do k = 1, dim[3]
do j = 1, dim[2] {
buf = impl3l (im, j, k)
# Pixel value eq pixel coords.
offset = 1
if (ndim > 1) {
if (dim[1] < 100)
scalar = 100
else
scalar = 1000
offset = offset + j * scalar
}
if (ndim > 2)
offset = offset + k * (scalar ** 2)
# Avoid integer overflow if large type short image.
if (IM_PIXTYPE(im) == TY_SHORT)
offset = min (MAX_SHORT, offset - dim[1])
# Initialize line of pixels.
do i = 0, dim[1]-1
Meml[buf+i] = offset + i
}
call imunmap (im)
end
# CUBE -- Get a subraster from an image, and print out the pixel values
# on the standard output.
define MAXDIM 3
procedure t_cube()
char imname[SZ_FNAME], fmt
int i, nx, ny, nz, ndim
int vs[IM_MAXDIM], ve[IM_MAXDIM]
pointer im, ras, imgs3r(), immap()
int clscan(), nscan()
char clgetc()
begin
call clgstr ("image_name", imname, SZ_FNAME)
fmt = clgetc ("numeric_format")
im = immap (imname, READ_ONLY, 0)
# Get the coordinates of the subraster to be extracted. Determine
# dimensionality of subraster.
if (clscan ("subraster_coordinates") != EOF) {
for (ndim=1; ndim <= MAXDIM; ndim=ndim+1) {
switch (fmt) {
case FMT_DECIMAL:
call gargi (vs[ndim])
call gargi (ve[ndim])
case FMT_OCTAL:
call gargrad (vs[ndim], 8)
call gargrad (ve[ndim], 8)
case FMT_HEX:
call gargrad (vs[ndim], 16)
call gargrad (ve[ndim], 16)
}
if (nscan() < ndim * 2) {
ndim = nscan() / 2
break
}
}
}
if (ndim == 0)
return
for (i=ndim+1; i <= MAXDIM; i=i+1) {
vs[i] = 1
ve[i] = 1
}
# Extract subraster from image. Print table on the standard
# output.
ras = imgs3r (im, vs[1], ve[1], vs[2], ve[2], vs[3], ve[3])
call imbln3 (im, nx, ny, nz)
call print_cube (STDOUT, Memr[ras], nx, ny, nz, vs, ve, fmt)
call imunmap (im)
end
# PRINT_CUBE -- Print a cube of pixels of type REAL on a file.
procedure print_cube (fd, cube, nx, ny, nz, vs, ve, fmt)
char fmt
int fd, nx, ny, nz
real cube[nx,ny,nz]
int vs[MAXDIM], ve[MAXDIM], vinc[MAXDIM]
int i, j, k
errchk fprintf, pargi, pargr
begin
do i = 1, MAXDIM # loop increments
if (vs[i] <= ve[i])
vinc[i] = 1
else
vinc[i] = -1
# Print table of pixel values on the standard output. Label bands,
# lines, and columns.
do k = 1, nz {
call fprintf (fd, "Band %0.0*:\n")
call pargc (fmt)
call pargi (vs[MAXDIM] + (k-1) * vinc[MAXDIM])
call fprintf (fd, "%9w")
do i = 1, nx { # label columns
call fprintf (fd, "%9* ")
call pargc (fmt)
call pargi (vs[1] + (i-1) * vinc[1])
}
call fprintf (fd, "\n")
do j = 1, ny {
call fprintf (fd, "%5* ")
call pargc (fmt)
call pargi (vs[2] + (j-1) * vinc[2])
do i = 1, nx { # print pixels
call fprintf (fd, "%12*")
call pargc (fmt)
call pargr (cube[i,j,k])
}
call fprintf (fd, "\n")
}
call fprintf (fd, "\n")
}
end
# MAXMIN -- Compute the minimum and maximum pixel values of an image.
# Works for images of any dimensionality, size, or datatype.
procedure t_maxmin()
char imname[SZ_FNAME]
real minval, maxval
long v[IM_MAXDIM], clktime()
pointer im, buf, immap(), imgnlr()
begin
call clgstr ("imname", imname, SZ_FNAME)
call amovkl (long(1), v, IM_MAXDIM) # start vector
im = immap (imname, READ_WRITE, 0)
# Only calculate minimum, maximum pixel values if the current
# values are unknown, or if the image was modified since the
# old values were computed.
if (IM_LIMTIME(im) < IM_MTIME(im)) {
IM_MIN(im) = MAX_REAL
IM_MAX(im) = -MAX_REAL
while (imgnlr (im, buf, v) != EOF) {
call alimr (Memr[buf], IM_LEN(im,1), minval, maxval)
IM_MIN(im) = min (IM_MIN(im), minval)
IM_MAX(im) = max (IM_MAX(im), maxval)
}
IM_LIMTIME(im) = clktime (long(0))
}
call clputr ("minval", IM_MIN(im))
call clputr ("maxval", IM_MAX(im))
call imunmap (im)
end
define MAXDIM 3
# GSUBRAS -- Get a type short subraster from an image, and print out the
# minimum and maximum pixel values on the standard output.
procedure t_gsubras()
char imname[SZ_FNAME], fmt
int i, nx, ny, nz, ndim
int vs[IM_MAXDIM], ve[IM_MAXDIM]
short minval, maxval
pointer im, ras
pointer imgs1s(), imgs2s(), imgs3s(), immap()
int clscan(), nscan()
char clgetc()
begin
call clgstr ("image_name", imname, SZ_FNAME)
fmt = clgetc ("numeric_format")
im = immap (imname, READ_ONLY, 0)
# Get the coordinates of the subraster to be extracted. Determine
# dimensionality of subraster.
if (clscan ("subraster_coordinates") != EOF) {
for (ndim=1; ndim <= MAXDIM; ndim=ndim+1) {
switch (fmt) {
case FMT_DECIMAL:
call gargi (vs[ndim])
call gargi (ve[ndim])
case FMT_OCTAL:
call gargrad (vs[ndim], 8)
call gargrad (ve[ndim], 8)
case FMT_HEX:
call gargrad (vs[ndim], 16)
call gargrad (ve[ndim], 16)
}
if (nscan() < ndim * 2) {
ndim = nscan() / 2
break
}
}
ndim = min (MAXDIM, ndim)
}
if (ndim == 0)
return
for (i=ndim+1; i <= MAXDIM; i=i+1) {
vs[i] = 1
ve[i] = 1
}
# Extract subraster from image. Print table on the standard
# output.
switch (ndim) {
case 1:
ras = imgs1s (im, vs[1], ve[1])
call imbln1 (im, nx)
ny = 1
nz = 1
case 2:
ras = imgs2s (im, vs[1], ve[1], vs[2], ve[2])
call imbln2 (im, nx, ny)
nz = 1
case 3:
ras = imgs3s (im, vs[1], ve[1], vs[2], ve[2], vs[3], ve[3])
call imbln3 (im, nx, ny, nz)
}
minval = MAX_SHORT
maxval = -MAX_SHORT
call alims (Mems[ras], nx * ny * nz, minval, maxval)
call printf ("min = %0.0*, max = %0.0*\n")
call pargc (fmt)
call pargs (minval)
call pargc (fmt)
call pargs (maxval)
call imunmap (im)
end
# DUMP -- Dump the user area of an image header for diagnostic purposes.
# Blanks are rendered into underscores to make them visible. This is a
# throwaway task.
procedure t_dump()
char image[SZ_FNAME]
int i
pointer ip, im
pointer immap()
begin
call clgstr ("image", image, SZ_FNAME)
im = immap (image, READ_ONLY, 0)
# Print ruler.
do i = 1, 80
if (mod(i,10) == 0)
call putci (STDOUT, TO_DIGIT(i/10))
else
call putci (STDOUT, ' ')
call putci (STDOUT, '\n')
do i = 1, 80
call putci (STDOUT, TO_DIGIT(mod(i,10)))
call putci (STDOUT, '\n')
# Map blanks into underscores.
for (ip = IM_USERAREA(im); Memc[ip] != EOS; ip=ip+1)
if (Memc[ip] == ' ')
Memc[ip] = '_'
# Dump user area.
call putline (STDOUT, Memc[IM_USERAREA(im)])
call imunmap (im)
end
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