Chapters: 1: Introduction 2: Simple example 3: Invocation 4: Finer Control 5: X-Y Plots 6: Contour Plots 7: Image Plots 8: Examples 9: Gri Commands 10: Programming 11: Environment 12: Emacs Mode 13: History 14: Installation 15: Gri Bugs 16: Test Suite 17: Gri in Press 18: Acknowledgments 19: License Indices: Concepts Commands Variables |
9.3.33: The `
There are several varieties of ` |
`read colornames from RGB ["\filename"]' |
With no filename given, reads an X11-format `rgb.txt
' file that
is provided with gri. Otherwise, reads the named file and tries to
interpret it as an X11 file. The file format has 4 or more columns,
the first three giving the red, green and blue values in the range 0
to 255, and the last columns giving the colorname (which may have more
than one word). Once you have read in a colorname table, the named
colors may be used as builtin colors (see Set Color). To view the
names and RGB values of the colors Gri knows, including builtin ones
and ones from `read colornames
', use `show colornames
'.
This command is akin to `set colorname
' (see Set Colorname),
except that the latter uses the Gri notation of color constituents being
in the range from 0 to 1, whereas for `read colornames
' uses an
X11 database, so that the color constitutents range from 0 to 255.
read columns
'
`read columns ...' |
Read numbers into columns. These columns have predefined
meanings and names. For example, `read columns x y
' instructs Gri
to read data into columns called `x
' and `y
'; it is these data
that Gri will use if you tell it to `draw curve
'. Other columns
are: `z
', used for contouring a function `z=z(x,y)
';
`weight
', used for weighting data points; `u
' and `v
',
used for arrow (vector) plots.
If the keyword `appending
' is given as the last word on the
`read columns
' line, then the new data will be appended to any
existing columnar data; otherwise they will overwrite any existing data.
As a special case, if the `x
' column is not indicated
(e.g. `read columns y
') then Gri creates x-values automatically, in
the sequence 0, 1, 2, etc.
read columns x y
'
Read `x
' in column 1, `y
' in column 2 until blank-line found.
Only the first two numbers on each line will be read; any extra numbers
(or words) on the line will be ignored.
read columns * y * * x
'
Read `x
' in column 5, `y
' in column 2. The `*
' character
is a spacer. It instructs Gri to skip the first, third, and fourth
words on the data line. These words need not be numbers. This example
illustrates a general mechanism of using the `*
' character to skip
over unwanted items in the data file. Note that there is no need to
supply `*
' characters for trailing extraneous words; Gri will skip
them anywary. Finally, note that any order of `x
' and `y
'
(and the other columns; see below) is allowed.
read columns y=2 x=5
' or `read columns x=5 y=2
'
As above; read `x
' in column 5 and `y
' in column 2. The
column number may be specified in this manner for all the named column
variables. No spaces are allowed before or after the `=
' sign.
The first column is called column 1. Whether this format is used or the
`*
' format is a matter of choice, except that numbered format also
permits using a given number to fill several variables (for example
`read columns x=1 y=2 u=1 v=2
').
read columns x="netCDF_name" ...
'
If the file is a `netCDF
' file, opened
by e.g. `open myfile.nc netCDF
', then the `netCDF
' variables
for the columns, e.g.
open latlon.nc netCDF read columns x="longitude" y="latitude" |
Note: the data must be stored as the `netCDF
' ``float''
type.
For more information on netCDF format, see
`http://www.unidata.ucar.edu/packages/netcdf/index.html
'
here .
read columns * y z * x
'
Read `x
' in column 5, `y
' in column 2, and `z
' in column
3. The `z
' column is used for contouring.
read columns x y u v
'
Read `x
' and `y
' in first two columns, and the ``arrow'' data
`u
' and `v
' as third and fourth columns.
read columns .rows. x y
'
Read `.rows.
' rows of column data.
Sometimes you'll have `x
' in one file and `y
' in another. In
that case, use the operating system or an editor to put the columns in
one file. In unix, the easy way is
open "paste file_with_x file_with_y |" read columns x y |
NOTE FOR BINARY FILES: For ascii files, Gri will proceed to a new line
after it has read the items requested; it skips any words appearing on
the data line after the last object of interest. Thus
`read columns x y
' will read the first two columns and ignore any other
columns that might be present. But for binary files, Gri has no way of
knowing how to "skip" to the next line (see `skip
' command), so you
will have to flesh out the `read columns
' command with as many
spacers as are present in your data. For example, if you have four
numbers in each data record and want to interpret the first two as
`x
' and `y
', you would use `read columns x y * *
' to read
the data.
RETURN VALUE:
Sets `\.return_value
' to
`N rows N non-missing N inside-clip-region
'
read grid
'read grid
' commands read grid characteristics. (The ``grid'' is
the object that is contoured.)
For normal ascii or binary files, the commands to read the grid's x-locations, y-locations and data are:
`read grid x [.rows.]' `read grid y [.rows.]' `read grid data [spacers] \ [.rows. .cols.] [spacers] [bycolumns]' |
For `netCDF
' files, the commands are as follows (note that it is
not possible to specify the number of data to read, nor to read the grid
by columns).
`read grid x = "variable_name"' `read grid y = "variable_name"' `read grid data = "variable_name"' |
The ordering of the y-grid data is the same as if they were read from a normal file: the first number is considered to be at the top of the plot.
For more information on netCDF format, see
`http://www.unidata.ucar.edu/packages/netcdf/index.html
'
here .
Details of the non-netCDF commands:
read grid x [.cols.]
'
Read the `x
' locations of the grid points, one number per line.
If `.cols.
' is supplied, then that many values will be read;
otherwise, reading will stop at end-of-file or blank-line.
read grid y [.rows.]
'
As above, but for y grid; `.rows.
' is the number of rows. The
first number to be read corresponds to the location of the top
edge of the grid. Thus, if you were to view the column of numbers with
a text editor, they would be oriented the same way as the corresponding
elements will appear on the page.
read grid data [.rows. .cols.]
'
Read data for a grid having `.rows.
' and `.cols.
' columns.
(If `.rows.
' and `.cols.
' are not supplied, but the grid
already exists, then those pre-existing values are used. If they are
specified here, then they are checked for consistency with the
pre-existing values if they exist.) Gri will read `.rows.
' lines,
each containing `.cols.
' numbers. (Extra information in the file
can be skipped; see discussion of the `*
' keyword below.) Gri
will interpret the first line it reads as the grid data corresponding
to a value of y equal to `y[.rows.]
'. Thus, file should be
arranged like this:
f(x[1], y[.rows.]) ... f(x[.cols.], y[.rows.]) . . . f(x[1], y[3]) ... f(x[.cols], y[3]) f(x[1], y[2]) ... f(x[.cols], y[2]) f(x[1], y[1]) ... f(x[.cols], y[1]) |
read grid data [.rows. .cols.] bycolumns
'
As above, but the `bycolumns
' keyword tells Gri to read the data
one column at a time, instead of one row at a time. Each line is
expected to contain `.rows.
' numbers (as opposed to `.cols.
'
numbers, as in the format where the `bycolumns
' keyword is not
present). (Extra information in the file can be skipped; see
discussion of the `*
' keyword below). The first line of the data
file contains the first column of the gridded data, corresponding to x
equal to `x[1]
'). The file should look like this:
f(x[1], y[1]) ... f(x[1], y[.cols.]) f(x[2], y[1]) ... f(x[2], y[.cols.]) f(x[3], y[1]) ... f(x[3], y[.cols.]) . . . f(x[.rows.],y[1]) ... f(x[.rows.], y[.cols.]) |
read grid data * * [.rows. .cols.]
'
As `read grid data .rows. .cols.
' except that the first two words
on each line are skipped. As usual, trailing extraneous numbers are
also skipped.
See also `set x grid
', `set y grid
'
RETURN VALUE:
`read grid x
' sets `\.return_value
' to `N cols
'
`read grid y
' sets `\.return_value
' to `N rows
'
`read grid data
' sets `\.return_value
' to `N rows N cols
'
read image colorscale
'
`read image colorscale [rgb|hsb]' |
Read colorscale for image, from 256 lines each containing values for Red, Green, and Blue (or Hue, Saturation and Brightness), separated by whitespace. The values are expected to be in the range 0 to 1, and are clipped to these limits if not.
For hints on how to create such an input file, see Read Image Grayscale. If the example given there has the following code instead,
open "awk 'BEGIN { \ for(i=0;i<256;i++) { \ print((i - 50)/50, 1, 1) \ } \ }' |" read image colorscale hsb |
then a linear full-color spectrum running from red at 10C to magenta at 15C is achieved.
read image grayscale
'
`read image grayscale' |
Read grayscale for an image, from 256 lines each containing a
single value. The values are expected to be in the range 0 to 1, and
are clipped to these limits if not. For 8-bit images, Gri multiplies
these values by 255, and uses this list for the grayscale mapping. Such
a list is created by `write image grayscale
'.
As an example, consider the code fragment (see Images).
set image range 5 30.5 set image grayscale black 10 white 15 |
is equivalent to
set image range 5 30.5 open "awk 'BEGIN {\ for(i=0;i<256;i++) {\ print(1-(i-50)/50)\ } \ }' |" read image grayscale close |
because the image formula is
Temperature = 5C + 0.1C * pixelvalue
where the pixelvalue ranges from 0 to 255. Therefore, a temperature of
10C is a pixelvalue of 50, and 15C is 100. To get a grayscale ranging
between these values, therefore, we create a linear function which maps
the 50th pixelvalue into grayvalue 1, and the 100th pixelvalue into
grayvalue 0. That is what the awk line does; to see the actual numbers,
you could insert the line `write image grayscale to TMP
' and look at
the file `TMP' (bear in mind that Gri will clip the values to the
range 0 to 1).
Sometimes you will have a file, say named `map.dat', with RGB numbers in the range 0-255, rather than 0-1 as Gri requires. To read them, use the operating system to convert the numbers for you (see Open).
open "cat map.dat \ | awk '{print(($1+$2+$3)/3/255)}' |" read image grayscale close |
read image mask
'
`read image mask rasterfile|{.rows. .cols.}' |
Read image mask. The mask is associated with the image read in by the
`read image
' command in the following way. When computing image
histograms, Gri ignores any pixels in the image for which the
corresponding pixel in the mask is set to `1
'.
read image mask rasterfile
'
The image size is specified in the rasterfile file itself, so
it is not specified.
read image mask .rows. .cols.
'
The file must contain `.rows.*.cols.
' binary data. Pixel
order is the same as for images.
read image
'read image
' commands, depending on the
file format. If the file is "raw", with no embedded information about
things like the width and height, then we need to specify everything, as
in the first format given below. The other formats make use of the
header information in, e.g. PGM files.
Headerless images
`read image .rows. .cols. \ [box .xleft. .ybottom. .xright. .ytop.] \ [bycolumns]' |
With no options specified (`read image .rows. .cols.
'), read binary
data defining an `image
'. The image range must have previously
have been set by `set image range
'. The data are as written by
"unsigned char" format in C.
When the `box
' option is specified, the geometry of the image, in
user coordinates, is specified in terms of the cartesian coordinates of
the lower-left corner (`.xleft.
', `.ybottom.
') and upper-right
corner (`.xright.
', `.ytop.
'). If the `box
' option is not
specified, this geometry can be specified with either `read x grid
'
or `set x grid
', plus either `read y grid
' or
`set y grid
'.
With the `bycolumns
' keyword present, the image is read sweeping
from top-to-bottom, then left-to-right, instead of the usual order.
Sun rasterfile images
`read image rasterfile [box .xleft. .ybottom. .xright. .ytop.]' |
Read image in Sun rasterfile format. Image geometry is inferred from
the header, so `.rows.
' and `.cols
' parameters are not given.
PGM images
`read image pgm [box .xleft. .ybottom. .xright. .ytop.]' |
Read image in PGM (Portable Gray Map) format. Image geometry is
inferred from the header, so `.rows.
' and `.cols
' parameters
are not given. Both ascii and binary PGM formats are supported (that
is, files with magic characters of P2 and P5).
NOTE that there are many image formats and Gri doesn't try to deal with them all. The idea is to use another program to convert images to a file format that Gri understands. In the future Gri may support PNG and other popular formats, especially in the Linux versions, for which libraries exist to ease the input.
read from \filename
'
`read from \filename' |
Cause future `read
' commands to read from the indicated file. If
that file is not open, an error message will result. Use
`read from \filename
' to shuffle reading among several open files.
Gri can look up filenames for `read from
' in terms of their
full pathnames or their local pathnames. Thus, a local file
called `a.dat
' in the directory `/home/gri
' can be referred to
by `read from a.dat
' or by `read from /home/gri/a.dat
', which
comes in handy if you need to work with two files of the same name, in
other directories. However, since Gri has the ability to search for
files in a "path" (see Set Path To), you may not have specified an
exact path name; this is why the `open
' command provides a return
value which names the full pathname (see Opening Simple Files).
read
' synonym/variable
`read [* [*...]] \synonym|.variable. [\synonym|.variable. [...]]}' |
Read one or more items from the next line of the input file. These
items may be synonyms or variables. The token `*
' indicates
that the word in the datafile should be skipped. As usual, the datafile
may be embedded in the commandfile, providing the last data line is blank.
Normally one would use synonyms for words, and variables for numbers. The items are separated by one or more "whitespace" characters (e.g. space or TAB). Thus, if a file contained the line
Temperature 10.3 |
then the line
read \var_name .var_value. |
would have the same result as
\var_name = "Temperature" .var_value. = 10.3 |
This command ignores any trailing items on the line. That is, the next
`read
' command will start on the next line of the file. In a
sense then, you get just one shot at analysing the input line in your
datafile. If you need flexibility, you may wish to read the
whole contents of the line into a synonym, which may be done
using the `read line
' command instead, to read it in as a string.
(see Read Line).
If the input file is in the netCDF format, the
indicated item will be read. For example,
`read \time:_MissingValue
' reads the missing value for the variable
called `time
'. This conveniently allows your data file to dictate
axes names, units, missing values, etc. Example:
# Plot profile of TU81N (age-corrected tritium) open profile.nc netCDF read columns x="TU81N" y="z" read \{z:_FillValue} # assume same for all read \{z:long_name} read \{z:units} read \{TU81N:long_name} read \{TU81N:units} close set missing value \{z:_FillValue} set x name "\{TU81N:long_name} (\{TU81N:units)}" set y name "\{z:long_name} (\{z:units)}" set y axis decreasing draw curve |
For more information on netCDF format, see
`http://www.unidata.ucar.edu/packages/netcdf/index.html
'
here .
read line
'
`read line \synonym' |
Read the next line of the datafile (or commandfile), trim off a trailing comment if there is one, and then store the next line of datafile into the named synonym.