PGPLOT Subroutine Descriptions

Introduction

This appendix includes a list of all the PGPLOT subroutines, and then gives detailed instructions for the use of each routine in Fortran programs. The subroutine descriptions are in alphabetical order.

Arguments

The subroutine descriptions indicate the data type of each argument. When arguments are described as ``input'', they may be replaced with constants or expressions in the CALL statement, but make sure that the constant or expression has the correct data type.
INTEGER arguments:
these should be declared INTEGER or INTEGER*4 in the calling program, not INTEGER*2.
REAL arguments:
these should be declared REAL or REAL*4 in the calling program, not REAL*8 or DOUBLE PRECISION.
LOGICAL arguments:
these should be declared LOGICAL or LOGICAL*4 in the calling program.
CHARACTER arguments:
any valid Fortran CHARACTER variable may be used (declared CHARACTER*n for some integer n).

Index of Routines

Version 5.2


PGARRO -- draw an arrow

      SUBROUTINE PGARRO (X1, Y1, X2, Y2)
      REAL X1, Y1, X2, Y2

Draw an arrow from the point with world-coordinates (X1,Y1) to 
(X2,Y2). The size of the arrowhead at (X2,Y2) is determined by 
the current character size set by routine PGSCH. The default size 
is 1/40th of the smaller of the width or height of the view surface.
The appearance of the arrowhead (shape and solid or open) is
controlled by routine PGSAH.

Arguments:
 X1, Y1 (input)  : world coordinates of the tail of the arrow.
 X2, Y2 (input)  : world coordinates of the head of the arrow.

PGASK -- control new page prompting

      SUBROUTINE PGASK (FLAG)
      LOGICAL FLAG

Change the ``prompt state'' of PGPLOT. If the prompt state is
ON, PGPAGE will type ``Type RETURN for next page:'' and will wait
for the user to type a carriage-return before starting a new page.
The initial prompt state (after the device has been opened) is ON
for interactive devices. Prompt state is always OFF for
non-interactive devices.

Arguments:
 FLAG   (input)  : if .TRUE., and if the device is an interactive
                   device, the prompt state will be set to ON. If
                   .FALSE., the prompt state will be set to OFF.

PGAXIS -- draw an axis

      SUBROUTINE PGAXIS (OPT, X1, Y1, X2, Y2, V1, V2, STEP, NSUB,
     :                   DMAJL, DMAJR, FMIN, DISP, ORIENT)
      CHARACTER*(*) OPT
      REAL X1, Y1, X2, Y2, V1, V2, STEP, DMAJL, DMAJR, FMIN, DISP
      REAL ORIENT
      INTEGER NSUB

Draw a labelled graph axis from world-coordinate position (X1,Y1) to
(X2,Y2).

Normally, this routine draws a standard LINEAR axis with equal
subdivisions.   The quantity described by the axis runs from V1 to V2;
this may be, but need not be, the same as X or Y. 

If the 'L' option is specified, the routine draws a LOGARITHMIC axis.
In this case, the quantity described by the axis runs from 10**V1 to
10**V2. A logarithmic axis always has major, labeled, tick marks 
spaced by one or more decades. If the major tick marks are spaced
by one decade (as specified by the STEP argument), then minor
tick marks are placed at 2, 3, .., 9 times each power of 10;
otherwise minor tick marks are spaced by one decade. If the axis
spans less than two decades, numeric labels are placed at 1, 2, and
5 times each power of ten.

If the axis spans less than one decade, or if it spans many decades,
it is preferable to use a linear axis labeled with the logarithm of
the quantity of interest.

Arguments:
 OPT    (input)  : a string containing single-letter codes for
                   various options. The options currently
                   recognized are:
                   L : draw a logarithmic axis
                   N : write numeric labels
                   1 : force decimal labelling, instead of automatic
                       choice (see PGNUMB).
                   2 : force exponential labelling, instead of
                       automatic.
 X1, Y1 (input)  : world coordinates of one endpoint of the axis.
 X2, Y2 (input)  : world coordinates of the other endpoint of the axis.
 V1     (input)  : axis value at first endpoint.
 V2     (input)  : axis value at second endpoint.
 STEP   (input)  : major tick marks are drawn at axis value 0.0 plus
                   or minus integer multiples of STEP. If STEP=0.0,
                   a value is chosen automatically.
 NSUB   (input)  : minor tick marks are drawn to divide the major
                   divisions into NSUB equal subdivisions (ignored if
                   STEP=0.0). If NSUB <= 1, no minor tick marks are
                   drawn. NSUB is ignored for a logarithmic axis.
 DMAJL  (input)  : length of major tick marks drawn to left of axis
                   (as seen looking from first endpoint to second), in
                   units of the character height.
 DMAJR  (input)  : length of major tick marks drawn to right of axis,
                   in units of the character height.
 FMIN   (input)  : length of minor tick marks, as fraction of major.
 DISP   (input)  : displacement of baseline of tick labels to
                   right of axis, in units of the character height.
 ORIENT (input)  : orientation of label text, in degrees; angle between
                   baseline of text and direction of axis (0-360°).

PGBAND -- read cursor position, with anchor

      INTEGER FUNCTION PGBAND (MODE, POSN, XREF, YREF, X, Y, CH)
      INTEGER MODE, POSN
      REAL XREF, YREF, X, Y
      CHARACTER*(*) CH

Read the cursor position and a character typed by the user.
The position is returned in world coordinates.  PGBAND positions
the cursor at the position specified (if POSN=1), allows the user to
move the cursor using the mouse or arrow keys or whatever is available
on the device. When he has positioned the cursor, the user types a
single character on the keyboard; PGBAND then returns this
character and the new cursor position (in world coordinates).

Some interactive devices offer a selection of cursor types,
implemented as thin lines that move with the cursor, but without
erasing underlying graphics. Of these types, some extend between
a stationary anchor-point at XREF,YREF, and the position of the
cursor, while others simply follow the cursor without changing shape
or size. The cursor type is specified with one of the following MODE
values. Cursor types that are not supported by a given device, are
treated as MODE=0.

-- If MODE=0, the anchor point is ignored and the routine behaves
like PGCURS.
-- If MODE=1, a straight line is drawn joining the anchor point 
and the cursor position.
-- If MODE=2, a hollow rectangle is extended as the cursor is moved,
with one vertex at the anchor point and the opposite vertex at the
current cursor position; the edges of the rectangle are horizontal
and vertical.
-- If MODE=3, two horizontal lines are extended across the width of
the display, one drawn through the anchor point and the other
through the moving cursor position. This could be used to select
a Y-axis range when one end of the range is known.
-- If MODE=4, two vertical lines are extended over the height of
the display, one drawn through the anchor point and the other
through the moving cursor position. This could be used to select an
X-axis range when one end of the range is known.
-- If MODE=5, a horizontal line is extended through the cursor
position over the width of the display. This could be used to select
an X-axis value such as the start of an X-axis range. The anchor point
is ignored.
-- If MODE=6, a vertical line is extended through the cursor
position over the height of the display. This could be used to select
a Y-axis value such as the start of a Y-axis range. The anchor point
is ignored.
-- If MODE=7, a cross-hair, centered on the cursor, is extended over
the width and height of the display. The anchor point is ignored.

Returns:
 PGBAND          : 1 if the call was successful; 0 if the device
                   has no cursor or some other error occurs.
Arguments:
 MODE   (input)  : display mode (0, 1, ..7: see above).
 POSN   (input)  : if POSN=1, PGBAND attempts to place the cursor
                   at point (X,Y); if POSN=0, it leaves the cursor
                   at its current position. (On some devices this
                   request may be ignored.)
 XREF   (input)  : the world x-coordinate of the anchor point.
 YREF   (input)  : the world y-coordinate of the anchor point.
 X      (in/out) : the world x-coordinate of the cursor.
 Y      (in/out) : the world y-coordinate of the cursor.
 CH     (output) : the character typed by the user; if the device has
                   no cursor or if some other error occurs, the value
                   CHAR(0) [ASCII NUL character] is returned.

Note: The cursor coordinates (X,Y) may be changed by PGBAND even if
the device has no cursor or if the user does not move the cursor.
Under these circumstances, the position returned in (X,Y) is that of
the pixel nearest to the requested position.

PGBBUF -- begin batch of output (buffer)

      SUBROUTINE PGBBUF

Begin saving graphical output commands in an internal buffer; the
commands are held until a matching PGEBUF call (or until the buffer
is emptied by PGUPDT). This can greatly improve the efficiency of
PGPLOT.  PGBBUF increments an internal counter, while PGEBUF
decrements this counter and flushes the buffer to the output
device when the counter drops to zero.  PGBBUF and PGEBUF calls
should always be paired.

Arguments: none

PGBEG -- open a graphics device

      INTEGER FUNCTION PGBEG (UNIT, FILE, NXSUB, NYSUB)
      INTEGER       UNIT
      CHARACTER*(*) FILE
      INTEGER       NXSUB, NYSUB

Note: new programs should use PGOPEN rather than PGBEG. PGBEG
is retained for compatibility with existing programs. Unlike PGOPEN,
PGBEG closes any graphics devices that are already open, so it 
cannot be used to open devices to be used in parallel.

PGBEG opens a graphical device or file and prepares it for
subsequent plotting. A device must be opened with PGBEG or PGOPEN
before any other calls to PGPLOT subroutines for the device.

If any device  is already open for PGPLOT output, it is closed before
the new device is opened.

Returns:
 PGBEG         : a status return value. A value of 1 indicates
                   successful completion, any other value indicates
                   an error. In the event of error a message is
                   written on the standard error unit.  
                   To test the return value, call
                   PGBEG as a function, eg IER=PGBEG(...); note
                   that PGBEG must be declared INTEGER in the
                   calling program. Some Fortran compilers allow
                   you to use CALL PGBEG(...) and discard the
                   return value, but this is not standard Fortran.
Arguments:
 UNIT  (input)   : this argument is ignored by PGBEG (use zero).
 FILE  (input)   : the "device specification" for the plot device.
                   (For explanation, see description of PGOPEN.)
 NXSUB  (input)  : the number of subdivisions of the view surface in
                   X (>0 or <0).
 NYSUB  (input)  : the number of subdivisions of the view surface in
                   Y (>0).
                   PGPLOT puts NXSUB x NYSUB graphs on each plot
                   page or screen; when the view surface is sub-
                   divided in this way, PGPAGE moves to the next
                   panel, not the  next physical page. If
                   NXSUB > 0, PGPLOT uses the panels in row
                   order; if <0, PGPLOT uses them in column order.

PGBIN -- histogram of binned data

      SUBROUTINE PGBIN (NBIN, X, DATA, CENTER)
      INTEGER NBIN
      REAL X(*), DATA(*)
      LOGICAL CENTER

Plot a histogram of NBIN values with X(1..NBIN) values along
the ordinate, and DATA(1...NBIN) along the abscissa. Bin width is
spacing between X values.

Arguments:
 NBIN   (input)  : number of values.
 X      (input)  : abscissae of bins.
 DATA   (input)  : data values of bins.
 CENTER (input)  : if .TRUE., the X values denote the center of the
                   bin; if .FALSE., the X values denote the lower
                   edge (in X) of the bin.

PGBOX -- draw labeled frame around viewport

      SUBROUTINE PGBOX (XOPT, XTICK, NXSUB, YOPT, YTICK, NYSUB)
      CHARACTER*(*) XOPT, YOPT
      REAL XTICK, YTICK
      INTEGER NXSUB, NYSUB

Annotate the viewport with frame, axes, numeric labels, etc.
PGBOX is called by on the user's behalf by PGENV, but may also be
called explicitly.

Arguments:
 XOPT   (input)  : string of options for X (horizontal) axis of
                   plot. Options are single letters, and may be in
                   any order (see below).
 XTICK  (input)  : world coordinate interval between major tick marks
                   on X axis. If XTICK=0.0, the interval is chosen by
                   PGBOX, so that there will be at least 3 major tick
                   marks along the axis.
 NXSUB  (input)  : the number of subintervals to divide the major
                   coordinate interval into. If XTICK=0.0 or NXSUB=0,
                   the number is chosen by PGBOX.
 YOPT   (input)  : string of options for Y (vertical) axis of plot.
                   Coding is the same as for XOPT.
 YTICK  (input)  : like XTICK for the Y axis.
 NYSUB  (input)  : like NXSUB for the Y axis.

Options (for parameters XOPT and YOPT):
 A : draw Axis (X axis is horizontal line Y=0, Y axis is vertical
     line X=0).
 B : draw bottom (X) or left (Y) edge of frame.
 C : draw top (X) or right (Y) edge of frame.
 G : draw Grid of vertical (X) or horizontal (Y) lines.
 I : Invert the tick marks; ie draw them outside the viewport
     instead of inside.
 L : label axis Logarithmically (see below).
 N : write Numeric labels in the conventional location below the
     viewport (X) or to the left of the viewport (Y).
 P : extend ("Project") major tick marks outside the box (ignored if
     option I is specified).
 M : write numeric labels in the unconventional location above the
     viewport (X) or to the right of the viewport (Y).
 T : draw major Tick marks at the major coordinate interval.
 S : draw minor tick marks (Subticks).
 V : orient numeric labels Vertically. This is only applicable to Y.
     The default is to write Y-labels parallel to the axis.
 1 : force decimal labelling, instead of automatic choice (see PGNUMB).
 2 : force exponential labelling, instead of automatic.

To get a complete frame, specify BC in both XOPT and YOPT.
Tick marks, if requested, are drawn on the axes or frame
or both, depending which are requested. If none of ABC is specified,
tick marks will not be drawn. When PGENV calls PGBOX, it sets both
XOPT and YOPT according to the value of its parameter AXIS:
-1: 'BC', 0: 'BCNST', 1: 'ABCNST', 2: 'ABCGNST'.

For a logarithmic axis, the major tick interval is always 1.0. The
numeric label is 10**(x) where x is the world coordinate at the
tick mark. If subticks are requested, 8 subticks are drawn between
each major tick at equal logarithmic intervals.

To label an axis with time (days, hours, minutes, seconds) or
angle (degrees, arcmin, arcsec), use routine PGTBOX.

PGCIRC -- draw a circle, using fill-area attributes

      SUBROUTINE PGCIRC (XCENT, YCENT, RADIUS)
      REAL XCENT, YCENT, RADIUS

Draw a circle. The action of this routine depends
on the setting of the Fill-Area Style attribute. If Fill-Area Style
is SOLID (the default), the interior of the circle is solid-filled
using the current Color Index. If Fill-Area Style is HOLLOW, the
outline of the circle is drawn using the current line attributes
(color index, line-style, and line-width).

Arguments:
 XCENT  (input)  : world x-coordinate of the center of the circle.
 YCENT  (input)  : world y-coordinate of the center of the circle.
 RADIUS (input)  : radius of circle (world coordinates).

PGCLOS -- close the selected graphics device

      SUBROUTINE PGCLOS

Close the currently selected graphics device. After the device has
been closed, either another open device must be selected with PGSLCT
or another device must be opened with PGOPEN before any further
plotting can be done. If the call to PGCLOS is omitted, some or all 
of the plot may be lost.

[This routine was added to PGPLOT in Version 5.1.0. Older programs
use PGEND instead.]

Arguments: none

PGCONB -- contour map of a 2D data array, with blanking

      SUBROUTINE PGCONB (A, IDIM, JDIM, I1, I2, J1, J2, C, NC, TR, 
     1                   BLANK)
      INTEGER IDIM, JDIM, I1, I2, J1, J2, NC
      REAL    A(IDIM,JDIM), C(*), TR(6), BLANK

Draw a contour map of an array. This routine is the same as PGCONS,
except that array elements that have the "magic value" defined by
argument BLANK are ignored, making gaps in the contour map. The
routine may be useful for data measured on most but not all of the
points of a grid.

Arguments:
 A      (input)  : data array.
 IDIM   (input)  : first dimension of A.
 JDIM   (input)  : second dimension of A.
 I1,I2  (input)  : range of first index to be contoured (inclusive).
 J1,J2  (input)  : range of second index to be contoured (inclusive).
 C      (input)  : array of contour levels (in the same units as the
                   data in array A); dimension at least NC.
 NC     (input)  : number of contour levels (less than or equal to
                   dimension of C). The absolute value of this
                   argument is used (for compatibility with PGCONT,
                   where the sign of NC is significant).
 TR     (input)  : array defining a transformation between the I,J
                   grid of the array and the world coordinates. The
                   world coordinates of the array point A(I,J) are
                   given by:
                     X = TR(1) + TR(2)*I + TR(3)*J
                     Y = TR(4) + TR(5)*I + TR(6)*J
                   Usually TR(3) and TR(5) are zero - unless the
                   coordinate transformation involves a rotation
                   or shear.
 BLANK   (input) : elements of array A that are exactly equal to
                   this value are ignored (blanked).

PGCONF -- fill between two contours

      SUBROUTINE PGCONF (A, IDIM, JDIM, I1, I2, J1, J2, C1, C2, TR)
      INTEGER IDIM, JDIM, I1, I2, J1, J2
      REAL    A(IDIM,JDIM), C1, C2, TR(6)

Shade the region between two contour levels of a function defined on
the nodes of a rectangular grid. The routine uses the current fill
attributes, hatching style (if appropriate), and color index.

If you want to both shade between contours and draw the contour
lines, call this routine first (once for each pair of levels) and 
then CALL PGCONT (or PGCONS) to draw the contour lines on top of the
shading.

Note 1: This routine is not very efficient: it generates a polygon
fill command for each cell of the mesh that intersects the desired
area, rather than consolidating adjacent cells into a single polygon.

Note 2: If both contours intersect all four edges of a particular
mesh cell, the program behaves badly and may consider some parts
of the cell to lie in more than one contour range.

Note 3: If a contour crosses all four edges of a cell, this
routine may not generate the same contours as PGCONT or PGCONS
(these two routines may not agree either). Such cases are always
ambiguous and the routines use different approaches to resolving
the ambiguity.

Arguments:
 A      (input)  : data array.
 IDIM   (input)  : first dimension of A.
 JDIM   (input)  : second dimension of A.
 I1,I2  (input)  : range of first index to be contoured (inclusive).
 J1,J2  (input)  : range of second index to be contoured (inclusive).
 C1, C2 (input)  : contour levels; note that C1 must be less than C2.
 TR     (input)  : array defining a transformation between the I,J
                   grid of the array and the world coordinates. The
                   world coordinates of the array point A(I,J) are
                   given by:
                     X = TR(1) + TR(2)*I + TR(3)*J
                     Y = TR(4) + TR(5)*I + TR(6)*J
                   Usually TR(3) and TR(5) are zero - unless the
                   coordinate transformation involves a rotation
                   or shear.

PGCONL -- label contour map of a 2D data array

      SUBROUTINE PGCONL (A, IDIM, JDIM, I1, I2, J1, J2, C, TR,
     1                   LABEL, INTVAL, MININT)
      INTEGER IDIM, JDIM, I1, J1, I2, J2, INTVAL, MININT
      REAL A(IDIM,JDIM), C, TR(6)
      CHARACTER*(*) LABEL

Label a contour map drawn with routine PGCONT. Routine PGCONT should
be called first to draw the contour lines, then this routine should be
called to add the labels. Labels are written at intervals along the
contour lines, centered on the contour lines with lettering aligned
in the up-hill direction. Labels are opaque, so a part of the under-
lying contour line is obscured by the label. Labels use the current
attributes (character height, line width, color index, character
font).

The first 9 arguments are the same as those supplied to PGCONT, and
should normally be identical to those used with PGCONT. Note that
only one contour level can be specified; tolabel more contours, call
PGCONL for each level.

The Label is supplied as a character string in argument LABEL.

The spacing of labels along the contour is specified by parameters
INTVAL and MININT. The routine follows the contour through the
array, counting the number of cells that the contour crosses. The
first label will be written in the MININT'th cell, and additional
labels will be written every INTVAL cells thereafter. A contour
that crosses less than MININT cells will not be labelled. Some
experimentation may be needed to get satisfactory results; a good
place to start is INTVAL=20, MININT=10.

Arguments:
 A      (input) : data array.
 IDIM   (input) : first dimension of A.
 JDIM   (input) : second dimension of A.
 I1, I2 (input) : range of first index to be contoured (inclusive).
 J1, J2 (input) : range of second index to be contoured (inclusive).
 C      (input) : the level of the contour to be labelled (one of the
                  values given to PGCONT).
 TR     (input) : array defining a transformation between the I,J
                  grid of the array and the world coordinates.
                  The world coordinates of the array point A(I,J)
                  are given by:
                    X = TR(1) + TR(2)*I + TR(3)*J
                    Y = TR(4) + TR(5)*I + TR(6)*J
                  Usually TR(3) and TR(5) are zero - unless the
                  coordinate transformation involves a rotation or
                  shear.
 LABEL  (input) : character strings to be used to label the specified
                  contour. Leading and trailing blank spaces are
                  ignored.
 INTVAL (input) : spacing along the contour between labels, in
                  grid cells.
 MININT (input) : contours that cross less than MININT cells
                  will not be labelled.

PGCONS -- contour map of a 2D data array (fast algorithm)

      SUBROUTINE PGCONS (A, IDIM, JDIM, I1, I2, J1, J2, C, NC, TR)
      INTEGER IDIM, JDIM, I1, I2, J1, J2, NC
      REAL    A(IDIM,JDIM), C(*), TR(6)

Draw a contour map of an array. The map is truncated if
necessary at the boundaries of the viewport.  Each contour line is
drawn with the current line attributes (color index, style, and
width).  This routine, unlike PGCONT, does not draw each contour as a
continuous line, but draws the straight line segments composing each
contour in a random order.  It is thus not suitable for use on pen
plotters, and it usually gives unsatisfactory results with dashed or
dotted lines.  It is, however, faster than PGCONT, especially if
several contour levels are drawn with one call of PGCONS.

Arguments:
 A      (input)  : data array.
 IDIM   (input)  : first dimension of A.
 JDIM   (input)  : second dimension of A.
 I1,I2  (input)  : range of first index to be contoured (inclusive).
 J1,J2  (input)  : range of second index to be contoured (inclusive).
 C      (input)  : array of contour levels (in the same units as the
                   data in array A); dimension at least NC.
 NC     (input)  : number of contour levels (less than or equal to
                   dimension of C). The absolute value of this
                   argument is used (for compatibility with PGCONT,
                   where the sign of NC is significant).
 TR     (input)  : array defining a transformation between the I,J
                   grid of the array and the world coordinates. The
                   world coordinates of the array point A(I,J) are
                   given by:
                     X = TR(1) + TR(2)*I + TR(3)*J
                     Y = TR(4) + TR(5)*I + TR(6)*J
                   Usually TR(3) and TR(5) are zero - unless the
                   coordinate transformation involves a rotation
                   or shear.

PGCONT -- contour map of a 2D data array (contour-following)

      SUBROUTINE PGCONT (A, IDIM, JDIM, I1, I2, J1, J2, C, NC, TR)
      INTEGER IDIM, JDIM, I1, J1, I2, J2, NC
      REAL A(IDIM,JDIM), C(*), TR(6)

Draw a contour map of an array.  The map is truncated if
necessary at the boundaries of the viewport.  Each contour line
is drawn with the current line attributes (color index, style, and
width); except that if argument NC is positive (see below), the line
style is set by PGCONT to 1 (solid) for positive contours or 2
(dashed) for negative contours.

Arguments:
 A      (input) : data array.
 IDIM   (input) : first dimension of A.
 JDIM   (input) : second dimension of A.
 I1, I2 (input) : range of first index to be contoured (inclusive).
 J1, J2 (input) : range of second index to be contoured (inclusive).
 C      (input) : array of NC contour levels; dimension at least NC.
 NC     (input) : +/- number of contour levels (less than or equal
                  to dimension of C). If NC is positive, it is the
                  number of contour levels, and the line-style is
                  chosen automatically as described above. If NC is
                  negative, it is minus the number of contour
                  levels, and the current setting of line-style is
                  used for all the contours.
 TR     (input) : array defining a transformation between the I,J
                  grid of the array and the world coordinates.
                  The world coordinates of the array point A(I,J)
                  are given by:
                    X = TR(1) + TR(2)*I + TR(3)*J
                    Y = TR(4) + TR(5)*I + TR(6)*J
                  Usually TR(3) and TR(5) are zero - unless the
                  coordinate transformation involves a rotation or
                  shear.

PGCONX -- contour map of a 2D data array (non rectangular)

      SUBROUTINE PGCONX (A, IDIM, JDIM, I1, I2, J1, J2, C, NC, PLOT)
      INTEGER  IDIM, JDIM, I1, J1, I2, J2, NC
      REAL     A(IDIM,JDIM), C(*)
      EXTERNAL PLOT

Draw a contour map of an array using a user-supplied plotting
routine.  This routine should be used instead of PGCONT when the
data are defined on a non-rectangular grid.  PGCONT permits only
a linear transformation between the (I,J) grid of the array
and the world coordinate system (x,y), but PGCONX permits any
transformation to be used, the transformation being defined by a
user-supplied subroutine. The nature of the contouring algorithm,
however, dictates that the transformation should maintain the
rectangular topology of the grid, although grid-points may be
allowed to coalesce.  As an example of a deformed rectangular
grid, consider data given on the polar grid theta=0.1n(pi/2),
for n=0,1,...,10, and r=0.25m, for m=0,1,..,4. This grid
contains 55 points, of which 11 are coincident at the origin.
The input array for PGCONX should be dimensioned (11,5), and
data values should be provided for all 55 elements.  PGCONX can
also be used for special applications in which the height of the
contour affects its appearance, e.g., stereoscopic views.

The map is truncated if necessary at the boundaries of the viewport.
Each contour line is drawn with the current line attributes (color
index, style, and width); except that if argument NC is positive
(see below), the line style is set by PGCONX to 1 (solid) for
positive contours or 2 (dashed) for negative contours. Attributes
for the contour lines can also be set in the user-supplied
subroutine, if desired.

Arguments:
 A      (input) : data array.
 IDIM   (input) : first dimension of A.
 JDIM   (input) : second dimension of A.
 I1, I2 (input) : range of first index to be contoured (inclusive).
 J1, J2 (input) : range of second index to be contoured (inclusive).
 C      (input) : array of NC contour levels; dimension at least NC.
 NC     (input) : +/- number of contour levels (less than or equal
                  to dimension of C). If NC is positive, it is the
                  number of contour levels, and the line-style is
                  chosen automatically as described above. If NC is
                  negative, it is minus the number of contour
                  levels, and the current setting of line-style is
                  used for all the contours.
 PLOT   (input) : the address (name) of a subroutine supplied by
                  the user, which will be called by PGCONX to do
                  the actual plotting. This must be declared
                  EXTERNAL in the program unit calling PGCONX.

The subroutine PLOT will be called with four arguments:
     CALL PLOT(VISBLE,X,Y,Z)
where X,Y (input) are real variables corresponding to
I,J indices of the array A. If  VISBLE (input, integer) is 1,
PLOT should draw a visible line from the current pen
position to the world coordinate point corresponding to (X,Y);
if it is 0, it should move the pen to (X,Y). Z is the value
of the current contour level, and may be used by PLOT if desired.
Example:
      SUBROUTINE PLOT (VISBLE,X,Y,Z)
      REAL X, Y, Z, XWORLD, YWORLD
      INTEGER VISBLE
      XWORLD = X*COS(Y) ! this is the user-defined
      YWORLD = X*SIN(Y) ! transformation
      IF (VISBLE.EQ.0) THEN
          CALL PGMOVE (XWORLD, YWORLD)
      ELSE
          CALL PGDRAW (XWORLD, YWORLD)
      END IF
      END

PGCTAB -- install the color table to be used by PGIMAG

      SUBROUTINE PGCTAB(L, R, G, B, NC, CONTRA, BRIGHT)
      INTEGER NC
      REAL    L(NC), R(NC), G(NC), B(NC), CONTRA, BRIGHT

Use the given color table to change the color representations of
all color indexes marked for use by PGIMAG. To change which
color indexes are thus marked, call PGSCIR before calling PGCTAB
or PGIMAG. On devices that can change the color representations
of previously plotted graphics, PGCTAB will also change the colors
of existing graphics that were plotted with the marked color
indexes. This feature can then be combined with PGBAND to
interactively manipulate the displayed colors of data previously
plotted with PGIMAG.

Limitations:
 1. Some devices do not propagate color representation changes
    to previously drawn graphics.
 2. Some devices ignore requests to change color representations.
 3. The appearance of specific color representations on grey-scale
    devices is device-dependent.

Notes:
 To reverse the sense of a color table, change the chosen contrast
 and brightness to -CONTRA and 1-BRIGHT.

 In the following, the term 'color table' refers to the input
 L,R,G,B arrays, whereas 'color ramp' refers to the resulting
 ramp of colors that would be seen with PGWEDG.

Arguments:
 L      (input)  : An array of NC normalized ramp-intensity levels
                   corresponding to the RGB primary color intensities
                   in R(),G(),B(). Colors on the ramp are linearly
                   interpolated from neighbouring levels.
                   Levels must be sorted in increasing order.
                    0.0 places a color at the beginning of the ramp.
                    1.0 places a color at the end of the ramp.
                   Colors outside these limits are legal, but will
                   not be visible if CONTRA=1.0 and BRIGHT=0.5.
 R      (input)  : An array of NC normalized red intensities.
 G      (input)  : An array of NC normalized green intensities.
 B      (input)  : An array of NC normalized blue intensities.
 NC     (input)  : The number of color table entries.
 CONTRA (input)  : The contrast of the color ramp (normally 1.0).
                   Negative values reverse the direction of the ramp.
 BRIGHT (input)  : The brightness of the color ramp. This is normally
                   0.5, but can sensibly hold any value between 0.0
                   and 1.0. Values at or beyond the latter two
                   extremes, saturate the color ramp with the colors
                   of the respective end of the color table.

PGCURS -- read cursor position

      INTEGER FUNCTION PGCURS (X, Y, CH)
      REAL X, Y
      CHARACTER*(*) CH

Read the cursor position and a character typed by the user.
The position is returned in world coordinates.  PGCURS positions
the cursor at the position specified, allows the user to move the
cursor using the joystick or arrow keys or whatever is available on
the device. When he has positioned the cursor, the user types a
single character on the keyboard; PGCURS then returns this
character and the new cursor position (in world coordinates).

Returns:
 PGCURS         : 1 if the call was successful; 0 if the device
                   has no cursor or some other error occurs.
Arguments:
 X      (in/out) : the world x-coordinate of the cursor.
 Y      (in/out) : the world y-coordinate of the cursor.
 CH     (output) : the character typed by the user; if the device has
                   no cursor or if some other error occurs, the value
                   CHAR(0) [ASCII NUL character] is returned.

Note: The cursor coordinates (X,Y) may be changed by PGCURS even if
the device has no cursor or if the user does not move the cursor.
Under these circumstances, the position returned in (X,Y) is that of
the pixel nearest to the requested position.

PGDRAW -- draw a line from the current pen position to a point

      SUBROUTINE PGDRAW (X, Y)
      REAL X, Y

Draw a line from the current pen position to the point
with world-coordinates (X,Y). The line is clipped at the edge of the
current window. The new pen position is (X,Y) in world coordinates.

Arguments:
 X      (input)  : world x-coordinate of the end point of the line.
 Y      (input)  : world y-coordinate of the end point of the line.

PGEBUF -- end batch of output (buffer)

      SUBROUTINE PGEBUF

A call to PGEBUF marks the end of a batch of graphical output begun
with the last call of PGBBUF.  PGBBUF and PGEBUF calls should always
be paired. Each call to PGBBUF increments a counter, while each call
to PGEBUF decrements the counter. When the counter reaches 0, the
batch of output is written on the output device.

Arguments: none

PGEND -- close all open graphics devices

      SUBROUTINE PGEND

Close and release any open graphics devices. All devices must be
closed by calling either PGCLOS (for each device) or PGEND before
the program terminates. If a device is not closed properly, some
or all of the graphical output may be lost.

Arguments: none

PGENV -- set window and viewport and draw labeled frame

      SUBROUTINE PGENV (XMIN, XMAX, YMIN, YMAX, JUST, AXIS)
      REAL XMIN, XMAX, YMIN, YMAX
      INTEGER JUST, AXIS

Set PGPLOT "Plotter Environment".  PGENV establishes the scaling
for subsequent calls to PGPT, PGLINE, etc.  The plotter is
advanced to a new page or panel, clearing the screen if necessary.
If the "prompt state" is ON (see PGASK), confirmation
is requested from the user before clearing the screen.
If requested, a box, axes, labels, etc. are drawn according to
the setting of argument AXIS.

Arguments:
 XMIN   (input)  : the world x-coordinate at the bottom left corner
                   of the viewport.
 XMAX   (input)  : the world x-coordinate at the top right corner
                   of the viewport (note XMAX may be less than XMIN).
 YMIN   (input)  : the world y-coordinate at the bottom left corner
                   of the viewport.
 YMAX   (input)  : the world y-coordinate at the top right corner
                   of the viewport (note YMAX may be less than YMIN).
 JUST   (input)  : if JUST=1, the scales of the x and y axes (in
                   world coordinates per inch) will be equal,
                   otherwise they will be scaled independently.
 AXIS   (input)  : controls the plotting of axes, tick marks, etc:
     AXIS = -2 : draw no box, axes or labels;
     AXIS = -1 : draw box only;
     AXIS =  0 : draw box and label it with coordinates;
     AXIS =  1 : same as AXIS=0, but also draw the
                 coordinate axes (X=0, Y=0);
     AXIS =  2 : same as AXIS=1, but also draw grid lines
                 at major increments of the coordinates;
     AXIS = 10 : draw box and label X-axis logarithmically;
     AXIS = 20 : draw box and label Y-axis logarithmically;
     AXIS = 30 : draw box and label both axes logarithmically.

For other axis options, use routine PGBOX. PGENV can be persuaded to
call PGBOX with additional axis options by defining an environment
parameter PGPLOT_ENVOPT containing the required option codes. 
Examples:
  PGPLOT_ENVOPT=P      ! draw Projecting tick marks
  PGPLOT_ENVOPT=I      ! Invert the tick marks
  PGPLOT_ENVOPT=IV     ! Invert tick marks and label y Vertically

PGERAS -- erase all graphics from current page

      SUBROUTINE PGERAS

Erase all graphics from the current page (or current panel, if
the view surface has been divided into panels with PGSUBP).

Arguments: none

PGERR1 -- horizontal or vertical error bar

      SUBROUTINE PGERR1 (DIR, X, Y, E, T)
      INTEGER DIR
      REAL X, Y, E
      REAL T

Plot a single error bar in the direction specified by DIR.
This routine draws an error bar only; to mark the data point at
the start of the error bar, an additional call to PGPT is required.
To plot many error bars, use PGERRB.

Arguments:
 DIR    (input)  : direction to plot the error bar relative to
                   the data point. 
                   One-sided error bar:
                     DIR is 1 for +X (X to X+E);
                            2 for +Y (Y to Y+E);
                            3 for -X (X to X-E);
                            4 for -Y (Y to Y-E).
                   Two-sided error bar:
                     DIR is 5 for +/-X (X-E to X+E); 
                            6 for +/-Y (Y-E to Y+E).
 X      (input)  : world x-coordinate of the data.
 Y      (input)  : world y-coordinate of the data.
 E      (input)  : value of error bar distance to be added to the
                   data position in world coordinates.
 T      (input)  : length of terminals to be drawn at the ends
                   of the error bar, as a multiple of the default
                   length; if T = 0.0, no terminals will be drawn.

PGERRB -- horizontal or vertical error bar

      SUBROUTINE PGERRB (DIR, N, X, Y, E, T)
      INTEGER DIR, N
      REAL X(*), Y(*), E(*)
      REAL T

Plot error bars in the direction specified by DIR.
This routine draws an error bar only; to mark the data point at
the start of the error bar, an additional call to PGPT is required.

Arguments:
 DIR    (input)  : direction to plot the error bar relative to
                   the data point. 
                   One-sided error bar:
                     DIR is 1 for +X (X to X+E);
                            2 for +Y (Y to Y+E);
                            3 for -X (X to X-E);
                            4 for -Y (Y to Y-E).
                   Two-sided error bar:
                     DIR is 5 for +/-X (X-E to X+E); 
                            6 for +/-Y (Y-E to Y+E).
 N      (input)  : number of error bars to plot.
 X      (input)  : world x-coordinates of the data.
 Y      (input)  : world y-coordinates of the data.
 E      (input)  : value of error bar distance to be added to the
                   data position in world coordinates.
 T      (input)  : length of terminals to be drawn at the ends
                   of the error bar, as a multiple of the default
                   length; if T = 0.0, no terminals will be drawn.

Note: the dimension of arrays X, Y, and E must be greater
than or equal to N. If N is 1, X, Y, and E may be scalar
variables, or expressions.

PGERRX -- horizontal error bar

      SUBROUTINE PGERRX (N, X1, X2, Y, T)
      INTEGER N
      REAL X1(*), X2(*), Y(*)
      REAL T

Plot horizontal error bars.
This routine draws an error bar only; to mark the data point in
the middle of the error bar, an additional call to PGPT or
PGERRY is required.

Arguments:
 N      (input)  : number of error bars to plot.
 X1     (input)  : world x-coordinates of lower end of the
                   error bars.
 X2     (input)  : world x-coordinates of upper end of the
                   error bars.
 Y      (input)  : world y-coordinates of the data.
 T      (input)  : length of terminals to be drawn at the ends
                   of the error bar, as a multiple of the default
                   length; if T = 0.0, no terminals will be drawn.

Note: the dimension of arrays X1, X2, and Y must be greater
than or equal to N. If N is 1, X1, X2, and Y may be scalar
variables, or expressions, eg:
      CALL PGERRX(1,X-SIGMA,X+SIGMA,Y)

PGERRY -- vertical error bar

      SUBROUTINE PGERRY (N, X, Y1, Y2, T)
      INTEGER N
      REAL X(*), Y1(*), Y2(*)
      REAL T

Plot vertical error bars.
This routine draws an error bar only; to mark the data point in
the middle of the error bar, an additional call to PGPT or
PGERRX is required.

Arguments:
 N      (input)  : number of error bars to plot.
 X      (input)  : world x-coordinates of the data.
 Y1     (input)  : world y-coordinates of top end of the
                   error bars.
 Y2     (input)  : world y-coordinates of bottom end of the
                   error bars.
 T      (input)  : length of terminals to be drawn at the ends
                   of the error bar, as a multiple of the default
                   length; if T = 0.0, no terminals will be drawn.

Note: the dimension of arrays X, Y1, and Y2 must be greater
than or equal to N. If N is 1, X, Y1, and Y2 may be scalar
variables or expressions, eg:
      CALL PGERRY(1,X,Y+SIGMA,Y-SIGMA)

PGETXT -- erase text from graphics display

      SUBROUTINE PGETXT

Some graphics terminals display text (the normal interactive dialog)
on the same screen as graphics. This routine erases the text from the
view surface without affecting the graphics. It does nothing on
devices which do not display text on the graphics screen, and on
devices which do not have this capability.

Arguments:
 None

PGFUNT -- function defined by X = F(T), Y = G(T)

      SUBROUTINE PGFUNT (FX, FY, N, TMIN, TMAX, PGFLAG)
      REAL FX, FY
      EXTERNAL FX, FY
      INTEGER N
      REAL TMIN, TMAX
      INTEGER PGFLAG

Draw a curve defined by parametric equations X = FX(T), Y = FY(T).

Arguments:
 FX     (external real function): supplied by the user, evaluates
                   X-coordinate.
 FY     (external real function): supplied by the user, evaluates
                   Y-coordinate.
 N      (input)  : the number of points required to define the
                   curve. The functions FX and FY will each be
                   called N+1 times.
 TMIN   (input)  : the minimum value for the parameter T.
 TMAX   (input)  : the maximum value for the parameter T.
 PGFLAG (input)  : if PGFLAG = 1, the curve is plotted in the
                   current window and viewport; if PGFLAG = 0,
                   PGENV is called automatically by PGFUNT to
                   start a new plot with automatic scaling.

Note: The functions FX and FY must be declared EXTERNAL in the
Fortran program unit that calls PGFUNT.

PGFUNX -- function defined by Y = F(X)

      SUBROUTINE PGFUNX (FY, N, XMIN, XMAX, PGFLAG)
      REAL FY
      EXTERNAL FY
      INTEGER N
      REAL XMIN, XMAX
      INTEGER PGFLAG

Draw a curve defined by the equation Y = FY(X), where FY is a
user-supplied subroutine.

Arguments:
 FY     (external real function): supplied by the user, evaluates
                   Y value at a given X-coordinate.
 N      (input)  : the number of points required to define the
                   curve. The function FY will be called N+1 times.
                   If PGFLAG=0 and N is greater than 1000, 1000
                   will be used instead.  If N is less than 1,
                   nothing will be drawn.
 XMIN   (input)  : the minimum value of X.
 XMAX   (input)  : the maximum value of X.
 PGFLAG (input)  : if PGFLAG = 1, the curve is plotted in the
                   current window and viewport; if PGFLAG = 0,
                   PGENV is called automatically by PGFUNX to
                   start a new plot with X limits (XMIN, XMAX)
                   and automatic scaling in Y.

Note: The function FY must be declared EXTERNAL in the Fortran
program unit that calls PGFUNX.  It has one argument, the
x-coordinate at which the y value is required, e.g.
  REAL FUNCTION FY(X)
  REAL X
  FY = .....
  END

PGFUNY -- function defined by X = F(Y)

      SUBROUTINE PGFUNY (FX, N, YMIN, YMAX, PGFLAG)
      REAL    FX
      EXTERNAL FX
      INTEGER N
      REAL    YMIN, YMAX
      INTEGER PGFLAG

Draw a curve defined by the equation X = FX(Y), where FY is a
user-supplied subroutine.

Arguments:
 FX     (external real function): supplied by the user, evaluates
                   X value at a given Y-coordinate.
 N      (input)  : the number of points required to define the
                   curve. The function FX will be called N+1 times.
                   If PGFLAG=0 and N is greater than 1000, 1000
                   will be used instead.  If N is less than 1,
                   nothing will be drawn.
 YMIN   (input)  : the minimum value of Y.
 YMAX   (input)  : the maximum value of Y.
 PGFLAG (input)  : if PGFLAG = 1, the curve is plotted in the
                   current window and viewport; if PGFLAG = 0,
                   PGENV is called automatically by PGFUNY to
                   start a new plot with Y limits (YMIN, YMAX)
                   and automatic scaling in X.

Note: The function FX must be declared EXTERNAL in the Fortran
program unit that calls PGFUNY.  It has one argument, the
y-coordinate at which the x value is required, e.g.
  REAL FUNCTION FX(Y)
  REAL Y
  FX = .....
  END

PGGRAY -- gray-scale map of a 2D data array

      SUBROUTINE PGGRAY (A, IDIM, JDIM, I1, I2, J1, J2,
     1                   FG, BG, TR)
      INTEGER IDIM, JDIM, I1, I2, J1, J2
      REAL    A(IDIM,JDIM), FG, BG, TR(6)

Draw gray-scale map of an array in current window. The subsection
of the array A defined by indices (I1:I2, J1:J2) is mapped onto
the view surface world-coordinate system by the transformation
matrix TR. The resulting quadrilateral region is clipped at the edge
of the window and shaded with the shade at each point determined
by the corresponding array value.  The shade is a number in the
range 0 to 1 obtained by linear interpolation between the background
level (BG) and the foreground level (FG), i.e.,

  shade = [A(i,j) - BG] / [FG - BG]

The background level BG can be either less than or greater than the
foreground level FG.  Points in the array that are outside the range
BG to FG are assigned shade 0 or 1 as appropriate.

PGGRAY uses two different algorithms, depending how many color
indices are available in the color index range specified for images.
(This range is set with routine PGSCIR, and the current or default
range can be queried by calling routine PGQCIR).

If 16 or more color indices are available, PGGRAY first assigns
color representations to these color indices to give a linear ramp
between the background color (color index 0) and the foreground color
(color index 1), and then calls PGIMAG to draw the image using these
color indices. In this mode, the shaded region is "opaque": every
pixel is assigned a color.

If less than 16 color indices are available, PGGRAY uses only
color index 1, and uses  a "dithering" algorithm to fill in pixels,
with the shade (computed as above) determining the faction of pixels
that are filled. In this mode the shaded region is "transparent" and
allows previously-drawn graphics to show through.

The transformation matrix TR is used to calculate the world
coordinates of the center of the "cell" that represents each
array element. The world coordinates of the center of the cell
corresponding to array element A(I,J) are given by:

         X = TR(1) + TR(2)*I + TR(3)*J
         Y = TR(4) + TR(5)*I + TR(6)*J

Usually TR(3) and TR(5) are zero -- unless the coordinate
transformation involves a rotation or shear.  The corners of the
quadrilateral region that is shaded by PGGRAY are given by
applying this transformation to (I1-0.5,J1-0.5), (I2+0.5, J2+0.5).

Arguments:
 A      (input)  : the array to be plotted.
 IDIM   (input)  : the first dimension of array A.
 JDIM   (input)  : the second dimension of array A.
 I1, I2 (input)  : the inclusive range of the first index
                   (I) to be plotted.
 J1, J2 (input)  : the inclusive range of the second
                   index (J) to be plotted.
 FG     (input)  : the array value which is to appear with the
                   foreground color (corresponding to color index 1).
 BG     (input)  : the array value which is to appear with the
                   background color (corresponding to color index 0).
 TR     (input)  : transformation matrix between array grid and
                   world coordinates.

PGHI2D -- cross-sections through a 2D data array

      SUBROUTINE PGHI2D (DATA, NXV, NYV, IX1, IX2, IY1, IY2, X, IOFF,
     1                   BIAS, CENTER, YLIMS)
      INTEGER NXV, NYV, IX1, IX2, IY1, IY2
      REAL    DATA(NXV,NYV)
      REAL    X(IX2-IX1+1), YLIMS(IX2-IX1+1)
      INTEGER IOFF
      REAL    BIAS
      LOGICAL CENTER

Plot a series of cross-sections through a 2D data array.
Each cross-section is plotted as a hidden line histogram.  The plot
can be slanted to give a pseudo-3D effect - if this is done, the
call to PGENV may have to be changed to allow for the increased X
range that will be needed.

Arguments:
 DATA   (input)  : the data array to be plotted.
 NXV    (input)  : the first dimension of DATA.
 NYV    (input)  : the second dimension of DATA.
 IX1    (input)
 IX2    (input)
 IY1    (input)
 IY2    (input)  : PGHI2D plots a subset of the input array DATA.
                   This subset is delimited in the first (x)
                   dimension by IX1 and IX2 and the 2nd (y) by IY1
                   and IY2, inclusively. Note: IY2 < IY1 is
                   permitted, resulting in a plot with the
                   cross-sections plotted in reverse Y order.
                   However, IX2 must be => IX1.
 X      (input)  : the abscissae of the bins to be plotted. That is,
                   X(1) should be the X value for DATA(IX1,IY1), and
                   X should have (IX2-IX1+1) elements.  The program
                   has to assume that the X value for DATA(x,y) is
                   the same for all y.
 IOFF   (input)  : an offset in array elements applied to successive
                   cross-sections to produce a slanted effect.  A
                   plot with IOFF > 0 slants to the right, one with
                   IOFF < 0 slants left.
 BIAS   (input)  : a bias value applied to each successive cross-
                   section in order to raise it above the previous
                   cross-section.  This is in the same units as the
                   data.
 CENTER (input)  : if .true., the X values denote the center of the
                   bins; if .false. the X values denote the lower
                   edges (in X) of the bins.
 YLIMS  (input)  : workspace.  Should be an array of at least
                   (IX2-IX1+1) elements.

PGHIST -- histogram of unbinned data

      SUBROUTINE PGHIST(N, DATA, DATMIN, DATMAX, NBIN, PGFLAG)
      INTEGER N
      REAL    DATA(*)
      REAL    DATMIN, DATMAX
      INTEGER NBIN, PGFLAG

Draw a histogram of N values of a variable in array
DATA(1...N) in the range DATMIN to DATMAX using NBIN bins.  Note
that array elements which fall exactly on the boundary between
two bins will be counted in the higher bin rather than the
lower one; and array elements whose value is less than DATMIN or
greater than or equal to DATMAX will not be counted at all.

Arguments:
 N      (input)  : the number of data values.
 DATA   (input)  : the data values. Note: the dimension of array
                   DATA must be greater than or equal to N. The
                   first N elements of the array are used.
 DATMIN (input)  : the minimum data value for the histogram.
 DATMAX (input)  : the maximum data value for the histogram.
 NBIN   (input)  : the number of bins to use: the range DATMIN to
                   DATMAX is divided into NBIN equal bins and
                   the number of DATA values in each bin is
                   determined by PGHIST.  NBIN may not exceed 200.
 PGFLAG (input)  : if PGFLAG = 1, the histogram is plotted in the
                   current window and viewport; if PGFLAG = 0,
                   PGENV is called automatically by PGHIST to start
                   a new plot (the x-limits of the window will be
                   DATMIN and DATMAX; the y-limits will be chosen
                   automatically.
                   IF PGFLAG = 2,3 the histogram will be in the same
                   window and viewport but with a filled area style.
                   If pgflag=4,5 as for pgflag = 0,1, but simple
                   line drawn as for PGBIN


PGIDEN -- write username, date, and time at bottom of plot

      SUBROUTINE PGIDEN

Write username, date, and time at bottom of plot.

Arguments: none.

PGIMAG -- color image from a 2D data array

      SUBROUTINE PGIMAG (A, IDIM, JDIM, I1, I2, J1, J2,
     1                   A1, A2, TR)
      INTEGER IDIM, JDIM, I1, I2, J1, J2
      REAL    A(IDIM,JDIM), A1, A2, TR(6)

Draw a color image of an array in current window. The subsection
of the array A defined by indices (I1:I2, J1:J2) is mapped onto
the view surface world-coordinate system by the transformation
matrix TR. The resulting quadrilateral region is clipped at the edge
of the window. Each element of the array is represented in the image
by a small quadrilateral, which is filled with a color specified by
the corresponding array value.

The subroutine uses color indices in the range C1 to C2, which can
be specified by calling PGSCIR before PGIMAG. The default values
for C1 and C2 are device-dependent; these values can be determined by
calling PGQCIR. Note that color representations should be assigned to
color indices C1 to C2 by calling PGSCR before calling PGIMAG. On some
devices (but not all), the color representation can be changed after
the call to PGIMAG by calling PGSCR again.

Array values in the range A1 to A2 are mapped on to the range of
color indices C1 to C2, with array values <= A1 being given color
index C1 and values >= A2 being given color index C2. The mapping
function for intermediate array values can be specified by
calling routine PGSITF before PGIMAG; the default is linear.

On devices which have no available color indices (C1 > C2),
PGIMAG will return without doing anything. On devices with only
one color index (C1=C2), all array values map to the same color
which is rather uninteresting. An image is always "opaque",
i.e., it obscures all graphical elements previously drawn in
the region.

The transformation matrix TR is used to calculate the world
coordinates of the center of the "cell" that represents each
array element. The world coordinates of the center of the cell
corresponding to array element A(I,J) are given by:

         X = TR(1) + TR(2)*I + TR(3)*J
         Y = TR(4) + TR(5)*I + TR(6)*J

Usually TR(3) and TR(5) are zero -- unless the coordinate
transformation involves a rotation or shear.  The corners of the
quadrilateral region that is shaded by PGIMAG are given by
applying this transformation to (I1-0.5,J1-0.5), (I2+0.5, J2+0.5).

Arguments:
 A      (input)  : the array to be plotted.
 IDIM   (input)  : the first dimension of array A.
 JDIM   (input)  : the second dimension of array A.
 I1, I2 (input)  : the inclusive range of the first index
                   (I) to be plotted.
 J1, J2 (input)  : the inclusive range of the second
                   index (J) to be plotted.
 A1     (input)  : the array value which is to appear with shade C1.
 A2     (input)  : the array value which is to appear with shade C2.
 TR     (input)  : transformation matrix between array grid and
                   world coordinates.

PGLAB -- write labels for x-axis, y-axis, and top of plot

      SUBROUTINE PGLAB (XLBL, YLBL, TOPLBL)
      CHARACTER*(*) XLBL, YLBL, TOPLBL

Write labels outside the viewport. This routine is a simple
interface to PGMTXT, which should be used if PGLAB is inadequate.

Arguments:
 XLBL   (input) : a label for the x-axis (centered below the
                  viewport).
 YLBL   (input) : a label for the y-axis (centered to the left
                  of the viewport, drawn vertically).
 TOPLBL (input) : a label for the entire plot (centered above the
                  viewport).

PGLCUR -- draw a line using the cursor

      SUBROUTINE PGLCUR (MAXPT, NPT, X, Y)
      INTEGER MAXPT, NPT
      REAL    X(*), Y(*)

Interactive routine for user to enter a polyline by use of
the cursor.  Routine allows user to Add and Delete vertices;
vertices are joined by straight-line segments.

Arguments:
 MAXPT  (input)  : maximum number of points that may be accepted.
 NPT    (in/out) : number of points entered; should be zero on
                   first call.
 X      (in/out) : array of x-coordinates (dimension at least MAXPT).
 Y      (in/out) : array of y-coordinates (dimension at least MAXPT).

Notes:

(1) On return from the program, cursor points are returned in
the order they were entered. Routine may be (re-)called with points
already defined in X,Y (# in NPT), and they will be plotted
first, before editing.

(2) User commands: the user types single-character commands
after positioning the cursor: the following are accepted:
  A (Add)    - add point at current cursor location.
  D (Delete) - delete last-entered point.
  X (eXit)   - leave subroutine.

PGLDEV -- list available device types on standard output

      SUBROUTINE PGLDEV

Writes (to standard output) a list of all device types available in
the current PGPLOT installation.

Arguments: none.

PGLEN -- find length of a string in a variety of units

      SUBROUTINE PGLEN (UNITS, STRING, XL, YL)
      REAL XL, YL
      INTEGER UNITS
      CHARACTER*(*) STRING

Work out length of a string in x and y directions 

Input
 UNITS    :  0 => answer in normalized device coordinates
             1 => answer in inches
             2 => answer in mm
             3 => answer in absolute device coordinates (dots)
             4 => answer in world coordinates
             5 => answer as a fraction of the current viewport size

 STRING   :  String of interest
Output
 XL       :  Length of string in x direction
 YL       :  Length of string in y direction


PGLINE -- draw a polyline (curve defined by line-segments)

      SUBROUTINE PGLINE (N, XPTS, YPTS)
      INTEGER  N
      REAL     XPTS(*), YPTS(*)

Primitive routine to draw a Polyline. A polyline is one or more
connected straight-line segments.  The polyline is drawn using
the current setting of attributes color-index, line-style, and
line-width. The polyline is clipped at the edge of the window.

Arguments:
 N      (input)  : number of points defining the line; the line
                   consists of (N-1) straight-line segments.
                   N should be greater than 1 (if it is 1 or less,
                   nothing will be drawn).
 XPTS   (input)  : world x-coordinates of the points.
 YPTS   (input)  : world y-coordinates of the points.

The dimension of arrays X and Y must be greater than or equal to N.
The "pen position" is changed to (X(N),Y(N)) in world coordinates
(if N > 1).

PGMOVE -- move pen (change current pen position)

      SUBROUTINE PGMOVE (X, Y)
      REAL X, Y

Primitive routine to move the "pen" to the point with world
coordinates (X,Y). No line is drawn.

Arguments:
 X      (input)  : world x-coordinate of the new pen position.
 Y      (input)  : world y-coordinate of the new pen position.

PGMTXT -- write text at position relative to viewport

      SUBROUTINE PGMTXT (SIDE, DISP, COORD, FJUST, TEXT)
      CHARACTER*(*) SIDE, TEXT
      REAL DISP, COORD, FJUST

Write text at a position specified relative to the viewport (outside
or inside).  This routine is useful for annotating graphs. It is used
by routine PGLAB.  The text is written using the current values of
attributes color-index, line-width, character-height, and
character-font.

Arguments:
 SIDE   (input)  : must include one of the characters 'B', 'L', 'T',
                   or 'R' signifying the Bottom, Left, Top, or Right
                   margin of the viewport. If it includes 'LV' or
                   'RV', the string is written perpendicular to the
                   frame rather than parallel to it.
 DISP   (input)  : the displacement of the character string from the
                   specified edge of the viewport, measured outwards
                   from the viewport in units of the character
                   height. Use a negative value to write inside the
                   viewport, a positive value to write outside.
 COORD  (input)  : the location of the character string along the
                   specified edge of the viewport, as a fraction of
                   the length of the edge.
 FJUST  (input)  : controls justification of the string parallel to
                   the specified edge of the viewport. If
                   FJUST = 0.0, the left-hand end of the string will
                   be placed at COORD; if JUST = 0.5, the center of
                   the string will be placed at COORD; if JUST = 1.0,
                   the right-hand end of the string will be placed at
                   at COORD. Other values between 0 and 1 give inter-
                   mediate placing, but they are not very useful.
 TEXT   (input) :  the text string to be plotted. Trailing spaces are
                   ignored when justifying the string, but leading
                   spaces are significant.


PGNCUR -- mark a set of points using the cursor

      SUBROUTINE PGNCUR (MAXPT, NPT, X, Y, SYMBOL)
      INTEGER MAXPT, NPT
      REAL    X(*), Y(*)
      INTEGER SYMBOL

Interactive routine for user to enter data points by use of
the cursor.  Routine allows user to Add and Delete points.  The
points are returned in order of increasing x-coordinate, not in the
order they were entered.

Arguments:
 MAXPT  (input)  : maximum number of points that may be accepted.
 NPT    (in/out) : number of points entered; should be zero on
                   first call.
 X      (in/out) : array of x-coordinates.
 Y      (in/out) : array of y-coordinates.
 SYMBOL (input)  : code number of symbol to use for marking
                   entered points (see PGPT).

Note (1): The dimension of arrays X and Y must be greater than or
equal to MAXPT.

Note (2): On return from the program, cursor points are returned in
increasing order of X. Routine may be (re-)called with points
already defined in X,Y (number in NPT), and they will be plotted
first, before editing.

Note (3): User commands: the user types single-character commands
after positioning the cursor: the following are accepted:
A (Add)    - add point at current cursor location.
D (Delete) - delete nearest point to cursor.
X (eXit)   - leave subroutine.

PGNUMB -- convert a number into a plottable character string

      SUBROUTINE PGNUMB (MM, PP, FORM, STRING, NC)
      INTEGER MM, PP, FORM
      CHARACTER*(*) STRING
      INTEGER NC

This routine converts a number into a decimal character
representation. To avoid problems of floating-point roundoff, the
number must be provided as an integer (MM) multiplied by a power of 10
(10**PP).  The output string retains only significant digits of MM,
and will be in either integer format (123), decimal format (0.0123),
or exponential format (1.23x10**5). Standard escape sequences \u, \d 
raise the exponent and \x is used for the multiplication sign.
This routine is used by PGBOX to create numeric labels for a plot.

Formatting rules:
  (a) Decimal notation (FORM=1):
      - Trailing zeros to the right of the decimal sign are
        omitted
      - The decimal sign is omitted if there are no digits
        to the right of it
      - When the decimal sign is placed before the first digit
        of the number, a zero is placed before the decimal sign
      - The decimal sign is a period (.)
      - No spaces are placed between digits (ie digits are not
        grouped in threes as they should be)
      - A leading minus (-) is added if the number is negative
  (b) Exponential notation (FORM=2):
      - The exponent is adjusted to put just one (non-zero)
        digit before the decimal sign
      - The mantissa is formatted as in (a), unless its value is
        1 in which case it and the multiplication sign are omitted
      - If the power of 10 is not zero and the mantissa is not
        zero, an exponent of the form \x10\u[-]nnn is appended,
        where \x is a multiplication sign (cross), \u is an escape
        sequence to raise the exponent, and as many digits nnn
        are used as needed
  (c) Automatic choice (FORM=0):
        Decimal notation is used if the absolute value of the
        number is less than 10000 or greater than or equal to
        0.01. Otherwise exponential notation is used.

Arguments:
 MM     (input)
 PP     (input)  : the value to be formatted is MM*10**PP.
 FORM   (input)  : controls how the number is formatted:
                   FORM = 0 -- use either decimal or exponential
                   FORM = 1 -- use decimal notation
                   FORM = 2 -- use exponential notation
 STRING (output) : the formatted character string, left justified.
                   If the length of STRING is insufficient, a single
                   asterisk is returned, and NC=1.
 NC     (output) : the number of characters used in STRING:
                   the string to be printed is STRING(1:NC).

PGOLIN -- mark a set of points using the cursor

      SUBROUTINE PGOLIN (MAXPT, NPT, X, Y, SYMBOL)
      INTEGER MAXPT, NPT
      REAL    X(*), Y(*)
      INTEGER SYMBOL

Interactive routine for user to enter data points by use of
the cursor.  Routine allows user to Add and Delete points.  The
points are returned in the order that they were entered (unlike
PGNCUR).

Arguments:
 MAXPT  (input)  : maximum number of points that may be accepted.
 NPT    (in/out) : number of points entered; should be zero on
                   first call.
 X      (in/out) : array of x-coordinates.
 Y      (in/out) : array of y-coordinates.
 SYMBOL (input)  : code number of symbol to use for marking
                   entered points (see PGPT).

Note (1): The dimension of arrays X and Y must be greater than or
equal to MAXPT.

Note (2): On return from the program, cursor points are returned in
the order they were entered. Routine may be (re-)called with points
already defined in X,Y (number in NPT), and they will be plotted
first, before editing.

Note (3): User commands: the user types single-character commands
after positioning the cursor: the following are accepted:
A (Add)    - add point at current cursor location.
D (Delete) - delete the last point entered.
X (eXit)   - leave subroutine.

PGOPEN -- open a graphics device

      INTEGER FUNCTION PGOPEN (DEVICE)
      CHARACTER*(*) DEVICE

Open a graphics device for PGPLOT output. If the device is
opened successfully, it becomes the selected device to which
graphics output is directed until another device is selected
with PGSLCT or the device is closed with PGCLOS.

The value returned by PGOPEN should be tested to ensure that
the device was opened successfully, e.g.,

      ISTAT = PGOPEN('plot.ps/PS')
      IF (ISTAT .LE. 0 ) STOP

Note that PGOPEN must be declared INTEGER in the calling program.

The DEVICE argument is a character constant or variable; its value
should be one of the following:

(1) A complete device specification of the form 'device/type' or
    'file/type', where 'type' is one of the allowed PGPLOT device
    types (installation-dependent) and 'device' or 'file' is the 
    name of a graphics device or disk file appropriate for this type.
    The 'device' or 'file' may contain '/' characters; the final
    '/' delimits the 'type'. If necessary to avoid ambiguity,
    the 'device' part of the string may be enclosed in double
    quotation marks.
(2) A device specification of the form '/type', where 'type' is one
    of the allowed PGPLOT device types. PGPLOT supplies a default
    file or device name appropriate for this device type.
(3) A device specification with '/type' omitted; in this case
    the type is taken from the environment variable PGPLOT_TYPE,
    if defined (e.g., setenv PGPLOT_TYPE PS). Because of possible
    confusion with '/' in file-names, omitting the device type
    in this way is not recommended.
(4) A blank string (' '); in this case, PGOPEN will use the value
    of environment variable PGPLOT_DEV as the device specification,
    or '/NULL' if the environment variable is undefined.
(5) A single question mark, with optional trailing spaces ('?'); in
    this case, PGPLOT will prompt the user to supply the device
    specification, with a prompt string of the form
        'Graphics device/type (? to see list, default XXX):'
    where 'XXX' is the default (value of environment variable
    PGPLOT_DEV).
(6) A non-blank string in which the first character is a question
    mark (e.g., '?Device: '); in this case, PGPLOT will prompt the
    user to supply the device specification, using the supplied
    string as the prompt (without the leading question mark but
    including any trailing spaces).

In cases (5) and (6), the device specification is read from the
standard input. The user should respond to the prompt with a device
specification of the form (1), (2), or (3). If the user types a 
question-mark in response to the prompt, a list of available device
types is displayed and the prompt is re-issued. If the user supplies
an invalid device specification, the prompt is re-issued. If the user
responds with an end-of-file character, e.g., ctrl-D in UNIX, program
execution is aborted; this  avoids the possibility of an infinite
prompting loop.  A programmer should avoid use of PGPLOT-prompting
if this behavior is not desirable.

The device type is case-insensitive (e.g., '/ps' and '/PS' are 
equivalent). The device or file name may be case-sensitive in some
operating systems.

Examples of valid DEVICE arguments:

(1)  'plot.ps/ps', 'dir/plot.ps/ps', '"dir/plot.ps"/ps', 
     'user:[tjp.plots]plot.ps/PS'
(2)  '/ps'      (PGPLOT interprets this as 'pgplot.ps/ps')
(3)  'plot.ps'  (if PGPLOT_TYPE is defined as 'ps', PGPLOT
                 interprets this as 'plot.ps/ps')
(4)  '   '      (if PGPLOT_DEV is defined)
(5)  '?  '
(6)  '?Device specification for PGPLOT: '

[This routine was added to PGPLOT in Version 5.1.0. Older programs
use PGBEG instead.]

Returns:
 PGOPEN          : returns either a positive value, the
                   identifier of the graphics device for use with
                   PGSLCT, or a 0 or negative value indicating an
                   error. In the event of error a message is
                   written on the standard error unit.
Arguments:
 DEVICE  (input) : the 'device specification' for the plot device
                   (see above).

PGPAGE -- advance to new page

      SUBROUTINE PGPAGE

Advance plotter to a new page or panel, clearing the screen if
necessary. If the "prompt state" is ON (see PGASK), confirmation is
requested from the user before clearing the screen. If the view
surface has been subdivided into panels with PGBEG or PGSUBP, then
PGPAGE advances to the next panel, and if the current panel is the
last on the page, PGPAGE clears the screen or starts a new sheet of
paper.  PGPAGE does not change the PGPLOT window or the viewport
(in normalized device coordinates); but note that if the size of the
view-surface is changed externally (e.g., by a workstation window
manager) the size of the viewport is changed in proportion.

Arguments: none

PGPANL -- switch to a different panel on the view surface

      SUBROUTINE PGPANL(IX, IY)
      INTEGER IX, IY

Start plotting in a different panel. If the view surface has been
divided into panels by PGBEG or PGSUBP, this routine can be used to
move to a different panel. Note that PGPLOT does not remember what
viewport and window were in use in each panel; these should be reset
if necessary after calling PGPANL. Nor does PGPLOT clear the panel:
call PGERAS after calling PGPANL to do this.

Arguments:
 IX     (input)  : the horizontal index of the panel (in the range
                   1 <= IX <= number of panels in horizontal
                   direction).
 IY     (input)  : the vertical index of the panel (in the range
                   1 <= IY <= number of panels in horizontal
                   direction).

PGPAP -- change the size of the view surface

      SUBROUTINE PGPAP (WIDTH, ASPECT)
      REAL WIDTH, ASPECT

This routine changes the size of the view surface ("paper size") to a
specified width and aspect ratio (height/width), in so far as this is
possible on the specific device. It is always possible to obtain a
view surface smaller than the default size; on some devices (e.g.,
printers that print on roll or fan-feed paper) it is possible to 
obtain a view surface larger than the default.

This routine should be called either immediately after PGBEG or
immediately before PGPAGE. The new size applies to all subsequent
images until the next call to PGPAP.

Arguments:
 WIDTH  (input)  : the requested width of the view surface in inches;
                   if WIDTH=0.0, PGPAP will obtain the largest view
                   surface available consistent with argument ASPECT.
                   (1 inch = 25.4 mm.)
 ASPECT (input)  : the aspect ratio (height/width) of the view
                   surface; e.g., ASPECT=1.0 gives a square view
                   surface, ASPECT=0.618 gives a horizontal
                   rectangle, ASPECT=1.618 gives a vertical rectangle.

PGPIXL -- draw pixels

      SUBROUTINE PGPIXL (IA, IDIM, JDIM, I1, I2, J1, J2, 
     1                   X1, X2, Y1, Y2)
      INTEGER IDIM, JDIM, I1, I2, J1, J2
      INTEGER IA(IDIM,JDIM)
      REAL    X1, X2, Y1, Y2

Draw lots of solid-filled (tiny) rectangles aligned with the
coordinate axes. Best performance is achieved when output is
directed to a pixel-oriented device and the rectangles coincide
with the pixels on the device. In other cases, pixel output is
emulated.

The subsection of the array IA defined by indices (I1:I2, J1:J2)
is mapped onto world-coordinate rectangle defined by X1, X2, Y1
and Y2. This rectangle is divided into (I2 - I1 + 1) * (J2 - J1 + 1)
small rectangles. Each of these small rectangles is solid-filled
with the color index specified by the corresponding element of 
IA.

On most devices, the output region is "opaque", i.e., it obscures
all graphical elements previously drawn in the region. But on
devices that do not have erase capability, the background shade
is "transparent" and allows previously-drawn graphics to show
through.

Arguments:
 IA     (input)  : the array to be plotted.
 IDIM   (input)  : the first dimension of array A.
 JDIM   (input)  : the second dimension of array A.
 I1, I2 (input)  : the inclusive range of the first index
                   (I) to be plotted.
 J1, J2 (input)  : the inclusive range of the second
                   index (J) to be plotted.
 X1, Y1 (input)  : world coordinates of one corner of the output
                   region
 X2, Y2 (input)  : world coordinates of the opposite corner of the
                   output region

PGPNTS -- draw several graph markers, not all the same

      SUBROUTINE PGPNTS (N, X, Y, SYMBOL, NS)
      INTEGER N, NS
      REAL X(*), Y(*)
      INTEGER SYMBOL(*)

Draw Graph Markers. Unlike PGPT, this routine can draw a different
symbol at each point. The markers are drawn using the current values
of attributes color-index, line-width, and character-height
(character-font applies if the symbol number is >31).  If the point
to be marked lies outside the window, no marker is drawn.  The "pen 
position" is changed to (XPTS(N),YPTS(N)) in world coordinates
(if N > 0).

Arguments:
 N      (input)  : number of points to mark.
 X      (input)  : world x-coordinate of the points.
 Y      (input)  : world y-coordinate of the points.
 SYMBOL (input)  : code number of the symbol to be plotted at each
                   point (see PGPT).
 NS     (input)  : number of values in the SYMBOL array.  If NS <= N,
                   then the first NS points are drawn using the value
                   of SYMBOL(I) at (X(I), Y(I)) and SYMBOL(1) for all
                   the values of (X(I), Y(I)) where I > NS.

Note: the dimension of arrays X and Y must be greater than or equal
to N and the dimension of the array SYMBOL must be greater than or
equal to NS.  If N is 1, X and Y may be scalars (constants or
variables).  If NS is 1, then SYMBOL may be a scalar.  If N is
less than 1, nothing is drawn.

PGPOLY -- draw a polygon, using fill-area attributes

      SUBROUTINE PGPOLY (N, XPTS, YPTS)
      INTEGER N
      REAL XPTS(*), YPTS(*)

Fill-area primitive routine: shade the interior of a closed
polygon in the current window.  The action of this routine depends
on the setting of the Fill-Area Style attribute (see PGSFS).
The polygon is clipped at the edge of the
window. The pen position is changed to (XPTS(1),YPTS(1)) in world
coordinates (if N > 1).  If the polygon is not convex, a point is
assumed to lie inside the polygon if a straight line drawn to
infinity intersects and odd number of the polygon's edges.

Arguments:
 N      (input)  : number of points defining the polygon; the
                   line consists of N straight-line segments,
                   joining points 1 to 2, 2 to 3,... N-1 to N, N to 1.
                   N should be greater than 2 (if it is 2 or less,
                   nothing will be drawn).
 XPTS   (input)  : world x-coordinates of the vertices.
 YPTS   (input)  : world y-coordinates of the vertices.
                   Note: the dimension of arrays XPTS and YPTS must be
                   greater than or equal to N.

PGPT -- draw several graph markers

      SUBROUTINE PGPT (N, XPTS, YPTS, SYMBOL)
      INTEGER N
      REAL XPTS(*), YPTS(*)
      INTEGER SYMBOL

Primitive routine to draw Graph Markers (polymarker). The markers
are drawn using the current values of attributes color-index,
line-width, and character-height (character-font applies if the symbol
number is >31).  If the point to be marked lies outside the window,
no marker is drawn.  The "pen position" is changed to
(XPTS(N),YPTS(N)) in world coordinates (if N > 0).

Arguments:
 N      (input)  : number of points to mark.
 XPTS   (input)  : world x-coordinates of the points.
 YPTS   (input)  : world y-coordinates of the points.
 SYMBOL (input)  : code number of the symbol to be drawn at each 
                   point:
                   -1, -2  : a single dot (diameter = current
                             line width).
                   -3..-31 : a regular polygon with ABS(SYMBOL)
                             edges (style set by current fill style).
                   0..31   : standard marker symbols.
                   32..127 : ASCII characters (in current font).
                             e.g. to use letter F as a marker, let
                             SYMBOL = ICHAR('F'). 
                   > 127  :  a Hershey symbol number.

Note: the dimension of arrays X and Y must be greater than or equal
to N. If N is 1, X and Y may be scalars (constants or variables). If
N is less than 1, nothing is drawn.

PGPT1 -- draw one graph marker

      SUBROUTINE PGPT1 (XPT, YPT, SYMBOL)
      REAL XPT, YPT
      INTEGER SYMBOL

Primitive routine to draw a single Graph Marker at a specified point.
The marker is drawn using the current values of attributes
color-index, line-width, and character-height (character-font applies
if the symbol number is >31).  If the point to be marked lies outside
the window, no marker is drawn.  The "pen position" is changed to
(XPT,YPT) in world coordinates.

To draw several markers with coordinates specified by X and Y
arrays, use routine PGPT.

Arguments:
 XPT    (input)  : world x-coordinate of the point.
 YPT    (input)  : world y-coordinate of the point.
 SYMBOL (input)  : code number of the symbol to be drawn:
                   -1, -2  : a single dot (diameter = current
                             line width).
                   -3..-31 : a regular polygon with ABS(SYMBOL)
                             edges (style set by current fill style).
                   0..31   : standard marker symbols.
                   32..127 : ASCII characters (in current font).
                             e.g. to use letter F as a marker, let
                             SYMBOL = ICHAR('F'). 
                   > 127  :  a Hershey symbol number.

PGPTXT -- write text at arbitrary position and angle

      SUBROUTINE PGPTXT (X, Y, ANGLE, FJUST, TEXT)
      REAL X, Y, ANGLE, FJUST
      CHARACTER*(*) TEXT

Primitive routine for drawing text. The text may be drawn at any
angle with the horizontal, and may be centered or left- or right-
justified at a specified position.  Routine PGTEXT provides a
simple interface to PGPTXT for horizontal strings. Text is drawn
using the current values of attributes color-index, line-width,
character-height, and character-font.  Text is NOT subject to
clipping at the edge of the window.

Arguments:
 X      (input)  : world x-coordinate.
 Y      (input)  : world y-coordinate. The string is drawn with the
                   baseline of all the characters passing through
                   point (X,Y); the positioning of the string along
                   this line is controlled by argument FJUST.
 ANGLE  (input)  : angle, in degrees, that the baseline is to make
                   with the horizontal, increasing counter-clockwise
                   (0.0 is horizontal).
 FJUST  (input)  : controls horizontal justification of the string.
                   If FJUST = 0.0, the string will be left-justified
                   at the point (X,Y); if FJUST = 0.5, it will be
                   centered, and if FJUST = 1.0, it will be right
                   justified. [Other values of FJUST give other
                   justifications.]
 TEXT   (input)  : the character string to be plotted.

PGQAH -- inquire arrow-head style

      SUBROUTINE PGQAH (FS, ANGLE, BARB)
      INTEGER  FS
      REAL ANGLE, BARB

Query the style to be used for arrowheads drawn with routine PGARRO.

Argument:
 FS     (output) : FS = 1 => filled; FS = 2 => outline.
 ANGLE  (output) : the acute angle of the arrow point, in degrees.
 BARB   (output) : the fraction of the triangular arrow-head that
                   is cut away from the back. 

PGQCF -- inquire character font

      SUBROUTINE PGQCF (FONT)
      INTEGER  FONT

Query the current Character Font (set by routine PGSCF).

Argument:
 FONT   (output)   : the current font number (in range 1-4).

PGQCH -- inquire character height

      SUBROUTINE PGQCH (SIZE)
      REAL SIZE

Query the Character Size attribute (set by routine PGSCH).

Argument:
 SIZE   (output) : current character size (dimensionless multiple of
                   the default size).

PGQCI -- inquire color index

      SUBROUTINE PGQCI (CI)
      INTEGER  CI

Query the Color Index attribute (set by routine PGSCI).

Argument:
 CI     (output) : the current color index (in range 0-max). This is
                   the color index actually in use, and may differ
                   from the color index last requested by PGSCI if
                   that index is not available on the output device.

PGQCIR -- inquire color index range

      SUBROUTINE PGQCIR(ICILO, ICIHI)
      INTEGER   ICILO, ICIHI

Query the color index range to be used for producing images with
PGGRAY or PGIMAG, as set by routine PGSCIR or by device default.

Arguments:
 ICILO  (output) : the lowest color index to use for images
 ICIHI  (output) : the highest color index to use for images

PGQCLP -- inquire clipping status

      SUBROUTINE PGQCLP(STATE)
      INTEGER  STATE

Query the current clipping status (set by routine PGSCLP).

Argument:
 STATE  (output) : receives the clipping status (0 => disabled,
                   1 => enabled).

PGQCOL -- inquire color capability

      SUBROUTINE PGQCOL (CI1, CI2)
      INTEGER  CI1, CI2

Query the range of color indices available on the current device.

Argument:
 CI1    (output) : the minimum available color index. This will be
                   either 0 if the device can write in the
                   background color, or 1 if not.
 CI2    (output) : the maximum available color index. This will be
                   1 if the device has no color capability, or a
                   larger number (e.g., 3, 7, 15, 255).

PGQCR -- inquire color representation

      SUBROUTINE PGQCR (CI, CR, CG, CB)
      INTEGER CI
      REAL    CR, CG, CB

Query the RGB colors associated with a color index.

Arguments:
 CI  (input)  : color index
 CR  (output) : red, green and blue intensities
 CG  (output)   in the range 0.0 to 1.0
 CB  (output)

PGQCS -- inquire character height in a variety of units

      SUBROUTINE PGQCS(UNITS, XCH, YCH)
      INTEGER UNITS
      REAL XCH, YCH

Return the current PGPLOT character height in a variety of units.
This routine provides facilities that are not available via PGQCH.
Use PGQCS if the character height is required in units other than
those used in PGSCH.

The PGPLOT "character height" is a dimension that scales with the
size of the view surface and with the scale-factor specified with
routine PGSCH. The default value is 1/40th of the height or width
of the view surface (whichever is less); this value is then
multiplied by the scale-factor supplied with PGSCH. Note that it
is a nominal height only; the actual character size depends on the
font and is usually somewhat smaller.

Arguments:
 UNITS  (input)  : Used to specify the units of the output value:
                   UNITS = 0 : normalized device coordinates
                   UNITS = 1 : inches
                   UNITS = 2 : millimeters
                   UNITS = 3 : pixels
                   UNITS = 4 : world coordinates
                   Other values give an error message, and are
                   treated as 0.
 XCH    (output) : The character height for text written with a
                   vertical baseline.
 YCH    (output) : The character height for text written with
                   a horizontal baseline (the usual case).

The character height is returned in both XCH and YCH.

If UNITS=1 or UNITS=2, XCH and YCH both receive the same value.

If UNITS=3, XCH receives the height in horizontal pixel units, and YCH
receives the height in vertical pixel units; on devices for which the
pixels are not square, XCH and YCH will be different.

If UNITS=4, XCH receives the height in horizontal world coordinates
(as used for the x-axis), and YCH receives the height in vertical
world coordinates (as used for the y-axis). Unless special care has
been taken to achive equal world-coordinate scales on both axes, the
values of XCH and YCH will be different.

If UNITS=0, XCH receives the character height as a fraction of the
horizontal dimension of the view surface, and YCH receives the
character height as a fraction of the vertical dimension of the view
surface.

PGQDT -- inquire name of nth available device type

      SUBROUTINE PGQDT(N, TYPE, TLEN, DESCR, DLEN, INTER)
      INTEGER N
      CHARACTER*(*) TYPE, DESCR
      INTEGER TLEN, DLEN, INTER

Return the name of the Nth available device type as a character
string. The number of available types can be determined by calling
PGQNDT. If the value of N supplied is outside the range from 1 to
the number of available types, the routine returns DLEN=TLEN=0.

Arguments:
 N      (input)  : the number of the device type (1..maximum).
 TYPE   (output) : receives the character device-type code of the
                   Nth device type. The argument supplied should be
                   large enough for at least 8 characters. The first
                   character in the string is a '/' character.
 TLEN   (output) : receives the number of characters in TYPE,
                   excluding trailing blanks.
 DESCR  (output) : receives a description of the device type. The
                   argument supplied should be large enough for at
                   least 64 characters.
 DLEN   (output) : receives the number of characters in DESCR,
                   excluding trailing blanks.
 INTER  (output) : receives 1 if the device type is an interactive
                   one, 0 otherwise.

PGQFS -- inquire fill-area style

      SUBROUTINE PGQFS (FS)
      INTEGER  FS

Query the current Fill-Area Style attribute (set by routine
PGSFS).

Argument:
 FS     (output) : the current fill-area style:
                     FS = 1 => solid (default)
                     FS = 2 => outline
                     FS = 3 => hatched
                     FS = 4 => cross-hatched

PGQHS -- inquire hatching style

      SUBROUTINE PGQHS (ANGLE, SEPN, PHASE)
      REAL ANGLE, SEPN, PHASE

Query the style to be used hatching (fill area with fill-style 3).

Arguments:
 ANGLE  (output) : the angle the hatch lines make with the
                   horizontal, in degrees, increasing 
                   counterclockwise (this is an angle on the
                   view surface, not in world-coordinate space).
 SEPN   (output) : the spacing of the hatch lines. The unit spacing
                   is 1 percent of the smaller of the height or
                   width of the view surface.
 PHASE  (output) : a real number between 0 and 1; the hatch lines
                   are displaced by this fraction of SEPN from a
                   fixed reference.  Adjacent regions hatched with the
                   same PHASE have contiguous hatch lines.

PGQID -- inquire current device identifier

      SUBROUTINE PGQID (ID)
      INTEGER  ID

This subroutine returns the identifier of the currently
selected device, or 0 if no device is selected.  The identifier is
assigned when PGOPEN is called to open the device, and may be used
as an argument to PGSLCT.  Each open device has a different
identifier.

[This routine was added to PGPLOT in Version 5.1.0.]

Argument:
 ID     (output) : the identifier of the current device, or 0 if
                   no device is currently selected.

PGQINF -- inquire PGPLOT general information

      SUBROUTINE PGQINF (ITEM, VALUE, LENGTH)
      CHARACTER*(*) ITEM, VALUE
      INTEGER LENGTH

This routine can be used to obtain miscellaneous information about
the PGPLOT environment. Input is a character string defining the
information required, and output is a character string containing the
requested information.

The following item codes are accepted (note that the strings must
match exactly, except for case, but only the first 8 characters are
significant). For items marked *, PGPLOT must be in the OPEN state
for the inquiry to succeed. If the inquiry is unsuccessful, either
because the item code is not recognized or because the information
is not available, a question mark ('?') is returned.

  'VERSION'     - version of PGPLOT software in use.
  'STATE'       - status of PGPLOT ('OPEN' if a graphics device
                  is open for output, 'CLOSED' otherwise).
  'USER'        - the username associated with the calling program.
  'NOW'         - current date and time (e.g., '17-FEB-1986 10:04').
  'DEVICE'    * - current PGPLOT device or file.
  'FILE'      * - current PGPLOT device or file.
  'TYPE'      * - device-type of the current PGPLOT device.
  'DEV/TYPE'  * - current PGPLOT device and type, in a form which
                  is acceptable as an argument for PGBEG.
  'HARDCOPY'  * - is the current device a hardcopy device? ('YES' or
                  'NO').
  'TERMINAL'  * - is the current device the user's interactive
                  terminal? ('YES' or 'NO').
  'CURSOR'    * - does the current device have a graphics cursor?
                  ('YES' or 'NO').
  'SCROLL'    * - does current device have rectangle-scroll
                  capability ('YES' or 'NO'); see PGSCRL.

Arguments:
 ITEM  (input)  : character string defining the information to
                  be returned; see above for a list of possible
                  values.
 VALUE (output) : returns a character-string containing the
                  requested information, truncated to the length 
                  of the supplied string or padded on the right with 
                  spaces if necessary.
 LENGTH (output): the number of characters returned in VALUE
                  (excluding trailing blanks).

PGQITF -- inquire image transfer function

      SUBROUTINE PGQITF (ITF)
      INTEGER  ITF

Return the Image Transfer Function as set by default or by a previous
call to PGSITF. The Image Transfer Function is used by routines
PGIMAG, PGGRAY, and PGWEDG.

Argument:
 ITF    (output) : type of transfer function (see PGSITF)

PGQLS -- inquire line style

      SUBROUTINE PGQLS (LS)
      INTEGER  LS

Query the current Line Style attribute (set by routine PGSLS).

Argument:
 LS     (output) : the current line-style attribute (in range 1-5).

PGQLW -- inquire line width

      SUBROUTINE PGQLW (LW)
      INTEGER  LW

Query the current Line-Width attribute (set by routine PGSLW).

Argument:
 LW     (output)  : the line-width (in range 1-201).

PGQNDT -- inquire number of available device types

      SUBROUTINE PGQNDT(N)
      INTEGER N

Return the number of available device types. This routine is
usually used in conjunction with PGQDT to get a list of the
available device types.

Arguments:
 N      (output) : the number of available device types.

PGQPOS -- inquire current pen position

      SUBROUTINE PGQPOS (X, Y)
      REAL X, Y

Query the current "pen" position in world C coordinates (X,Y).

Arguments:
 X      (output)  : world x-coordinate of the pen position.
 Y      (output)  : world y-coordinate of the pen position.

PGQTBG -- inquire text background color index

      SUBROUTINE PGQTBG (TBCI)
      INTEGER  TBCI

Query the current Text Background Color Index (set by routine
PGSTBG).

Argument:
 TBCI   (output) : receives the current text background color index.

PGQTXT -- find bounding box of text string

      SUBROUTINE PGQTXT (X, Y, ANGLE, FJUST, TEXT, XBOX, YBOX)
      REAL X, Y, ANGLE, FJUST
      CHARACTER*(*) TEXT
      REAL XBOX(4), YBOX(4)

This routine returns a bounding box for a text string. Instead
of drawing the string as routine PGPTXT does, it returns in XBOX
and YBOX the coordinates of the corners of a rectangle parallel
to the string baseline that just encloses the string. The four
corners are in the order: lower left, upper left, upper right,
lower right (where left and right refer to the first and last
characters in the string).

If the string is blank or contains no drawable characters, all
four elements of XBOX and YBOX are assigned the starting point
of the string, (X,Y).

Arguments:
 X, Y, ANGLE, FJUST, TEXT (input) : these arguments are the same as
                   the corrresponding arguments in PGPTXT.
 XBOX, YBOX (output) : arrays of dimension 4; on output, they
                   contain the world coordinates of the bounding
                   box in (XBOX(1), YBOX(1)), ..., (XBOX(4), YBOX(4)).

PGQVP -- inquire viewport size and position

      SUBROUTINE PGQVP (UNITS, X1, X2, Y1, Y2)
      INTEGER UNITS
      REAL    X1, X2, Y1, Y2

Inquiry routine to determine the current viewport setting.
The values returned may be normalized device coordinates, inches, mm,
or pixels, depending on the value of the input parameter CFLAG.

Arguments:
 UNITS  (input)  : used to specify the units of the output parameters:
                   UNITS = 0 : normalized device coordinates
                   UNITS = 1 : inches
                   UNITS = 2 : millimeters
                   UNITS = 3 : pixels
                   Other values give an error message, and are
                   treated as 0.
 X1     (output) : the x-coordinate of the bottom left corner of the
                   viewport.
 X2     (output) : the x-coordinate of the top right corner of the
                   viewport.
 Y1     (output) : the y-coordinate of the bottom left corner of the
                   viewport.
 Y2     (output) : the y-coordinate of the top right corner of the
                   viewport.

PGQVSZ -- inquire size of view surface

      SUBROUTINE PGQVSZ (UNITS, X1, X2, Y1, Y2)
      INTEGER UNITS
      REAL X1, X2, Y1, Y2

This routine returns the dimensions of the view surface (the maximum
plottable area) of the currently selected graphics device, in 
a variety of units. The size of the view surface is device-dependent
and is established when the graphics device is opened. On some 
devices, it can be changed by calling PGPAP before starting a new
page with PGPAGE. On some devices, the size can be changed (e.g.,
by a workstation window manager) outside PGPLOT, and PGPLOT detects
the change when PGPAGE is used. Call this routine after PGPAGE to 
find the current size.

Note 1: the width and the height of the view surface in normalized
device coordinates are both always equal to 1.0.

Note 2: when the device is divided into panels (see PGSUBP), the
view surface is a single panel.

Arguments:
 UNITS  (input)  : 0,1,2,3 for output in normalized device coords, 
                   inches, mm, or device units (pixels)
 X1     (output) : always returns 0.0
 X2     (output) : width of view surface
 Y1     (output) : always returns 0.0
 Y2     (output) : height of view surface

PGQWIN -- inquire window boundary coordinates

      SUBROUTINE PGQWIN (X1, X2, Y1, Y2)
      REAL X1, X2, Y1, Y2

Inquiry routine to determine the current window setting.
The values returned are world coordinates.

Arguments:
 X1     (output) : the x-coordinate of the bottom left corner
                   of the window.
 X2     (output) : the x-coordinate of the top right corner
                   of the window.
 Y1     (output) : the y-coordinate of the bottom left corner
                   of the window.
 Y2     (output) : the y-coordinate of the top right corner
                   of the window.

PGRECT -- draw a rectangle, using fill-area attributes

      SUBROUTINE PGRECT (X1, X2, Y1, Y2)
      REAL X1, X2, Y1, Y2

This routine can be used instead of PGPOLY for the special case of
drawing a rectangle aligned with the coordinate axes; only two
vertices need be specified instead of four.  On most devices, it is
faster to use PGRECT than PGPOLY for drawing rectangles.  The
rectangle has vertices at (X1,Y1), (X1,Y2), (X2,Y2), and (X2,Y1).

Arguments:
 X1, X2 (input) : the horizontal range of the rectangle.
 Y1, Y2 (input) : the vertical range of the rectangle.

PGRND -- find the smallest `round' number greater than x

      REAL FUNCTION PGRND (X, NSUB)
      REAL X
      INTEGER NSUB

Routine to find the smallest "round" number larger than x, a
"round" number being 1, 2 or 5 times a power of 10. If X is negative,
PGRND(X) = -PGRND(ABS(X)). eg PGRND(8.7) = 10.0,
PGRND(-0.4) = -0.5.  If X is zero, the value returned is zero.
This routine is used by PGBOX for choosing  tick intervals.

Returns:
 PGRND         : the "round" number.
Arguments:
 X      (input)  : the number to be rounded.
 NSUB   (output) : a suitable number of subdivisions for
                   subdividing the "nice" number: 2 or 5.

PGRNGE -- choose axis limits

      SUBROUTINE PGRNGE (X1, X2, XLO, XHI)
      REAL X1, X2, XLO, XHI

Choose plotting limits XLO and XHI which encompass the data
range X1 to X2.

Arguments:
 X1, X2 (input)  : the data range (X1<X2), ie, the min and max values
                   to be plotted.
 XLO, XHI (output) : suitable values to use as the extremes of a graph
                   axis (XLO <= X1, XHI >= X2).

PGSAH -- set arrow-head style

      SUBROUTINE PGSAH (FS, ANGLE, BARB)
      INTEGER  FS
      REAL ANGLE, BARB

Set the style to be used for arrowheads drawn with routine PGARRO.

Argument:
 FS     (input)  : FS = 1 => filled; FS = 2 => outline.
                   Other values are treated as 2. Default 1.
 ANGLE  (input)  : the acute angle of the arrow point, in degrees;
                   angles in the range 20.0 to 90.0 give reasonable
                   results. Default 45.0.
 BARB   (input)  : the fraction of the triangular arrow-head that
                   is cut away from the back. 0.0 gives a triangular
                   wedge arrow-head; 1.0 gives an open >. Values 0.3
                   to 0.7 give reasonable results. Default 0.3.

PGSAVE -- save PGPLOT attributes

      SUBROUTINE PGSAVE

This routine saves the current PGPLOT attributes in a private storage
area. They can be restored by calling PGUNSA (unsave). Attributes
saved are: character font, character height, color index, fill-area
style, line style, line width, pen position, arrow-head style, 
hatching style, and clipping state. Color representation is not saved.

Calls to PGSAVE and PGUNSA should always be paired. Up to 20 copies
of the attributes may be saved. PGUNSA always retrieves the last-saved
values (last-in first-out stack).

Note that when multiple devices are in use, PGUNSA retrieves the
values saved by the last PGSAVE call, even if they were for a
different device.

Arguments: none

PGUNSA -- restore PGPLOT attributes

      ENTRY PGUNSA

This routine restores the PGPLOT attributes saved in the last call to
PGSAVE. Usage: CALL PGUNSA (no arguments). See PGSAVE.

Arguments: none

PGSCF -- set character font

      SUBROUTINE PGSCF (FONT)
      INTEGER  FONT

Set the Character Font for subsequent text plotting. Four different
fonts are available:
  1: (default) a simple single-stroke font ("normal" font)
  2: roman font
  3: italic font
  4: script font
This call determines which font is in effect at the beginning of
each text string. The font can be changed (temporarily) within a text
string by using the escape sequences \fn, \fr, \fi, and \fs for fonts
1, 2, 3, and 4, respectively.

Argument:
 FONT   (input)  : the font number to be used for subsequent text
                   plotting (in range 1-4).

PGSCH -- set character height

      SUBROUTINE PGSCH (SIZE)
      REAL SIZE

Set the character size attribute. The size affects all text and graph
markers drawn later in the program. The default character size is
1.0, corresponding to a character height about 1/40 the height of
the view surface.  Changing the character size also scales the length
of tick marks drawn by PGBOX and terminals drawn by PGERRX and PGERRY.

Argument:
 SIZE   (input)  : new character size (dimensionless multiple of
                   the default size).

PGSCI -- set color index

      SUBROUTINE PGSCI (CI)
      INTEGER  CI

Set the Color Index for subsequent plotting, if the output device
permits this. The default color index is 1, usually white on a black
background for video displays or black on a white background for
printer plots. The color index is an integer in the range 0 to a
device-dependent maximum. Color index 0 corresponds to the background
color; lines may be "erased" by overwriting them with color index 0
(if the device permits this).

If the requested color index is not available on the selected device,
color index 1 will be substituted.

The assignment of colors to color indices can be changed with
subroutine PGSCR (set color representation).  Color indices 0-15
have predefined color representations (see the PGPLOT manual), but
these may be changed with PGSCR.  Color indices above 15  have no
predefined representations: if these indices are used, PGSCR must
be called to define the representation.

Argument:
 CI     (input)  : the color index to be used for subsequent plotting
                   on the current device (in range 0-max). If the
                   index exceeds the device-dependent maximum, the
                   default color index (1) is used.

PGSCIR -- set color index range

      SUBROUTINE PGSCIR(ICILO, ICIHI)
      INTEGER   ICILO, ICIHI

Set the color index range to be used for producing images with
PGGRAY or PGIMAG. If the range is not all within the range supported
by the device, a smaller range will be used. The number of
different colors available for images is ICIHI-ICILO+1.

Arguments:
 ICILO  (input)  : the lowest color index to use for images
 ICIHI  (input)  : the highest color index to use for images

PGSCLP -- enable or disable clipping at edge of viewport

      SUBROUTINE PGSCLP(STATE)
      INTEGER STATE

Normally all PGPLOT primitives except text are ``clipped'' at the
edge of the viewport: parts of the primitives that lie outside
the viewport are not drawn. If clipping is disabled by calling this
routine, primitives are visible wherever they lie on the view
surface. The default (clipping enabled) is appropriate for almost
all applications.

Argument:
 STATE  (input)  : 0 to disable clipping, or 1 to enable clipping.

25-Feb-1997 [TJP] - new routine.

PGSCR -- set color representation

      SUBROUTINE PGSCR (CI, CR, CG, CB)
      INTEGER CI
      REAL    CR, CG, CB

Set color representation: i.e., define the color to be
associated with a color index.  Ignored for devices which do not
support variable color or intensity.  Color indices 0-15
have predefined color representations (see the PGPLOT manual), but
these may be changed with PGSCR.  Color indices 16-maximum have no
predefined representations: if these indices are used, PGSCR must
be called to define the representation. On monochrome output
devices (e.g. VT125 terminals with monochrome monitors), the
monochrome intensity is computed from the specified Red, Green, Blue
intensities as 0.30*R + 0.59*G + 0.11*B, as in US color television
systems, NTSC encoding.  Note that most devices do not have an
infinite range of colors or monochrome intensities available;
the nearest available color is used.  Examples: for black,
set CR=CG=CB=0.0; for white, set CR=CG=CB=1.0; for medium gray,
set CR=CG=CB=0.5; for medium yellow, set CR=CG=0.5, CB=0.0.

Argument:
 CI     (input)  : the color index to be defined, in the range 0-max.
                   If the color index greater than the device
                   maximum is specified, the call is ignored. Color
                   index 0 applies to the background color.
 CR     (input)  : red, green, and blue intensities,
 CG     (input)    in range 0.0 to 1.0.
 CB     (input)

PGSCRL -- scroll window

      SUBROUTINE PGSCRL (DX, DY)
      REAL DX, DY

This routine moves the window in world-coordinate space while
leaving the viewport unchanged. On devices that have the
capability, the pixels within the viewport are scrolled
horizontally, vertically or both in such a way that graphics
previously drawn in the window are shifted so that their world
coordinates are unchanged.

If the old window coordinate range was (X1, X2, Y1, Y2), the new
coordinate range will be approximately (X1+DX, X2+DX, Y1+DY, Y2+DY).
The size and scale of the window are unchanged.

Thee window can only be shifted by a whole number of pixels
(device coordinates). If DX and DY do not correspond to integral
numbers of pixels, the shift will be slightly different from that
requested. The new window-coordinate range, and hence the exact
amount of the shift, can be determined by calling PGQWIN after this
routine.

Pixels that are moved out of the viewport by this operation are
lost completely; they cannot be recovered by scrolling back.
Pixels that are ``scrolled into'' the viewport are filled with
the background color (color index 0).

If the absolute value of DX is bigger than the width of the window,
or the aboslute value of DY is bigger than the height of the window,
the effect will be the same as zeroing all the pixels in the
viewport.

Not all devices have the capability to support this routine.
It is only available on some interactive devices that have discrete
pixels. To determine whether the current device has scroll capability,
call PGQINF.

Arguments:
 DX     (input)  : distance (in world coordinates) to shift the
                   window horizontally (positive shifts window to the
                   right and scrolls to the left).
 DY     (input)  : distance (in world coordinates) to shift the
                   window vertically (positive shifts window up and
                   scrolls down).

PGSCRN -- set color representation by name

      SUBROUTINE PGSCRN(CI, NAME, IER)
      INTEGER CI
      CHARACTER*(*) NAME
      INTEGER IER

Set color representation: i.e., define the color to be
associated with a color index.  Ignored for devices which do not
support variable color or intensity.  This is an alternative to
routine PGSCR. The color representation is defined by name instead
of (R,G,B) components.

Color names are defined in an external file which is read the first
time that PGSCRN is called. The name of the external file is
found as follows:
1. if environment variable (logical name) PGPLOT_RGB is defined,
   its value is used as the file name;
2. otherwise, if environment variable PGPLOT_DIR is defined, a
   file "rgb.txt" in the directory named by this environment
   variable is used;
3. otherwise, file "rgb.txt" in the current directory is used.
If all of these fail to find a file, an error is reported and
the routine does nothing.

Each line of the file
defines one color, with four blank- or tab-separated fields per
line. The first three fields are the R, G, B components, which
are integers in the range 0 (zero intensity) to 255 (maximum
intensity). The fourth field is the color name. The color name
may include embedded blanks. Example:

255   0   0 red
255 105 180 hot pink
255 255 255 white
  0   0   0 black

Arguments:
 CI     (input)  : the color index to be defined, in the range 0-max.
                   If the color index greater than the device
                   maximum is specified, the call is ignored. Color
                   index 0 applies to the background color.
 NAME   (input)  : the name of the color to be associated with
                   this color index. This name must be in the
                   external file. The names are not case-sensitive.
                   If the color is not listed in the file, the
                   color representation is not changed.
 IER    (output) : returns 0 if the routine was successful, 1
                   if an error occurred (either the external file
                   could not be read, or the requested color was
                   not defined in the file).

PGSFS -- set fill-area style

      SUBROUTINE PGSFS (FS)
      INTEGER  FS

Set the Fill-Area Style attribute for subsequent area-fill by
PGPOLY, PGRECT, or PGCIRC.  Four different styles are available: 
solid (fill polygon with solid color of the current color-index), 
outline (draw outline of polygon only, using current line attributes),
hatched (shade interior of polygon with parallel lines, using
current line attributes), or cross-hatched. The orientation and
spacing of hatch lines can be specified with routine PGSHS (set
hatch style).

Argument:
 FS     (input)  : the fill-area style to be used for subsequent
                   plotting:
                     FS = 1 => solid (default)
                     FS = 2 => outline
                     FS = 3 => hatched
                     FS = 4 => cross-hatched
                   Other values give an error message and are
                   treated as 2.

PGSHLS -- set color representation using HLS system

      SUBROUTINE PGSHLS (CI, CH, CL, CS)
      INTEGER CI
      REAL    CH, CL, CS

Set color representation: i.e., define the color to be
associated with a color index.  This routine is equivalent to
PGSCR, but the color is defined in the Hue-Lightness-Saturation
model instead of the Red-Green-Blue model. Hue is represented
by an angle in degrees, with red at 120, green at 240,
and blue at 0 (or 360). Lightness ranges from 0.0 to 1.0, with black
at lightness 0.0 and white at lightness 1.0. Saturation ranges from
0.0 (gray) to 1.0 (pure color). Hue is irrelevant when saturation
is 0.0.

Examples:           H     L     S        R     G     B
    black          any   0.0   0.0      0.0   0.0   0.0
    white          any   1.0   0.0      1.0   1.0   1.0
    medium gray    any   0.5   0.0      0.5   0.5   0.5
    red            120   0.5   1.0      1.0   0.0   0.0
    yellow         180   0.5   1.0      1.0   1.0   0.0
    pink           120   0.7   0.8      0.94  0.46  0.46

Reference: SIGGRAPH Status Report of the Graphic Standards Planning
Committee, Computer Graphics, Vol.13, No.3, Association for
Computing Machinery, New York, NY, 1979. See also: J. D. Foley et al,
``Computer Graphics: Principles and Practice'', second edition,
Addison-Wesley, 1990, section 13.3.5.

Argument:
 CI     (input)  : the color index to be defined, in the range 0-max.
                   If the color index greater than the device
                   maximum is specified, the call is ignored. Color
                   index 0 applies to the background color.
 CH     (input)  : hue, in range 0.0 to 360.0.
 CL     (input)  : lightness, in range 0.0 to 1.0.
 CS     (input)  : saturation, in range 0.0 to 1.0.

PGSHS -- set hatching style

      SUBROUTINE PGSHS (ANGLE, SEPN, PHASE)
      REAL ANGLE, SEPN, PHASE

Set the style to be used for hatching (fill area with fill-style 3).
The default style is ANGLE=45.0, SEPN=1.0, PHASE=0.0.

Arguments:
 ANGLE  (input)  : the angle the hatch lines make with the
                   horizontal, in degrees, increasing 
                   counterclockwise (this is an angle on the
                   view surface, not in world-coordinate space).
 SEPN   (input)  : the spacing of the hatch lines. The unit spacing
                   is 1 percent of the smaller of the height or
                   width of the view surface. This should not be
                   zero.
 PHASE  (input)  : a real number between 0 and 1; the hatch lines
                   are displaced by this fraction of SEPN from a
                   fixed reference.  Adjacent regions hatched with the
                   same PHASE have contiguous hatch lines. To hatch
                   a region with alternating lines of two colors,
                   fill the area twice, with PHASE=0.0 for one color
                   and PHASE=0.5 for the other color.

PGSITF -- set image transfer function

      SUBROUTINE PGSITF (ITF)
      INTEGER  ITF

Set the Image Transfer Function for subsequent images drawn by
PGIMAG, PGGRAY, or PGWEDG. The Image Transfer Function is used
to map array values into the available range of color indices
specified with routine PGSCIR or (for PGGRAY on some devices)
into dot density.

Argument:
 ITF    (input)  : type of transfer function:
                     ITF = 0 : linear
                     ITF = 1 : logarithmic
                     ITF = 2 : square-root

PGSLCT -- select an open graphics device

      SUBROUTINE PGSLCT(ID)
      INTEGER ID

Select one of the open graphics devices and direct subsequent
plotting to it. The argument is the device identifier returned by
PGOPEN when the device was opened. If the supplied argument is not a
valid identifier of an open graphics device, a warning message is
issued and the current selection is unchanged.

[This routine was added to PGPLOT in Version 5.1.0.]

Arguments:

ID (input, integer): identifier of the device to be selected.

PGSLS -- set line style

      SUBROUTINE PGSLS (LS)
      INTEGER  LS

Set the line style attribute for subsequent plotting. This
attribute affects line primitives only; it does not affect graph
markers, text, or area fill.
Five different line styles are available, with the following codes:
1 (full line), 2 (dashed), 3 (dot-dash-dot-dash), 4 (dotted),
5 (dash-dot-dot-dot). The default is 1 (normal full line).

Argument:
 LS     (input)  : the line-style code for subsequent plotting
                   (in range 1-5).

PGSLW -- set line width

      SUBROUTINE PGSLW (LW)
      INTEGER  LW

Set the line-width attribute. This attribute affects lines, graph
markers, and text. The line width is specified in units of 1/200 
(0.005) inch (about 0.13 mm) and must be an integer in the range
1-201. On some devices, thick lines are generated by tracing each
line with multiple strokes offset in the direction perpendicular to
the line.

Argument:
 LW     (input)  : width of line, in units of 0.005 inch (0.13 mm)
                   in range 1-201.

PGSTBG -- set text background color index

      SUBROUTINE PGSTBG (TBCI)
      INTEGER  TBCI

Set the Text Background Color Index for subsequent text. By default
text does not obscure underlying graphics. If the text background
color index is positive, however, text is opaque: the bounding box
of the text is filled with the color specified by PGSTBG before
drawing the text characters in the current color index set by PGSCI.
Use color index 0 to erase underlying graphics before drawing text.

Argument:
 TBCI   (input)  : the color index to be used for the background
                   for subsequent text plotting:
                     TBCI < 0  => transparent (default)
                     TBCI >= 0 => text will be drawn on an opaque
                   background with color index TBCI.

PGSUBP -- subdivide view surface into panels

      SUBROUTINE PGSUBP (NXSUB, NYSUB)
      INTEGER NXSUB, NYSUB

PGPLOT divides the physical surface of the plotting device (screen,
window, or sheet of paper) into NXSUB x NYSUB `panels'. When the 
view surface is sub-divided in this way, PGPAGE moves to the next
panel, not the next physical page. The initial subdivision of the
view surface is set in the call to PGBEG. When PGSUBP is called,
it forces the next call to PGPAGE to start a new physical page,
subdivided in the manner indicated. No plotting should be done
between a call of PGSUBP and a call of PGPAGE (or PGENV, which calls
PGPAGE).

If NXSUB > 0, PGPLOT uses the panels in row order; if <0, 
PGPLOT uses them in column order, e.g.,
     
 NXSUB=3, NYSUB=2            NXSUB=-3, NYSUB=2   
                                               
+-----+-----+-----+         +-----+-----+-----+
|  1  |  2  |  3  |         |  1  |  3  |  5  |
+-----+-----+-----+         +-----+-----+-----+
|  4  |  5  |  6  |         |  2  |  4  |  6  |
+-----+-----+-----+         +-----+-----+-----+

PGPLOT advances from one panels to the next when PGPAGE is called,
clearing the screen or starting a new page when the last panel has
been used. It is also possible to jump from one panel to another
in random order by calling PGPANL.

Arguments:
 NXSUB  (input)  : the number of subdivisions of the view surface in
                   X (>0 or <0).
 NYSUB  (input)  : the number of subdivisions of the view surface in
                   Y (>0).

PGSVP -- set viewport (normalized device coordinates)

      SUBROUTINE PGSVP (XLEFT, XRIGHT, YBOT, YTOP)
      REAL XLEFT, XRIGHT, YBOT, YTOP

Change the size and position of the viewport, specifying
the viewport in normalized device coordinates.  Normalized
device coordinates run from 0 to 1 in each dimension. The
viewport is the rectangle on the view surface "through"
which one views the graph.  All the PG routines which plot lines
etc. plot them within the viewport, and lines are truncated at
the edge of the viewport (except for axes, labels etc drawn with
PGBOX or PGLAB).  The region of world space (the coordinate
space of the graph) which is visible through the viewport is
specified by a call to PGSWIN.  It is legal to request a
viewport larger than the view surface; only the part which
appears on the view surface will be plotted.

Arguments:
 XLEFT  (input)  : x-coordinate of left hand edge of viewport, in NDC.
 XRIGHT (input)  : x-coordinate of right hand edge of viewport,
                   in NDC.
 YBOT   (input)  : y-coordinate of bottom edge of viewport, in NDC.
 YTOP   (input)  : y-coordinate of top  edge of viewport, in NDC.

PGSWIN -- set window

      SUBROUTINE PGSWIN (X1, X2, Y1, Y2)
      REAL X1, X2, Y1, Y2

Change the window in world coordinate space that is to be mapped on
to the viewport.  Usually PGSWIN is called automatically by PGENV,
but it may be called directly by the user.

Arguments:
 X1     (input)  : the x-coordinate of the bottom left corner
                   of the viewport.
 X2     (input)  : the x-coordinate of the top right corner
                   of the viewport (note X2 may be less than X1).
 Y1     (input)  : the y-coordinate of the bottom left corner
                   of the viewport.
 Y2     (input)  : the y-coordinate of the top right corner
                   of the viewport (note Y2 may be less than Y1).

PGTBOX -- draw frame and write (DD) HH MM SS.S labelling

      SUBROUTINE PGTBOX (XOPT, XTICK, NXSUB, YOPT, YTICK, NYSUB)

      REAL XTICK, YTICK
      INTEGER NXSUB, NYSUB
      CHARACTER XOPT*(*), YOPT*(*)

Draw a box and optionally label one or both axes with (DD) HH MM SS 
style numeric labels (useful for time or RA - DEC plots).   If this 
style of labelling is desired, then PGSWIN should have been called
previously with the extrema in SECONDS of time.

In the seconds field, you can have at most 3 places after the decimal
point, so that 1 ms is the smallest time interval you can time label.

Large numbers are coped with by fields of 6 characters long.  Thus 
you could have times with days or hours as big as 999999.  However, 
in practice, you might have trouble with labels overwriting  themselves
with such large numbers unless you a) use a small time INTERVAL, 
b) use a small character size or c) choose your own sparse ticks in 
the call to PGTBOX.  

PGTBOX will attempt, when choosing its own ticks, not to overwrite
the labels, but this algorithm is not very bright and may fail.

Note that small intervals but large absolute times such as
TMIN = 200000.0 s and TMAX=200000.1 s will cause the algorithm
to fail.  This is inherent in PGPLOT's use of single precision
and cannot be avoided.  In such cases, you should use relative
times if possible.

PGTBOX's labelling philosophy is that the left-most or bottom tick of
the axis contains a full label.  Thereafter, only changing fields are
labelled.  Negative fields are given a '-' label, positive fields
have none.   Axes that have the DD (or HH if the day field is not
used) field on each major tick carry the sign on each field.  If the
axis crosses zero, the zero tick will carry a full label and sign.

This labelling style can cause a little confusion with some special
cases, but as long as you know its philosophy, the truth can be divined.
Consider an axis with TMIN=20s, TMAX=-20s.   The labels will look like

       +----------+----------+----------+----------+
    0h0m20s      10s      -0h0m0s      10s        20s

Knowing that the left field always has a full label and that
positive fields are unsigned, informs that time is decreasing
from left to right, not vice versa.   This can become very 
unclear if you have used the 'F' option, but that is your problem !

Exceptions to this labelling philosophy are when the finest time
increment being displayed is hours (with option 'Y') or days.  
Then all fields carry a label.  For example,

       +----------+----------+----------+----------+
     -10h        -8h        -6h        -4h        -2h


PGTBOX can be used in place of PGBOX; it calls PGBOX and only invokes 
time labelling if requested. Other options are passed intact to PGBOX.

Inputs:
 XOPT   :  X-options for PGTBOX.  Same as for PGBOX plus 

            'Z' for (DD) HH MM SS.S time labelling
            'Y' means don't include the day field so that labels
                are HH MM SS.S rather than DD HH MM SS.S   The hours
                will accumulate beyond 24 if necessary in this case.
            'X' label the HH field as modulo 24.  Thus, a label
                such as 25h 10m would come out as 1h 10m
            'H' means superscript numbers with d, h, m, & s  symbols
            'D' means superscript numbers with    o, ', & '' symbols 
            'F' causes the first label (left- or bottom-most) to
                be omitted. Useful for sub-panels that abut each other.
                Care is needed because first label carries sign as well.
            'O' means omit leading zeros in numbers < 10
                E.g.  3h 3m 1.2s rather than 03h 03m 01.2s  Useful
                to help save space on X-axes. The day field does not 
                use this facility.

 YOPT   :  Y-options for PGTBOX.  See above.
 XTICK  :  X-axis major tick increment.  0.0 for default. 
 YTICK  :  Y-axis major tick increment.  0.0 for default. 
           If the 'Z' option is used then XTICK and/or YTICK must
           be in seconds.
 NXSUB  :  Number of intervals for minor ticks on X-axis. 0 for default
 NYSUB  :  Number of intervals for minor ticks on Y-axis. 0 for default

 The regular XOPT and YOPT axis options for PGBOX are

 A : draw Axis (X axis is horizontal line Y=0, Y axis is vertical
     line X=0).
 B : draw bottom (X) or left (Y) edge of frame.
 C : draw top (X) or right (Y) edge of frame.
 G : draw Grid of vertical (X) or horizontal (Y) lines.
 I : Invert the tick marks; ie draw them outside the viewport
     instead of inside.
 L : label axis Logarithmically (see below).
 N : write Numeric labels in the conventional location below the
     viewport (X) or to the left of the viewport (Y).
 P : extend ("Project") major tick marks outside the box (ignored if
     option I is specified).
 M : write numeric labels in the unconventional location above the
     viewport (X) or to the right of the viewport (Y).
 T : draw major Tick marks at the major coordinate interval.
 S : draw minor tick marks (Subticks).
 V : orient numeric labels Vertically. This is only applicable to Y.
     The default is to write Y-labels parallel to the axis.
 1 : force decimal labelling, instead of automatic choice (see PGNUMB).
 2 : force exponential labelling, instead of automatic.

     The default is to write Y-labels parallel to the axis
 

       ******************        EXCEPTIONS       *******************

       Note that 
         1) PGBOX option 'L' (log labels) is ignored with option 'Z'
         2) The 'O' option will be ignored for the 'V' option as it 
            makes it impossible to align the labels nicely
         3) Option 'Y' is forced with option 'D'

       ***************************************************************



PGTEXT -- write text (horizontal, left-justified)

      SUBROUTINE PGTEXT (X, Y, TEXT)
      REAL X, Y
      CHARACTER*(*) TEXT

Write text. The bottom left corner of the first character is placed
at the specified position, and the text is written horizontally.
This is a simplified interface to the primitive routine PGPTXT.
For non-horizontal text, use PGPTXT.

Arguments:
 X      (input)  : world x-coordinate of start of string.
 Y      (input)  : world y-coordinate of start of string.
 TEXT   (input)  : the character string to be plotted.

PGTICK -- draw a single tick mark on an axis

      SUBROUTINE PGTICK (X1, Y1, X2, Y2, V, TIKL, TIKR, DISP, 
     :                   ORIENT, STR)
      REAL X1, Y1, X2, Y2, V, TIKL, TIKR, DISP, ORIENT
      CHARACTER*(*) STR

Draw and label single tick mark on a graph axis. The tick mark is
a short line perpendicular to the direction of the axis (which is not
drawn by this routine). The optional text label is drawn with its
baseline parallel to the axis and reading in the same direction as
the axis (from point 1 to point 2). Current line and text attributes
are used.

Arguments:
 X1, Y1 (input)  : world coordinates of one endpoint of the axis.
 X2, Y2 (input)  : world coordinates of the other endpoint of the axis.
 V      (input)  : draw the tick mark at fraction V (0<=V<=1) along
                   the line from (X1,Y1) to (X2,Y2).
 TIKL   (input)  : length of tick mark drawn to left of axis
                   (as seen looking from first endpoint to second), in
                   units of the character height.
 TIKR   (input)  : length of major tick marks drawn to right of axis,
                   in units of the character height.
 DISP   (input)  : displacement of label text to
                   right of axis, in units of the character height.
 ORIENT (input)  : orientation of label text, in degrees; angle between
                   baseline of text and direction of axis (0-360°).
 STR    (input)  : text of label (may be blank).

PGUPDT -- update display

      SUBROUTINE PGUPDT

Update the graphics display: flush any pending commands to the
output device. This routine empties the buffer created by PGBBUF,
but it does not alter the PGBBUF/PGEBUF counter. The routine should
be called when it is essential that the display be completely up to
date (before interaction with the user, for example) but it is not
known if output is being buffered.

Arguments: none

PGVECT -- vector map of a 2D data array, with blanking

      SUBROUTINE PGVECT (A, B, IDIM, JDIM, I1, I2, J1, J2, C, NC, TR,
     1                   BLANK)
      INTEGER IDIM, JDIM, I1, I2, J1, J2, NC
      REAL    A(IDIM,JDIM), B(IDIM, JDIM), TR(6), BLANK, C

Draw a vector map of two arrays.  This routine is similar to
PGCONB in that array elements that have the "magic value" defined by
the argument BLANK are ignored, making gaps in the vector map.  The
routine may be useful for data measured on most but not all of the
points of a grid. Vectors are displayed as arrows; the style of the
arrowhead can be set with routine PGSAH, and the the size of the
arrowhead is determined by the current character size, set by PGSCH.

Arguments:
 A      (input)  : horizontal component data array.
 B      (input)  : vertical component data array.
 IDIM   (input)  : first dimension of A and B.
 JDIM   (input)  : second dimension of A and B.
 I1,I2  (input)  : range of first index to be mapped (inclusive).
 J1,J2  (input)  : range of second index to be mapped (inclusive).
 C      (input)  : scale factor for vector lengths, if 0.0, C will be
                   set so that the longest vector is equal to the
                   smaller of TR(2)+TR(3) and TR(5)+TR(6).
 NC     (input)  : vector positioning code.
                   <0 vector head positioned on coordinates
                   >0 vector base positioned on coordinates
                   =0 vector centered on the coordinates
 TR     (input)  : array defining a transformation between the I,J
                   grid of the array and the world coordinates. The
                   world coordinates of the array point A(I,J) are
                   given by:
                     X = TR(1) + TR(2)*I + TR(3)*J
                     Y = TR(4) + TR(5)*I + TR(6)*J
                   Usually TR(3) and TR(5) are zero - unless the
                   coordinate transformation involves a rotation
                   or shear.
 BLANK   (input) : elements of arrays A or B that are exactly equal to
                   this value are ignored (blanked).

PGVSIZ -- set viewport (inches)

      SUBROUTINE PGVSIZ (XLEFT, XRIGHT, YBOT, YTOP)
      REAL XLEFT, XRIGHT, YBOT, YTOP

Change the size and position of the viewport, specifying
the viewport in physical device coordinates (inches).  The
viewport is the rectangle on the view surface "through"
which one views the graph.  All the PG routines which plot lines
etc. plot them within the viewport, and lines are truncated at
the edge of the viewport (except for axes, labels etc drawn with
PGBOX or PGLAB).  The region of world space (the coordinate
space of the graph) which is visible through the viewport is
specified by a call to PGSWIN.  It is legal to request a
viewport larger than the view surface; only the part which
appears on the view surface will be plotted.

Arguments:
 XLEFT  (input)  : x-coordinate of left hand edge of viewport, in
                   inches from left edge of view surface.
 XRIGHT (input)  : x-coordinate of right hand edge of viewport, in
                   inches from left edge of view surface.
 YBOT   (input)  : y-coordinate of bottom edge of viewport, in
                   inches from bottom of view surface.
 YTOP   (input)  : y-coordinate of top  edge of viewport, in inches
                   from bottom of view surface.

PGVSTD -- set standard (default) viewport

      SUBROUTINE PGVSTD

Define the viewport to be the standard viewport.  The standard
viewport is the full area of the view surface (or panel),
less a margin of 4 character heights all round for labelling.
It thus depends on the current character size, set by PGSCH.

Arguments: none.

PGWEDG -- annotate an image plot with a wedge

      SUBROUTINE PGWEDG(SIDE, DISP, WIDTH, FG, BG, LABEL)
      CHARACTER *(*) SIDE,LABEL
      REAL DISP, WIDTH, FG, BG

Plot an annotated grey-scale or color wedge parallel to a given axis
of the the current viewport. This routine is designed to provide a
brightness/color scale for an image drawn with PGIMAG or PGGRAY.
The wedge will be drawn with the transfer function set by PGSITF
and using the color index range set by PGSCIR.

Arguments:
 SIDE   (input)  : The first character must be one of the characters
                   'B', 'L', 'T', or 'R' signifying the Bottom, Left,
                   Top, or Right edge of the viewport.
                   The second character should be 'I' to use PGIMAG
                   to draw the wedge, or 'G' to use PGGRAY.
 DISP   (input)  : the displacement of the wedge from the specified
                   edge of the viewport, measured outwards from the
                   viewport in units of the character height. Use a
                   negative value to write inside the viewport, a
                   positive value to write outside.
 WIDTH  (input)  : The total width of the wedge including annotation,
                   in units of the character height.
 FG     (input)  : The value which is to appear with shade
                   1 ("foreground"). Use the values of FG and BG
                   that were supplied to PGGRAY or PGIMAG.
 BG     (input)  : the value which is to appear with shade
                   0 ("background").
 LABEL  (input)  : Optional units label. If no label is required
                   use ' '.

PGWNAD -- set window and adjust viewport to same aspect ratio

      SUBROUTINE PGWNAD (X1, X2, Y1, Y2)
      REAL X1, X2, Y1, Y2

Change the window in world coordinate space that is to be mapped on
to the viewport, and simultaneously adjust the viewport so that the
world-coordinate scales are equal in x and y. The new viewport is
the largest one that can fit within the previously set viewport
while retaining the required aspect ratio.

Arguments:
 X1     (input)  : the x-coordinate of the bottom left corner
                   of the viewport.
 X2     (input)  : the x-coordinate of the top right corner
                   of the viewport (note X2 may be less than X1).
 Y1     (input)  : the y-coordinate of the bottom left corner
                   of the viewport.
 Y2     (input)  : the y-coordinate of the top right corner of the
                   viewport (note Y2 may be less than Y1).

PGADVANCE -- non-standard alias for PGPAGE

      SUBROUTINE PGADVANCE

See description of PGPAGE.

PGBEGIN -- non-standard alias for PGBEG

      INTEGER FUNCTION PGBEGIN (UNIT, FILE, NXSUB, NYSUB)
      INTEGER       UNIT
      CHARACTER*(*) FILE
      INTEGER       NXSUB, NYSUB

See description of PGBEG.   

PGCURSE -- non-standard alias for PGCURS

      INTEGER FUNCTION PGCURSE (X, Y, CH)
      REAL X, Y
      CHARACTER*1 CH

See description of PGCURS.

PGLABEL -- non-standard alias for PGLAB

      SUBROUTINE PGLABEL (XLBL, YLBL, TOPLBL)
      CHARACTER*(*) XLBL, YLBL, TOPLBL

See description of PGLAB.

PGMTEXT -- non-standard alias for PGMTXT

      SUBROUTINE PGMTEXT (SIDE, DISP, COORD, FJUST, TEXT)
      CHARACTER*(*) SIDE, TEXT
      REAL DISP, COORD, FJUST

See description of PGMTXT.

PGNCURSE -- non-standard alias for PGNCUR

      SUBROUTINE PGNCURSE (MAXPT, NPT, X, Y, SYMBOL)
      INTEGER MAXPT, NPT
      REAL    X(*), Y(*)
      INTEGER SYMBOL

See description of PGNCUR.

PGPAPER -- non-standard alias for PGPAP

      SUBROUTINE PGPAPER (WIDTH, ASPECT)
      REAL WIDTH, ASPECT

See description of PGPAP.

PGPOINT -- non-standard alias for PGPT

      SUBROUTINE PGPOINT (N, XPTS, YPTS, SYMBOL)
      INTEGER N
      REAL XPTS(*), YPTS(*)
      INTEGER SYMBOL

See description of PGPT.

PGPTEXT -- non-standard alias for PGPTXT

      SUBROUTINE PGPTEXT (X, Y, ANGLE, FJUST, TEXT)
      REAL X, Y, ANGLE, FJUST
      CHARACTER*(*) TEXT

See description of PGPTXT.

PGVPORT -- non-standard alias for PGSVP

      SUBROUTINE PGVPORT (XLEFT, XRIGHT, YBOT, YTOP)
      REAL XLEFT, XRIGHT, YBOT, YTOP

See description of PGSVP.

PGVSIZE -- non-standard alias for PGVSIZ

      SUBROUTINE PGVSIZE (XLEFT, XRIGHT, YBOT, YTOP)
      REAL XLEFT, XRIGHT, YBOT, YTOP

See description of PGVSIZ.

PGVSTAND -- non-standard alias for PGVSTD

      SUBROUTINE PGVSTAND

See description of PGVSTD.

PGWINDOW -- non-standard alias for PGSWIN

      SUBROUTINE PGWINDOW (X1, X2, Y1, Y2)
      REAL X1, X2, Y1, Y2

See description of PGSWIN.