(all the functions starting with
ploth) in which the user has little to do but explain what type of plot
he wants, and whose syntax is similar to the one used in the preceding
(called rectplot functions,
sharing the prefix
plot), where every drawing primitive (point, line,
box, etc.) is specified by the user. These low-level functions work as
follows. You have at your disposal 16 virtual windows which are filled
independently, and can then be physically ORed on a single window at
user-defined positions. These windows are numbered from 0 to 15, and must be
initialized before being used by the function
plotinit, which specifies
the height and width of the virtual window (called a rectwindow in the
sequel). At all times, a virtual cursor (initialized at [0,0]) is associated
to the window, and its current value can be obtained using the function
A number of primitive graphic objects (called rect objects) can then
be drawn in these windows, using a default color associated to that window
(which can be changed using the
plotcolor function) and only the part
of the object which is inside the window will be drawn, with the exception of
polygons and strings which are drawn entirely. The ones sharing the prefix
plotr draw relatively to the current position of the virtual cursor,
the others use absolute coordinates. Those having the prefix
put in the rectwindow a large batch of rect objects corresponding to the
output of the related
Finally, the actual physical drawing is done using
rectwindows are preserved so that further drawings using the same windows at
different positions or different windows can be done without extra work. To
erase a window, use
plotkill. It is not possible to partially erase a
window: erase it completely, initialize it again, then fill it with the
graphic objects that you want to keep.
In addition to initializing the window, you may use a scaled window to
avoid unnecessary conversions. For this, use
plotscale. As long as this
function is not called, the scaling is simply the number of pixels, the
origin being at the upper left and the y-coordinates going downwards.
Plotting functions are platform independent, but a number of graphical
drivers are available for screen output: X11-windows (hence also for GUI's
based on X11 such as Openwindows and Motif), and the Qt and FLTK graphical
libraries. The physical window opened by
plotdraw or any of the
ploth* functions is completely separated from
gp (technically, a
fork is done, and the non-graphical memory is immediately freed in the
child process), which means you can go on working in the current
session, without having to kill the window first. This window can be closed,
enlarged or reduced using the standard window manager functions. No zooming
procedure is implemented though (yet).
in the same way that
printtex allows you to have a TeX output
corresponding to printed results, the functions starting with
you to have
PostScript output of the plots. This will not be identical
with the screen output, but sufficiently close. Note that you can use
PostScript output even if you do not have the plotting routines enabled. The
PostScript output is written in a file whose name is derived from the
psfile default (
./pari.ps if you did not tamper with it). Each
time a new PostScript output is asked for, the PostScript output is appended
to that file. Hence you probably want to remove this file, or change the
psfile, in between plots. On the other hand, in this manner,
as many plots as desired can be kept in a single file.
None of the graphic functions are available
within the PARI library, you must be under
gp to use them. The reason
for that is that you really should not use PARI for heavy-duty graphical work,
there are better specialized alternatives around. This whole set of routines
was only meant as a convenient, but simple-minded, visual aid. If you really
insist on using these in your program (we warned you), the source
plot*.c) should be readable enough for you to achieve something.
Crude ASCII plot of the function represented by expression expr from a to b, with Y ranging from Ymin to Ymax. If Ymin (resp. Ymax) is not given, the minimum (resp. the maximum) of the computed values of the expression is used instead.
Let (x1,y1) be the current position of the virtual cursor. Draw in the rectwindow w the outline of the rectangle which is such that the points (x1,y1) and (x2,y2) are opposite corners. Only the part of the rectangle which is in w is drawn. The virtual cursor does not move.
`clips' the content of rectwindow w, i.e remove all parts of the
drawing that would not be visible on the screen. Together with
plotcopy this function enables you to draw on a scratchpad before
committing the part you're interested in to the final picture.
Set default color to c in rectwindow w.
This is only implemented for the X-windows, fltk and Qt graphing engines.
Possible values for c are given by the
factory setting are
1 = black, 2 = blue, 3 = violetred, 4 = red, 5 = green, 6 = grey, 7 = gainsborough.
but this can be considerably extended.
Copy the contents of rectwindow sourcew to rectwindow destw with offset (dx,dy). If flag's bit 1 is set, dx and dy express fractions of the size of the current output device, otherwise dx and dy are in pixels. dx and dy are relative positions of northwest corners if other bits of flag vanish, otherwise of: 2: southwest, 4: southeast, 6: northeast corners
Give as a 2-component vector the current (scaled) position of the virtual cursor corresponding to the rectwindow w.
Physically draw the rectwindows given in list which must be a vector whose number of components is divisible by 3. If list = [w1,x1,y1,w2,x2,y2,...], the windows w1, w2, etc. are physically placed with their upper left corner at physical position (x1,y1), (x2,y2),...respectively, and are then drawn together. Overlapping regions will thus be drawn twice, and the windows are considered transparent. Then display the whole drawing in a special window on your screen. If flag != 0, x1, y1 etc. express fractions of the size of the current output device
High precision plot of the function y = f(x) represented by the expression expr, x going from a to b. This opens a specific window (which is killed whenever you click on it), and returns a four-component vector giving the coordinates of the bounding box in the form [xmin,xmax,ymin,ymax].
ploth may evaluate
expr thousands of
times; given the relatively low resolution of plotting devices, few
significant digits of the result will be meaningful. Hence you should keep
the current precision to a minimum (e.g. 9) before calling this function.
n specifies the number of reference point on the graph, where a value of 0 means we use the hardwired default values (1000 for general plot, 1500 for parametric plot, and 8 for recursive plot).
If no flag is given, expr is either a scalar expression f(X), in which case the plane curve y = f(X) will be drawn, or a vector [f_1(X),...,f_k(X)], and then all the curves y = f_i(X) will be drawn in the same window.
The binary digits of flag mean:
* 1 =
Parametric: parametric plot. Here expr must
be a vector with an even number of components. Successive pairs are then
understood as the parametric coordinates of a plane curve. Each of these are
ploth(X=0,2*Pi,[sin(X),cos(X)], "Parametric") ploth(X=0,2*Pi,[sin(X),cos(X)]) ploth(X=0,2*Pi,[X,X,sin(X),cos(X)], "Parametric")draw successively a circle, two entwined sinusoidal curves and a circle cut by the line y = x.
* 2 =
Recursive: recursive plot. If this flag is set,
only one curve can be drawn at a time, i.e. expr must be either a
two-component vector (for a single parametric curve, and the parametric flag
has to be set), or a scalar function. The idea is to choose pairs of
successive reference points, and if their middle point is not too far away
from the segment joining them, draw this as a local approximation to the
curve. Otherwise, add the middle point to the reference points. This is
fast, and usually more precise than usual plot. Compare the results of
ploth(X=-1,1, sin(1/X), "Recursive") ploth(X=-1,1, sin(1/X))
for instance. But beware that if you are extremely unlucky, or choose too few reference points, you may draw some nice polygon bearing little resemblance to the original curve. For instance you should never plot recursively an odd function in a symmetric interval around 0. Try
ploth(x = -20, 20, sin(x), "Recursive")
to see why. Hence, it's usually a good idea to try and plot the same curve with slightly different parameters.
The other values toggle various display options:
* 4 =
no_Rescale: do not rescale plot according to the
computed extrema. This is used in conjunction with
graphing multiple functions on a rectwindow (as a
s = plothsizes(); plotinit(0, s-1, s-1); plotscale(0, -1,1, -1,1); plotrecth(0, t=0,2*Pi, [cos(t),sin(t)], "Parametric|no_Rescale") plotdraw([0, -1,1]);
This way we get a proper circle instead of the distorted ellipse produced by
ploth(t=0,2*Pi, [cos(t),sin(t)], "Parametric")
* 8 =
no_X_axis: do not print the x-axis.
* 16 =
no_Y_axis: do not print the y-axis.
* 32 =
no_Frame: do not print frame.
* 64 =
no_Lines: only plot reference points, do not join them.
* 128 =
Points_too: plot both lines and points.
* 256 =
Splines: use splines to interpolate the points.
* 512 =
no_X_ticks: plot no x-ticks.
* 1024 =
no_Y_ticks: plot no y-ticks.
* 2048 =
Same_ticks: plot all ticks with the same length.
* 4096 =
Complex: is a parametric plot but where each member of
expr is considered a complex number encoding the two coordinates of a
point. For instance:
ploth(X=0,2*Pi,exp(I*X), "Complex") ploth(X=0,2*Pi,[(1+I)*X,exp(I*X)], "Complex")will draw respectively a circle and a circle cut by the line y = x.
Given listx and listy two vectors of equal length, plots (in
high precision) the points whose (x,y)-coordinates are given in
listx and listy. Automatic positioning and scaling is done, but
with the same scaling factor on x and y. If flag is 1, join points,
other non-0 flags toggle display options and should be combinations of bits
>= 3 as in
Return data corresponding to the output window
in the form of a 6-component vector: window width and height, sizes for ticks
in horizontal and vertical directions (this is intended for the
interface and is currently not significant), width and height of characters.
If flag = 0, sizes of ticks and characters are in pixels, otherwise are fractions of the screen size
Initialize the rectwindow w, destroying any rect objects you may have already drawn in w. The virtual cursor is set to (0,0). The rectwindow size is set to width x and height y; omitting either x or y means we use the full size of the device in that direction. If flag = 0, x and y represent pixel units. Otherwise, x and y are understood as fractions of the size of the current output device (hence must be between 0 and 1) and internally converted to pixels.
The plotting device imposes an upper bound for x and y, for instance the
number of pixels for screen output. These bounds are available through the
plothsizes function. The following sequence initializes in a portable
way (i.e independent of the output device) a window of maximal size, accessed
through coordinates in the [0,1000] x [0,1000] range:
s = plothsizes(); plotinit(0, s-1, s-1); plotscale(0, 0,1000, 0,1000);
Erase rectwindow w and free the corresponding memory. Note that if you
want to use the rectwindow w again, you have to use
to specify the new size. So it's better in this case to use
directly as this throws away any previous work in the given rectwindow.
Draw on the rectwindow w the polygon such that the (x,y)-coordinates of the vertices are in the vectors of equal length X and Y. For simplicity, the whole polygon is drawn, not only the part of the polygon which is inside the rectwindow. If flag is non-zero, close the polygon. In any case, the virtual cursor does not move.
X and Y are allowed to be scalars (in this case, both have to).
There, a single segment will be drawn, between the virtual cursor current
position and the point (X,Y). And only the part thereof which
actually lies within the boundary of w. Then move the virtual cursor
to (X,Y), even if it is outside the window. If you want to draw a
line from (x1,y1) to (x2,y2) where (x1,y1) is not necessarily the
position of the virtual cursor, use
plotmove(w,x1,y1) before using this
Change the type of lines subsequently plotted in rectwindow w.
type -2 corresponds to frames, -1 to axes, larger values may
correspond to something else. w = -1 changes highlevel plotting. This is
only taken into account by the
Move the virtual cursor of the rectwindow w to position (x,y).
Draw on the rectwindow w the
points whose (x,y)-coordinates are in the vectors of equal length X and
Y and which are inside w. The virtual cursor does not move. This
is basically the same function as
plothraw, but either with no scaling
factor or with a scale chosen using the function
As was the case with the
plotlines function, X and Y are allowed to
be (simultaneously) scalar. In this case, draw the single point (X,Y) on
the rectwindow w (if it is actually inside w), and in any case
move the virtual cursor to position (x,y).
Changes the "size" of following points in rectwindow w. If w = -1,
change it in all rectwindows. This only works in the
Change the type of points subsequently plotted in rectwindow w.
type = -1 corresponds to a dot, larger values may correspond to
something else. w = -1 changes highlevel plotting. This is only taken into
account by the
Draw in the rectwindow w the outline of the rectangle which is such that the points (x1,y1) and (x1+dx,y1+dy) are opposite corners, where (x1,y1) is the current position of the cursor. Only the part of the rectangle which is in w is drawn. The virtual cursor does not move.
Writes to rectwindow w the curve output of
ploth(w,X = a,b,expr,flag,n). Returns a vector for the bounding box.
Plot graph(s) for
data in rectwindow w. flag has the same significance here as in
ploth, though recursive plot is no more significant.
data is a vector of vectors, each corresponding to a list a coordinates. If parametric plot is set, there must be an even number of vectors, each successive pair corresponding to a curve. Otherwise, the first one contains the x coordinates, and the other ones contain the y-coordinates of curves to plot.
Draw in the rectwindow w the part of the segment (x1,y1)-(x1+dx,y1+dy) which is inside w, where (x1,y1) is the current position of the virtual cursor, and move the virtual cursor to (x1+dx,y1+dy) (even if it is outside the window).
Move the virtual cursor of the rectwindow w to position (x1+dx,y1+dy), where (x1,y1) is the initial position of the cursor (i.e. to position (dx,dy) relative to the initial cursor).
Draw the point (x1+dx,y1+dy) on the rectwindow w (if it is inside w), where (x1,y1) is the current position of the cursor, and in any case move the virtual cursor to position (x1+dx,y1+dy).
Scale the local coordinates of the rectwindow w so that x goes from
x1 to x2 and y goes from y1 to y2 (x2 < x1 and y2 < y1 being
allowed). Initially, after the initialization of the rectwindow w using
plotinit, the default scaling is the graphic pixel count,
and in particular the y axis is oriented downwards since the origin is at
the upper left. The function
plotscale allows to change all these
defaults and should be used whenever functions are graphed.
Draw on the rectwindow w the String x (see Section [Label: se:strings]), at the current position of the cursor.
flag is used for justification: bits 1 and 2 regulate horizontal alignment: left if 0, right if 2, center if 1. Bits 4 and 8 regulate vertical alignment: bottom if 0, top if 8, v-center if 4. Can insert additional small gap between point and string: horizontal if bit 16 is set, vertical if bit 32 is set (see the tutorial for an example).
plotdraw, except that the output is a PostScript program
appended to the
psfile, and flag != 0 scales the plot from size of the
current output device to the standard PostScript plotting size
ploth, except that the output is a PostScript program
appended to the
plothraw, except that the output is a PostScript program
appended to the