Difference between revisions of "Asymptote: Reference"

 
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==Paths==
 
==Paths==
A '''path''' (or ''guide'' - see [[Asymptote: Basics|Variables and Data Types]] for the difference) in Asymptote is simply a cubic function of a parameter <math>t</math>, parameterized as <math>t</math> ranges from <math>0</math> to the number of nodes (say <math>n</math>) that determine the path.  The most basic way to make paths is by joining points (which can be thought of as paths with length 0) and paths together with the <tt>--</tt> and <tt>..</tt> operators.  The former connects each pair of points or paths with a straight line, and the latter connects them with a Bezier cubic spline interpolation so that paths are joined smoothly. The symbol <tt>cycle</tt> connected to a path tells Asymptote to form a cyclic path by joining the endpoint with <math>t=n</math> to that with <math>t=0</math>.   As an example, try both
+
A '''path''' (or ''guide'' - see [[Asymptote: Basics|Variables and Data Types]] for the difference) in Asymptote is simply a piecewise cubic function of a parameter <math>t</math>, parameterized as <math>t</math> ranges from <math>0</math> to the number of nodes (say <math>n</math>) that determine the path.  The most basic way to make paths is by joining points (which can be thought of as paths with length 0) or paths <tt>p</tt>, <tt>q</tt> together with one of the following operators:
  draw((0,0)--(1,0)--(1/2,sqrt(3)/2)--cycle);  
+
;<tt>p--q</tt>
and
+
:Connects the end of path p to the beginning of q with a straight line.
  draw((0,0)..(1,0)..(1/2,sqrt(3)/2)..cycle);
+
;<tt>p..q..r</tt>
 +
:Connects p, q, and r with a Bezier cubic spline interpolation so that paths are joined smoothly in an curve that can be twisted. Keep in mind that if only two things are connected with <tt>..</tt>, the curve will be a straight line.
 +
;<tt>p^^q</tt>
 +
:Merges the two paths into a single one without adding anything else.
 +
 
 +
Connecting the symbol <tt>cycle</tt> to a path tells Asymptote to form a cyclic path by joining the endpoint with <math>t=n</math> to that with <math>t=0</math>.
 +
 
 +
The following example includes the benefits of all three types of path joins:
 +
unitsize(1inch);
 +
path T,ct,tt;
 +
T=(0,0)--(1,0)--(1/2,sqrt(3)/2)--cycle;
 +
ct=(0,0)..(1,0)--(1/2,sqrt(3)/2)..cycle;
 +
tt=shift(sqrt(3)/6*dir(30))*(scale(1/2)*T);
 +
draw(T);
 +
draw(shift(2*right)*ct);
 +
fill(reverse(shift(4*right)*tt)^^(shift(4*right)*T),blue);
 +
 
 +
outputs:
 +
<asy>
 +
unitsize(1inch);
 +
path T,ct,tt;
 +
T=(0,0)--(1,0)--(1/2,sqrt(3)/2)--cycle;
 +
ct=(0,0)..(1,0)--(1/2,sqrt(3)/2)..cycle;
 +
tt=shift(sqrt(3)/6*dir(30))*(scale(1/2)*T);
 +
draw(T);
 +
draw(shift(2*right)*ct);
 +
fill(reverse(shift(4*right)*tt)^^(shift(4*right)*T),blue);
 +
</asy>
  
 
==Pens and Coloring==
 
==Pens and Coloring==
  A '''pen''' is just that - the style with which Asymptote draws your paths or pictures.  Pens can have various '''colors''', dash patterns ('''linetypes'''), and '''linewidths'''.  The following table gives a variety of examples of pen types and their output:
+
A '''pen''' is just that - the style with which Asymptote draws your paths or pictures.  Pens can have various '''colors''', dash patterns ('''linetypes'''), and '''linewidths'''.  The following table gives a variety of examples of pen types and their output:
  \begin{center}
+
 
  \begin{tabular}{|c|c|c|} \hline
+
[[Image:Table2.gif]]
  \textbf{Pen} & \textbf{Alternate Name} & \verb draw((0,0)--(100,0),Pen); \\ \hline
 
  \verb rgb(1,0,0) & \verb red & \includegraphics{Pen1.pdf} \\\hline
 
  \verb rgb(0,1,0) & \verb green & \includegraphics{Pen2.pdf} \\\hline
 
  \verb rgb(0,0,1) & \verb blue & \includegraphics{Pen3.pdf} \\\hline
 
  \verb rgb(0,1,1) & \verb green+blue & \includegraphics{Pen4.pdf} \\
 
  \verb cmyk(1,0,0,0) & \verb cyan & \\\hline
 
  \verb rgb(1,1,0) & \verb red+blue & \includegraphics{Pen5.pdf} \\
 
  \verb cmyk(0,1,0,0) & \verb magenta & \\\hline
 
  \verb rgb(1,0,1) & \verb red+green & \includegraphics{Pen6.pdf} \\
 
  \verb cmyk(0,0,1,0) & \verb yellow & \\\hline
 
  \verb rgb(1,1,1) & \verb black & \includegraphics{Pen7.pdf} \\
 
  \verb cmyk(0,0,0,1) &  & \\\hline
 
  \verb rgb(.7,.7,.7) & \verb gray(.7) & \includegraphics{Pen8.pdf} \\\hline
 
  \verb2linetype("8 8")2 & \verb dashed & \includegraphics{Pen9.pdf} \\\hline
 
  \verb2linetype("0 4")2 & \verb dotted & \includegraphics{Pen10.pdf} \\\hline
 
  \verb2linetype("8 8 0 8")2 & \verb dashdotted & \includegraphics{Pen11.pdf} \\\hline
 
  \verb linewidth(1) & & \includegraphics{Pen12.pdf} \\\hline
 
  \verb linewidth(2) & & \includegraphics{Pen13.pdf} \\\hline
 
  \end{tabular}
 
  \end{center}
 
  
 
We can also add pens with the + operator.  For example, the command  
 
We can also add pens with the + operator.  For example, the command  
 
   draw((0,0)--(100,100),orange+dashed+linewidth(1));
 
   draw((0,0)--(100,100),orange+dashed+linewidth(1));
 
will produce the image
 
will produce the image
  \includegraphics{Pen14.pdf}
+
 
 +
[[Image:Pen14.gif]]
 +
 
 
The default pen has linetype <tt>solid</tt>="", linewidth .5, and color <tt>black</tt>.
 
The default pen has linetype <tt>solid</tt>="", linewidth .5, and color <tt>black</tt>.
  
 
==Basic drawing commands==
 
==Basic drawing commands==
Asymptote has four basic drawing commands, draw, fill, clip, and label.  The most important of these is draw.
+
Asymptote has four basic drawing commands: draw, fill, clip, and label.  The most important of these is draw.
  
 
===Draw===
 
===Draw===
Line 61: Line 70:
 
This fills a cyclic path g in picture pic (see the section on Paths above) with a specified pen p (most often a color - see Pens and Coloring above).  For example, the command  
 
This fills a cyclic path g in picture pic (see the section on Paths above) with a specified pen p (most often a color - see Pens and Coloring above).  For example, the command  
 
  fill((0,0)--(0,1)--(1,1)--(1,0)--cycle,red);
 
  fill((0,0)--(0,1)--(1,1)--(1,0)--cycle,red);
will fill the unit square with the color red.
+
where unitsize is 1 inch outputs:
 +
 
 +
[[Image:Fill1.gif]]
 +
 
 
===Clip===
 
===Clip===
 
The structure of clip is also simple:   
 
The structure of clip is also simple:   
 
   void clip(picture pic=currentpicture, path g, pen p=currentpen);
 
   void clip(picture pic=currentpicture, path g, pen p=currentpen);
  
This crops a picture so that the boundary is the given path g, and the boundary is then drawn with pen p.
+
This crops a picture so that the boundary is the given path g, with fill rule p.  A ''fill rule'' tells when a point is inside the boundary of the path; the default fill rule, <tt>zerowinding</tt> or <tt>fillrule(0)</tt>, checks to see if the number of horizontal intersections from the point to the right is equal to the number of downward intersections with the path.  Another useful fill rule is <tt>evenodd</tt>, or <tt>fillrule(1)</tt>, which checks if the total number of such intersections is even.
 +
 
 +
For example, say we drew a smiley:
 +
import graph;
 +
unitsize(1inch);
 +
filldraw(Circle((0,0),1),yellow,black);
 +
fill(Circle((-.3,.4),.1),black);
 +
fill(Circle((.3,.4),.1),black);
 +
draw(Arc((0,0),.5,-140,-40),blue);
 +
 
 +
and we wanted to clip this to a star-shaped boundary.  Then we add the lines:
 +
path star;
 +
star=expi(0)--(scale((3-sqrt(5))/2)*expi(pi/5))--expi(2*pi/5)--
 +
      (scale((3-sqrt(5))/2)*expi(3*pi/5))--expi(4pi/5)--
 +
      (scale((3-sqrt(5))/2)*expi(5*pi/5))--expi(6*pi/5)--
 +
      (scale((3-sqrt(5))/2)*expi(7*pi/5))--expi(8*pi/5)--
 +
      (scale((3-sqrt(5))/2)*expi(9*pi/5))--cycle;
 +
clip(currentpicture,scale(1.7)*rotate(18)*star);
 +
draw(scale(1.7)*rotate(18)*star);
 +
 
 +
and we get:
 +
 
 +
[[Image:Clip1.gif]]
 +
 
 +
If we wanted to clip to a pattern in an alternating fashion, we could use the <tt>evenodd</tt> fill rule:
 +
 
 +
path zones[];
 +
zones=(Circle((0,0),.2)^^Circle((0,0),.6)^^Circle((0,0),.8)^^Circle((0,0),1));
 +
clip(currentpicture,zones,evenodd);
 +
 
 +
This produces:
 +
 
 +
[[Image:Clip2.gif]]
  
 
===Label===
 
===Label===
Line 75: Line 119:
 
           align align=NoAlign, pen p=nullpen, filltype filltype=NoFill);
 
           align align=NoAlign, pen p=nullpen, filltype filltype=NoFill);
  
This places a label L (usually a string, which can include LaTeX code!) at the point position, aligned by default so that the center of the label is at the position, with optional pen and filltype for its bounding box.  The alignment options, however, can be very useful; any pair can be given as a direction for alignment, and the built-in alignment directions are the compass directions N, E, S, W, NE, NW, SE, SW, ENE, etc. Thus if you wish to label the lower left hand vertex of the right triangle <tt>2(0,0)--(100,0)--(0,100)--cycle</tt> with the letter <math>A</math>, you can use the SW alignment so that the label does not overlap with the diagram:
+
This places a label L (usually a string, which can include LaTeX code!) at the point position, aligned by default so that the center of the label is at the position, with optional pen and filltype for its bounding box.  The alignment options, however, can be very useful; any pair can be given as a direction for alignment, and the built-in alignment directions are the compass directions N, E, S, W, NE, NW, SE, SW, ENE, etc. For example, the image below:
   label("<math>A</math>",(0,0),SW);
+
 
''Try it!''
+
[[Image:Label1.gif]]
 +
 
 +
was produced by 8 double commands of the form
 +
  label("S",(1,0),S);
 +
   dot((1,0));
 +
 
 +
See also: [[Asymptote:Labeling]]
  
 
==Pictures==
 
==Pictures==
Line 89: Line 139:
 
   draw(unitcircle);
 
   draw(unitcircle);
 
will display:
 
will display:
  \includegraphics{Picture1.pdf}
+
 
 
+
[[Image:Picture1.gif]]
 +
 
 
==Transforms==
 
==Transforms==
  \textbf{Transforms} are objects that can be applied to pairs, paths, pictures, and other transforms by the \verb *  operator.  The most commonly used transforms are: \\
+
'''Transforms''' are objects that can be applied to pairs, paths, pictures, and other transforms by the <tt>*</tt> operator.  The most commonly used transforms are:
  \begin{center}
+
[[Image:Transforms.gif]]
  \begin{tabular}{lr}
+
 
  \verb1shift(pair p)1 & translates by vector <math>p</math> \\
+
Another useful transform that is not listed above:
  \verb1rotate(real angle,pair p=(0,0))1 & rotates by angle degrees about p \\
+
 
  \verb1xscale(real r)1 & scales in the x-direction by <math>r</math> \\
+
<code>reflect(pair a, pair b);
  \verb1yscale(real r)1 & scales in the y-direction by <math>r</math> \\
+
reflects about the line a--b.</code>
  \verb1scale(real r)1 & scales in both x and y-directions by <math>r</math> \\
+
 
 
+
[[Asymptote: Useful commands and their Output|Next: Examples]]
  \end{tabular}
 
  \end{center}
 
\pagebreak
 

Latest revision as of 20:38, 26 March 2024

Asymptote (Vector Graphics Language)
Getting Started - Basics - Drawing - Labeling - Filling - Useful functions - Examples - Macros and Packages

Help - Reference - Advanced Asymptote - 3D Graphics - CSE5 Package - How to

Points

A point is associated with a cartesian coordinate pair in Asymptote. There are two useful functions that allow one to use polar coordinates as well:

 dir(theta)

returns the point (cos(theta),sin(theta)) where theta is in degrees, and

 expi(theta)

returns the complex number $e^{i\theta}$, i.e. (cos(theta),sin(theta)) where theta is measured in radians.

Paths

A path (or guide - see Variables and Data Types for the difference) in Asymptote is simply a piecewise cubic function of a parameter $t$, parameterized as $t$ ranges from $0$ to the number of nodes (say $n$) that determine the path. The most basic way to make paths is by joining points (which can be thought of as paths with length 0) or paths p, q together with one of the following operators:

p--q
Connects the end of path p to the beginning of q with a straight line.
p..q..r
Connects p, q, and r with a Bezier cubic spline interpolation so that paths are joined smoothly in an curve that can be twisted. Keep in mind that if only two things are connected with .., the curve will be a straight line.
p^^q
Merges the two paths into a single one without adding anything else.

Connecting the symbol cycle to a path tells Asymptote to form a cyclic path by joining the endpoint with $t=n$ to that with $t=0$.

The following example includes the benefits of all three types of path joins:

unitsize(1inch);
path T,ct,tt;
T=(0,0)--(1,0)--(1/2,sqrt(3)/2)--cycle;
ct=(0,0)..(1,0)--(1/2,sqrt(3)/2)..cycle;
tt=shift(sqrt(3)/6*dir(30))*(scale(1/2)*T);
draw(T);
draw(shift(2*right)*ct);
fill(reverse(shift(4*right)*tt)^^(shift(4*right)*T),blue);

outputs: [asy] unitsize(1inch); path T,ct,tt; T=(0,0)--(1,0)--(1/2,sqrt(3)/2)--cycle; ct=(0,0)..(1,0)--(1/2,sqrt(3)/2)..cycle; tt=shift(sqrt(3)/6*dir(30))*(scale(1/2)*T); draw(T); draw(shift(2*right)*ct); fill(reverse(shift(4*right)*tt)^^(shift(4*right)*T),blue); [/asy]

Pens and Coloring

A pen is just that - the style with which Asymptote draws your paths or pictures. Pens can have various colors, dash patterns (linetypes), and linewidths. The following table gives a variety of examples of pen types and their output:

Table2.gif

We can also add pens with the + operator. For example, the command

 draw((0,0)--(100,100),orange+dashed+linewidth(1));

will produce the image

Pen14.gif

The default pen has linetype solid="", linewidth .5, and color black.

Basic drawing commands

Asymptote has four basic drawing commands: draw, fill, clip, and label. The most important of these is draw.

Draw

The function draw can take many arguments. The following is the structure of a draw command, where anything with = denotes the default value:

 void draw(picture pic=currentpicture, Label L="", path g,
         align align=NoAlign, pen p=currentpen,
         arrowbar arrow=None, arrowbar bar=None, margin margin=NoMargin,
         Label legend="", marker marker=nomarker);

So with draw, you can draw path g to the picture pic along with a string label L, with pen p, etc. Of course, most of this is unnecessary for a basic diagram. The most important thing to notice is that the only non-optional argument of draw is the path g. The command draw(g); where g is a path simply draws the path on top of your current picture.

Fill

The structure of fill is much simpler than that of draw:

  void fill(picture pic=currentpicture, path g,pen p=currentpen);

This fills a cyclic path g in picture pic (see the section on Paths above) with a specified pen p (most often a color - see Pens and Coloring above). For example, the command

fill((0,0)--(0,1)--(1,1)--(1,0)--cycle,red);

where unitsize is 1 inch outputs:

Fill1.gif

Clip

The structure of clip is also simple:

 void clip(picture pic=currentpicture, path g, pen p=currentpen);

This crops a picture so that the boundary is the given path g, with fill rule p. A fill rule tells when a point is inside the boundary of the path; the default fill rule, zerowinding or fillrule(0), checks to see if the number of horizontal intersections from the point to the right is equal to the number of downward intersections with the path. Another useful fill rule is evenodd, or fillrule(1), which checks if the total number of such intersections is even.

For example, say we drew a smiley:

import graph;
unitsize(1inch);
filldraw(Circle((0,0),1),yellow,black);
fill(Circle((-.3,.4),.1),black);
fill(Circle((.3,.4),.1),black);
draw(Arc((0,0),.5,-140,-40),blue);

and we wanted to clip this to a star-shaped boundary. Then we add the lines:

path star;
star=expi(0)--(scale((3-sqrt(5))/2)*expi(pi/5))--expi(2*pi/5)--
     (scale((3-sqrt(5))/2)*expi(3*pi/5))--expi(4pi/5)--
     (scale((3-sqrt(5))/2)*expi(5*pi/5))--expi(6*pi/5)--
     (scale((3-sqrt(5))/2)*expi(7*pi/5))--expi(8*pi/5)--
     (scale((3-sqrt(5))/2)*expi(9*pi/5))--cycle;
clip(currentpicture,scale(1.7)*rotate(18)*star);
draw(scale(1.7)*rotate(18)*star);

and we get:

Clip1.gif

If we wanted to clip to a pattern in an alternating fashion, we could use the evenodd fill rule:

path zones[];
zones=(Circle((0,0),.2)^^Circle((0,0),.6)^^Circle((0,0),.8)^^Circle((0,0),1));
clip(currentpicture,zones,evenodd);

This produces:

Clip2.gif

Label

Label is used for, well, labeling your diagram.

Structure:

void label(picture pic=currentpicture, Label L, pair position,
          align align=NoAlign, pen p=nullpen, filltype filltype=NoFill);

This places a label L (usually a string, which can include LaTeX code!) at the point position, aligned by default so that the center of the label is at the position, with optional pen and filltype for its bounding box. The alignment options, however, can be very useful; any pair can be given as a direction for alignment, and the built-in alignment directions are the compass directions N, E, S, W, NE, NW, SE, SW, ENE, etc. For example, the image below:

Label1.gif

was produced by 8 double commands of the form

 label("S",(1,0),S);
 dot((1,0));

See also: Asymptote:Labeling

Pictures

The basic drawing commands all draw onto pictures, the default picture being currentpicture, which is the one that you see when you build your image. However, you can define a new picture in order to treat several drawn parts as a single object, which can be shifted and transformed as a whole relative to currentpicture. One picture (pic1) can be added to another (pic2) with the command add(pic2,pic1), and by default add(pic) simply adds pic to currentpicture. For example:

 picture pic;
 size(3cm);
 draw(pic,unitsquare);
 draw(pic,unitcircle);
 add(shift(3*right)*pic);
 draw(unitsquare);
 draw(unitcircle);

will display:

Picture1.gif

Transforms

Transforms are objects that can be applied to pairs, paths, pictures, and other transforms by the * operator. The most commonly used transforms are: Transforms.gif

Another useful transform that is not listed above:

reflect(pair a, pair b); reflects about the line a--b.

Next: Examples