Copyright © 2003, 2004 Laurence D. Finston.
Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A copy of the license is included in the section entitled "GNU Free Documentation License".
Please note that the figures cannot be shown in the Info output format.
3DLDF is a free software package for three-dimensional drawing written by Laurence D. Finston, who is also the author of this manual. It is written in C++ using CWEB and it outputs MetaPost code.
3DLDF is a GNU package. It is part of the GNU Project of the Free Software Foundation and is published under the GNU General Public License. See the website http://www.gnu.org for more information. 3DLDF is available for downloading from http://ftp.gnu.org/gnu/3dldf. The official 3DLDF website is http://www.gnu.org/software/3dldf. More information about 3DLDF can be found at the author's website: http://wwwuser.gwdg.de/~lfinsto1.
Please send bug reports to:
bug-3DLDF@gnu.org and
Two other mailing lists may be of interest to users of 3DLDF: help-3DLDF@gnu.org is for people to ask other users for help and info-3DLDF@gnu.org is for sending announcements to users. To subscribe, send an email to the appropriate mailing list or lists with the word "subscribe" as the subject. The author's website is http://wwwuser.gwdg.de/~lfinsto1.
My primary purpose in writing 3DLDF was to make it possible to use MetaPost for three-dimensional drawing. I've always enjoyed using MetaPost, and thought it was a shame that I could only use it for making two-dimensional drawings. 3DLDF is a front-end that operates on three-dimensional data, performs the necessary calculations for the projection onto two dimensions, and writes its output in the form of MetaPost code.
While 3DLDF's data types and operations are modelled on those of Metafont and MetaPost, and while the only form of output 3DLDF currently produces is MetaPost code, it is nonetheless not in principle tied to MetaPost. It could be modified to produce PostScript code directly, or output in other formats. It would also be possible to modify 3DLDF so that it could be used for creating graphics interactively on a terminal, by means of an appropriate interface to the computer's graphics hardware.
The name "3DLDF" ("3D" plus the author's initials) was chosen because, while not pretty, it's unlikely to conflict with any of the other programs called "3D"-something.
This handbook, and the use of 3DLDF itself, presuppose at least some
familiarity on the part of the reader with Metafont, MetaPost,
CWEB, and C++
. If you are not familiar with any or all of them, I
recommend the following sources of information:
Knuth, Donald Ervin.
The METAFONTbook.
Computers and Typesetting; C.
Addison Wesley Publishing Company, Inc.
Reading, Massachusetts 1986.
Hobby, John D.
A User's Manual for MetaPost.
AT & T Bell Laboratories.
Murray Hill, NJ. No date.
Knuth, Donald E. and Silvio Levy.
The CWEB System of Structured Documentation.
Version 3.64--February 2002.
Stroustrup, Bjarne.
The C++
Programming Language.
Special Edition.
Reading, Massachusetts 2000.
Addison-Wesley.
ISBN 0-201-70073-5.
The manuals for MetaPost and CWEB are available from the Comprehensive TeX Archive Network (CTAN). See one of the following web sites for more information:
This manual has been created using Texinfo, a documentation system which is part of the GNU Project, whose main sponsor is the Free Software Foundation. Texinfo can be used to generate online and printed documentation from the same input files.
For more information about Texinfo, see:
Stallmann, Richard M. and Robert J. Chassell.
Texinfo. The GNU Documentation Format.
The Free Software Foundation. Boston 1999.
For more information about the GNU Project and the Free Software Foundation, see the following web site: http://www.gnu.org.
The edition of this manual is 1.1.5.1 and it documents version 1.1.5.1 of 3DLDF. The edition number of the manual and the version number of the program are the same (as of 16 January 2004), but may diverge at a later date.
Note that "I", "me", etc., in this manual refers to Laurence D. Finston, so far the sole author of both 3DLDF and this manual. "Currently" and similar formulations refer to version 1.1.5.1 of 3DLDF as of 16 January 2004.
This manual is intended for both beginning and advanced users of 3DLDF. So, if there's something you don't understand, it's probably best to skip it and come back to it later. Some of the more difficult points, or ones that presuppose familiarity with features not yet described, are in the footnotes.
I firmly believe that an adequate program with good documentation is more useful than a great program with poor or no documentation. The ideal case, of course, is a great program with great documentation. I'm sorry to say, that this manual is not yet as good as I'd like it to be. I apologize for the number of typos and other errors. I hope they don't detract too much from its usefulness. I would have liked to have proofread and corrected it again before publication, but for reasons external to 3DLDF, it is necessary for me to publish now. I plan to set up an errata list on the official 3DLDF website, and/or my own website.
Unless I've left anything out by mistake, this manual documents all of the data types, constants and variables, namespaces, and functions defined in 3DLDF. However, some of the descriptions are terser than I would like, and I'd like to have more examples and illustrations. There is also more to be said on a number of topics touched on in this manual, and some topics I haven't touched on at all. In general, while I've tried to give complete information on the "what and how", the "why and wherefore" has sometimes gotten short shrift. I hope to correct these defects in future editions.
Data types are formatted like this: int
,
Point
, Path
. Plurals are formatted in the same way:
ints
, Points
, Paths
. It is poor
typographical practice to typeset a single word using more than one
font, e.g., int
s, Point
s, Path
s. This applies to
data types whose plurals do not end in "s" as well, e.g.,
the plural of the C++
class Polyhedron
is Polyhedra
.
When C++
functions are discussed in this manual, I always include a
pair
of parentheses to make it clear that the item in question is a function
and not a variable, but I generally do not
include the arguments. For example, if I mention the
function
foo()
, this doesn't imply that foo()
takes no
arguments. If it were appropriate, I would include the argument type:
foo(int)
or the argument type and a placeholder name:
foo(int arg)
or I would write
foo(void)
to indicate that foo()
takes no arguments. Also, I
generally don't indicate the return type, unless it is relevant. If it
is a member function
of a class, I may indicate this,
e.g.,, bar_class::foo()
, or not,
depending on whether this information is relevant. This convention
differs from that used in the Function Index, which is generated
automatically by Texinfo. There, only the name of the function appears,
without parentheses, parameters, or return values. The class type
of member functions may appear in the Function Index, (e.g.,
bar_class::foo
), but only in index entries that have been entered
explicitly by the author; such entries are not generated by Texinfo
automatically.
Examples are formatted as follows:
Point p0(1, 2, 3); Point p1(5, 6, 7.9); Path pa(p0, p1); p0.show("p0:"); -| p0: (1, 2, 3)
The beautiful mathematical typesetting produced by TeX unfortunately does not appear in the Info and HTML versions of this manual. In these, the following symbols are used to replace the proper mathematical symbols.
a^2
as
"a squared".
x_1
as
"x sub one".
x * y
as
"x times y".
sqrt(x)
as
"the square root of x".
In addition, examples can contain the following symbols:
This manual does not use all of the symbols provided by Texinfo. If you
find a symbol you don't understand in this manual (which shouldn't
happen), see page 103 of the Texinfo manual.
Symbols:
The illustrations in this manual have been created using 3DLDF. The
code that generates them is in the Texinfo files themselves, that
contain the text of the manual. Texinfo is based on TeX, so it's
possible to make use of the latter's facility for writing ASCII text to
files using TeX's \write
command.
The file 3DLDF-1.1.5.1/CWEB/exampman.web
contains the
C++
code, and the file 3DLDF-1.1.5.1/CWEB/examples.mp
contains the MetaPost code for generating the illustrations.
3DLDF was built using GCC 2.95 when the illustrations were generated.
For some reason, GCC 3.3 has difficulty with them. It works to generate
them in batches of about 50 with GCC 3.3.
MetaPost outputs Encapsulated PostScript files. These can be included in TeX files, as explained below. However, in order to display the illustrations in the HTML version of this manual, I had to convert them to PNG ("Portable Network Graphics") format. See Converting EPS Files, for instructions on how to do this.
Please note that the illustrations cannot be shown in the Info output format!
If you have problems including the illustrations in the printed version,
for example, if your
installation doesn't have dvips
, look for the following lines
in 3DLDF.texi
:
\doepsftrue %% One of these two lines should be commented-out. %\doepsffalse
Now, remove the %
from in front of \doepsffalse
and put
one in front of \doepsftrue
. This will prevent the illustrations
from being included. This should only be done as a last resort,
however, because it will make it difficult if
not impossible to understand this manual.
The C++ code in an example is not always the complete code used to create the illustration that follows it, since the latter may be cluttered with commands that would detract from the clarity of the example. The actual code used always follows the example in the Texinfo source file, so the latter may be referred to, if the reader wishes to see exactly what code was used to generate the illustration.
You may want to skip the following paragraphs in this section, if you're reading this manual for the first time. Don't worry if you don't understand it, it's meaning should become clear after reading the manual and some experience with using 3DLDF.
The file 3DLDF.texi
in the directory
3DLDF-1.1.5.1/DOC/TEXINFO
, the driver file for this manual, contains
the following TeX code:
\newif\ifmakeexamples \makeexamplestrue %% One of these two lines should be commented-out. %\makeexamplesfalse
When texi2dvi
is run on 3DLDF.texi
,
\makeexamplestrue
is not commented-out, and
\makeexamplesfalse
is,
the C++
code for the illustrations is written to the file
examples.web
.
If the EPS files don't already exist (in the directory
3DLDF-1.1.5.1/DOC/TEXINFO/EPS
),
the TeX macro \PEX
,
which includes them in the Texinfo files, will signal an error each time
it can't find one. Just type s
at the command line to tell
TeX to keep going.
If you want to be sure that these are indeed the only errors, you can
type <RETURN>
after each one instead.
texi2dvi 3DLDF.texi
also generates the file
extext.tex
, which contains TeX code for including the
illustrations by themselves.
examples.web
must now be moved to 3DLDF-1.1.5.1/CWEB/
and
ctangled, examples.c
must compiled,
and 3DLDF must be relinked. ctangle examples
also generates
the header file example.h
, which is included
in main.web
. Therefore, if the contents of examples.h
have
changed since the last time main.web
was ctangled,
main.web
will have to be ctangled, and main.c
recompiled,
before 3dldf
is relinked.1
Running 3dldf
and MetaPost now
generates the EPS (Encapsulated PostScript) files
3DLDFmp.1
through (currently) 3DLDFmp.199
for the illustrations. They must be moved to
3DLDF-1.1.5.1/DOC/TEXINFO/EPS
.
Now, when texi2dvi 3DLDF.texi
is run again, the
dvips
command
\epsffile
includes the EPS files for the illustrations in the
manual. 3DLDF.texi
includes the line \input epsf
, so
that \epsffile
works.
Of course, dvips
(or some other program that does the
job) must be used to convert 3DLDF.dvi
to a PostScript file.
To see exactly how this is done, take a look at the
.texi
source files of this manual.2
In the 3DLDF.texi
belonging to the 3DLDF distribution,
\makeexamplestrue
will be commented-out, and
makeexamplesfalse
won't be, because the EPS files for the
illustrations are included in the distribution.
The version of examples.web
in 3DLDF-1.1.5.1/CWEB
merely
includes the files subex1.web
and subex2.web
.
If you rename 3DLDF-1.1.5.1/CWEB/exampman.web
to examples.web
,
you can generate the illustrations.
As mentioned above, 3DLDF has been programmed using CWEB, which is a "literate programming" tool developed by Donald E. Knuth and Silvio Levy. See Sources of Information, for a reference to the CWEB manual. Knuth's TeX--The Program and Metafont--The Program both include a section "How to read a WEB" (pp. x-xv, in both volumes).
CWEB files combine source code
and documentation. Running ctangle
on a CWEB file,
for example, main.web
, produces the file main.c
containing
C or C++
code. Running cweave main.web
creates a
TeX file with pretty-printed source code and nicely formatted
documentation. I find that using CWEB makes it more natural to
document my code as I write it, and makes the source files easier to
read when editing them. It does have certain consequences
with regard to compilation, but these are taken care of by make
.
See Adding a File, and Changes, for more
information.
The CWEB files in the directory 3DLDF-1.1.5.1/CWEB/
contain the
source code for 3DLDF. The file 3DLDFprg.web
in this directory
is only ever used for cweaving; it is never ctangled and contains no
C++
code for compilation. It does, however, include all of the other
CWEB files, so that cweave 3DLDFprg.web
generates the TeX file
containing the complete documentation of the source code of 3DLDF.
The files 3DLDF-1.1.5.1/CWEB/3DLDFprg.tex
,
3DLDF-1.1.5.1/CWEB/3DLDFprg.dvi
, and
3DLDF-1.1.5.1/CWEB/3DLDFprg.ps
are
included in the distribution of 3DLDF as a
convenience. However, users may generate them themselves, should there
be some reason for doing so, by entering make ps
from the command line of a shell from the working
directory 3DLDF-1.1.5.1/
or 3DLDF-1.1.5.1/CWEB
.
Alternatively, the user may generate them
by hand from the working directory 3DLDF-1.1.5.1/CWEB/
in the
following way:
cweave 3DLDFprg.web
generates 3DLDFprg.tex
.
tex 3DLDFprg
or tex 3DLDFprg.tex
generates
3DLDFprg.dvi
.
dvips -o 3DLDFprg.ps 3DLDFprg
(possibly with additional options)
generates 3DLDFprg.ps
.
lpr -P<
print queue> 3DLDFprg.ps
sends 3DLDFprg.ps
to a printer, on a UNIX or UNIX-like system.
The individual commands may differ, depending on the system you're using.
Metafont is a system created by Donald E. Knuth for generating fonts, in particular for use with TeX, his well-known typsetting system.3 Expressed in a somewhat simplified way, Metafont is a system for programming curves, which are then digitized and output in the form of run-time encoded bitmaps. (See Knuth's The Metafontbook for more information).
John D. Hobby modified Metafont's source code to create
MetaPost, which functions in much the same way, but outputs
encapsulated PostScript (EPS) files instead of bitmaps. MetaPost is
very useful for creating graphics and is a convenient
interface to PostScript. It is also easy both to imbed
TeX code in MetaPost programs, for instance, for typesetting
labels, and to include MetaPost graphics in ordinary TeX
files, e.g., by using dvips
.4
Apart from simply printing the PostScript file output by
dvips
, there are many programs that can process ordinary
or encapsulated PostScript files and convert them to other formats.
Just two of the many possibilities are ImageMagick and GIMP, both of
which can be used to create animations from MetaPost graphics.
However, MetaPost inherited a significant limitation from Metafont: it's not possible to use it for making three-dimensional graphics, except in a very limited way. One insuperable problem is the severe limitation on the magnitude of user-defined numerical variables in Metafont and MetaPost.5 This made sense for Metafont's and MetaPost's original purposes, but they make it impossible to perform the calculations needed for 3D graphics.
Another problem is the data types defined in Metafont: Points are represented as pairs of real values and affine transformations as sets of 6 real values. This corresponds to the representation of points and affine transformations in the plane as a two-element vector on the one hand and a six element matrix on the other. While it is possible to work around the limitation imposed by having points be represented by only two values, it is impracticable in the case of the transformations.
For these reasons, I decided to write a program that would behave more or less like Metafont, but with suitable extensions, and the ability to handle three dimensional data; namely 3DLDF. It stores the data and performs the transformations and other necessary calculations and is not subject to the limitations of MetaPost and its data types. Upon output, it performs a perspective transformation, converting the 3D image into a 2D one. The latter can now be expressed as an ordinary MetaPost program, so 3DLDF writes its output as MetaPost code to a file.
In the following, it may be a little unclear why I sometimes refer to
Metafont and sometimes to MetaPost. The reason is that Metafont
inherited much of its functionality from Metafont. Certain operations
in Metafont have no meaning in MetaPost and so have been removed, while
MetaPost's function of interfacing with PostScript has caused other
operations to be added. For example, in MetaPost, color
is a
data type, but not in Metafont. Unless otherwise stated, when I refer to
Metafont, it can be assumed that what I say applies to MetaPost as well.
However, when I refer to MetaPost, it will generally be in connection
with features specific to MetaPost.
When 3DLDF is run, it uses the three-dimensional data contained in the
user code to create a two-dimensional projection.
Currently, this can be a perspective projection, or a parallel
projection onto one of the major planes. MetaPost code representing
this projection is then written to the output file.
3DLDF does no scan conversion,6
so all of the curves in the projection are
generated by means of the algorithms MetaPost inherited from Metafont.
These algorithms, however, are designed to find the
"most pleasing curve"7
given one or more two-dimensional points and connectors; they do not
account for the the fact that the two-dimensional points are projections
of three-dimensional ones. This can lead to unsatisfactory results,
especially where extreme foreshortening occurs. In particular,
curl
, dir
, tension
, and control points should be
used cautiously, or avoided altogether, when specifying connectors.
3DLDF operates on the assumption that, given an adequate number of points, MetaPost will produce an adequate approximation to the desired curve in perspective, since the greater the number of points given for a curve, the less "choice" MetaPost has for the path through them. My experience with 3DLDF bears this out. Generally, the curves look quite good. Where problems arise, it usually helps to increase the number of points in a curve.
A more serious problem is the imprecision resulting from the operation of rotation. Rotations use the trigonometric functions, which return approximate values. This has the result that points that should have identical coordinate values, sometimes do not. This has consequences for the functions that compare points. The more rotations are applied to points, the greater the divergence between their actual coordinate values, and the values they should have. So far, I haven't found a solution for this problem. On the other hand, it hasn't yet affected the usability of 3DLDF.
3DLDF does not yet include a routine for reading input files. This means that user code must be written in C++ , compiled, and linked with the rest of the program. I admit, this is not ideal, and writing an input routine for user code is one of the next things I plan to add to 3DLDF.
I plan to use Flex and Bison to write the input routine.8 The syntax of the input code should be as close as possible to that of MetaPost, while taking account of the differences between MetaPost and 3DLDF.
For the present, however, the use of 3DLDF is limited to
those who feel comfortable using C++
and compiling and
relinking programs. Please don't be put off by this! It's not so
difficult, and make
does most of the work of recompiling and
running 3DLDF. See Installing and Running 3DLDF, for more
information.
I originally developed 3DLDF on a DECalpha Personal Workstation with two processors running under the operating system Tru64 Unix 5.1, using the DEC C++ compiler. I then ported it to a PC Pentium 4 running under Linux 2.4, using the GNU C++ compiler GCC 2.95.3, and a PC Pentium II XEON under Linux 2.4, using GCC 3.3. I am currently only maintaining the last version. I do not believe that it's worthwhile to maintain a version for GCC 2.95. While I would like 3DLDF to run on as many platforms as possible, I would rather spend my time developing it than porting it. This is something where I would be grateful for help from other programmers.
Although I am no longer supporting ports to other systems, I have left some conditionally compiled code for managing platform dependencies in the CWEB sources of 3DLDF. This may make it easier for other people who want to port 3DLDF to other platforms.
Currently, the files io.web
, loader.web
, main.web
,
points.web
,
and pspglb.web
contain conditionally compiled code, depending on
which compiler, or in the case of GCC, which version of the compiler, is
used. The DEC C++
compiler defines the preprocessor macro
__DECCXX
and GCC defines __GNUC__
. In order to
distinguish between GCC 2.95.3 and GCC 3.3, I've added the macros
LDF_GCC_2_95
and LDF_GCC_3_3
in loader.web
, which
should be defined or undefined, depending on which compiler you're
using. In the distribution, LDF_GCC_3_3
is defined and
LDF_GCC_2_95
is undefined, so if you want to try using GCC 2.95, you'll
have to change this (it's not guaranteed to work).
3DLDF 1.1.5.1 now uses Autoconf and Automake, and the
configure
script generates a config.h
file, which is now
included in loader.web
. Some of
the preprocessor macros defined in config.h
are used to
conditionally include library header files, but so far, there is no error
handling code for the case that a file can't be included. I hope to improve the
way 3DLDF works together with Autoconf and Automake in the near future.
3DLDF 1.1.5 is the first release that contains template functions. Template instantiation differs from compiler to compiler, so using template functions will tend to make 3DLDF less portable. See Template Functions, for more information. I am no longer able to build 3DLDF on the DECalpha Personal Workstation. I'm fairly sure that it would be possible to port it, but I don't plan to do this, since Tru64 Unix 5.1 and the DEC C++
compiler are non-free software.
So far, I've been the sole author and user of 3DLDF. I would be very interested in having other programmers contribute to it. I would be particularly interested in help in making 3DLDF conform as closely as possible to the GNU Coding Standards. I would be grateful if someone would write proper Automake and Autoconf files, since I haven't yet learned how to do so (I'm working on it).
See Introduction, for information on how to contact the author.
Since 3DLDF does not yet have an input routine, user code must be
written in C++
(in main.web
, or some other file) and compiled.
Then, 3DLDF must be relinked, together with the new file of object
code resulting from the compilation.
For now, the important point is that the text of
the examples in this manual represent C++
code.
See Installing and Running 3DLDF, for more information.
The most basic drawable object in 3DLDF is class Point
. It is
analogous to pair
in Metafont. For example, in Metafont one
can define a pair
using the "z" syntax as
follows:
z0 = (1cm, 1cm);
There are other ways of defining pairs
in Metafont (and
MetaPost), but this is the usual way.
In 3DLDF, a Point is declared and initialized as follows:
Point pt0(1, 2, 3);
This simple example demonstrates several differences between Metafont
and 3DLDF. First of all, there is no analog in 3DLDF to Metafont's
"z" syntax.
If I want to have Points
called "pt0
", "pt1
",
"pt2
", etc., then I must declare each of them to be a
Point
:
Point pt0(10, 15, 2); Point pt1(13, 41, 5.5); Point pt2(62.9, 7.02, 8);
Alternatively, I could declare an array of Points
:
Point pt[3];
Now I can refer to pt[0]
, pt[1]
, and pt[2]
.
In the Metafont example, the x and y-coordinates of the pair z0
are specified using the unit of measurement, in this case, centimeters.
This is currently not possible in 3DLDF. The current unit of
measurement is stored in the static variable Point::measurement_units
,
which is a string
. Its default value is "cm"
for
"centimeters".
At present, it is best to stick with one unit of measurement for a
drawing.
After I've defined an input routine, 3DLDF should handle
units of measurement in the same way that Metafont does.
Another difference is that the Points
pt0
, pt1
, and
pt2
have three coordinates, x, y, and z, whereas z0
has
only two, x and y. Actually, the difference goes deeper than this. In
Metafont, a pair
has two parts, xpart
and ypart
,
which can be examined by the user. In 3DLDF, a Point
contains
the following sets of coordinates:
world_coordinates user_coordinates view_coordinates projective_coordinates
These are sets of 3-dimensional homogeneous coordinates, which means that they contain four coordinates: x, y, z, and w. Homogeneous coordinates are used in the affine and perspective transformations (see Transforms).
Currently, only world_coordinates
and
projective_coordinates
are used in 3DLDF.
The world_coordinates
refer to the position of a Point
in
3DLDF's basic, unchanging coordinate system.
The projective_coordinates
are the coordinates of the
two-dimensional projection of the Point
onto a plane.
This projection is what is ultimately printed out or displayed on the
computer screen. Please note, that when the coordinates of a
Point
are referred to in this manual, the
world_coordinates
are meant, unless otherwise stated.
Points
can be declared and their values can be set in different
ways.
Point pt0; Point pt1(1); Point pt2(2.3, 52); Point pt3(4.5, 7, 13.205);
pt0
is declared without any arguments, i.e., using the default
constructor, so the values of its x, y, and
z-coordinates are all 0.
pt1
is declared and initialized with one argument for the x-coordinate,
so its y and z-coordinates are initialized with the values of
CURR_Y
and CURR_Z
respectively.
The latter are static constant data members
of class Point
, whose values are 0 by default. They can be reset
by the user, who should
make sure that they have sensible values.
pt2
is declared and initialized with two arguments for its x and
y-coordinates, so its z-coordinate is initialized to the value of
CURR_Z
. Finally, pt3
has an argument for each of its
coordinates.
Please note that pt0
is constructed using a the default
constructor, whereas the other Points
are constructed using a
constructor with one required argument (for the x-coordinate), and two
optional arguments (for the y and z-coordinates). The default
constructor always sets all the coordinates to 0, irrespective of the
values of CURR_Y
and CURR_Z
.
It is possible to change the value of the coordinates of Points
by using the assignment operator =
(Point::operator=()
) or the function Point::set()
(with appropriate arguments):
Point pt0(2, 3.3, 7); Point pt1; pt1 = pt0; pt0.set(34, 99, 107.5); pt0.show("pt0:"); -| pt0: (34, 99, 107.5) pt1.show("pt1:"); -| pt1: (2, 3.3, 7)
In this example, pt0
is initialized with the coordinates (2, 3.3, 7)
,
and pt1
with the coordinates (0, 0, 0)
.
pt1 = pt0
causes pt1
to have the same coordinates as
pt0
, then the coordinates of pt0
are changed to (34,
99, 107.5)
. This doesn't affect pt1
, whose coordinates remain
(2, 3.3, 7)
.
Another way of declaring and initializing Points
is by using the
copy constructor:
Point pt0(1, 3.5, 19); Point pt1(pt0); Point pt2 = pt0; Point pt3; pt3 = pt0;
In this example, pt1
and pt2
are both declared and
initialized using the copy constructor; Point pt2 = pt0
does not
invoke the assignment operator. pt3
, on the other hand, is
declared using the default constructor, and not initialized. In the
following line, pt3 = pt0
does invoke the assignment operator,
thus resetting the coordinate values of pt3
to those of
pt0
.
Points
don't always have to remain in the same place. There are
various ways of moving or transforming them:
shift
, so I call it "shifting".
class Point
has several member functions
for applying these affine transformations9
to a Point
.
Most of the arguments to these functions are of
type real
. As you may know, there is no such data type in C++
.
I have defined real
using typedef
to be either
float
or double
, depending on the value of a preprocessor
switch for conditional compilation.10
3DLDF uses many real
values and I wanted to be able to
change the precision used by making one change (in the file
pspglb.web
) rather than having to examine all the places in the
program where float
or double
are used. Unfortunately,
setting real
to double
currently doesn't work.
The function
shift()
adds its arguments to the corresponding
world_coordinates
of a Point
. In the following example,
the function show()
is used to print the world_coordinates
of p0
to standard output.
Point p0(0, 0, 0); p0.shift(1, 2, 3); p0.show("p0:"); -| p0: (1, 2, 3) p0.shift(10); p0.show("p0:"); -| p0: (11, 2, 3) p0.shift(0, 20); p0.show("p0:"); -| p0: (11, 22, 3) p0.shift(0, 0, 30); p0.show("p0:"); -| p0: (11, 22, 33)
shift
takes three real
arguments, whereby the second and
third are optional. To shift a Point
in the direction of
the positive or negative y-axis, and/or the positive or negative z-axis
only, then a 0 argument for the
x direction, and possibly one for the y direction
must be used as placeholders, as in the example above.
shift()
can be invoked with a Point
argument
instead of real
arguments. In this case, the x, y, and
z-coordinates of the argument are used for shifting the Point
:
Point a(10, 10, 10); Point b(1, 2, 3); a.shift(b); a.show("a:") -| a: (11, 12, 13)
Another way of shifting Points
is to use the binary +=
operator (Point::operator+=()
) with a Point
argument.
Point a0(1, 1, 1); Point a1(2, 2, 2); a0 += a1; a0.show("a0:"); -| a0: (3, 3, 3)
The function scale()
takes three real
arguments.
The x, y, and z-coordinates of the Point
are
multiplied by the first, second, and third arguments respectively. Only
the first argument is required; the default for the others is 1.
If one wants to perform scaling in either the y-dimension only, or the y and z-dimensions only, a dummy argument of 1 must be passed for scaling in the x-dimension. Similarly, if one wants to perform scaling in the z-dimension only, dummy arguments of 1 must be passed for scaling in the x and y-dimensions.
Point p0(1, 2, 3); p0.scale(2, 3, 4); p0.show("p0:"); -| p0: (2, 6, 12) p0.scale(2); p0.show("p0:"); -| p0: (4, 6, 12) p0.scale(1, 3); p0.show("p0:"); -| p0: (4, 18, 12) p0.scale(1, 1, 3); p0.show("p0:"); -| p0: (4, 18, 36)
Shearing is more complicated than shifting or scaling. The function
shear()
takes six real
arguments.
If p is a Point
, then p.shear(a, b, c, d, e, f)
sets
x_p to x_p + ay_p + bz_p, y_p to
y_p + cx_p + dz_p, and
z_p to z_p + ex_p + fy_p.
In this way, each coordinate of a Point
is modified based on the
values of the other two coordinates, whereby the influence of the
other coordinates on the new value is weighted according to the
arguments.
Point p(1, 1, 1); p.shear(1); p.show("p:"); -| p: (2, 1, 1) p.set(1, 1, 1); p.shear(1, 1); p.show("p:"); -| p: (3, 1, 1) p.set(1, 1, 1); p.shear(1, 1, 2, 2, 3, 3); p.show("p:"); -| p: (3, 5, 7)
[next figure] demonstrates the effect of shearing the points of a rectangle in the x-y plane.
Point P0; Point P1(3); Point P2(3, 3); Point P3(0, 3); Rectangle r(p0, p1, p2, p3); r.draw(); Rectangle q(r); q.shear(1.5); q.draw(black, "evenly");
Fig. 1.
The function rotate()
rotates a Point
about one or more of
the main axes.
It takes three real
arguments, specifying the
angles of rotation in degrees about the x, y, and z-axes respectively.
Only the first argument is required, the other two are 0 by default. If
rotation about the y-axis, or the y and z-axes only are required, then 0
must be used as a placeholder for the first and possibly the second
argument.
Point p(0, 1); p.rotate(90); p.show("p:"); -| p: (0, 0, -1) p.rotate(0, 90); p.show("p:"); -| p: (1, 0, 0) p.rotate(0, 0, 90); p.show("p:"); -| p: (0, 1, 0)
The rotations are performed successively about the
x, y, and z-axes. However, rotation is not a commutative
operation, so if rotation about the main axes in a different
order is required, then rotate()
must be invoked more than once:
Point A(2, 3, 4); Point B(A); A.rotate(30, 60, 90); A.show("A:"); -| A: (-4.59808, -0.700962, 2.7141) B.rotate(0, 0, 90); B.rotate(0, 60); B.rotate(30); B.show("B:"); -| B: (-4.9641, 1.43301, -1.51795)
Rotation need not be about the main axes; it can also be performed
about a line defined by two Points
. The function rotate()
with two Point
arguments and a real
argument for the
angle of rotation (in degrees) about the axis. The real
argument
is optional, with
180 degrees
as the default.
Point p0 (-1.06066, 0, 1.06066); Point p1 (1.06066, 0, -1.06066); p1 *= p0.rotate(0, 30, 30); p0.show("p0:"); -| p0: (-1.25477, -0.724444, 0.388228) p1.show("p1:"); -| p1: (1.25477, 0.724444, -0.388228) p0.draw(p1); Point p2(1.06066, 0, 1.06066); p2.show("p2:"); -| p2: (1.06066, 0, 1.06066) Point p3(p2); p3.rotate(p1, p0, 45); p3.show("p3:"); -| p3 (1.09721, 1.15036, 1.17879) Point p4(p2); p4.rotate(p1, p0, 90); p4.show("p4:"); -| p4: (0.882625, 2.05122, 0.485242) Point p5(p2); p5.rotate(p1, p0, 135); p5.show("p5:"); -| p5: (0.542606, 2.17488, -0.613716) Point p6(p2); p6.rotate(p1, p0); p6.show("p6:"); -| p6: (0.276332, 1.44889, -1.47433)
Fig. 2.
I have sometimes gotten erroneous results using rotate()
for
rotation about two Points
. It's usually worked to reverse the
order of the Point
arguments, or to change sign of the angle
argument. I think I've fixed the problem, though.
When Points
are transformed using shift()
, shear()
,
or one of the other transformation functions, the
world_coordinates
are not modified directly. Instead,
another data member of class Point
is used to store the
information about the transformation, namely transform
of
type class Transform
. A Transform
object has a single
data element of type Matrix
and a number of member functions. A
Matrix
is
simply a
4 X 4
array11
of reals
defined using typedef real Matrix[4][4]
.
Such a matrix suffices for performing all
of the transformations (affine and perspective) possible in
three-dimensional space.12
Any combination of transformations can be represented by a single
transformation matrix. This means that consecutive transformations
of a Point
can be "saved up" and applied to its coordinates
all at once when needed, rather than updating them for each
transformation.
Transforms
work by performing matrix multiplication of
Matrix
with the homogeneous world_coordinates
of
Points
.
If a set of homogeneous coordinates
\alpha = (x, y, z, w)
and
Matrix M
=
a e i m
b f j n
c g k o
d h l p
then the set of homogeneous coordinates \beta resulting from
multiplying \alpha and M is calculated as follows:
\beta = \alpha\times M = ((xa + yb + zc + wd), (xe + yf + zg + wh), (xi + yj + zk + wl), (xm + yn + zo + wp))Please note that each coordinate of \beta can be influenced by all of the coordinates of \alpha.
Operations on matrices are very important in computer graphics applications and are described in many books about computer graphics and geometry. For 3DLDF, I've mostly used Huw Jones' Computer Graphics through Key Mathematics and David Salomon's Computer Graphics and Geometric Modeling.
It is often useful to declare and use Transform
objects in 3DLDF,
just as it is for transforms
in Metafont. Transformations can be
stored in Transforms
and then be used to transform Points
by means of Point::operator*=(const Transform&)
.
1. Transform t; 2. t.shift(0, 1); 3. Point p(1, 0, 0); 4. p *= t; 5. p.show("p:"); -| p: (1, 1, 0)
When a Transform
is declared (line 1), it is
initialized to an identity matrix. All identity matrices are
square, all of the elements of the main diagonal (upper left to lower
right) are 1, and all of the other elements are 0.
So a
4 X 4
identity matrix, as used in 3DLDF, looks like this:
1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1If a matrix A is multiplied with an identity matrix I, the result is identical to A, i.e., A * I = A. This is the salient property of an identity matrix.
The same affine transformations are applied in the same way to
Transforms
as they are to Points
, i.e., the functions
scale()
, shift()
,
shear()
, and rotate()
correspond to the Point
versions of these functions, and they take the same arguments:
Point p; Transform t; p.shift(3, 4, 5); t.shift(3, 4, 5); => p.transform == t p.show_transform("p:"); -| p: Transform: 0 0.707 0.707 0 -0.866 0.354 -0.354 0 -0.5 -0.612 0.612 0 0 0 0 1 t.show("t:"); -| t: 0 0.707 0.707 0 -0.866 0.354 -0.354 0 -0.5 -0.612 0.612 0 0 0 0 1
A Transform
t is applied to a
Point
P using the binary *=
operation
(Point::operator*=(const Transform&)
)
which performs matrix multiplication of P.transform
by t
.
See Point Reference; Operators.
Point P(0, 1); Transform t; t.rotate(90); t.show("t:"); -| t: 1 0 0 0 0 0 -1 0 0 1 0 0 0 0 0 1 P *= t; P.show_transform("P:"); -| P: Transform: 1 0 0 0 0 0 -1 0 0 1 0 0 0 0 0 1 P.show("P:"); -| P: (0, 0, -1)
In the example above, there is no real need to use a Transform
,
since P.rotate(90)
could have been called directly.
As constructions become more complex, the power of Transforms
becomes clear:
1. Point p0(0, 0, 0); 2. Point p1(10, 5, 10); 3. Point p2(16, 14, 32); 4. Point p3(25, 50, 99); 5. Point p4(12, 6, 88); 6. Transform a; 7. a.shift(2, 3, 4); 8. a.scale(1, 3, 1); 9. p2 *= p3 *= a; 10. a.rotate(p0, p1, 75); 11. p4 *= a; 12. p2.show("p2:"); -| p2: (18, 51, 36) 13. p3.show("p3:"); -| p3: (27, 159, 103) 14. p4.show("p4:"); -| p4: (24.4647, -46.2869, 81.5353)
In this example, a is shifted and scaled, and a is applied
to both in line 9. This works, because
the binary operation
operator*=(const Transform& t)
returns t,
making it possible to chain invocations of *=
.
Following this, a is rotated
75 degrees
about the line through p_0 and p_1. Finally, all three transformations, which are stored in a, are applied to p_4.
Inversion is another operation that can be performed on
Transforms
. This makes it possible to reverse the effect of a
Transform
, which may represent multiple transformations.
Point p; Transform t; t.shift(1, 2, 3); t.scale(2, 3, 4); t.rotate(45, 45, 30); t.show("t:"); -| t: 1.22 0.707 1.41 0 0.238 2.59 -1.5 0 -3.15 1.45 2 0 -7.74 10.2 4.41 1 p *= t; p.show("p:"); -| p: (-7.74, 10.2, 4.41) Transform u; u = t.inverse(); u.show("u:"); -| u: 0.306 0.0265 -0.197 2.85e-09 0.177 0.287 0.0906 -1.12e-09 0.354 -0.167 0.125 0 -1 -2 -3 1 p *= u; p.show("p:"); -| p: (0, 0, 0) u *= t; u.show("u:"); -| u: 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1
If inverse()
is called with no argument, or with the argument
false
, it returns a
Transform
representing its inverse, and remains unchanged. If it
is called with the argument true
, it is set to its inverse.
Complete reversal of the transformations applied to a Point
, as
in the previous example, probably won't make much sense. However,
partial reversal is a valuable technique. For example, it is used in
rotate()
for rotation about a line defined by two Points
.
The following example merely demonstrates the basic principle; an
example that does something useful would be too complicated.
Transform t; t.shift(3, 4, 5); t.rotate(45); t.scale(2, 2, 2); Point p; p *= t; p.show("p:"); -| p: (6, 12.7279, 1.41421) t.inverse(true); p.rotate(90, 90); p *= t; p.show("p:"); -| p: (3.36396, -5.62132, -2.37868)
It's all very well to declare Points
, place them at particular
locations, print their locations to standard output, and transform them,
but none of these operations produce any MetaPost output.
In order to do this, the first step is to use drawing and
filling commands. The drawing and filling commands in 3DLDF are
modelled on those in Metafont.
The following example demonstrates how to draw a dot specifying a
Color
(see Color Reference) and a
pen13.
Point P(0, 1); P.drawdot(Colors::black, "pencircle scaled 3mm");
Fig. 3.
In drawdot()
, a Color
argument precedes the
string
argument for the pen, so "Colors::black
" must be
specified as a placeholder in the call to
drawdot()
.14
The following example "undraws" a dot at the same location using a
smaller pen. undraw()
does not take a Color
argument.
p.undrawdot("pencircle scaled 2mm");
Fig. 4.
For complete descriptions of drawdot()
and undrawdot()
,
see Point Reference; Drawing.
Drawing and undrawing dots is not very exciting. In order to make a
proper drawing it is necessary to connect the Points
. The most
basic way of doing this is to use the Point
member function
draw()
with a Point
argument:
Point p0; Point p1(2, 2); p0.draw(p1);
Fig. 5.
p0.draw(p1)
is equivalent in its effect to
p1.draw(p0)
.
The function Point::draw()
takes a required Point&
argument (a reference15
to a Point
) an optional Color
argument, and optional string
arguments for
the dash pattern and the
pen. The string
arguments, if present, are passed unchanged to
the output file.
The empty string
following the
argument p1
is a placeholder for the dash pattern argument, which
isn't used here.
p0.draw(p1, Colors::gray, "", "pensquare scaled .5cm rotated 45");
Fig. 6.
The function Point::undraw()
takes a required Point&
argument and
optional string
arguments for the dash pattern and the
pen. Unlike Point::draw()
, a Color
argument would have no
meaning for Point::undraw()
.
The string
arguments are passed unchanged to the output file.
undraw()
can be used to "hollow out" the region
drawn in [the previous figure]
. Since a dash pattern is used, portions
of the middle of the region are not undrawn.
p0.undraw(p1, "evenly scaled 6", "pencircle scaled .2cm");
Fig. 7.
For complete descriptions of draw()
and undraw()
,
see Point Reference; Drawing.
The labels in the previous examples were made by using the functions
Point::label()
and Point::dotlabel()
, which make it
possible to include TeX text in a drawing.
label()
and dotlabel()
take string
arguments for
the text of the label and the position of the label with respect to the
Point
. The label text is formatted using TeX, so it can contain
math mode material between dollar signs. Please note that double backslashes
must be used, where a single backslash would suffice in a file of
MetaPost code, for example, for TeX control sequences.
Alternatively, a short
argument can be used for the label.
The position argument is optional, with "top"
as the default. If
the empty string
""
is used, the label will centered about
the Point
itself. This will usually only make sense for
label()
, because it would otherwise interfere with the dot.
Valid arguments for the
position are the same as in MetaPost: "top"
, "bot"
(bottom), "lft"
(left), "rt"
(right),
"ulft"
(upper left), "urt"
(upper right),
"llft"
(lower left), and "lrt"
(lower right).
Point p0; Point p1(1); Point p2(2); Point p3(p0); Point p4(p1); Point p5(p2); p3 *= p4 *= p5.shift(0, 1); p0.draw(p1); p1.draw(p2); p2.draw(p5); p5.draw(p4); p4.draw(p3); p3.draw(p0); p0.label($p_0$, ""); p1.dotlabel(1); p2.dotlabel("p2", "bot"); p3.dotlabel("This is $p_3$", "lft"); p4.label(4); p5.label("$\\leftarrow p_5$", "rt");
Fig. 8.
For complete descriptions of Point::label()
and
Point::dotlabel()
, see Points; Labelling.
Points
alone are not enough for making useful drawings. The next
step is to combine them into Paths
, which are similar to
Metafont's paths, except that they are three-dimensional.
A Path
consists of a number of Points
and strings
representing the connectors. The latter are not processed by
3DLDF, but are passed unchanged to the output file. They must be valid
connectors for MetaPost, e.g.:
.. ... -- --- & curl{2}.. {dir 60}.. {z1 - z2}.. .. tension 1 and 1.5.. ..controls z1 and z2..
Usually, it will only make sense to use .. or -, and not
..., --, tension, curl, controls, or any of the
other possibilities, in Paths
, unless
you are sure that they will only be viewed with no foreshortening due to
the perspective
projection. This can be the case, when a Path
lies in a plane
parallel to one of the major planes, and is projected using parallel
projection onto that plane. Otherwise,
the result of using these connectors is likely to be unsatisfactory, because
MetaPost performs its calculations based purely on the two-dimensional
values of the points in the perspective projection.
While the Points
on the Path
will be projected correctly,
the course of the Path
between these Points
is likely to
differ, depending on the values of the Focus
used (see Focuses), so that
different views of the same Path
may well be mutually
inconsistent.
This problem doesn't arise with "-", since the perspective
projection does not "unstraighten" straight lines,
but it does with "..", even without tension, curl,
or controls.
The solution is to use enough Points
, since a greater number of
Points
on a Path
tends to reduce the number
of possible courses through the Points
.16
There are various ways of declaring and initializing Paths
. The
simplest is to use the constructor taking two Point
arguments:
Point A; Point B(2, 2); Path p(A, B); p.draw();
Fig. 9.
Paths
created in this way are important, because they are
guaranteed to be linear, as long as no operations are performed on them
that cause them to become non-linear.
Linear Paths
can be used to find intersections.
See Path Intersections.
Paths
can be declared and initialized using a single connector
and an arbitrary number of Points
. The first argument is a
string
specifying the connector. It is followed by a
bool
, indicating whether the
Path
is cyclical or not. Then, an arbitrary number of
pointers to Point
follow. The last argument must be 0.17
Point p[3]; p[0].shift(1); p[1].set(1, 2, 2); p[2].set(1, 0, 2); Path pa("--", true, &p[0], &p[1], &p[2], 0); pa.draw();
Fig. 10.
Another constructor must be used for Paths
with
more than one connector and an arbitrary number of Points
.
The argument list starts with a pointer to Point
, followed by
string
for the first connector. Then,
pointer to Point
arguments alternate with string
arguments
for the connectors.
Again, the list of arguments ends in 0. There is no
need for a bool
to indicate whether the Path
is cyclical
or not; if it is, the last non-zero argument will be a connector,
otherwise, it will be a pointer to Point
.
Point p[8]; p[0].set(-2); p[1].set(2); p[2].set(0, 0, -2); p[3].set(0, 0, 2); p[4] = p[0].mediate(p[2]); p[5] = p[2].mediate(p[1]); p[6] = p[1].mediate(p[3]); p[7] = p[3].mediate(p[0]); p[4] *= p[5] *= p[6] *= p[7].shift(0, 1); Path pa(&p[0], "..", &p[4], "...", &p[2], "..", &p[5], "...", &p[1], "..", &p[6], "...", &p[3], "..", &p[7], "...", 0); pa.draw();
Fig. 11.
As mentioned above (see Accuracy), specifying connectors is
problematic for three-dimensional Paths
,
because MetaPost ultimately calculates the "most pleasing curve"
based on the two-dimensional points in the MetaPost code written by
3DLDF.18
For this reason, it's advisable to avoid specifying curl
,
dir
, tension
or control points in connectors.
The more Points
a (3DLDF) Path
or other object contains,
the less freedom MetaPost has to determine the (MetaPost) path
through them.
So a three-dimensional Path
or
other object in 3DLDF should have enough Points
to ensure
satisfactory results. The Path
in [the previous figure]
does not
really have enough Points
. It may require some trial and error
to determine
what a sufficient number of Points
is in a given case.
Paths
are very flexible, but not always convenient. 3DLDF
provides a number of classes representing common geometric
Shapes
, which will be described in subsequent sections, and I
intend to add more in the course of time.
The easiest way to draw a Path
is with no arguments.
Point pt[5]; pt[0].set(-1, -2); pt[1].set(0, -3); pt[2].set(1, 0); pt[3].set(2, 1); pt[4].set(-1, 2); Path pa("..", true, &pt[0], &pt[1], &pt[2], &pt[3], &pt[4], 0); pa.draw();
Fig. 12.
Since pa
is closed, it can be filled as well as drawn. The
following example uses fill()
with a Color
argument, in
order to avoid having a large splotch of black on the page.
Common Colors
are declared in the namespace Colors
.
See Color Reference.
pa.fill(Colors::gray);
Fig. 13.
Closed Paths
can be filled and drawn, using the function
filldraw()
. This function draws the Path
using the pen
specified, or MetaPost's currentpen
by default. A Color
for drawing the Path
can also be specified, otherwise, the
default color (currently Colors::black
) is used.
In addition, the Path
is filled using a second Color
,
which can be specified, or the background_color
(Colors::background_color
), by default.
Filling a Path
using the background color causes it to hide
objects that lie behind it.
See Surface Hiding, for a description of the surface hiding
algorithm, and examples. Currently, this algorithm is quite primitive
and only works
for simple cases.
Point p0(-3, 0, 1); Point p1(3, 1, 1); p0.draw(p1); pa.filldraw();
Fig. 14.
The following example uses arguments for the Colors
used for
drawing and filling, and the pen. The empty string argument before the
pen argument is a placeholder for the dash pattern argument.
pa.filldraw(black, gray, "", "pensquare xscaled 3mm yscaled 1mm rotated 60");
Fig. 15.
Paths
can also be "undrawn", "unfilled", and "unfilldrawn",
using the corresponding functions:
pa.fill(gray); p0.undraw(p1, "", "pencircle scaled 3mm");
Fig. 16.
pa.fill(gray); Path q; q = pa; q.scale(.5, .5); q.unfill();
Fig. 17.
The function unfilldraw()
takes a Color
argument for
drawing the Path
, which is *Colors::background_color
by
default. This makes it possible to unfill the Path
while drawing
the outline with a visible Color
. On the other hand, it also
makes it necessary to specify *Colors::background_color
or
Colors::white
, if the user wants to use the dash pattern and/or
pen arguments, without drawing the Path
.
pa.fill(gray); q.unfilldraw(white, "", "pensquare xscaled 3mm yscaled 1mm");
Fig. 18.
The following example demonstrates the use of unfilldraw()
with
black
as its Color
argument. Unfortunately, it also
demonstrates one of the limitations of the surface hiding algorith: The
line from p0
to p1
is hidden by the
filled Path pa
. Since the portion of pa
covered by
Path q
has been unfilled,
the line from p_0 to p_1
should be visible as it passes through q
. However, from the
point of view of 3DLDF, there is no relationship between pa
and
q
; nor does it "know" whether a Path
has been filled or
unfilled. If it's on a Picture
, it will hide objects lying
behind it, unless the surface hiding algorithm fails for another
reason. See Surface Hiding, for more information.
p0.draw(p1); pa.fill(gray); q.unfilldraw(black, "", "pensquare xscaled 3mm yscaled 1mm");
Fig. 19.
See Paths; Drawing and Filling, for more information, and complete descriptions of the functions.
3DLDF currently includes the following classes representing plane
geometric figures: Polygon
, Reg_Cl_Plane_Curve
("Regular Closed Plane Curve"), Reg_Polygon
("Regular
Polygon"), Rectangle
, Ellipse
and
Circle
. Polygon
and Reg_Cl_Plane_Curve
are derived
from Path
, Reg_Polygon
and Rectangle
are derived
from Polygon
, and Ellipse
and Circle
are derived
from Reg_Cl_Plane_Curve
. Polygon
and
Reg_Cl_Plane_Curve
are meant to be used as base classes only, so
objects of these types should normally never be declared.
Since Reg_Polygon
, Rectangle
, Ellipse
, and
Circle
all ultimately derive from Path
, they are really
just special kinds of Path
.
In particular, they inherit their drawing and filling functions from
Path
, and their transformation functions take the same arguments
as the Path
versions.
They also have constructors
and setting functions that work in a similar way, with a few minor
differences, to account for their different natures.
See Polygon Reference, Rectangle Reference,
Ellipse Reference, and Circle Reference, for complete
information on these classes.
The following example creates a pentagon in the x-z plane, centered about the origin, whose enclosing circle has a radius equal to 3cm.
default_focus.set(2, 3, -10, 2, 3, 10, 10); Reg_Polygon p(origin, 5, 3); p.draw();
Fig. 20.
Three additional arguments cause the pentagon to be rotated about the x, y, and z axes by the amount indicated. In this example, it's rotated 90 degrees
about the x-axis, so that it comes to lie in the x-y plane:
Reg_Polygon p(origin, 5, 3, 90); p.draw();
Fig. 21.
In this example, it's rotated 36 degrees
about the y-axis, so that it appears to point in the opposite direction from the first example:
Reg_Polygon p(origin, 5, 3, 0, 36); p.draw();
Fig. 22.
In this example, it's rotated 90 degrees
about the z-axis, so that it lies in the z-y plane:
Reg_Polygon p(origin, 5, 3, 0, 0, 90); p.draw();
Fig. 23.
In this example, it's rotated 45 degrees
about the x, y, and z-axes in that order:
Reg_Polygon p(origin, 5, 3, 45, 45, 45); p.draw();
Fig. 24.
Reg_Polygons
need not be centered about the origin
. If
another Point
pt is used as the first argument, the Reg_Polygon
is first created with its center at the origin, then the specified
rotations, if any, are performed. Finally, the Reg_Polygon
is
shifted such that its center comes to lie on pt:
Point P(-2, 1, 1); Reg_Polygon hex(P, 6, 4, 60, 30, 30); hex.draw();
Fig. 25.
In the following example, the Reg_Polygon
polygon
is first
declared using the default constructor, which creates an empty
Reg_Polygon
. Then, the polygon
is repeatedly changed using
the setting function corresponding to the constructor used in the
previous examples. [next figure]
demonstrates that a given
Reg_Polygon
need not always have the same number of sides.
Point p(0, -3); Reg_Polygon polygon; for (int i = 3; i < 9; ++i) { polygon.set(p, i, 3); polygon.draw(); p.shift(0, 1); }
Fig. 26.
A Rectangle
can be constructed in the x-z plane by specifying a
center Point
, the width, and the height:
Rectangle r(origin, 2, 3); r.draw();
Fig. 27.
Three additional arguments can be used to specify rotation about the x, y, and z-axes respectively:
Rectangle r(origin, 2, 3, 30, 45, 15); r.draw();
Fig. 28.
If a Point
p other than the origin is specified as the center of
the Rectangle
, the latter is first created in the x-z plane,
centered about the origin, as above. Then, any rotations specified are
performed. Finally, the Rectangle
is shifted such that its center
comes to lie at p:
Point p0(.5, 1, 3); Rectangle r(p0, 4, 2, 30, 30, 30); r.draw();
Fig. 29.
This constructor has a corresponding setting function:
Rectangle r; for (int i = 0; i < 180; i += 30) { r.set(origin, 4, 2, i); r.draw(); }
Fig. 30.
Rectangles
can also be specified using four Points
as
arguments, whereby they must be ordered so that they are contiguous in
the resulting Rectangle
:
Point pt[4]; pt[0].shift(-1, -2); pt[2] = pt[1] = pt[0]; pt[1].rotate(180); pt[3] = pt[1]; pt[2] *= pt[3].rotate(0, 180); Rectangle r(pt[0], pt[2], pt[3], pt[1]); r.draw();
Fig. 31.
This constructor checks whether the Point
arguments are coplanar,
however, it does not check whether they are really the corners of a
valid rectangle; the user, or the code that calls this function, must
ensure that they are. In the following
example, r
, although not rectangular, is a Rectangle
, as
far as 3DLDF is concerned:
pt[0].shift(0, -1); pt[3].shift(0, 1); Rectangle q(pt[0], pt[2], pt[3], pt[1]); q.draw();
Fig. 32.
This constructor is not really intended to be used directly, but should
mostly be called from within other functions, that should ensure that
the arguments produce a rectangular Rectangle
. There is also no
guarantee that transformations or other functions called on
Rectangle
, Circle
, or other classes representing
geometric figures won't cause them to become non-rectangular,
non-circular, or otherwise irregular. Sometimes, this might even be
desirable. I plan to add the function
Rectangle::is_rectangular()
soon, so that users can test
Rectangles
for rectangularity.
Ellipse
has a constructor similar to those for
Reg_Polygon
and Rectangle
. The first argument is the
center of the Ellipse
, and the following two specify the lengths
of the horizontal and vertical axes respectively. The Ellipse
is
first created in the x-z plane, centered about the origin. The
horizontal axis lies along the x-axis and the vertical axis lies along
the z-axis. The three subsequent arguments specify the amounts of
rotation about the x, y, and z-axes respectively and default to 0.
Finally,
Ellipse
is shifted such that its center comes to lie at the
Point
specified in the first argument.
Point pt(-1, 1, 1); Ellipse e(pt, 3, 6, 90); e.draw();
Fig. 33.
As you may expect, this constructor has a corresponding setting function:
Ellipse e; real h_save = 1.5; real v_save = 2; real h = h_save; real v = v_save; Point p(-1); for (int i = 0; i < 5; ++i) { e.set(p, h, v, 90); e.draw(); h_save += .25; v_save += .25; h *= sqrt(h_save); v *= sqrt(v_save); p.shift(0, 0, 2); }
Fig. 34.
Circles
are constructed just like Ellipses
, except that
the vertical and horizontal axes are per definition the same, so
there's only one argument for the diameter, instead of two for the
horizontal and vertical axes:
Point P(0, 2, 1); Circle c(P, 3.5, 90, 90); c.draw();
Fig. 35.
This constructor, too, has a corresponding setting function:
Circle c; Point p(-1, 0, 5); for (int i = 0; i < 16; ++i) { c.set(p, 5, i * 22.5, 0, 0, 64); c.draw(); }
Fig. 36.
In the preceding example, the last argument to set()
, namely "64",
is for the number of Points
used for constructing the perimeter
of the Circle
. The default value is 16, however, if it is used,
foreshortening distorts the most nearly horizontal Circle
.
Increasing the number of points used improves its appearance. However,
there may be a limit to how much improvement is possible.
See Accuracy.
A cuboid is a solid figure consisting of six rectangular faces
that meet at right angles. A cube is a special form of cuboid, whose
faces are all squares. The constructor for the class Cuboid
follows the pattern familiar from the constructors for the plane
figures: The first argument is the center of the Cuboid
,
followed by three real
arguments for the height, width, and
depth, and then three more real
arguments for the angles of
rotation about the x, y, and z-axes. The Cuboid
is first
constructed with its center at the origin. Its width, height, and depth
are measured along the x, y, and z-axes respectively. If rotations are
specified, it is rotated about the x, y, z-axes in that order. Finally,
it is shifted such that its center comes to lie on its Point
argument, if the latter is not the origin.
If the width, height, and depth arguments are equal, the Cuboid
is a cube:
Cuboid c0(origin, 3, 3, 3, 0, 30); c0.draw();
Fig. 37.
In the following example, the Cuboid
is "filldrawn", so that
the lines dilineating the hidden surfaces of the Cuboid
are
covered.
Cuboid c1(origin, 3, 4, 5, 0, 30); c1.filldraw();
Fig. 38.
The class Polyhedron
is meant for use only as a base class;
no objects of type Polyhedron
should be declared. Instead, there
is a class for each of the different drawable polyhedra. Currently,
3DLDF defines only three: Tetrahedron
, Dodecahedron
, and
Icosahedron
. There's no need for a Cube
class, because
cubes can be drawn using Cuboid
(see Cuboid Getstart).
Polyhedra have a high priority in my plans for 3DLDF.
I intend to add Octahedron
soon, which will complete the set of regular
Platonic polyhedra. Then I will begin adding the semi-regular
Archimedean polyhedra, and their duals.
The constructors for the classes derived from Polyhedron
follow
the pattern familiar from the classes already described. The constructors
for the classes described below have identical arguments: First, a
Point
specifying the center, then a real
for the
diameter of the surrounding circle (Umkreis, in German) of one of
its polygonal faces, followed by three
real
arguments for the angles of rotation about the main axes.
The center of a tetrahedron is the intersection of the lines from a
vertex to the center of the opposite side. At least, in 3DLDF, this is
the center
of a Tetrahedron
. I'm not 100 degrees
certain
that this is mathematically correct.
Tetrahedron t(origin, 4); t.draw(); t.get_center().dotlabel("$c$");
Fig. 39.
A dodecahedron has 12 similar regular pentagonal faces.
The following examples show the same Dodecahedron
using different
projections:
default_focus.set(2, 5, -10, 2, 5, 10, 10); Dodecahedron d(origin, 3); d.draw();
Fig. 40.
Fig. 41.
Please note that the Dodecahedron
in [next figure]
is drawn, and not
filldrawn!
Fig. 42.
Fig. 43.
In [next figure]
, d
is filldrawn. In this case,
the surface hiding algorithm has worked properly.
See Surface Hiding.
Fig. 44.
An icosahedron has 20 similar regular triangular faces.
The following examples show the same Icosahedron
using different
projections:
default_focus.set(3, 0, -10, 2, 0, 10, 10); Icosahedron i(origin, 3); i.draw();
Fig. 45.
Fig. 46.
Fig. 47.
Fig. 48.
In [next figure]
, i
is filldrawn. In this case,
the surface hiding algorithm has worked properly.
See Surface Hiding.
Fig. 49.
Applying drawing and filling operations to the drawable objects described
in the previous chapters isn't enough to produce output. These
operations merely modify the Picture
object that was passed to
them as an argument (current_picture
, by default).
Pictures
in 3DLDF are quite different from pictures
in
MetaPost.
When a drawing or filling operation is applied to an object O, a
copy of O, C, is allocated on the free store, a pointer to
Shape
S is pointed at C, and S is pushed onto
the vector<Shape*> shapes
on the Picture
P, which
was passed as an argument to the drawing or filling command. The
arguments for the pen,
dash pattern, Color
, and any others, are used to set the
corresponding data members of C (not O).
In order to actually
cause MetaPost code to be written to the output file, it is necessary
to invoke P.output()
. Now, the appropriate version of
output()
is applied to each of the objects pointed to
by a pointer on P.shapes
. output()
is a pure
virtual function in Shape
, so all classes derived from
Shape
must have an output()
function. So, if
shapes[0]
points to a Path
,
Path::output()
is called, if
shapes[1]
points to a Point
,
Point::output()
is called, and if shapes[2]
points to an
object of a type derived from Solid
, Solid::output()
is
called.
Point
, Path
, and Solid
are namely the only classes
derived from Shape
for which a version of output()
is defined. All
other Shapes
are derived from one of these classes.
These output()
functions then write the MetaPost code to the
output file through the output file stream out_stream
.
beginfig(1); default_focus.set(0, 0, -10, 0, 0, 10, 10); Circle c(origin, 3, 90); c.draw(); c.shift(1.5); c.draw(); current_picture.output(); endfig(1);
Fig. 50.
The C++
code for [the previous figure]
starts with the command
beginfig(1)
and ends with the command
endfig(1)
.
They simply write "beginfig(<arg>
)
" and
"endfig()
" to
out_stream
,
The optional
unsigned int
argument to endfig()
is not written to
out_stream
, it's merely
"syntactic sugar" for the user.
In MetaPost, the endfig
command causes output and then clears
currentpicture
. This is not the case in 3DLDF, where
Picture::output()
and Picture::clear()
must
be invoked explicitly:
beginfig(1); Point p0; Point p1(1, 2, 3); p0.draw(p1); current_picture.output(); endfig(1); beginfig(2); current_picture.clear(); Circle C(origin, 3); C.fill(); current_picture.output(); endfig(2);
In [next figure]
, two Pictures
are used within a single figure.
beginfig(1); Picture my_picture; default_focus.set(0, 0, -10, 0, 0, 10, 10); Circle c(origin, 3, 90); c.draw(my_picture); my_picture.output(); c.shift(1.5); c.fill(light_gray); current_picture.output(); endfig(1);
Fig. 51.
Multiple objects, or complex objects made up of sub-objects, can be
stored in a Picture
, so that operations can be applied to them
as a group:
default_focus.set(7, 5, -10, 7, 5, 10, 10); Cuboid c0(origin, 5, 5, 5); c0.shift(0, 0, 3); c0.draw(); Circle z0(c0.get_rectangle_center(0), 2.5, 90, 0, 0, 64); z0.draw(); Circle z1(z0); z1.shift(0, 0, -1); z1.draw(); int i; int j = z0.get_size(); for (i = 0; i < 8; ++i) z0.get_point(i * j/8).draw(z1.get_point(i * j/8)); Cuboid c1(c0.get_rectangle_center(4), 5, 3, 3); c1.shift(0, 2.5); c1.draw(); Rectangle r0 = *c1.get_rectangle_ptr(3); Point p[10]; for (i = 0; i < 4; ++i) p[i] = r0.get_point(i); p[4] = r0.get_mid_point(0); p[5] = r0.get_mid_point(2); p[6] = p[4].mediate(p[5], 2/3.0); Circle z2(p[6], 2, 90, 90, 0, 16); z2.draw(); Circle z3 = z2; z3.shift(3); z3.draw(); j = z2.get_size(); for (i = 0; i < 8; ++i) z2.get_point(i * j/8).draw(z3.get_point(i * j/8)); p[7] = c0.get_rectangle_center(2); p[7].shift(-4); p[8] = c0.get_rectangle_center(3); p[8].shift(4); current_picture.output(); current_picture.rotate(45, 45); current_picture.shift(10, 0, 3); current_picture.output();
Fig. 52.
Let's say the complex object in [the previous figure]
represents a
furnace. From the point of view of 3DLDF, however, it's not an object
at all, and the drawing consists of a collection of unrelated
Cuboids
, Circles
, Rectangles
, and Paths
.
If we hadn't put it into a Picture
, we could still have rotated
and shifted it, but only by applying the operations to each of the
sub-objects individually.
One consequence of the way Pictures
are output in 3DLDF is, that
the following code will not work:
beginfig(1); Point p(1, 2); Point q(1, 3); out_stream << "pickup pencircle scaled .5mm;" << endl; origin.draw(p); out_stream << "pickup pensquare xscaled .3mm rotated 30;" << endl; origin.draw(q); current_picture.output(); endfig();
This is the MetaPost code that results:
beginfig(1); pickup pencircle scaled .5mm; pickup pensquare xscaled .3mm rotated 30; draw (0.000000cm, -3.000000cm) -- (1.000000cm, -1.000000cm); draw (0.000000cm, -3.000000cm) -- (1.000000cm, 0.000000cm); endfig;
It's perfectly legitimate to write
raw MetaPost code to out_stream
, as in lines 4 and 6 of this
example. However, the draw()
commands do not cause any output to
out_stream
. The MetaPost drawing commands are written to
out_stream
when current_picture.output()
is called.
Therefore, the pickup
commands are "bunched up" before the
drawing commands.
In this example,
setting currentpen
to pencircle scaled .5mm
has no effect,
because it is immediately reset to
pensquare xscaled .3mm rotated 30
in the MetaPost code, before
the draw
commands.
It is not possible to change currentpen
in this way within a
Picture
.
Since the draw()
commands in the 3DLDF
code didn't specify a pen argument,
currentpen
with its final value is used for both of the MetaPost
draw
commands. For any given invocation of
Picture::output()
, there can only be one value of
currentpen
. All other pens must be passed as arguments to the
drawing commands.
In order for a 3D graphic program to be useful, it must be able to make two-dimensional projections of its three-dimensional constructions so that they can be displayed on computer screens and printed out. These are some of the possible projections:
The function Picture::output()
takes a const unsigned
short
argument specifying the projection to be used. The user should
probably avoid using explicit unsigned shorts
, but should use the
constants defined for this purpose in the
namespace Projections
.19
The constants are PERSP
, PARALLEL_X_Y
,
PARALLEL_X_Z
,
PARALLEL_Z_Y
, AXON
, and ISO
. The latter two should
not be used, because the axonometric and isometric projections have not
yet been implemented.
When a Picture
is projected onto the x-y plane, the
x and y-values from the world_coordinates
of the Points
belonging to the objects on the
Picture
are copied to
their projective_coordinates
, which are
used in the MetaPost code written to out_stream
.
If a Picture
p contains an object in the x-y plane,
or in a plane parallel to the x-y plane, then
the result of p
.output(Projections::PARALLEL_X_Y)
is more-or-less
equivalent to just using MetaPost without 3DLDF.
Rectangle r(origin, 3, 3, 90); Circle c(origin, 3, 90); c *= r.shift(0, 0, 5); r.draw(); c.draw(); current_picture.output(Projections::PARALLEL_X_Y);
Fig. 53.
If the objects do not lie in the x-y plane, or a plane parallel to the x-y plane, then the projection will be distorted:
current_picture.output(Projections::PARALLEL_X_Y);
Fig. 54.
Picture::output()
can be called with an additional real
argument factor for magnifying or shrinking the Picture
.
Rectangle r(origin, 4, 4, 90, 60); Circle c(origin, 4, 90, 60); c *= r.shift(0, 0, 5); r.filldraw(black, gray); c.unfilldraw(black); current_picture.output(Projections::PARALLEL_X_Y, .5); current_picture.shift(2.5); current_picture.output(Projections::PARALLEL_X_Y); current_picture.shift(1); current_picture.output(Projections::PARALLEL_X_Y, 2);
Fig. 55.
Parallel projection onto the x-z and z-y planes are completely analogous to parallel projection onto the x-y plane.
The perspective projection obeys the laws of linear perspective. In 3DLDF, it is performed by means of a transformation, whose effect is, to the best of my knowledge, exactly equivalent to the result of a perspective projection done by hand using vanishing points and rulers.
It is very helpful to the artist to understand the laws of linear perspective, and to know how to make a perspective drawing by hand.20 However, it is a very tedious and error-prone procedure (I know, I've done it). One of my main motivations for writing 3DLDF was so I wouldn't have to do it anymore.
[next figure] shows a perspective construction, the way it could be done by hand. The point of view, or focus is located 6cm from the picture plane, and 4cm above the ground (or x-z) plane at the point (0, 4, -6). The rectangle R lies in the ground plane, with the point r_0 at (2, 0, 1.5). The right side of R, with length = 2cm lies at an angle of 40 to the ground line, which corresponds to the intersection line of the ground plane with the picture plane, and the left side, with length = 5cm, at an angle of 90 degrees - 40 degrees = 50 degrees to the ground line.
Fig. 56.
While it's possible to use 3DLDF to make a perspective construction in the traditional way, as [the previous figure] shows, the code for [next figure]
achieves the same result more efficiently:
default_focus.set(0, 4, -6, 0, 4, 6, 6); Rectangle r(origin, 2, 5, 0, 40); Point p(2, 0, 1.5); r.shift(p - r.get_point(0)); r.draw();
Fig. 57.
In [the second-to-last figure]
, it was
convenient to start with the corner point r_0;
if we needed the center of R, it would have to be found from the
corner points.
However, in 3DLDF, Rectangles
are most often constructed about
the center. Therefore, in [next figure]
, R is first
constructed about the origin, with the
rotation about the y-axis passed as an argument to the constructor.
It is then shifted such that *(
R.points[0])
, the first
(or zeroth, if you will) Point
on R comes to lie at
(2, 0, 1.5).
Unlike the other transformations currently used in 3DLDF, the perspective transformation is non-affine. Affine transformations maintain parallelity of lines, while the rules of perspective state that parallel lines, with one exception, appear to recede toward a vanishing point.21
In [the second-to-last figure] , the lines from r_0 to r_1 and from r_3 to r_2 appear to vanish toward the right-hand 40 degrees vanishing point, while the lines from r_0 to r_3 and from r_1 to r_2 appear to vanish toward the left-hand 50 degrees vanishing point. The lower the angle of a vanishing point, the further away it is from the center of vision, as [next figure] shows:
Fig. 58.
In [the previous figure] , the 0.5 degrees vanishing point is nearly 5 and 3/4 meters away from the CV, and a line receding to it will be very nearly horizontal. However, the distance from the focus to the CV is only 5cm. As this distance increases, the distance from the CV to a given vanishing point increases proportionately. If the distance is 30cm, a more reasonable value for a drawing, then the x-coordinate of VP 10 degrees is 170.138cm, that of VP 5 degrees is 342.902cm, and that of VP 0.5 degrees is 3437.66cm! This is the reason why perspective drawings done by hand rarely contain lines receding to the horizon at low angles.
This problem doesn't arise when the perspective transformation is used. In this case, any angle can be calculated as easily as any other:
default_focus.set(0, 4, -6, 0, 4, 6, 6); Rectangle r; Point center(0, 2); r.set(center, 2, 5, 0, 0, 0.5); r.draw(); r.set(center, 2, 5, 0, 0, 2.5); r.draw(); r.set(center, 2, 5, 0, 0, 5); r.draw(); current_picture.output();
Fig. 59.
The perspective transformation requires a focus; as a consequence,
outputting a Picture
requires an object of class
Focus
.
Picture::output()
takes an optional pointer-to-Focus
argument, which is 0 by default. If the default is used, (or 0 is
passed explicitly), the global variable default_focus
is used.
See Focus Reference; Global Variables.
A Focus
can be thought of as the observer of a scene, or a
camera. It contains a Point position
for its location with
respect to 3DLDF's coordinate system, and a Point direction
,
specifying the direction where the observer is looking, or where the
camera is pointed. The Focus
can be rotated freely about the
line
PD,
where P stands for position
and
D
for direction
,
so a Focus
contains a third Point up
, to indicate which
direction will be "up" on the projection, when a Picture
is
projected.
The projection plane q will always be perpendicular to the line PD, or to put it another way, the line PD, is normal to q.
Unlike the traditional perspective construction, where the distance from
the focus to the center of vision fixes both the location of the focus
in space, and its distance to the
picture plane,22
these two parameters can be set independently when the perspective
transformation is used.
The distance from a Focus
to the picture plane is stored in the
data member distance
, of type real
.
A Focus
can be declared using two Point
arguments for
position
and direction
, and a real
argument for
distance
, in that order.
Point pos(0, 5, -10); Point dir(0, 5, 10); Focus f(pos, dir, 10); Point center(2, 0, 3); Rectangle r(center, 3, 3); r.draw(); current_picture.output(f);
Fig. 60.
The "up" direction is calculated by the Focus
constructor
automatically. An optional argument can be used to specify the angle by
which to rotate the Focus
about
the line PD.
Point pos(0, 5, -10); Point dir(0, 5, 10); Focus f(pos, dir, 10, 30); Point center(2, 0, 3); Rectangle r(center, 3, 3); r.draw(); current_picture.output(f);
Fig. 61.
Alternatively, a Focus
can be declared using three real
arguments each for the x, y, and z-coordinates of position
and
direction
, respectively, followed by the real
arguments
for distance
and the angle of rotation:
Focus f(3, 5, -5, 0, 3, 0, 10, 10); Point center(2, 0, 3); Rectangle r(center, 3, 3); r.draw(); current_picture.output(f);
Fig. 62.
Focuses
contain two Transforms
, transform
and persp
.
A Focus
can be located anywhere in 3DLDF's coordinate system.
However, performing the perspective projection is more convenient, if
position
and direction
both lie on one of the major axes,
and the plane of projection corresponds to one of the major planes.
transform
is the transformation which would have this affect on
the Focus
, and is calculated by the Focus
constructor.
When a Picture
is output using that Focus
,
transform
is applied to all of the Shapes
on the
Picture
, maintaining the relationship between the Focus
and the Shapes
, while making it easier to calculate the
projection. The Focus
need never be
transformed by transform
.
The actual perspective transformation is stored
in persp
.
Focuses
can be moved by using one of the setting functions, which
take the same arguments as the constructors.
Currently, there are no affine transformation functions for moving
Focuses
, but I plan to add them soon. If 3DLDF is used for
making
animation, resetting the Focus
can be used to simulate camera
movements:
beginfig(1); Point pos(2, 10, 3); Point dir(2, -10, 3); Focus f; Point center(2, 0, 3); for (int i = 0; i < 5; ++i) { f.set(pos, dir, 10, (15 * i)); Rectangle r(center, 3, 3); r.draw(); current_picture.output(f); current_picture.clear(); pos.shift(1, 1, 0); dir.rotate(0, 0, 10); } endfig(1);
Fig. 63.
In [the previous figure]
, current_picture
is output 5 times within a single
MetaPost figure. Since the file passed to MetaPost is called
persp.mp
, the file of Encapsulated PostScript (EPS) code
containing [the previous figure]
is called persp.1
.
To use this technique for making an animation, it's necessary to output
the Picture
into multiple MetaPost figures.
Point pos(2, 10, 3); Point dir(2, -10, 3); Focus f; Point center(2, 0, 3); for (int i = 0; i < 5; ++i) { f.set(pos, dir, 10, (15 * i)); Rectangle r(center, 3, 3); r.draw(); beginfig(i+1); current_picture.output(f); endfig(); current_picture.clear(); pos.shift(1, 1, 0); dir.rotate(0, 0, 10); }
Now, running MetaPost on persp.mp
generates the EPS files
persp.1
, persp.2
, persp.3
, persp.4
, and
persp.5
, containing the five separate drawings of r.
In [next figure]
, Circle
c lies in front of Rectangle
r.
Since c is drawn and not filled, r is visible behind
c.
default_focus.set(1, 3, -5, 0, 3, 5, 10); Point p(0, -2, 5); Rectangle r(p, 3, 4, 90); r.draw(); Point q(2, -2, 3); Circle c(q, 3, 90); c.draw(); current_picture.output();
Fig. 64.
If instead, c is filled or filldrawn, only the parts of r that are not covered by c should be visible:
r.draw(); c.filldraw();
Fig. 65.
What parts of r
are covered depend on the point of view, i.e.,
the position and direction of the Focus
used for outputting the
Picture
:
default_focus.set(8, 0, -5, 5, 3, 5, 10);
Fig. 66.
Determining what objects cover other objects in a program for 3D graphics is called surface hiding, and is performed by a hidden surface algorithm. 3DLDF currently has a very primitive hidden surface algorithm that only works for the most simple cases.
The hidden surface algorithm used in 3DLDF is a
painter's algorithm, which means that the objects that are
furthest away from the Focus
are drawn first, followed by the
objects that are closer, which may thereby cover them. In order to make
this possible, the Shapes
on a Picture
must be sorted
before they are output. They are sorted according to the z-values in
the projective_coordinates
of the Points
belonging to the
Shape
. This may seem strange, since the
projection is two-dimensional and only the x and y-values from
projective_coordinates
are written to out_stream
.
However, the perspective transformation also produces a z-coordinate,
which indicates the distance of the Points
from the Focus
in the z-dimension.
The problem is, that all Shapes
, except Points
themselves,
consist of multiple Points
, that may have different
z-coordinates. 3DLDF currently does not yet have a satisfactory way of
dealing with this situtation. In order to try to cope with it, the user
can specify four different ways of sorting the Shapes
: They
can be sorted according to the maximum z-coordinate, the
minimum z-coordinate, the mean of the maximum and minimum z-coordinate
(max + min) / 2,
and not sorted.
In the last case, the Shapes
are output in the order of the
drawing and filling commands in the user code.
The z-coordinates referred to are those in
projective_coordinates
, and will have been calculated for a
particular Focus
.
The function Picture::output()
takes a
const unsigned short
sort_value argument that specifies
which style of sorting
should be used. The namespace Sorting
contains the following
constants which should be used for sort_value: MAX_Z
,
MIN_Z
, MEAN_Z
, and NO_SORT
. The default is
MAX_Z
.
3DLDF's primitive hidden surface algorithm cannot work for objects that intersect. The following examples demonstrate why not:
using namespace Sorting; using namespace Colors; using namespace Projections; default_focus.set(5, 3, -10, 3, 1, 1, 10, 180); Rectangle r0(origin, 3, 4, 45); Rectangle r1(origin, 2, 6, -45); r0.draw(); r1.draw(); current_picture.output(default_focus, PERSP, 1, MAX_Z); r0.show("r0:"); -| r0: fill_draw_value == 0 (-1.5, -1.41421, -1.41421) -- (1.5, -1.41421, -1.41421) -- (1.5, 1.41421, 1.41421) -- (-1.5, 1.41421, 1.41421) -- cycle; r0.show("r0:", 'p'); -| r0: fill_draw_value == 0 Perspective coordinates. (-5.05646, -4.59333, -0.040577) -- (-2.10249, -4.86501, -0.102123) -- (-1.18226, -1.33752, 0.156559) -- (-3.51276, -1.2796, 0.193084) -- cycle; r1.show("r1:"); -| r1: fill_draw_value == 0 (-1, 2.12132, -2.12132) -- (1, 2.12132, -2.12132) -- (1, -2.12132, 2.12132) -- (-1, -2.12132, 2.12132) -- cycle; r1.show("r1:", 'p'); -| r1: fill_draw_value == 0 Perspective coordinates. (-5.09222, -0.995681, -0.133156) -- (-2.98342, -1.03775, -0.181037) -- (-1.39791, -4.05125, 0.208945) -- (-2.87319, -3.93975, 0.230717) -- cycle;
Fig. 67.
In [the previous figure]
, the Rectangles
r_0 and r_1 intersect along the
x-axis. The z-values of the world_coordinates
of r_0 are
-1.41421 and 1.41421 (two Points
each), while those of r_1
are 2.12132 and -2.12132. So r_1 has two Points
with
z-coordinates greater than the z-coordinate of any Point
on r_0, and two Points
with z-coordinates less than the
z-coordinate of any Point
on r_0. The
Points
on r_0 and r_1 all have different z-values in
their projective_coordinates
, but r_1 still has a Point
with a z-coordinate greater than that of any of the Points
on
r_0, and one with a z-coordinate less than that of any of the
Points
on r_0.
In [next figure]
, the Shapes
on current_picture
are sorted
according to the maximum z-values of the projective_coordinates
of the Points
belonging to the Shapes
. r_1 is
filled and drawn first,
because it has the Point
with the positive z-coordinate of
greatest magnitude.
When subsequently r_0 is drawn, it covers part of the top of
r_1, which lies in front of r_0, and should be visible:
current_picture.output(default_focus, PERSP, 1, MAX_Z);
Fig. 68.
In [next figure]
, the Shapes
on current_picture
are sorted
according to the minimum z-values of the projective_coordinates
of the Points
belonging to the Shapes
. r1
is drawn
and filled last, because
it has the Point
with the negative z-coordinate of greatest
magnitude.
It thereby covers the bottom part of
r0
, which lies in front of r1
, and should be visible.
current_picture.output(default_focus, PERSP, 1, MIN_Z);
Fig. 69.
Neither sorting by the mean z-value in the
projective_coordinates
, nor suppressing sorting does any good.
In each case, one Rectangle
is always drawn and filled last,
covering parts of the other that lie in front of the first.
3DLDF's hidden surface algorithm will fail wherever objects intersect, not just where one extends past the other in both the positive and negative z-directions.
Rectangle r(origin, 3, 4, 45); Circle c(origin, 2, -45); r.filldraw(); c.filldraw(black, gray); current_picture.output(default_focus, PERSP, 1, NO_SORT);
Fig. 70.
Even where objects don't intersect, their projections may. In order to
handle these cases properly, it is necessary to break up the
Shapes
on a Picture
into smaller Shapes
, until
there are none that intersect or whose projections intersect. Then, any
of the three methods of sorting described above can be used to sort the
Shapes
, and they can be output.
Before this can be done, 3DLDF must be able to find the intersections of
all of the different kinds of Shapes
. If 3DLDF converted solids
to polyhedra and curves to sequences of line segments, this would reduce
to the problem of finding the intersections of lines and planes, however
it does not yet do this.
Even if it did, a fully functional hidden surface algorithm must compare
each Shape
on a Picture
with every other Shape
.
Therefore, for n Shapes
, there will be
n! / ((n - r)! r!)
(possibly time-consuming) comparisons.
Fig. 71.
Clearly, such a hidden surface algorithm would considerably increase run-time.
Currently, all of the Shapes
on a Picture
are output, as
long as they lie completely within the boundaries passed as arguments to
Picture::output()
.
See Pictures; Outputting. It
would be more efficient to suppress output for them, if they are
completely covered by other objects. This also requires comparisions,
and could be implemented together with a fully-functional hidden surface
algorithm.
Shadows, reflections, highlights and shading are all effects requiring
comparing each Shape
with every other Shape
, and could
greatly increase run-time.
There are no functions for finding the intersection points of two (or
more) arbitrary Paths
. This is impossible, so long as 3DLDF
outputs MetaPost code.
3DLDF only "knows" about the Points
on a
Path
; it doesn't actually generate the curve or other figure
that passes through the Points
, and consequently doesn't "know"
how it does this.
In addition, an arbitrary Path
can contain connectors.
In 3DLDF, the connectors are
merely strings
and are written verbatim to the output file,
however, in MetaPost they influence the form of a Path
.
3DLDF can, however, find the intersection points of some
non-arbitrary Paths
. So far, it can find the intersection
point of the following combinations of Paths
:
Paths
, i.e., Paths
for which Path::is_linear()
returns true
(see Path Reference; Querying).
In addition, the static Point
member function
Point::intersection_points()
can be called with four Point
arguments. The first and second arguments are treated as the end points
of one line, and the third and fourth arguments as the end points of the
other.
Polygon
. Currently, Reg_Polygon
and
Rectangle
are the only classes derived from Polygon
.
Polygons
.
Reg_Cl_Plane_Curve
,
see Regular Closed Plane Curve Reference; Intersections). Currently,
Ellipse
and Circle
are the only classes derived from
Reg_Cl_Plane_Curve
.
Ellipses
. Since a Circle
is also an Ellipse
,
one or both of the Ellipses
may be a Circle
.
See Ellipse Reference; Intersections.
Adding more functions for finding the intersections of various geometric figures is one of my main priorities with respect to extending 3DLDF.
There are currently no special
functions for finding the intersection points
of a line and a Circle
or two Circles
. Since the
class Circle
is derived from class Ellipse
,
Circle::intersection_points()
resolves to
Ellipse::intersection_points()
, which, in turn, calls
Reg_Cl_Plane_Curve::intersection_points()
.
This does the trick, but it's much easier to find the intersections for
Circles
that it is for Ellipses
. In particular, the
intersections of two coplanar Circles
can be found
algebraically, whereas I've had to implement a numerical solution for
the case of two coplanar Ellipses
with different centers and/or
axis orientation. It may also be worthwhile to write
a specialization for
finding the intersection points of a Circle
and an
Ellipse
.
The theory of intersections is a fascinating and non-trivial branch of
mathematics.23
As I learn more about it, I plan to define more
classes
to represent various curves (two-dimensional ones to
start with) and functions for finding their intersection points.
3DLDF is available for downloading from
http://ftp.gnu.org/gnu/3dldf.
The official 3DLDF website is
http://www.gnu.org/software/3dldf.
The "tarball", i.e., the compressed archive file
3DLDF-1.1.5.1.tar.gz
unpacks into a directory called
/3DLDF-1.1.5.1/
.
On a typical Unix-like system, entering the following commands at the command line in a shell will unpack the 3DLDF distribution. Please note that the form of the commands may differ on your system.
gunzip 3DLDF-1.1.5.1.tar.gz tar xpvf 3DLDF-1.1.5.1.tar
The p
option to tar
ensures that the files will have
the same permissions as when they were packed.
The directory 3DLDF-1.1.5.1/
contains a
configure
script, which should
be called from the command line in the shell, using the absolute path of
3DLDF-1.1.5.1/
as the prefix argument. For example, if
the path is /usr/local/mydir/3DLDF-1.1.5.1/
,
configure
should be invoked as follows:
cd 3DLDF-1.1.5.1 configure --prefix=/usr/local/mydir/3DLDF-1.1.5.1/
configure
generates a Makefile
from the Makefile.in
in 3DLDF-1.1.5.1/
, and
in each of the subdirectories 3DLDF-1.1.5.1/CWEB
,
3DLDF-1.1.5.1/DOC
,
and 3DLDF-1.1.5.1/DOC/TEXINFO
.
Now, make install
causes the 3DLDF to be built.
The executable is called 3dldf
.
See the files README
and INSTALL
in the 3DLDF distribution
for more information.
3DLDF 1.1.5 is the first release that contains template functions,
namely
template <class C> C* create_new()
, which is defined in
creatnew.web
, and
template <class Real> Real get_second_largest()
, which is defined
in gsltmplt.web
.
See Dynamic Allocation of Shapes, and
Get Second Largest Real.
In order for template functions to be instantiated correctly, their
definitions must be available in each compilation unit where
specializations are declared or used. For non-template functions, it
suffices for their declarations to be available, and their
definitions are found at link-time. For this reason, the
definitions of create_new()
and get_second_largest()
are
in their own CWEB files, and are written to their own header files. The
latter are included in the other CWEB files that need them.
In addition, AM_CXXFLAGS = -frepo
has been added to the file
Makefile.am
in 3DLDF-1.1.5/CWEB/
, so that the C++
compiler is called using the -frepo
option.
The manual Using and Porting the GNU Compiler
Collection explains this as follows:
"Compile your template-using code with-frepo
. The compiler will generate files with the extension.rpo
listing all of the template instantiations used in the corresponding object files which could be instantiated there; the link wrapper,collect2
, will then update the.rpo
files to tell the compiler where to place those instantiations and rebuild any affected object files. The link-time overhead is negligible after the first pass, as the compiler will continue to place the instantiations in the same files."24
The first time the executable 3dldf
is built, the files that use
the template functions are recompiled one or more times, and the linker
is also called several times. This doesn't happen anymore, once the
.rpo
files exist.
Template instantiation differs from compiler to compiler, so using template functions will tend to make 3DLDF less portable. I am no longer able to compile it on the DECalpha Personal Workstation I had been using with the DEC C++ compiler. See Ports, for more information.
To use 3DLDF, call
make run
from the command line in the
shell. The working directory should be
3DLDF-1.1.5.1/
or 3DLDF-1.1.5.1/CWEB
.
Either will work, but the latter may be more convenient, because
this is the location of the CWEB, TeX and MetaPost files that you'll
be editing.
Alternatively, call ldfr
, which is merely a
shell script that calls make run
.
This takes care of running 3dldf
, MetaPost, TeX,
and dvips
, producing a PostScript file containing your
drawings. You can display the latter on your terminal using Ghostview
or some other
PostScript viewer, print it out, and whatever else you like to do with
PostScript files.
However, you can also perform the actions performed by
make run
by hand, by writing your own shell
scripts, by defining Emacs-Lisp commands, or in other ways. Even if you
choose to use make run
, it's important to understand what it
does. The following explains how to do this by hand.
The CWEB source files for 3DLDF are in the subdirectory
3DLDF-1.1.5.1/CWEB/
. They
must be ctangled
, and the resulting C++
files must be
compiled and
linked, in order to create the executable file 3dldf
.
The C++
files and header files generated by ctangle
,
the object files generated by the compiler, and the executable
3dldf
all reside in 3DLDF-1.1.5.1/CWEB/
. Therefore, the
latter must be your working directory.
Since 3DLDF has no input routine as yet,
as explained in No Input Routine,
it is necessary to add C++
code to the function main()
in
main.web
, and/or in a separate function in another file. In the
latter case, the function containing the user code must be invoked in
main()
. Look for the line "Your code here!" in
main.web
.
This is an example of what you could write in main()
.
Feel free to make it more complicated, if you wish.
beginfig(1); default_focus.set(2, 3, -10, 2, 3, 10, 20); Rectangle R(origin, 5, 3); Circle C(origin, 3, 90); C.half(180).filldraw(black, light_gray); R.filldraw(); C.half().filldraw(black, light_gray); Point p = C.get_point(4); p.shift(0, -.5 * p.get_y()); p.label("$C$", ""); Point q = R.get_mid_point(0); q.shift(0, 0, -.5 * q.get_z()); q.label("$R$", ""); current_picture.output(default_focus, PERSP, 1, NO_SORT); endfig(1);
Fig. 72.
main.web
, and any other CWEB files you've changed.
Since these files have changed, they must be ctangled
, and the
resulting C++
files must be recompiled. If you've changed any files
other than
main.web
, ctangle
will also generate a header
file for each of these files. If a header file differs from the version
that existed before ctangle
was run, all of the C++
files
that depend on it must be recompiled. Then 3dldf
must be
relinked. To do this, call make 3dldf
from the command line.
If you've made any errors in typing your code, the
compiler should have issued error messages, so go back into
the appropriate CWEB file and correct your errors. Then call
make 3dldf
again.
CWEB/3dldf
at the command line. It writes a
file of MetaPost code called 3DLDFput.mp
.
3DLDFmp.mp
, which inputs
3DLDFput.mp
.
mpost 3DLDFput
The result is an Encapsulated PostScript file
3DLDFput.
<integer> for each figure in your drawing.
3DLDFtex.tex
should contain code for including the
3DLDFput.
<integer> files. This is an example taken from
the 3DLDFtex.tex
included in the distribution.
You may change it to suit your purposes.
\vbox to \vsize{\vskip 2cm \line{\hskip 2cm Figure 1.\hss}% \vfil \line{\hskip 2cm\epsffile{3DLDFmp.1}\hss}% \vss}
3DLDFtex.tex
to produce the DVI file,
3DLDFtex.dvi
.
tex 3DLDFtex
dvips
on the DVI file to produce the PostScript file,
3DLDFtex.ps
.
dvips -o 3DLDFtex.ps 3DLDFtex
3DLDFtex.ps
can be viewed using Ghostview, it can be printed using
lpr
(on a Unix-like system), you can convert it to PDF with
ps2pdf
, or to some other format using the appropriate program.
I sincerely hope that it worked. If it didn't, ask your local computer wizard for help.
On the computer I'm using, I found that special
arguments for
setting landscape
and papersize
in TeX files for
DIN A3 landscape didn't work. Ghostview cut off the right sides of the
drawings. Nor did it work to call
dvips -t landscape -t a3
.
This caused an error message which said that
landscape
would be ignored. When I called dvips
with the -t landscape
option alone, it worked, and
Ghostview showed the entire drawing.
Another problem was Adobe Acrobat. It would display the entire DIN A3 page, but not always in landscape format. I was unable to find a way of rotating the pages in Acrobat. I finally found out, that if I included even a single letter of text in a label, Acrobat would display the document correctly.
It is possible to have MetaPost generate structured PostScript directly
by including the command prologues:=1;
at the beginning of the
MetaPost input.
However, this "generally doesn't work when you use TeX
fonts."25
This is a significant problem if your labels contain math mode
material, and you haven't already taken steps to ensure that appropriate
fonts will be used in the PS output.
In the following, I describe the only way I've found to convert an EPS image to PNG format while still using TeX fonts. There may be other and better ways of doing this, but I haven't found them.
3DLDFmp.1
Include the EPS image in a TeX file
which looks like this:
\advance\voffset by -1in \advance\hoffset by -1in \nopagenumbers \input epsf \epsfverbosetrue \def\epsfsize#1#2{#1} \setbox0=\vbox{\epsffile{3DLDFmp.1}} \vsize=\ht0 \hsize=\wd0 \special{papersize=\the\wd0,\the\ht0} \box0 \bye
Do not name this file 3DLDFmp.1.tex
!
While this worked fine for me on a DECalpha Personal Workstation
running under Tru64 Unix 5.1, with TeX, Version 3.1415
(C version 6.1), and dvipsk 5.58f,
it failed on a PC Pentium II XEON under Linux 2.4,
with TeX, Version 3.14159 (Web2C 7.4.5), and
dvips(k) 5.92b, kpathsea version 3.4.5,
with the following error message:
``No BoundingBox comment found in file examples.1; using defaults''
The resulting PS image had the wrong size and the the graphic was positioned improperly.
Apparently, it confuses the EPSF macros when the name of an
included image is the same as \jobname
.
So, for this example, let's call it 3DLDFmp.1_.tex
.
You don't really need to call the macro \epsfverbosetrue
. If you
do, it will print the measurements of the bounding box and other information
to standard output.26
tex 3DLDFmp.1_.tex
.
dvips -o 3DLDF.1.ps 3DLDFmp.1_.dvi
.
convert 3DLDF.1.ps 3DLDFmp.1.png
.
display
' utility, which can be used to display the
PNG image:
display 3DLDFmp.1.png
It can be included in an HTML document as follows:
<img src="3DLDFmp.1.png" alt="[Fig. 1]."
Please note! The PNG files for this manual are now called
filename 3DLDF1.png
, 3DLDF2.png
, ...,
3DLDF199.png
,
because I wasn't able to write files
with names like 3DLDFmp.<
number>.png
to a CD-R (Compact
Disk, Recordable), when `number' had more than one digit.
The file 3DLDF-1.1.5.1/CWEB/cnepspng.el
contains
definitions of two Emacs-Lisp functions that can be used to
convert Encapsulated PostScript (EPS) files to structured PostScript
(PS) and Portable Network Graphics (PNG) files.
convert-eps filename do-not-delete-files | Emacs-Lisp function |
Converts an EPS image file to the PS and PNG formats.
If called interactively, If do-not-delete-files is |
convert-eps-loop arg start end | Emacs-Lisp function |
Converts a set of EPS image files to the PS and PNG formats.
The files
must all have the same filename, and the extensions must form a range of
positive integers. For example, convert-eps-loop can be
used to convert the files 3DLDFmp.1 , 3DLDFmp.2 , and
3DLDFmp.3 to 3DLDFmp.1.ps , 3DLDFmp.2.ps , and
3DLDFmp.3.ps on the one hand, and
3DLDFmp.1.png , 3DLDFmp.2.png ,
3DLDFmp.3.png on the other.
If For all i \in \INT and start \le i \le end,
do-not-delete-files is also passed to |
3dldf
can be called with the following
command line arguments.
--help
--silent
3dldf
is run
--verbose
3dldf
is run.
--version
Currently, 3dldf
can only handle long options. -
cannot be substituted for --
. However, the names of the options
themselves can be abbreviated, as long as the abbreviation is
unambigous. For example, 3dldf --h
and 3dldf --verb
are
valid, but 3dldf --ver
is not.
3DLDF defines a number of data types for various reasons, e.g., for the
sake of convenience, for use in conditional compilation, or as return
values of functions. Some of these data types can be defined using
typedef
, while others are defined as structs
.
The typedefs and utility structures described in this chapter are
found in pspglb.web
. Others, that contain objects of types
defined in 3DLDF, are described in subsequent chapters.
real | typedef |
Synonymous either with float or double , depending on the
values of the preprocessor variables LDF_REAL_FLOAT and
LDF_REAL_DOUBLE . The meaning of real is determined by
means of conditional compilation. If real is float , 3DLDF
will require less memory than if real is double , but its
calculations will be less precise. real is "typedeffed" to
float by default.
|
real_pair first second | typedef |
Synonymous with pair<real, real> .
|
real_triple first second third | struct |
All three data elements of real_triple are reals .
It also has two constructors, described below. There are no other
member functions.
|
void real_triple (void) | Constructor |
void real_triple (real a, real b, real c) | Constructor |
The constructor taking no arguments sets first , second ,
and third to 0. The constructor taking three real
arguments sets first to a, second to b, and
third to c.
|
Matrix | typedef |
A Matrix is a 4 X 4
array of real , e.g.,
Matrix M; == real M[4][4] .
It is used in class Transform for storing transformation
matrices. See Transforms, and See Transform Reference, for more
information.
|
real_short first second | typedef |
Synonymous with pair<real, signed short> .
It is the return type of Plane::get_distance() .
|
bool_pair first second | typedef |
Synonymous with pair<bool, bool> .
|
bool_real first second | typedef |
Synonymous with pair<bool, real> .
|
The global constants and variables described in this chapter are
found in pspglb.web
. Others, of types
defined in 3DLDF, are described in subsequent chapters.
bool ldf_real_float | Constants |
bool ldf_real_double |
Set to 0 or 1 to match the values of the preprocessor macros
LDF_REAL_FLOAT and LDF_REAL_DOUBLE . The latter are used
for conditional compilation and determine whether real is
"typedeffed" to float or double , i.e., whether
real is made to be a synonym of float or double
using typedef .
|
real PI | Constant |
The value of PI
is calculated as
4.0 * arctan(1.0).
I believe that a preprocessor macro "PI " was
available when I compiled 3DLDF using the DEC C++
compiler, and that
it wasn't, when I used GNU CC under Linux, but I'm no longer sure.
|
valarray <real> null_coordinates | Variable |
Contains four elements, all 0. Used for resetting the sets of
coordinates belonging to Points , but only when the DEC C++
compiler is used. This doesn't work when GCC is used. |
real INVALID_REAL | Constant |
Actually, INVALID_REAL is the largest possible real value
(i.e., float or double ) on a given machine.
So, from the point of view of the compiler, it's not invalid at all.
However, 3DLDF uses it to indicate failure of some kind. For example,
the return value of a function returning real can be compared
with INVALID_REAL to check whether the function succeeded or
failed.
An alternative approach would be to use the exception handling facilities of C++ . I do use these, but only in a couple of places, so far. |
real_pair INVALID_REAL_PAIR | Constant |
first and second are both INVALID_REAL .
|
real INVALID_REAL_SHORT | Constant |
first is INVALID_REAL and second is 0.
|
real MAX_REAL | Variable |
The largest real value permitted in the the elements of
Transforms and the coordinates of
Points . It is the second largest real value (i.e.,
float or double ) on a given machine (INVALID_REAL
is the largest).
|
real MAX_REAL_SQRT | Variable |
The square root of MAX_REAL .
Metafont implements an operation called Pythagorean addition,
notated as " |
template <class C> C* create_new (const C* arg)
|
Template function |
template <class C> C* create_new (const C& arg)
|
Template function |
These functions dynamically allocate an object derived from
Shape on the free store,
returning a pointer to the type of the Shape and setting
on_free_store to true .
If a non-zero pointer or a reference is passed to It is not possible to instantiate more than one specialization of
Point* p = create_new<Point>(0); p->show("*p:"); -| *p: (0, 0, 0) Color c(.3, .5, .25); Color* d = create_new<Color>(c); d->show("*d:"); -| *d: name == use_name == 0 red_part == 0.3 green_part == 0.5 blue_part == 0.25 Point a0(3, 2.5, 6); Point a1(10, 11, 14); Path q(a0, a1); Path* r = create_new<Path>(&q); r->show("*r:"); -| *r: points.size() == 2 connectors.size() == 1 (3, 2.5, 6) -- (10, 11, 14); Specializations of this template function are currently declared for
|
The functions described in this chapter are all declared in the
namespace System
. They are for finding out information
about the system on which 3DLDF is being run. They are declared and
defined in pspglb.web
, except for the template function
get_second_largest()
, which is declared and defined in
gsltmplt.web
.
There are two reasons for this. The first is that template definitions
must be available
in the compilation units where specializations are instantiated.
I therefore write the template definition of get_second_largest()
to gsltmplt.h
, so it can be included by the CWEB files that need
it, currently main.web
only. If I
wrote it to pspglb.h
, it would be included by all of the CWEB
files except for loader.web
, causing unnecessarily bloated object
code.
The other reason is because of the way way 3DLDF is built using Automake
and make. I originally tried to define get_second_largest()
in pspglb.web
and wrote the definition to gsltmplt.cc
,
which is no problem with CWEB. However, I was unable to express the
dependencies among the CWEB, C++
, and object files in such a way that
3DLDF was built properly.
Therefore all template functions will be put into files either by themselves, or in small groups.
signed short get_endianness ([const bool verbose = false ])
|
Function |
Returns the following values:
It is called by If verbose is This function has been adapted from Harbison, Samuel P., and Guy L. Steele Jr. C, A Reference Manual, pp. 163-164. This book has the clearest explanation of endianness that I've found so far. This is the C++ code: signed short System::get_endianness(const bool verbose) { union { long Long; char Char[sizeof(long)]; } u; u.Long = 1; if (u.Char[0] == 1) { if (verbose) cout << "Processor is little-endian." << endl << endl << flush; return 0; } else if (u.Char[sizeof(long) - 1] == 1) { if (verbose) cout << "Processor is big-endian." << endl << endl << flush; return 1; } else { cerr << "ERROR! In System::get_endianness():\n" << "Can't determine endianness. Returning -1" << endl << endl << flush; return -1; } } |
bool is_big_endian ([const bool verbose = false ])
|
Function |
Returns true if the processor is big-endian, otherwise false .
If verbose is true , messages are printed to standard
output.
|
bool is_little_endian ([const bool verbose = false ])
|
Function |
Returns true if the processor is little-endian, otherwise false .
If verbose is true , messages are printed to standard
output.
|
unsigned short get_register_width (void) | Function |
Returns the register width of the CPU of the system on which 3DLDF is
being run. This will normally be either 32 or 64 bits.
This is the C++ code: return (sizeof(void*) * CHAR_BIT); This assumes that an address will be the same size as the processor's
registers, and that This function is called by |
bool is_32_bit (void) | Function |
Returns true if the CPU of the system on which 3DLDF is being run
has a register width of 32 bits, otherwise false .
|
bool is_64_bit (void) | Function |
Returns true if the CPU of the system on which 3DLDF is being run
has a register width of 64 bits, otherwise false .
|
template <class Real> Real get_second_largest (Real MAX_VAL, [bool verbose = false ])
|
Template function |
float get_second_largest (float, bool) | Template specialization |
double get_second_largest (double, bool) | Template specialization |
get_second_largest returns the second largest floating point
number of the type specified the template paramater Real.
If verbose is true , messages are printed to standard
output.
This function is used for setting the value of
MAX_VAL should be the largest number of type Real on a given
architecture. The GNU C++
compiler GCC 3.3 does not currently supply
the |
Class Color
is defined in colors.web
.
string name | Variable |
The name of the Color .
|
bool use_name | Variable |
If true , name is written to out_stream when the
Color is used for drawing or filling. Otherwise, the
RGB (red-green-blue) values are written to out_stream .
|
bool on_free_store | Variable |
true , if the Color has been created by
create_new<Color>() , which allocates memory for the
Color on the free store. Otherwise false .
Colors should only ever be dynamically allocated by using
create_new<Color>() .
See Color Reference;;Constructors and Setting Functions.
|
real red_part | Variable |
real green_part | Variable |
real blue_part | Variable |
The RGB (red-green-blue) values of the Color .
A real value r is valid for these variables if and
only if
0 <= r <= 1.
|
void Color (void) | Default constructor |
Creates a Color and initializes its red_part ,
green_part , and blue_part to 0. use_name and
on_free_store are set to false .
|
void Color (const Color& c, [const string n = "", [const bool u = true ]])
|
Copy constructor |
Creates a Color and makes it a copy of c. If n is
not the empty string and u is true , use_name is set
to true . Otherwise, its set to false .
|
void Color (const string n, const unsigned short r, const unsigned short g, const unsigned short b, [const bool u = true ])
|
Constructor |
Creates a Color with name n. Its red_part ,
green_part , and blue_part are set to
r/255.0, g/255.0, and b/255.0,
respectively.
use_name is set to u.
|
void set (const string n, const unsigned short r, const unsigned short g, const unsigned short b, [const bool u = false ])
|
Setting function |
Corresponds to the constructor above, except that u is false by default.
|
void Color (const real r, const real g, const real b) | Constructor |
Creates an unnamed Color using the real values r,
g, and b for its red_part , green_part , and
blue_part , respectively.
|
void set (const real r, const real g, const real b) | Setting function |
Corresponds to the constructor above. |
Color* create_new<Color> (const Color* c) | Template specializations |
Color* create_new<Color> (const Color& c) |
Pseudo-constructors for dynamic allocation of Colors .
They create a Color on the free store and allocate memory for it using
new(Color) . They return a pointer to the new Color .
If c is a non-zero pointer or a reference,
the new This function is used in the drawing and filling functions for
|
void operator= (const Color& c) | Assignment operator |
Sets name to the empty string , use_name to
false , and red_part , green_part , and
blue_part to c.red_part , c.green_part , and
c.blue_part , respectively.
|
bool operator== (const Color& c) | const operator |
Equality operator. Returns true , if the red_parts ,
green_parts , and blue_parts of *this and c
are equal, otherwise false . The names and
use_names are not compared.
|
bool operator!= (const Color& c) | const operator |
Inequality operator. Returns false , if the red_parts ,
green_parts , and blue_parts of *this and c
are equal, otherwise true . The names and
use_names are not compared.
|
ostream& operator<< (ostream& o, const Color& c) | Non-member function |
Output operator. Writes the MetaPost code for the Color to
out_stream when a Picture is output. This occurs when
the Color has been used as an argument to
drawing or filling functions.
If |
void set_name (const string s) | Function |
Sets name to s. use_name is not reset.
|
void set_use_name (const bool b) | Function |
Sets use_name to b.
|
void modify (const real r, [const real g = 0, [const real b = 0]]) | Function |
Adds r, g, and b to red_part ,
green_part , and blue_part , respectively. Following the
addition, if red_part , green_part , and/or blue_part
is greater than 1, it is reduced to 1. If it is less than 0, it is
increased to 0.
|
void set_red_part (const real q) | Function |
void set_green_part (const real q) | Function |
void set_blue_part (const real q) | Function |
Let p stand for red_part ,
green_part , or blue_part , depending upon which function is
used.
If
0 <= q <= 1,
p is set to q. If
q < 0, p is set to 0.
If q > 1, p is set to 1.
|
void show ([string text = ""]) | const function |
Prints information about the Color to standard output.
If text is not the empty string , prints text on a
line of its own. Otherwise, it prints "Color:". Then it prints
name , use_name , red_part , green_part , and
blue_part .
|
bool is_on_free_store (void) | const function |
Returns on_free_store . This will only be true, if the
Color was created by create_new<Color>() .
See Color Reference; Constructors and Setting Functions.
|
real get_red_part ([bool decimal = false ])
|
Inline const function |
real get_green_part ([bool decimal = false ])
|
Inline const function |
real get_blue_part ([bool decimal = false ])
|
Inline const function |
These functions return the red_part , green_part , or
blue_part of the Color , respectively. If decimal is
false (the default), the actual real value of the "part"
is returned. Otherwise, the corresponding whole number
n such that
0 <= n <= 255
is returned.
|
bool get_use_name (void) | const function |
Returns use_name .
|
string get_name (void) | Inline const function |
Returns name .
|
void define_color_mp () | const function |
Writes MetaPost code to out_stream , in order to define objects of
type color within MetaPost, and set their redparts ,
greenparts , and blueparts .
|
void initialize_colors (void) | Static function |
Calls define_color_mp() (described above) for the
Colors that are defined in namespace Colors
(see Namespace Colors).
|
const Color red | Constant |
const Color green | Constant |
const Color blue | Constant |
const Color cyan | Constant |
const Color yellow | Constant |
const Color magenta | Constant |
const Color orange_red | Constant |
const Color violet_red | Constant |
const Color pink | Constant |
const Color green_yellow | Constant |
const Color orange | Constant |
const Color violet | Constant |
const Color purple | Constant |
const Color blue_violet | Constant |
const Color yellow_green | Constant |
const Color black | Constant |
const Color white | Constant |
const Color gray | Constant |
const Color light_gray | Constant |
These constant Colors can be used in drawing and filling
commands.
|
const Color default_background | Constant |
The default background color. Equal to white per default.
|
const Color* background_color | Pointer |
Points to default_background by default.
|
const Color* default_color | Pointer |
Points to black by default.
|
const Color* help_color | Pointer |
Points to green by default.
|
The following vectors of pointers to Color
can be used in the
drawing and filling functions for Solid
(see Solid Reference; Drawing and Filling).
const vector <const Color*> default_color_vector | Vector |
Contains one pointer, namely default_color .
|
const vector <const Color*> help_color_vector | Vector |
Contains one pointer, namely help_color .
|
const vector <const Color*> background_color_vector | Vector |
Contains one pointer, namely background_color .
|
ifstream in_stream | Variable |
Intended for inputting files of input code. However, 3DLDF does not
currently have a routine for reading input code.
in_stream is currently attached to the file ldfinput.ldf
by initialize_io() (see I/O Functions).
in_stream is read in character-by-character in main() ,
however this serves no useful purpose as yet.
|
ofstream out_stream | Variable |
Used for writing the file of MetaPost code, which is 3DLDF's output.
Currently attached to the file subpersp.mp by
initialize_io() (see I/O Functions).
|
ofstream tex_stream | Variable |
TeX code can be written to a file through tex_stream , if
desired. 3DLDF makes no use of it itself.
Currently attached to subpersp.tex by
initialize_io() (see I/O Functions).
|
void initialize_io (string in_stream_name, string out_stream_name, string tex_stream_name, char* program_name) | Function |
Opens files with names specified by the first three arguments, and
attaches them to the file streams in_stream , out_stream , and
tex_stream , respectively. Comments are written at the beginning
of the files, containing their names, a datestamp, and the name of the
program used to generate them.
|
void write_footers (void) | Function |
Writes code at the end of the files attached to in_stream ,
out_stream , and tex_stream , before the streams are
closed. Currently, they write comments containing
local variable lists
for use in
Emacs.
|
void beginfig (unsigned short i) | Inline function |
Writes "beginfig( i) " to out_stream .
|
void endfig ([unsigned short i = 0]) | Inline function |
Writes "endfig() " to out_stream . The argument i
is "syntactic sugar"; it's ignored by endfig() ,
but may help the user keep track of what figure is being ended.
|
Class Shape
is defined in shapes.web
.
Shape
is an abstract class, which means that
all of its member functions are pure virtual functions, and
that it's only used as a base class, i.e., no objects of type
Shape
may be declared.
All of the "drawable" types in 3DLDF, Point
,
Path
, Ellipse
, etc., are derived from Shape
.
Deriving all of the drawable types from Shape
makes it possible
to handle objects of different types in the same way. This is
especially important in the Picture
functions, where objects of
various types (but all derived from Shape
) are accessed through
pointers to Shape
. See Picture Reference.
signed short DRAWDOT | Protected static constants |
signed short DRAW | |
signed short FILL | |
signed short FILLDRAW | |
signed short UNDRAWDOT | |
signed short UNDRAW | |
signed short UNFILL | |
signed short UNFILLDRAW |
Values used in the output() functions of the classes derived from
Shape . For example, in Path , if the data member
fill_draw_value = DRAW , then the MetaPost command
draw is written to out_stream when that Path is
output.
|
Transform operator*= (const Transform& t) | Pure virtual function |
Shape* get_copy (void) | const pure virtual function |
Copies an object, allocating memory on the free store for the copy,
and returns a pointer to Shape for accessing the copy.
Used in the drawing and filling functions for copying the |
bool set_on_free_store (bool b = true )
|
Pure virtual function |
Sets the data member on_free_store to b. All classes
derived from Shape must therefore also have a data member
on_free_store .
This function is used in the template function
|
Transform rotate (const real x, const real y, const real z) | Pure virtual functions |
Transform scale (real x, real y, real z) | |
Transform shear (real xy, real xz, real yx, real yz, real zx, real zy) | |
Transform shift (real x, real y, real z) | |
Transform rotate (const Point& p0, const Point& p1, const real r) |
See Point Reference; Affine Transformations. |
void apply_transform (void) | Pure virtual function |
Applies the Transform stored in the transform data member
of the Points belonging to the Shape to their
world_coordinates . The transforms are subsequently reset
to the identity Transform .
|
void clear (void) | Pure virtual function |
The precise definition of this function will depend on the nature of the
derived class. In general, it will call the destructor on dynamically
allocated objects belonging to the Shape , and deallocate the
memory they occupied.
|
bool is_on_free_store (void) | const pure virtual function |
Returns true if the object was allocated on the free store,
otherwise false .
|
void show ([string text = "", [char coords = 'w', [const bool do_persp = true , [const bool do_apply = true , [Focus* f = 0, [const unsigned short proj = 0, [const real factor = 1]]]]]]])
|
const pure virtual function |
Prints information about an object to standard output.
See the descriptions of show() for the classes derived from
Shape for more information.
|
void output (void) | Pure virtual function |
Called by Picture::output() for writing MetaPost code to
out_stream for a Shape pointed to by a pointer on the
vector<Shape*> shapes belonging to the Picture . Such
a Shape will have been created by a drawing or filling
function.
|
vector<Shape*> extract (const Focus& f, const unsigned short proj, real factor) | Pure virtual function |
Called in Picture::output() . It determines whether a
Shape can be output. If it can, and an output() function
for the type of the Shape exists, a vector<Shape*>
containing a pointer to the Shape is returned.
On the other
hand, it is possible to define a type derived from Currently, there are no |
bool set_extremes (void) | Pure virtual function |
Sets the values of projective_extremes for the Shape .
This is needed in Picture::output() for determining the order in
which objects are output.
|
real get_minimum_z (void) | const pure virtual functions |
real get_maximum_z (void) | |
real get_mean_z (void) |
These functions return the minimum, maximum, and mean z-value
respectively of the projected Points belonging to
the Shape , i.e., from projective_extremes . The values for
the Shapes on the Picture are used for determining the
order in which they are output
|
const valarray<real> get_extremes (void) | const pure virtual function |
Returns projective_extremes .
|
void suppress_output (void) | Pure virtual function |
Sets do_output to false . This function is called in
Picture::output() , if a Shape on a Picture cannot
be output using the arguments passed to Picture::output() .
|
void unsuppress_output (void) | Pure virtual function |
Sets do_output to true . Called in
Picture::output() after output() is called on the Shapes .
This way, output of Shapes that couldn't be output when
Picture::output() was called with a particular set of arguments
won't necessarily be suppressed when
Picture::output() is called again with different arguments.
|
f
Class Transform
is defined in transfor.web
.
Point
is a friend
of Transform
.
Matrix matrix | Private variable |
A 4 X 4
matrix of |
Transform user_transform | Variable |
Currently has no function. It is intended to be used for transforming
the coordinates of Points between the world coordinate system
(WCS) and a user coordinate system (UCS), when routines for managing
user coordinate systems are implemented.
|
const Transform INVALID_TRANSFORM
|
Constant |
Every member of matrix in INVALID_TRANSFORM is
equal to INVALID_REAL .
|
const Transform IDENTITY_TRANSFORM
|
Constant |
Homogeneous coordinates and Transforms are unchanged by
multiplication with IDENTITY_TRANSFORM .
matrix is an identity matrix:
1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1See Transforms. |
void Transform (void) | Default constructor |
Creates a Transform containing the identity matrix.
|
void Transform (real r) | Constructor |
Creates a Transform and sets all of the elements of matrix
to r. Currently, this
constructor is never used, but who knows? Maybe someday it will be
useful for something.
|
void Transform (real r0_0, real r0_1, real r2, real r0_2, real r0_3, real r1_0, real r1_1, real r1_2, real r1_3, real r2_0, real r2_1, real r2_2, real r2_3, real r3_0, real r3_1, real r3_2, real r3_3) | Constructor |
Each of the sixteen real arguments is
assigned to the corresponding element of matrix:
matrix[0][0] = r0_0 , matrix[0][1] = r0_1 , etc.
Useful for specifying a transformation matrix completely.
|
Transform operator= (const Transform& t) | Assignment operator |
Sets *this to t and returns t. Returning *this would, of course, have exactly the same effect. |
real operator*= (real r) | Operator |
Multiplication with assignment by a scalar.
This operator multiplies each element
E
of matrix by
the scalar r.
The return value is r . This makes it possible to
chain invocations of this function:
For a_x, b_x, c_x, ..., p_x in R
,
x in N
Transform T0(a_0, b_0, c_0, d_0, e_0, f_0, g_0, h_0, i_0, j_0, k_0 l_0, m_0, n_0, o_0, p_0); Transform T1(a_1, b_1, c_1, d_1, e_1, f_1, g_1, h_1, i_1, j_1, k_1 l_1, m_1, n_1, o_1, p_1); Transform T2(a_2, b_2, c_2, d_2, e_2, f_2, g_2, h_2, i_2, j_2, k_2 l_2, m_2, n_2, o_2, p_2); real r = 5; Let M_0, M_1, and M_2 stand for
M_0 = a_0 b_0 c_0 d_0 e_0 f_0 g_0 h_0 i_0 j_0 k_0 l_0 m_0 m_0 o_0 p_0 M_1 = a_1 b_1 c_1 d_1 e_1 f_1 g_1 h_1 i_1 j_1 k_1 l_1 m_1 m_1 o_1 p_1 M_2 = a_2 b_2 c_2 d_2 e_2 f_2 g_2 h_2 i_2 j_2 k_2 l_2 m_2 m_2 o_2 p_2 T0 *= T1 *= T2 *= r; Now, M_0 = 5a_0 5b_0 5c_0 5d_0 5e_0 5f_0 5g_0 5h_0 5i_0 5j_0 5k_0 5l_0 5m_0 5m_0 5o_0 5p_0 M_1 = 5a_1 5b_1 5c_1 5d_1 5e_1 5f_1 5g_1 5h_1 5i_1 5j_1 5k_1 5l_1 5m_1 5m_1 5o_1 5p_1 M_2 = 5a_2 5b_2 5c_2 5d_2 5e_2 5f_2 5g_2 5h_2 5i_2 5j_2 5k_2 5l_2 5m_2 5m_2 5o_2 5p_2 This function is not currently used anywhere, but it may turn out to be useful for something. |
Transform operator* (const real r) | const operator |
Multiplication of a Transform by a scalar without assignment.
The return value is a Transform
A.
If this.matrix has elements
E_T, then A.matrix has elements E_A such that
E_A = r * E_T
for all E. |
Transform operator*= (const Transform& t) | Operator |
Performs matrix multiplication on matrix and
t.matrix . The result is assigned to matrix .
t is returned, not *this ! This makes it possible to
chain invocations of this function:
Transform a; a.shift(1, 1, 1); Transform b; b.rotate(0, 90); Transform c; c.shear(5, 4); Transform d; d.scale(3, 4, 5); Let a_m, b_m, and c_m stand for
a_m = 1 0 0 0 0 1 0 0 0 0 1 0 1 1 1 1 b_m = 0.5 0.5 0.707 0 0.146 0.854 -0.5 0 -0.854 0.146 0.5 0 0 0 0 1 c_m = 1 12 14 0 10 1 15 0 11 13 1 0 0 0 0 1 d_m = 3 0 0 0 0 4 0 0 0 0 5 0 0 0 0 1 a *= b *= c *= d; a , b , and c are transformed by d , which
remains unchanged.
Now, a_m = 3 0 0 0 0 4 0 0 0 0 5 0 3 4 5 1 b_m = 1.5 2 3.54 0 -0.439 3.41 -2.5 0 -2.56 0.586 2.5 0 0 0 0 1 c_m = 3 48 70 0 30 4 75 0 33 52 5 0 0 0 0 1d_m is unchanged. |
Transform operator* (const Transform t) | const operator |
Multiplication of a Transform by another Transform without
assignment.
The return value is a Transform whose matrix contains
values that are the result of the matrix multiplication of
matrix and t.matrix .
|
Transform inverse (void) | const function |
Transform inverse ([bool assign = false ])
|
Function |
Returns a Transform T with a T.matrix that is the
inverse of matrix . If assign==true , then
matrix is set to its inverse.
In the |
void set_element (const unsigned short row, const unsigned short col, real r) | Function |
Sets the element of matrix indicated by the arguments to r.
Transform t; t.set_element(0, 2, -3.45569); t.show("t:"); -| t: 1 0 -3.46 0 0 1 0 0 0 0 1 0 0 0 0 1 |
bool is_identity (void) | Function |
Returns true if *this is the identity Transform ,
otherwise false . This function has both a const and a
non-const version. In the non-const version,
clean() is called on *this before comparing the elements of
matrix with 1 (for the main diagonal) and 0 (for the other
elements). In the const version, *this is copied,
clean() is called on the copy, and the elements of the copy's
matrix are compared with 0 and 1.
|
real get_element (const unsigned short row, const unsigned short col) | const function |
Returns the value stored in the element of matrix indicated by the arguments.
Transform t; t.shift(1, 2, 3); t.scale(2.5, -1.2, 4); t.rotate(30, 15, 60); t.show("t:"); -| t: 1.21 2.09 0.647 0 0.822 -0.654 0.58 0 -2.18 0.224 3.35 0 -3.69 1.45 11.8 1 cout << t.get_element(2, 1); -| 0.224 |
real epsilon (void) | Static function |
Returns the positive real value of smallest magnitude
\epsilon which an element of a Transform should
contain. An element of a Transform may also contain
-\epsilon.
The value \epsilon is used for in the
function
Please note: I haven't tested whether 0.000000001 is a good
value yet, so users should be aware of this if they set Rotation causes a significant loss of precision to due to the use of the
|
void show ([string text = ""]) | const function |
If the optional argument text is used, and is not the empty
string (""), text is printed on a line of its own to
the standard output first. Otherwise, "Transform:" is printed
on a line of its own to the standard output.
Then, the elements of matrix are printed to standard output.
Transform t; t.show("t:"); -| t: 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 t.scale(1, 2, 3); t.shift(1, 1, 1); t.rotate(90, 90, 90); t.show("t:"); -| t: 0 0 1 0 0 2 0 0 -3 0 0 0 -1 1 1 1 |
The affine transformation functions use their arguments to create a new
Transform
t
(local to the function) representing the
appropriate transformation. Then, *this
is multiplied by t
and t
is returned.
Returning t
instead of *this
makes it possible to put the
affine transformation function at the end of a chain of invocations of
Transform::operator*=()
:
Transform t0, t1, t2, t3; ... t0 *= t1 *= t2 *= t3.scale(2, 3.5, 9);
t0
, t1
, and t2
are all multiplied by the
Transform
with
matrix
=
2 0 0 0
0 3.5 0 0
0 0 9 0
0 0 0 1
representing the scaling operation, not t3
, which may
represent a combination of transformations.
Transform scale (real x, [real y = 1, [real z = 1]]) | Function |
Creates a Transform t representing the scaling operation locally,
multiplies *this by t , and returns t .
A Transform representing scaling only, when applied to a
Point p , will cause its x-coordinate to be multiplied by
x, its y-coordinate to be multiplied by y, and its
z-coordinate to be multiplied by z.
=>
Transform t; t.scale(12.5, 20, 1.3); t.show("t:"); -| t: 12.5 0 0 0 0 20 0 0 0 0 1.3 0 0 0 0 1 |
Transform shear (real xy, [real xz = 0, [real yx = 0, [real yz = 0, [real zx = 0, [real zy = 0]]]]]) | Function |
Creates a Transform t representing the shearing operation locally,
multiplies *this by t , and returns t .
When applied to a Point p(x,y,z); Transform t; t.shear(a, b, c, d, e, f); p *= t; => p = ((x + ay + bz), (y + cx + dz), (z + ex + fy)) Transform t; t.shear(2, 3, 4, 5, 6, 7); t.show("t:"); -| t: 1 4 6 0 2 1 7 0 3 5 1 0 0 0 0 1 |
Transform shift (real x, [real y = 0, [real z = 0]]) | Function |
Transform shift (const Point& p) | Function |
These functions create a The version with the argument When a Point p(x,y,z); Transform t; t.shift(a, b, c); p *= t; => p = (x + a, y + b, z + c) |
Transform shift_times (real x, [real y = 1, [real z = 1]]) | Function |
Multiplies the corresponding elements of matrix by
the real arguments, i.e.,
matrix[3][0] is multiplied by x,
matrix[3][1] is multiplied by y, and
matrix[3][2] is multiplied by z. Returns *this .
Ordinary shifting is additive, so a special function is needed to
multiply the elements of If the Transform t; t.shift(1, 2, 3); =>
t.shift_times(2, 2, 2); =>
Rectangle r[4]; r[0].set(origin, 1, 1, 90); r[3] = r[2] = r[1] = r[0]; Transform t; t.shift(1.5, 1.5); r[0] *= t; r[0].draw(); t.shift_times(1.5, 1.5); r[1] *= t; r[1].draw(); t.shift_times(1.5, 1.5); r[2] *= t; r[2].draw(); t.shift_times(1.5, 1.5); r[3] *= t; r[3].draw();
Cuboid c(origin, 1, 1, 1); c.draw(); Transform t; t.rotate(30, 30, 30); t.shift(1, 0, 1); c *= t; c.draw(); t.shift_times(1.5, 0, 1.5); c *= t; c.draw(); t.shift_times(1.5, 0, 1.5); c *= t; c.draw(); t.shift_times(1.5, 0, 1.5); c *= t; c.draw(); t.shift_times(1.5, 0, 1.5); c *= t; c.draw();
|
Transform rotate (real x, [real y = 0, [real z = 0]]) | Function |
Rotation around the main axes.
Creates a Transform t representing the rotation,
multiplies *this by t , and returns t .
|
Transform rotate (Point p0, Point p1, [const real angle = 180]) | Function |
Rotation around an arbitrary axis. The Point arguments represent
the end points of the axis, and angle is the angle of rotation.
Since 180 degrees
rotation is needed so often, 180 is the default for
angle.
|
Transform rotate (const Path& p, [const real angle = 180]) | Function |
Rotation around an arbitrary axis. Path argument.
The Path p must be linear, i.e., p.is_linear() must
return true . See Path Reference; Querying.
|
Transform align_with_axis (Point p0, Point p1, [char axis = 'z']) | Function |
Returns the Transform that would align the line through p0
and p1 with the major axis denoted by the axis argument.
The default is the z-axis. This function is used in the functions that
find intersections.
Point P0(1, 1, 1); Point P1(2, 3, 4); P0.draw(P1); P0.dotlabel("$P_0$"); P1.dotlabel("$P_1$"); Transform t; t.align_with_axis(P0, P1, 'z'); P0 *= P1 *= t; t.show("t:"); -| t: 0.949 -0.169 0.267 0 0 0.845 0.535 0 -0.316 -0.507 0.802 0 -0.632 -0.169 -1.6 1 P0.show("P0:"); -| P0: (0, 0, 0) P1.show("P1:"); -| P1: (0, 0, 3.74) The following example shows how default_focus.set(2, 3, -10, 2, 3, 10, 10); Circle c(origin, 3, 75, 25, 6); c.shift(2, 3); c.draw(); Point n = c.get_normal(); n.shift(c.get_center()); Transform t; t.align_with_axis(c.get_center(), n, 'y'); t.show("t:"); -| t: 0.686 0.379 -0.621 0 0.543 0.3 0.784 0 0.483 -0.875 0 0 -3 -1.66 -1.11 1 n *= c *= t; c.draw(); c.show("c:"); -| c: fill_draw_value == 0 (1.31, 0, -0.728) .. (1.49, 0, -0.171) .. (1.44, 0, 0.413) .. (1.17, 0, 0.933) .. (0.728, 0, 1.31) .. (0.171, 0, 1.49) .. (-0.413, 0, 1.44) .. (-0.933, 0, 1.17) .. (-1.31, 0, 0.728) .. (-1.49, 0, 0.171) .. (-1.44, 0, -0.413) .. (-1.17, 0, -0.933) .. (-0.728, 0, -1.31) .. (-0.171, 0, -1.49) .. (0.413, 0, -1.44) .. (0.933, 0, -1.17) .. cycle; n.show("n:"); -| n: (0, 1, 0)
|
void reset (void) | Function |
Resets matrix to the identity matrix. |
void clean (void) | Function |
Sets elements in matrix whose absolute values are
< epsilon() to 0.
|
Class Label
is defined in pictures.web
.
Point
and Picture
are friends
of Label
.
Labels can be included in drawings by using the label()
and
dotlabel()
functions, which are currently defined for the classes
Point
and Path
, and the classes derived from them.
See Point Reference; Labelling, and
See Path Reference; Labelling.
They are currently not defined for Solid
, and its derived classes.
I plan to add them for Solid
soon.
Users will normally
never need to declare objects of type Label
, access its data
members or call its member functions directly.
When label()
or dotlabel()
is invoked, one or more Labels
is
allocated dynamically and pointers to the new Labels
are placed
onto the vector<Label*> labels
of a Picture
:
current_picture
, by default. There are no explicitly defined
constructors for Label
, nor is it intended that Labels
ever be created in any way other than through label()
or
dotlabel()
. When a Picture
is copied, the Labels
are
copied, too, and when a Picture
is cleared (using
Picture::clear()
) or destroyed, the Labels
are deallocated
and destroyed.
Point* pt | Private variable |
A pointer to the Point representing the location of the
Label .
|
bool dot | Private variable |
true if the label should be dotted, otherwise
false .
|
string text | Private variable |
The text of the label.
text is always put between "btex " and "etex " in
the MetaPost code, so that TeX will be used to format the labels. In
particular, this means that TeX's math mode can be used. However,
double backslashes must be used instead of single backslashes, in order
that single backslashes be written to out_stream .
Point P(1, 1, 2); origin.drawarrow(P); P.label("$\\vec{P}$");
|
string position | Private variable |
The position of the text with respect to
*pt . Valid values are as in MetaPost:
"top", "bot" (bottom), "lft" (left), "rt"
(right), "ulft" (upper left),
"llft" (lower left), "urt" (upper right),
"lrt" (lower right).
|
bool DO_LABELS | Public static variable |
Enables or disables creation
of Labels . If true , label
and dotlabel() cause Labels to be
created and put onto a Picture . If
false , they are not. Note that it is also
possible to suppress output of existing
Labels when outputting a Picture .
|
Label* get_copy (void) | const Function |
Creates a copy of the Label and returns a pointer to the copy.
Called in Picture::operator=() and Picture::operator+=()
where Pictures are copied.
Users should never need to call this function directly.
See Picture Reference; Operators.
This function dynamically allocates a new
|
void output (const Focus& f, const unsigned short proj, real factor, const Transform& t) | Function |
Writes MetaPost code for the labels to out_stream .
It is called in Picture::output()
(see Picture Reference; Outputting).
Users should never need to call this function directly.
When |
Class Picture
is defined in pictures.web
.
Transform transform | Private variable |
Applied to the Shapes on the Picture when the latter is
output. It is initialized as the identity Transform , and can be
modified by the transformation functions, by
Picture::operator*=(const Transform&)
(see Picture Reference; Operators), and by
Picture::set_transform()
(see Picture Reference; Modifying).
|
vector<Shape*> shapes | Private variable |
Contains pointers to the Shapes on the Picture .
When a drawing or filling function is invoked for a Shape , a copy
is dynamically allocated and a pointer to the copy is placed onto
shapes .
|
vector<Label*> labels | Private variable |
Contains pointers to the Labels on the Picture . When a
Point is labelled, either directly or through a call to
label() or dotlabel() for another type of
Shape 31,
a Label is dynamically allocated, the Point is copied to
*Label::pt , and a pointer to the Label is placed onto
labels .
|
bool do_labels | Private variable |
Used for enabling or disabling output of Labels when outputting a
Picture . The default value is true . It is set to
false by using suppress_labels() and can be reset to
true by using unsuppress_labels() .
See Picture Reference; Output Functions.
Often, when a |
Variable Picture current_picture | Variable |
The Picture used as the default by the drawing and filling
functions.
|
void Picture (void) | Default constructor |
Creates an empty Picture .
|
void Picture (const Picture& p) | Copy constructor |
Creates a copy of Picture p.
Circle c(origin, 3); c.draw(); current_picture.output(Projections::PARALLEL_X_Z); Picture new_picture(current_picture); new_picture.shift(2); new_picture.output(Projections::PARALLEL_X_Z);
|
void operator= (const Picture& p) | Assignment operator |
Makes *this a copy of p, destroying the old contents of *this .
|
void operator+= (const Picture& p) | Operator |
Adds the contents of p to *this . p remains unchanged.
|
void operator+= (Shape* s) | Operator |
Puts s onto shapes . Note that the pointer s
itself is put onto shapes , so any allocation and copying must be
performed first. This is a low-level function that users normally won't
need to use directly.
|
void operator+= (Label* label) | Operator |
Puts label onto labels .
Note that the pointer label
itself is put onto labels , so any allocation and copying must be
performed first. This is a low-level function that users normally won't
need to invoke directly.
|
Transform operator*= (const Transform& t) | Operator |
Multiplies transform by t. This has the effect of
transforming all of the Shapes on shapes and all of
the Points of the Labels on labels by t upon
output.
Transform t; t.rotate(0, 0, 180); t.shift(3); Reg_Polygon pl(origin, 5, 3, 90); pl.draw(); pl.label(); current_picture.output(Projections::PARALLEL_X_Y); current_picture *= t; current_picture.output(Projections::PARALLEL_X_Y);
|
The functions in this section all operate on the transform
data
member of the Picture
and return a Transform
representing the
transformation--not transform
.
Transform scale (real x, [real y = 1, [real z = 1]]) | Function |
Performs transform.scale( x, y, z) and returns
the result. This has the effect of scaling
all of the elements of shapes and labels .
|
Transform shift (real x, [real y = 0, [real z = 0]]) | Function |
Performs transform.shift( x, y, z) and returns
the result. This has the effect of shifting
all of the Shapes and Labels on the Picture .
|
Transform shift (const Point& p) | Function |
Performs transform.shift( p) and returns
the result. This has the effect of shifting
all of the Shapes and Labels on the Picture by the
x, y, and z-coordinates of p.
|
Transform rotate (const real x, [const real y = 0, [const real z = 0]]) | Function |
Performs transform.rotate( x, y, z) and returns
the result. This has the effect of rotating
all of the elements of shapes and labels .
|
Transform rotate (const Point& p0, const Point& p1, [const real angle = 180]); | Function |
Performs transform.rotate( p0, p1, angle) and returns
the result. This has the effect of rotating
all of the elements of shapes and labels about the line
from p_0 to p_1.
|
void clear (void) | Function |
Destroys the Shapes and Labels on the
Picture and removes all the Shape pointers from
shapes and the Label pointers from labels .
All dynamically allocated objects are deallocated, namely the
Shapes , the Labels , and the Points belonging to the
Labels . transform is reset to the identity Transform .
|
void reset_transform (void) | Function |
Resets transform to the identity Transform .
|
Transform set_transform (const Transform& t) | Function |
Sets transform to t and returns t .
|
void kill_labels (void) | Function |
Removes the Labels from the Picture .
|
void show ([string text = "", [bool stop = false ]])
|
Function |
Prints information about the Picture to standard output.
|
void show_transform ([string text = "Transform from Picture:"]) | Function |
Calls transform.show() , passing text as the argument to the
latter function.
|
The namespace Projections
is defined in pictures.web
.
const unsigned short PERSP | Constant |
const unsigned short PARALLEL_X_Y | Constant |
const unsigned short PARALLEL_X_Z | Constant |
const unsigned short PARALLEL_Z_Y | Constant |
const unsigned short AXON | Constant |
const unsigned short ISO | Constant |
These constants can be used for the projection argument in
Picture::output() , described in
Picture Reference; Outputting; Functions,
below.
|
The namespace Sorting
is defined in pictures.web
.
const unsigned short NO_SORT | Constant |
const unsigned short MAX_Z | Constant |
const unsigned short MIN_Z | Constant |
const unsigned short MEAN_Z | Constant |
These constants can be used for the sort_value argument in
Picture::output() , described in
Picture Reference; Outputting; Functions,
below.
|
void output (const Focus& f, [const unsigned short projection = Projections::PERSP , [real factor = 1, [const unsigned short sort_value = Sorting::MAX_Z , [const bool do_warnings = true , [const real min_x_proj = -40, [const real max_x_proj = 40, [const real min_y_proj = -40, [const real max_y_proj = 40, [const real min_z_proj = -40, [const real max_z_proj = 40]]]]]]]]]])
|
Function |
void output ([const unsigned short projection = Projections::PERSP , [real factor = 1, [const unsigned short sort_value = Sorting::MAX_Z , [const bool do_warnings = true , [const real min_x_proj = -40, [const real max_x_proj = 40, [const real min_y_proj = -40, [const real max_y_proj = 40, [const real min_z_proj = -40, [const real max_z_proj = 40]]]]]]]]]])
|
Function |
These functions create a two-dimensional projection of the objects on the
Picture and write MetaPost code to out_stream for
drawing it.
The arguments:
|
void suppress_labels (void) | Function |
Suppresses output of the Labels on a Picture when
output() is called. This can be useful when a Picture is
output, transformed, and output again, one or more times, in a single figure.
Usually, it will not be desirable to have the Labels output more
than once.
In [next figure]
, Ellipse e(origin, 3, 5); e.label(); e.draw(); Point pt0(-3); Point pt1(3); pt0.draw(pt1); Point pt2(0, 0, -4); Point pt3(0, 0, 4); pt2.draw(pt3); pt0.dotlabel("0", "lft"); pt1.dotlabel("1", "rt"); pt2.dotlabel("2", "bot"); pt3.dotlabel("3"); current_picture.output(Projections::PARALLEL_X_Z); current_picture.rotate(0, 60); current_picture.suppress_labels(); current_picture.output(Projections::PARALLEL_X_Z); current_picture.rotate(0, 60); current_picture.output(Projections::PARALLEL_X_Z);
|
void unsuppress_labels (void) | Inline function |
Sets do_labels to true . If a Picture contains
Labels , unsuppress_labels() ensures that they will be
output, when Picture::output() is called, so long as there is no
intervening call to suppress_labels() or kill_labels() .
|
Class Point
is defined in points.web
.
It is derived from Shape
using protected
derivation.
The function
Transform Transform::align_with_axis(Point, Point, char)
is a friend
of Point
.
valarray<real> world_coordinates | Private variable |
The set of four homogeneous coordinates x, y, z, and w that represent
the position of the Point within 3DLDF's global coordinate
system.
|
valarray<real> projective_coordinates | Private variable |
The set of four homogeneous coordinates x, y, z, and w that represent
the position of the projection of the Point onto a
two-dimensional plane for output. The x and y values are used in the
MetaPost code written to out_stream . The z value is used
in the hidden surface algorithm (which is currently rather primitive and
doesn't work very well. see Surface Hiding). The w value can be
!= 1
,
depending on the projection used; the perspective projection is
non-affine, so w can take on other values.
|
valarray<real> user_coordinates | Private variable |
A set of four homogeneous coordinates x, y, z, and w.
|
valarray<real> view_coordinates | Private variable |
A set of four homogeneous coordinates x, y, z, and w.
|
Transform transform | Private variable |
Contains the product of the transformations applied to the Point .
When apply_transform() is called for the Point , directly
or indirectly, the world_coordinates are updated and
transform is reset to the identity Transform .
See Point Reference; Applying Transformations.
|
bool on_free_store | Private variable |
Returns on_free_store . This should only be true if
the Point was dynamically allocated on the
free store. Points should only ever be dynamically
allocated by create_new<Point>() , which
uses set_on_free_store() to set on_free_store
to true .
See Point Reference; Constructors and Setting Functions, and
Point Reference; Modifying.
|
signed short drawdot_value | Private variable |
Used to tell Point::output() what MetaPost drawing command
(drawdot() or undrawdot() ) to write to out_stream
when outputting a Point .
When |
const Color* drawdot_color | Private variable |
Used to tell Point::output() what string to write to out_stream
for the color when outputting a Point .
|
string pen | Private variable |
Used to tell Point::output() what string to write to out_stream
for the pen when outputting a Point .
|
valarray<real> projective_extremes | Protected variable |
A set of 6 real values indicating the maximum and minumum x, y,
and
z-coordinates of the Point .
Used for determining whether a Point is projectable with the
parameters of a particular invocation of Picture::output() .
See Picture Reference; Outputting.
Obviously, the maxima and minima
will always be the same for a |
bool do_output | Protected variable |
true by default. Set to false by suppress_output() ,
which is called on a Shape by Picture::output() , if the
Shape is not projectable.
See Picture Reference; Outputting.
|
string measurement_units | Public static variable |
The unit of measurement for all distances within a Picture ,
"cm" (for centimeters) by default. The x and y-coordinates of
the projected Points are always followed by measurement_units
when they're written to out_stream . Unlike Metafont, units of
measurement cannot be indicated for individual coordinates. Nor can
measurement_unit be changed within a Picture .
When I write an input routine, I plan to make it behave the way Metafont does, however, 3DLDF will probably also convert all of the input values to a standard unit, as Metafont does. |
real CURR_Y | Public static variable |
real CURR_Z | Public static variable |
Default values for the y and z-coordinate of Points , when the
x-coordinate, or the x and y-coordinates only are specified.
Both are 0 by default.
These values only used in the constructor and setting function taking
one required Point A(1); A.show("A:"); -| A: (1, 0, 0); CURR_Y = 5; A.set(2); A.show("A:"); -| A: (2, 5, 0); CURR_Z = 12; Point B(3); B.show("B:"); -| B: (3, 5, 12); Point C; C.show("C:"); -| C: (0, 0, 0); |
point_pair first second | typedef |
Synonymous with pair<Point, Point> .
|
bool_point b pt | struct |
b is a bool and pt is a Point .
bool_point also contains two constructors and an assignment
operator, described below.
|
void bool_point (void) | Default constructor |
Creates a bool_point and sets b to false and
pt to INVALID_POINT .
|
void bool_point (bool bb, const Point& ppt) | Default constructor |
Creates a bool_point and sets b to bb and pt
to ppt.
|
void bool_point::operator= (const bool_point& bp) | Assignment operator |
Sets b to
bp.b and pt to bp.pt .
|
bool_point_pair first second | typedef |
Synonymous with pair <bool_point, bool_point> .
|
bool_point_quadruple first second third fourth | struct |
This structure contains four bool_points . It also has two
constructors and an assignment operator, described below.
|
void bool_point_quadruple (void) | Default constructor |
Creates a bool_point_quadruple , and sets
first , second , third , and fourth all to
INVALID_BOOL_POINT .
|
void bool_point_quadruple (bool_point a, bool_point b, bool_point c, bool_point d) | Constructor |
Creates a bool_point_quadruple and sets
first to a, second to b, third to
c, and fourth to d.
|
void bool_point_quadruple::operator= (const bool_point_quadruple& arg) | Assignment operator |
Makes *this a copy of arg.
|
bool_real_point b r pt | struct |
b is a bool , r is a real , and pt is a
Point . bool_real_point also contains three constructors
and an assignment operator, described below.
|
void bool_real_point (void) | Default constructor |
Creates a bool_real_point and sets b to false ,
r to INVALID_REAL and pt to INVALID_POINT .
|
void bool_real_point (const bool_real_point& brp) | Copy constructor |
Creates a bool_real_point and sets b to brp.b ,
r to brp.r , and pt to brp.pt .
|
void bool_real_point (const bool& bb, const real& rr, const Point& ppt) | Constructor |
Creates a bool_real_point and sets b to bb,
r to rr, and pt to ppt.
|
void bool_real_point::operator= (const bool_real_point& brp) | Assignment operator |
Makes *this a copy of brp.
|
Point INVALID_POINT | Constant |
The x, y, and z-values in world_coordinates are all INVALID_REAL .
|
Point origin | Constant |
The x, y, and z-values in world_coordinates are all 0.
|
bool_point INVALID_BOOL_POINT | Constant |
b is false and pt is INVALID_POINT .
|
bool_point_pair INVALID_BOOL_POINT_PAIR | Constant |
first and second are both INVALID_BOOL_POINT .
|
bool_real_point INVALID_BOOL_REAL_POINT | Constant |
b is false , r is INVALID_REAL , and pt
is INVALID_POINT .
|
bool_point_quadruple INVALID_BOOL_POINT_QUADRUPLE | Constant |
first , second , third , and fourth are all
INVALID_BOOL_POINT .
|
void Point (void) | Default constructor |
Creates a Point and initializes its x, y, and z-coordinates
to 0.
|
void Point (const real x, [const real y = CURR_Y , [const real z = CURR_Z ]])
|
Constructor |
Creates a Point and initializes its x, y, and z-coordinates
to the values of the arguments x, y, and z. The
arguments y and z are optional. If they are not specified,
the values of CURR_Y and CURR_Z are used. They are 0 by
default, but can be changed by the user. This can be convenient, if all
of the Points being drawn in a particular section of a program
have the same z or y and z values.
|
void set (const real x, [const real y = CURR_Y , [const real z = CURR_Z ]])
|
Setting function |
Corresponds to the constructor above, but is used for resetting the coordinates of an existing
Point .
|
void Point (const Point& p) | Copy constructor |
Creates a Point and copies the values for its x, y, and z-coordinates
from p.
|
void set (const Point& p) | Setting function |
Corresponds to the copy constructor above, but is used for resetting the coordinates
of an existing Point . This function exists purely as a convenience;
the operator operator=()
(see Point Reference; Operators)
performs exactly the
same function.
|
Point* create_new<Point> (const Point* p) | Template specializations |
Point* create_new<Point> (const Point& p) |
Pseudo-constructors for dynamic allocation of Points .
They create a Point on the free store and allocate memory for it using
new(Point) . They return a pointer to the new Point .
If p is a non-zero pointer or a reference,
the new One use for Programmers who dynamically allocate |
void ~Point (void )
|
virtual Destructor |
This function currently has an empty definition, but its existence prevents GCC 3.3 from issuing the following warning: "`class Point' has virtual functions but non-virtual destructor". |
void operator= (const Point& p) | Assignment operator |
Makes *this a copy of p.
|
Transform operator*= (const Transform& t) | Operator |
Multiplies transform by t.
By multiplying a Point successively by
one or more Transforms , the effect of the transformations is
"saved up" in transform . Only when an operation that needs
updated values for the world_coordinates is called on a
Point , or the Point is passed as an argument to such an
operation, is the transformation stored in transform applied to
world_coordinates by apply_transform() ,
which subsequently, resets transform to
the identity Transform .
See Point Reference; Applying Transformations.
|
Point operator+ (Point p) | const operator |
Returns a Point with world_coordinates that are the sums of
the corresponding world_coordinates of *this and p,
after they've been updated.
*this remains unchanged; as in many other functions with
Point arguments, p is passed by value, because
apply_transform() must be called on it, in order to update its
world_coordinates . If p were a const Point& , it
would have to copied within the function anyway, because
apply_transform() is a non-const operation.
Point p0(-2, -6, -28); Point p1(3, 14, 92); Point p2(p0 + p1); p2.show("p2:"); -| p2: (1, 8, 64) |
void operator+= (Point p) | Operator |
Adds the updated world_coordinates of p to those of
*this .
Equivalent in effect to shift( p)
In fact, this
function merely calls p.apply_transform() and
Point::shift(real, real, real) with p's x, y, and z
coordinates (from world_coordinates ) as its arguments.
See Point Reference; Affine Transformations.
|
Point operator- (Point p) | const operator |
Returns a Point with world_coordinates representing the
difference between the updated values of
this->world_coordinates and
p.world_coordinates .
|
void operator-= (Point p) | Operator |
Subtracts the updated values of p.world_coordinates from
those of this->world_coordinates .
|
real operator*= (const real r) | Operator |
Multiplies the updated x, y, and z coordinates (world_coordinates ) of
the Point by r and returns r. This makes it possible to
chain invocations of this function.
If Point P(1, 2, 3); P *= 7; P.show("P:"); -| P: (7, 14, 21); Point Q(1.5, 2.7, 13.82); Q *= P *= -1.28; P.show("P:"); -| P: (-8.96, -17.92, -26.88) Q.show("Q:"); -| Q: (-1.92, -3.456, -17.6896) |
Point operator* (const real r) | const operator |
Returns a Point with x, y, and z coordinates
(world_coordinates ) equal to the updated x, y, and z coordinates
of *this multiplied by r.
|
Point operator* (const real r, const Point& p) | Non-member operator |
Equivalent to Point::operator*(const real r) (see above),
but with r placed first.
Point p0(10, 11, 12); real r = 2.5; Point p1 = r * p0; p1.show(); -|Point: -|(25, 27.5, 30) |
Point operator- (void) | const operator |
Unary minus (prefix). Returns a Point with x, y, and z
coordinates (world_coordinates ) equal to the
the x, y, and z-coordinates (world_coordinates ) of
*this multiplied by -1.
|
void operator/= (const real r) | Operator |
Divides the updated x, y, and z coordinates (world_coordinates ) of
the Point by r.
|
Point operator/ (const real r) | const operator |
Returns a Point with x, y, and z coordinates
(world_coordinates ) equal to the updated x, y, and z coordinates
of *this
divided by r.
|
bool operator== (Point p) | Operator |
bool operator== (const Point& p) | const operator |
Equality comparison for Points . These functions return
true if the updated values of the world_coordinates of the two
Points differ by less than the value returned by
Point::epsilon() , otherwise false .
See Point Reference; Returning Information.
|
bool operator!= (const Point& p) | const operator |
Inequality comparison for Points . Returns false if
*this == p , otherwise true .
|
Shape* get_copy (void) | const function |
Creates a copy of the Point , and allocates memory for it on the
free store using create_new<Point>() .
It returns a pointer to Shape that points to the new Point .
This function is used in the drawing commands for putting Points
onto Pictures .
See Point Reference; Drawing.
|
bool is_identity (void) | inline function |
Returns true if transform is the identity Transform .
|
Transform get_transform (void) | const inline function |
Returns transform .
|
bool is_on_free_store (void) | const function |
Returns true if memory for the Point has been dynamically
allocated on the
free store, i.e., if the Point has been created using
create_new<Point>() .
See Point Reference; Constructors and Setting Functions.
|
bool is_on_plane (const Plane& p) | const function |
Returns true , if the Point lies on the
Plane p, otherwise false .
Planes are conceived of as having infinite extension, so while
the Point P(1, 1, 1); Rectangle r(P, 4, 4, 20, 45, 35); Plane q = r.get_plane(); Point A(2, 0, 2); Point B(2, 1.64143, 2); Point C(0.355028, 2.2185, 6.48628); cout << A.is_on_plane(q); -| 0 cout << B.is_on_plane(q); -| 1 cout << "C.is_on_plane(q)"; -| 1
|
bool is_in_triangle (const Point& p0, const Point& p1, const Point& p2, [bool verbose = false , [bool test_points = true ]])
|
const function |
Returns true , if *this lies within the triangle determined by
the three Point arguments, otherwise false .
If the code calling If the verbose argument is This function is needed for determining whether a line intersects with a polygon. |
The functions in this section return either a single coordinate or a set of
coordinates. Each has
a const
and a non-const
version.
The arguments are the same, with one exception:
char
c
get_coord()
. Indicates which coordinate should be
returned. Valid values are 'x'
, 'X'
, 'y'
,
'Y'
, 'z'
, 'Z'
, 'w'
, and 'W'
.
char
coords
'w'
for world_coordinates
(the default), 'p'
for
projective_coordinates
, 'u'
for user_coordinates
,
and 'v'
for view_coordinates
.
const bool
do_persp
projective_coordinates
, or one of its elements
is to be returned. If true
, the
default, then project()
is called, thereby generating values for
projective_coordinates
. If do_persp is false
, then
projective_coordinates
, or one of its elements, is
returned unchanged, which may sometimes be useful.
const bool
do_apply
true
(the default), apply_transform()
is called,
thereby updating the world_coordinates
. Otherwise, it's not, so
that the values stored in world_coordinates
remain unchanged.
Note that if coords is 'p'
and do_persp is true
,
apply_transform()
will be called in project()
whether do_apply
is true
or false
. If for some
reason, one wanted get projective_coordinates
, or one of its
values, based on the
projection of world_coordinates
without first updating them, one
would have to call reset_transform()
before calling one of
these functions. It would probably be a good idea to save transform
before doing so.
Focus*
f
Focus
is to be used for projection.
Only relevant if coords
is 'p'
, i.e.,
projective_coordinates
, or one of its elements, is to be
returned. The default is 0, in which case f points to the global
variable default_focus
.
const unsigned short
proj
coords
is 'p'
, i.e.,
projective_coordinates
, or one of its elements, is to be
returned. The default is Projections::PERSP
, which causes the
perspective projection to be applied.
real
factor
project()
. The values of the x and y coordinates in
projective_coordinates
are multiplied by factor.
Only relevant if coords
is 'p'
, i.e.,
projective_coordinates
, or one of its elements, is to be
returned. The default is 1.
valarray <real> get_all_coords ([char coords = 'w', [const bool do_persp = true, [const bool do_apply = true, [Focus* f = 0, [const unsigned short proj = Projections::PERSP, [real factor = 1]]]]]]) | Function |
Returns one of the sets of coordinates; world_coordinates by
default.
Returns a complete set of coordinates: 'w' for world_coordinates ,
'p' for projective_coordinates , 'u' for
user_coordinates , or'v' for view_coordinates .
|
real get_coord (char c, [char coords = 'w', [const bool do_persp = true, [const bool do_apply = true, [Focus* f = 0, [const unsigned short proj = Projections::PERSP , [real factor = 1]]]]]])
|
Function |
Returns one coordinate , x, y, z, or w, from the set of
coordinates indicated (or world_coordinates , by default).
|
real get_x ([char coords = 'w', [const bool do_persp = true, [const bool do_apply = true, [Focus* f = 0, [const unsigned short proj = Projections::PERSP, [real factor = 1]]]]]]) | Function |
Returns the x-coordinate from the set of coordinates indicated (or
world_coordinates , by default).
|
real get_y ([char coords = 'w', [const bool do_persp = true, [const bool do_apply = true, [Focus* f = 0, [const unsigned short proj = Projections::PERSP, [real factor = 1]]]]]]) | Function |
Returns the y-coordinate from the set of coordinates indicated (or
world_coordinates , by default).
|
real get_z ([char coords = 'w', [const bool do_persp = true, [const bool do_apply = true, [Focus* f = 0, [const unsigned short proj = Projections::PERSP, [real factor = 1]]]]]]) | Function |
Returns the z-coordinate from the set of coordinates indicated (or
world_coordinates , by default).
|
real get_w ([char coords = 'w', [const bool do_persp = true, [const bool do_apply = true, [Focus* f = 0, [const unsigned short proj = Projections::PERSP, [real factor = 1]]]]]]) | Function |
Returns the w-coordinate from the set of coordinates indicated (or
world_coordinates , by default).
|
real epsilon (void) | Static function |
Returns the positive real value of smallest magnitude
\epsilon that should be used as a coordinate value in a
Point .
A coordinate of a Point may also contain
-\epsilon.
The value \epsilon is used for testing the equality of
Let \epsilon be the value returned by
Please note: I haven't tested whether 0.000000001 is a good
value yet, so users should be aware of this if they set Rotation causes a significant loss of precision to due to the use of the
|
bool set_on_free_store ([bool b = true]) | Virtual function |
This function is used in the template function
create_new() . It sets on_free_store to true .
See Point Reference; Data Members, and
Point Reference; Constructors and Setting Functions.
|
void clear (void) | Function |
Sets all of the coordinates in all of the sets of coordinates (i.e.,
world_coordinates , user_coordinates , view_coordinates , and
projective_coordinates ) to 0 and resets transform
|
void clean ([int factor = 1]) | Function |
Calls apply_transform() and sets the values of
world_coordinates to 0, whose absolute values are less than
epsilon() * factor
.
|
void reset_transform (void) | Function |
Sets Transform to the identity Transform . Performed in
apply_transform() , after the latter updates world_coordinates .
Point Reference; Applying Transformations.
|
Transform rotate (const real x, [const real y = 0, [const real z = 0]]) | Function |
Transform rotate (const Point& p0, const Point& p1, [const real angle = 180]) | Function |
Transform rotate (const Path& p, [const real angle = 180]) | Function |
Each of these functions calls the corresponding version of
Transform::rotate() , and returns its
return value, namely, a Transform representing the rotation
only.
In the first version, taking three Point p0(1, 0, 2); p0.rotate(90); p0.show("p0:") -| p0: (1, 2, 0) Point p1(-1, 1, 1); p1.rotate(-90, 90, 90); p1.show("pt1:"); -| p1: (1, -1, -1)
Please note that rotations are not commutative operations. Nor are they
commutative with other transformations.
So, if you want to rotate a Point pt0(1, 1, 1); pt0.rotate(0, 45); pt0.rotate(45); pt0.show("pt0:"); -| pt0: (0, 1.70711, 0.292893) In the version taking two Point P(2, 0, 0); Point A; Point B(2, 2, 2); P.rotate(A, B, 180);
|
Transform scale (real x, [real y = 1, [real z = 1]]) | Function |
Calls transform.scale( x, y, z) and returns its
return value, namely, a Transform representing the scaling operation
only.
Scaling causes the x-coordinate of the Point p0(1, 0, 3); p0.scale(4); p0.show("p0:"); -| p0: (4, 0, 3) Point p1(-2, -1, -2); p1.scale(-2, -3, -4); p1.show("p1:"); -| p1: (4, 3, 8)
|
Transform shear (real xy, [real xz = 0, [real yx = 0, [real yz = 0, [real zx = 0, [real zy = 0]]]]]) | Function |
Calls transform.shear() with the same arguments
and returns its
return value, namely, a Transform representing the shearing operation
only.
Shearing modifies each coordinate of a x_1 == x_0 + \alpha y + \beta z y_1 == y_0 + \gamma x + \delta z z_1 == z_0 + \epsilon x + \zeta y [next figure]
demonstrates the effect of shearing the four
Point P0; Point P1(3); Point P2(3, 3); Point P3(0, 3); Rectangle r(p0, p1, p2, p3); r.draw(); r.shear(1.5); r.draw(black, "evenly");
|
Transform shift (real x, [real y = 0, [real z = 0]]) | Function |
Transform shift (const Point& p) | Function |
Each of these functions calls the corresponding version of
Transform::shift() on transform , and returns its return
value, namely, a Transform representing the shifting operation
only.
The p0(1, 2, 3); p0.shift(2, 3, 5); p0.show("p0:"); -| p0: (3, 5, 8) |
Transform shift_times (real x, [real y = 1, [real z = 1]]) | Function |
Transform shift_times (const Point& p) | Function |
Each of these functions calls the corresponding version of
Transform::shift_times() on transform and
returns its return value, namely the new value of transform .
Point P; P.drawdot(); P.shift(1, 1, 1); P.drawdot(); P.shift_times(2, 2, 2); P.drawdot(); P.shift_times(2, 2, 2); P.drawdot(); P.shift_times(2, 2, 2); P.drawdot();
|
void apply_transform (void) | Function |
Updates world_coordinates by multiplying it by transform ,
which is subsequently reset to the identity Transform .
|
bool project (const Focus& f, [const unsigned short proj = Projections::PERSP, [real factor = 1]]) | Function |
bool project ([const unsigned short& proj = Projections::PERSP, [real factor = 1]]) | Function |
These functions calculate projective_coordinates .
proj indicates which projection is to be performed.
If it is Projections::PERSP , then f indicates which
Focus is to be used (in the first version), or the global variable
default_focus is used (in the second). If
Projections::PARALLEL_X_Y , Projections::PARALLEL_X_Z , or
Projections::PARALLEL_Z_Y is used, f is ignored, since
these projections don't use a Focus . Currently, no other
projections are defined. The x and y coordinates in
projective_coordinates are multiplied by factor with the default
being 1.
|
Mathematically speaking, vectors and points are not the same. However,
they can both be represented as triples of real numbers (in a
three-dimensional Cartesian space). It is sometimes convenient to treat
points as though they were vectors, and vice versa. In particular, it
is convenient to use the same data type, namely class Point
, to
represent both points and vectors in 3DLDF.
real dot_product (Point p) | const function |
Returns the dot or scalar product of *this and p.
If P and Q are P \dot Q = x_P * x_Q + y_P * y_Q + z_P * z_Q = |P||Q| * cos(\theta)where |P| and |Q| are the magnitudes of P and Q, respectively, and \theta is the angle between P and Q. Since \theta = arccos(P \dot Q / |P||Q|),the dot product can be used for finding the angle between two vectors. Point P(1, -1, -1); Point Q(3, 2, 5); cout << P.angle(Q); -| 112.002 cout << P.dot_product(Q); -| -4 real P_Q_angle = (180.0 / PI) * acos(P.dot_product(Q) / (P.magnitude() * Q.magnitude())); cout << P_Q_angle; -| 112.002
If the angle \theta between two vectors P and Q is
90 degrees
, then
\cos(\theta) is 0, so
P \dot Q
will also be 0. Therefore,
Point P(2); Point Q(P); Point Q0(P0); Q0 *= Q.rotate(0, 0, 90); P *= Q.rotate(0, 45, 45); P *= Q.rotate(45); cout << P.angle(Q); -| 90 cout << P.dot_product(Q); -| 0
|
Point cross_product (Point p) | const function |
Returns the cross or vector product of *this and p.
If P and Q are P * Q = ((y_P * z_Q - z_P * y_Q), (z_P * x_Q - x_P * z_Q), (x_P * y_Q - y_P * x_Q)) = |P||Q| * sin(\theta) * n, where |P| and |Q| are the magnitudes of
P and Q, respectively,
\theta is the angle between P and Q, and n
is a unit vector
perpendicular to both P and Q in the direction of a
right-hand screw from P towards Q. Therefore,
Point P(2, 2, 2); Point Q(-2, 2, 2); Point n = P.cross_product(Q); n.show("n:"); -| n: (0, -8, 8) real theta = (PI / 180.0) * P.angle(Q); cout << theta; -| 1.23096 real n_mag = P.magnitude() * Q.magnitude() * sin(theta); cout << n_mag; -| 11.3137 n /= n_mag; cout << n.magnitude(); -| 1
If \theta = 0 degrees or 180 degrees, \sin(\theta) will be 0, and P * Q will be (0, 0, 0). The cross product thus provides a test for parallel vectors. Point P(1, 2, 1); Point Q(P); Point R; R *= Q.shift(-3, -1, 1); Point s(Q - R); Point n = P.cross_product(s); n.show("n:"); -| n: (0, 0, 0)
|
real magnitude (void) | const function |
Returns the magnitude of the Point . This is its distance from
origin and is equal to
sqrt(x^2 + y^2 + z^2).
Point P(13, 15.7, 22); cout << P.magnitude(); -| 29.9915 |
real angle (Point p) | const function |
Returns the angle in degrees between two Points .
Point P(3.75, -1.25, 6.25); Point Q(-5, 2.5, 6.25); real angle = P.angle(Q); cout << angle; -| 73.9084 Point n = origin.get_normal(P, Q); n.show("n:"); -| n: (0.393377, 0.91788, -0.0524503)
|
Point unit_vector (const bool assign, [const bool silent = false]) | Function |
Point unit_vector (void) | const function |
These functions return a Point with the x, y, and z-coordinates
of world_coordinates divided by the magnitude of the Point .
The magnitude of the resulting Point is thus 1. The first
version assigns the result to *this and should only ever be
called with assign = true . Calling it with the
argument false is equivalent to calling the const version,
with no assignment. If unit_vector() is called with assign
and silent both false , it issues a warning message is
issued and the const version is called. If silent is
true , the message is suppressed.
Point P(21, 45.677, 91); Point Q = P.unit_vector(); Q.show("Q:"); -| Q: (0.201994, 0.439357, 0.875308) P.rotate(30, 25, 10); P.show("P:"); P: (-19.3213, 82.9627, 59.6009) cout << P.magnitude(); -| 103.963 P.unit_vector(true); P.show("P:"); -| P: (-0.185847, 0.797999, 0.573287) cout << P.magnitude(); -| 1 |
Line get_line (const Point& p) | const function |
Returns the Line l corresponding to the line from *this to
p. l.position will be *this , and
l.direction will be p - *this .
See Line Reference.
|
real slope (Point p, [char m = 'x', [char n = 'y']]) | const function |
Returns a real number representing the slope of the trace
of the line defined by
*this and p on the plane indicated by the arguments m
and n.
Point p0(3, 4, 5); Point p1(2, 7, 12); real r = p0.slope(p1, 'x', 'y'); => r == -3 r = p0.slope(p1, 'x', 'z'); => r == -7 r = p0.slope(p1, 'z', 'y'); => r == 0.428571 |
bool_real is_on_segment (Point p0, Point p1) | Function |
bool_real is_on_segment (const Point& p0, const Point& p1) | const function |
These functions return a bool_real , where the bool part is
true , if
the Point lies on the line segment between p0 and p1,
otherwise false . If the Point lies on the line segment, the
real part is a value
r such that
0 <= r <= 1
indicating how far the Point is along the way from
p0 to p1. For example, if the Point is half of the way
from p0 to p1, r will be .5. If the Point
does not lie on the line
segment, but on the line passing through p0 and p1,
r will be <0 or >1.
If the Point p0(-1, -2, 1); Point p1(3, 2, 5); Point p2(p0.mediate(p1, .75)); Point p3(p0.mediate(p1, 1.5)); Point p4(p2); p4.shift(-2, 1, -1); bool_real br = p2.is_on_segment(p0, p1); cout << br.first; -| 1 cout << br.second; -| 0.75 bool_real br = p3.is_on_segment(p0, p1); cout << br.first; -| 0 cout << br.second; -| 1.5 bool_real br = p4.is_on_segment(p0, p1); cout << br.first; -| 0 cout << br.second; -| 3.40282e+38 cout << (br.second == INVALID_REAL) -| 1
|
bool_real is_on_line (const Point& p0, const Point& p1) | const function |
Returns a bool_real where the bool part is true , if
the Point lies on the line passing through p0 and p1,
otherwise false . If the Point lies on the line, the
real part is a value r indicating how how far the Point
is along the way from p0 to p1, otherwise
INVALID_REAL . The following
values of r are possible for a call to P.is_on_line(A, B) ,
where the Point P lies on the line
AB:
P == A ---> r== 0. P == B ---> r== 1. P lies on the opposite side of A from B ---> r < 0. P lies between A and B ---> 0 < r < 1. P lies on the opposite side of A from B ---> r > 1 Point A(-1, -2); Point B(2, 3); Point C(B.mediate(A, 1.25)); bool_real br = C.is_on_line(A, B); Point D(A.mediate(B)); br = D.is_on_line(A, B); Point E(A.mediate(B, 1.25)); br = E.is_on_line(A, B); Point F(D); F.shift(-1, 1); br = F.is_on_line(A, B);
|
Point mediate (Point p, [const real r = .5]) | const function |
Returns a Point r of the way from *this to p.
Point p0(-1, 0, -1); Point p1(10, 0, 10); Point p2(5, 5, 5); Point p3 = p0.mediate(p1, 1.5); p3.show("p3:"); -| p3: (15.5, 0, 15.5) Point p4 = p0.mediate(p2, 1/3.0); p4.show("p4:"); -| p4: (1, 1.66667, 1)
|
bool_point intersection_point (Point p0, Point p1, Point q0, Point q1) | Static function |
bool_point intersection_point (Point p0, Point p1, Point q0, Point q1, const bool trace) | Static function |
These functions find the intersection point, if any, of the lines determined by
p0 and p1 on the one hand, and q0 and q1 on the other.
Let The two versions use different methods of finding the intersection
point. The first uses a vector calculation, the second looks for the
intersections of the traces of the lines on the major planes. If the
trace argument is used, the second version will be called, whether
trace is Point A(-1, -1); Point B(1, 1); Point C(-1, 1); Point D(1, -1); bool_point bp = Point::intersection_point(A, B, C, D); bp.pt.dotlabel("$i$"); cout << "bp.b == " << bp.b << endl << flush; -| bp.b == 1
Point A(.5, .5); Point B(1.5, 1.5); Point C(-1, 1); Point D(1, -1); bool_point bp = Point::intersection_point(A, B, C, D, true); bp.pt.dotlabel("$i$"); cout << "bp.b == " << bp.b << endl << flush; -| bp.b == 0
|
There are two versions for each of the drawing functions. The second
one has the Picture
argument picture at the beginning of the
argument list, rather than at the end. This is convenient when passing
a picture
argument. Where picture is optional, the default
is always current_picture
.
void drawdot ([const Color& ddrawdot_color = *Colors::default_color , [const string ppen = "", [Picture& picture = current_picture ]]])
|
const function |
void drawdot ([Picture& picture = current_picture , [const Color& ddrawdot_color = *Colors::default_color , [const string ppen = "", ]]])
|
const function |
Draws a dot on picture. If ppen is specified, a "pen
expression" is included in the drawdot command written to
out_stream . Otherwise, MetaPost's currentpen is used.
If ddrawdot_color is specified, the dot will be drawn using that
Color . Otherwise, the Color currently pointed to by the pointer
Colors::default_color will be used. This will normally be
Colors::black . See Color Reference, for more information
about Colors and the namespace Colors .
Please note that the "dot" will always be parallel to the plane of projection. Even where it appears to be a surface, as in [next figure] , it is never put into perspective, but will always have the same size and shape. Point P(1, 1); P.drawdot(gray, "pensquare scaled 1cm");
|
void undrawdot ([string pen = "", [Picture& picture = current_picture ]])
|
Function |
void undrawdot ([Picture& picture = current_picture , [string pen = ""]])
|
Function |
Undraws a dot on picture. If ppen is specified, a "pen
expression" is included in the undrawdot command written to
out_stream . Otherwise, MetaPost's currentpen is used.
Point P(1, 1); P.drawdot(gray, "pensquare scaled 1cm"); P.undrawdot("pencircle scaled .5cm");
|
void draw (const Point& p, [const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture , [bool aarrow = false ]]]]])
|
Function |
void draw (Picture& picture = current_picture , const Point& p, [const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [bool aarrow = false ]]]])
|
Function |
Draws a line from *this to p.
Returns the Path *this -- p1 .
See Path Reference; Drawing and Filling,
for more information.
Point P(-1, -1, -1); Point Q(2, 3, 5); P.draw(Q, Colors::gray, "", "pensquare scaled .5cm");
|
void undraw (const Point& p, [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]])
|
Function |
void undraw (Picture& picture, const Point& p, [string ddashed = "", [string ppen = ""]]) | Function |
Undraws a line from *this to p.
Returns the Path *this -- p1 .
See Path Reference; Drawing and Filling,
for more information.
Point P(-1, -1, -1); Point Q(2, 3, 5); P.draw(Q, Colors::gray, "", "pensquare scaled .5cm"); P.undraw(Q, "evenly scaled 6", "pencircle scaled .3cm");
|
Path draw_help (const Point& p, [const Color& ddraw_color = *Colors::help_color, [string ddashed = "", [string ppen = "", [Picture& picture = current_picture]]]]) | Function |
Path draw_help (Picture& picture, const Point& p, [const Color& ddraw_color = *Colors::help_color, [string ddashed = "", [string ppen = ""]]]) | Function |
Draws a "help line" from *this to p , but only if the
static Path data member do_help_lines is true .
See Path Reference; Data Members.
"Help lines" are lines that are used when constructing a drawing, but that should not be printed in the final version. |
Path drawarrow (const Point& p, [const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]]])
|
Function |
Path drawarrow (Picture& picture, const Point& p, [const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = ""]]])
|
Function |
Draws an arrow from *this to p and returns
the Path *this -- p .
The second version is convenient for passing a Picture argument
without having to specify all of the other arguments.
Point P(-3, -2, 1); Point Q(3, 3, 5); P.drawarrow(Q);
|
Labels make it possible to include TeX text within a drawing.
Labels are implemented by means of class Label
.
The functions label()
and dotlabel()
, described in this
section, create objects of type Label
, and add them to the
Picture
, which was passed to them as an argument
(current_picture
, by default).
See Label Reference, for more information.
void label (const string text_str, [const string position_str = "top", [const bool dot = false , [Picture& picture = current_picture ]]])
|
const function |
void label (const short text_short, [const string position_str = "top", [const bool dot = false , [Picture& picture = current_picture ]]])
|
const function |
These functions cause a Point to be labelled in the drawing.
The first argument is the text of the label. It can either be a
string , in the first version, or a short , in the second.
It will often be the name of the Point in the C++
code, for
example, "p0" .
It is not possible to automate this kind of
labelling, because it is not possible to access the names of variables
through the variables themselves in C++
.
text_str is always placed between
" Point p0(2, 3); p0.label("$p_0$");
If backslashes are needed in the text of the label, then
text_str must contain double backslashes, so that single
backslashes will be written to Point P; Point Q(2, 2); Point R(P.mediate(Q)); R.label("$\\overrightarrow{PQ}$", "ulft");
The position argument indicates where the text of the label should
be located relative to the The dot argument is used to determine whether the label should be
dotted or not. The default is |
void dotlabel ([const string text_str, [const string position_str = "top", [Picture& picture = current_picture ]]])
|
const function |
void dotlabel (const short text_short, [const string position_str = "top", [Picture& picture = current_picture]]) | const function |
These functions are like label() except that they always produces a
dot.
Point p0(2, 3); p0.dotlabel("$p_0$");
|
void show ([string text = "", [char coords = 'w', [const bool do_persp = true, [const bool do_apply = true, [Focus* f = 0, [const unsigned short proj = Projections::persp, [const real factor = 1]]]]]]]) | const function |
Prints text followed by the values of a set of coordinates to
standard output (stdout ). The other arguments are similar to
those used in the functions described in Returning Coordinates.
Point P(1, 3, 5); P.rotate(15, 67, 98); P.show("P:"); -| P: (-3.68621, -3.89112, 2.50421) |
void show_transform ([string text = ""]) | Function |
Prints text to standard output (stdout ),
or "transform:" , if text is the empty string (the
default), and then
calls transform.show() .
Point A(-1, 1, 1); Point B(13, 12, 6); Point Q(31, 17.31, 6); Q.rotate(A, B, 32); Q.show_transform("Q.transform:"); -| Q.transform: Transform: 0.935 0.212 -0.284 0 -0.0749 0.902 0.426 0 0.346 -0.377 0.859 0 -0.336 0.687 -0.569 1 |
ostream& operator<< (ostream& o, Point& p) | Non-member function |
Used in Path::output() for writing
the x and y values of the projective_coordinates of Points to
out_stream . See Path Reference; Outputting.
This is a low-level function that ordinary users should never have to
invoke directly.
|
void output (void) | Function |
Writes the MetaPost code for drawing or undrawing a Point to
out_stream . Called by Picture::output() , when a
Shape on the Picture is a Point .
See Picture Reference; Outputting.
|
void suppress_output (void) | Virtual function |
Sets do_output to false , which causes a Point
not to be output. This function is called in
Picture::output() , when a Point cannot be projected.
See Picture Reference; Outputting.
|
virtual void unsuppress_output (void) | Virtual function |
Resets do_output to true , so that a Point can
potentially be output, if Picture::output() is called again for
the Picture the Point is on.
This function is called in
Picture::output() .
See Picture Reference; Outputting.
|
vector<shape*> extract (const Focus& f, const unsigned short proj, real factor)
|
Function |
Attempts to project the Point
using the arguments passed to Picture::output() , which calls this
function. If extract() succeeds,
it returns a vector<shape*> containing only the Point .
Otherwise, it returns an empty vector<shape*> .
|
bool set_extremes (void) | Virtual function |
Sets "extreme" values
for x, y, and z in projective_coordinates . This
is, of course, trivial for
Points , because they only have one x, y and z-coordinate.
So the maxima and minima for each coordinate are always the same.
|
valarray <real> get_extremes (void)
|
Virtual inline const function |
Returns projective_extremes .
|
real get_minimum_z (void) | Virtual const function |
real get_maximum_z (void) | Virtual const function |
real get_mean_z (void) | Virtual const function |
These functions return the minimum, maximum, and mean z-value of the
Point .
get_minimum_z() returns projective_extremes[4] ,
get_maximum_z() returns projective_extremes[5] , and
get_mean_z() returns
(projective_extremes[4] + projective_extremes[5]) / 2 .
However, since a Point has only one z-coordinate
(from world_coordinates ), these values will all be the same.
These functions are pure virtual functions in |
Class Focus
is defined in points.web
.
Focuses
are used when creating a perspective projection.
They represent the center of projection and can be thought of like a
camera viewing the scene.
Point position | Private variable |
The location of the Focus in the world coordinate system.
|
Point direction | Private variable |
The direction of view from position into the scene.
|
Point up | Private variable |
The direction that will be at the top of the projected drawing. |
real distance | Private variable |
The distance of the Focus from the plane of projection.
|
real angle | Private variable |
Used for determining the up direction.
|
char axis | Private variable |
The main axis onto which the Focus is transformed in order to
perform the perspective projection, z by default.
It will normally not matter which axis is used, but it might be advantageous to use a particular axis in some special situations. |
Transform transform | Private variable |
The Transform , which will be applied to the Shapes on the
Picture , when the latter is output. The effect of this is
equivalent to transforming the Focus , so that it lies on a major
axis.
Focus f(5, 5, -10, 2, 4, 10, 10, 180); =>
|
Transform persp | Private variable |
The Transform representing the perspective transformation for a
particular Focus .
Let d stand for distance , then
|
Focus default_focus | Variable |
Effectively, the default Focus in Picture::output() .
See Picture Reference; Outputting; Functions.
It's not really the default, but the version of
output() that doesn't take a
Focus argument calls another version
that does take one, passing default_focus to the
latter as its Focus argument.
It's necessary to do this in such a roundabout way,
because The declaration |
void Focus (void) | Default constructor |
Creates an empty Focus
|
void Focus (const real pos_x, const real pos_y, const real pos_z, const real dir_x, const real dir_y, const real dir_z, const real dist, [const real ang = 0, [char ax = 'z']]) | Constructor |
Constructs a Focus using the first three real arguments as
the x, y, and z-coordinates of position , and the fourth through the
sixth argument as the x, y, and z-coordinates of direction . dist
specifies the distance of the Focus
from the plane of projection, ang the angle of rotation, which affects which
direction is considered to be "up", and ax the major axis to
which the Focus is aligned.
|
void set (const real pos_x, const real pos_y, const real pos_z, const real dir_x, const real dir_y, const real dir_z, const real dist, [const real ang = 0, [char ax = 'z']]) | Setting function |
Resets an existing Focus . Corresponds to the constructor above.
|
void Focus (const Point& pos, const Point& dir, const real dist, [const real ang = 0, [char ax = 'z']]) | Constructor |
Constructs a Focus using Point arguments for
position and direction . Otherwise, the arguments of this constructor
correspond to those of the one above.
|
void set (const Point& pos, const Point& dir, const real dist, [const real ang = 0, [char ax = 'z']]) | Setting function |
Resets an existing Focus . Corresponds to the constructor above.
|
const Focus& operator= (const Focus& f) | Assignment operator |
Sets the Focus to f.
|
void reset_angle (const real ang) | Function |
Resets the value of angle and recalculates the Transforms
transform and persp .
|
const Point& get_position (void) | Inline const function |
Returns position .
|
const Point& get_direction (void) | Inline const function |
Returns direction .
|
const real& get_distance (void) | Inline const function |
Returns distance .
|
const Point& get_up (void) | Inline const function |
Returns up .
|
const Transform& get_transform (void) | Inline const function |
Returns transform .
|
const real& get_transform_element (const unsigned int row, const unsigned int column) | Inline const function |
Returns an element of transform , given two unsigned ints for the row
and the column.
|
const Transform& get_persp (void) | Inline const function |
Returns persp .
|
const real& get_persp_element (const unsigned int row, const unsigned int column) | Inline const function |
Returns an element of persp , given two unsigned ints for the row
and the column.
|
void show ([const string text_str = "Focus:", [const bool show_transforms = false]]) | const function |
Prints text_str to standard output (stdout ), then calls
Point::show() on position , direction , and
up . Then the values of distance , axis , and
angle are printed to stdout . If show_transforms is
true , transform and persp are shown as well.
|
The struct Line
is defined in lines.web
.
Lines
are not Shapes
. They are used for
performing vector operations. A Line
is defined by a
Point
representing a position vector and a Point
representing a direction vector.
See also the descriptions of Point::get_line()
in
Points and Lines, and
Path::get_line()
in
Path Reference; Querying.
Point position | Public variable |
Represents the position vector of the Line .
|
Point direction | Public variable |
Represents the direction vector of the Line .
|
const Line INVALID_LINE | Constant |
position and direction are both INVALID_POINT .
|
void Line (const Point& pos = origin , const Point& dir = origin )
|
Default constructor |
Creates a Line , setting position to pos, and
direction to dir. If this function is called with no
arguments, it creates a Line at the origin with no
direction.
Point p(2, 1, 2); Point d(-3, 3, 3.5); Line L0(p, d); Line L1 = p.get_line(d);
|
void Line (const Line& l) | Copy constructor |
Creates a Line , making it a copy of l.
|
void operator= (const Line& l) | Assignment operator |
Sets *this to l.
|
Path get_path (void) | const function |
Returns a linear Path with two Points
on the Line . The first Point will be position , and
the second will be position + direction .
|
void show ([string text = ""]) | Function |
If text is not the empty string (the default), it is
printed on a line of its own to standard output. Otherwise, Line:
is printed. Following this, Point::show() is called on
position and direction .
Point p(1, -2, 3); Point d(-12.3, 21, 36.002); Line L0(p, d); L0.show("L0:"); -| L0: position: (1, -2, 3) direction: (-12.3, 21, 36.002) Line L1 = p.get_line(d); L1.show("L1:"); -| L1: position: (1, -2, 3) direction: (-13.3, 23, 33.002) Path q = L1.get_path(); q.show("q:"); -| q: fill_draw_value == 0 (1, -2, 3) -- (-12.3, 21, 36.002); |
The struct Plane
is defined in planes.web
.
Planes
are not Shapes
. They are used for
performing vector operations. A Plane
is defined by a
Point
representing a point on the plane, a Point
representing the normal to the plane, and the distance of the plane from
the origin.
The most common use of Planes
is to represent the
plane in which an existing plane figure lies. Therefore, they
most likely to be created by using Path::get_plane()
.
See Path Reference; Querying. However, class
Plane
does have constructors for creating Planes
directly, if
desired.
See Planes Reference; Constructors.
Because the main purpose of Plane
is to
provide information about Shapes
, its data members are all
public
.
Point point | Public variable |
Represents a point on the plane. |
Point normal | Public variable |
Represents the normal to the plane. |
real distance | Public variable |
The distance of the plane from the origin. |
const Plane INVALID_PLANE | Constant |
A Plane with point == normal , and
distance == INVALID_REAL .
|
void Plane (void) | Default constructor |
Creates a degenerate Plane with
point == normal == origin , and
distance == 0.
|
void Plane (const Plane& p) | Copy constructor |
Creates a new Plane , making it a copy of p.
|
void Plane (const Point& p, const Point& n) | Constructor |
If p is not equal to n, this constructor creates a
Plane and sets point to p. normal
is set to n, and made a unit vector.
distance is calculated according to the following formula:
Let n stand for normal , p for point , and d for
distance :
d = -p \dot n.
If d = 0, origin
lies in the Plane . If d > 0, origin lies on the side of the
Plane that normal points to, considered to be "outside".
If d<0, origin lies on the side of the
Plane that normal does not point to, considered to be
"inside".
However, if p == n, Point P(1, 1, 1); Point N(0, 1); N.rotate(-35, 30, 20); N.show("N:"); -| N: (-0.549659, 0.671664, 0.496732) Plane q(P, N); cout << q.distance; -| -0.618736
|
const Plane& operator= (const Plane& p) | Assignment operator |
Sets point to p.point , normal to
p.normal , and distance to p.distance .
The return value is p, so that invocations of this function can be
chained.
Point pt(2, 2.3, 6); Point norm(-1, 12, -36); Plane A(pt, norm); Plane B; Plane C; B = C = A; A.show("A:"); -| A: normal: (-0.0263432, 0.316118, -0.948354) point: (2, 2.3, 6) distance == 5.01574 cout << (A == B && A == C && B == C); -| 1 |
bool operator== (const Plane& p) | const operator |
Equality operator. Compares *this and p, and returns
true , if point == p.point ,
normal == p.normal , and
distance == p.distance ,
otherwise false .
|
bool operator!= (const Plane& p) | const operator |
Inequality operator. Compares *this and p and returns
true , if point !=
p.point , or
normal !=
p.normal , or
distance !=
p.distance .
Otherwise, it returns false .
|
real_short get_distance (const Point& p) | const function |
real_short get_distance (void) | const function |
The version of this function taking a Point argument returns
a real_short r, whose real part
(r.first ) represents
the distance of p from the Plane . This value is always
positive. r.second can take on three values:
The version taking no argument returns
the absolute of the data member It would have been possible to use Point N(0, 1); N.rotate(-10, 20, 20); Point P(1, 1, 1); Plane q(P, N); Point A(4, -2, 4); Point B(-1, 3, 2); Point C = q.intersection_point(A, B).pt; real_short bp; bp = q.get_distance(); cout << bp.first; -| 0.675646 cout << bp.second -| -1 bp = q.get_distance(A) cout << bp.first; -| 3.40368 cout << bp.second; -| -1 bp = q.get_distance(B) cout << bp.first; -| 2.75865 cout << bp.second; -| 1 bp = q.get_distance(C) cout << bp.first; -| 0 cout << bp.second; -| 0
|
bool_point intersection_point (const Point& p0, const Point& p1) | const function |
bool_point intersection_point (const Path& p) | const function |
These functions find the intersection point of the Plane and a
line. In the first version, the
line is defined by the two Point arguments. In the second
version, the Path p must be linear, i.e.,
p.is_linear() must be true .
Both versions of Point center(2, 2, 3.5); Reg_Polygon h(center, 6, 4, 80, 30, 10); Plane q = h.get_plane(); Point P0 = center.mediate(h.get_point(2)); P0.shift(5 * (N - center)); Point P1(P0); P1.rotate(h.get_point(1), h.get_point(4)); P1 = 3 * (P1 - P0); P1.shift(P0); P1.shift(3, -.5, -2); bool_point bp = q.intersection_point(P0, P1); Point i_P = bp.pt; Point P4 = h.get_point(3).mediate(h.get_point(0), .75); P4.shift(N - center); Point P5(P4); P5.rotate(h.get_point(3), h.get_point(0)); P4.shift(-1, 2); Path theta(P4, P5); bp = q.intersection_point(theta); Point i_theta = bp.pt; draw_axes();
|
Line intersection_line (const Plane& p) | const function |
Returns a Line l. representing the line of intersection of two
Planes . See Line Reference.
In [next figure]
, Rectangle r0(origin, 5, 5, 10, 15, 6); Rectangle r1(origin, 5, 5, 90, 50, 10); r1 *= r0.rotate(30, 30, 30); r1 *= r0.shift(1, -1, 3); Plane q0 = r0.get_plane(); Plane q1 = r1.get_plane(); Line l = q0.intersection_line(q1); l.show("l:"); -| l: position: (0, 11.2193, 20.0759) direction: (0.0466595, -0.570146, -0.796753) Point P0(l.direction); P0.shift(l.position); P0.show("P0:"); -| P0: (0.0466595, 10.6491, 19.2791) Point P1(-l.direction); P1.shift(l.position); Point P2(P0 - P1); P2 *= 12.5; P2.shift(P0); cout << P2.is_on_plane(q0); -| 1 cout << P2.is_on_plane(q1); -| 1 Point P3(P0 - P1); P3 *= 7; P3.shift(P0); cout << P3.is_on_plane(q0); -| 1 cout << P3.is_on_plane(q1); -| 1
|
void show ([string text = ""]) | const function |
Prints information about the Plane to standard output.
If text is not the empty string , it is printed to the
standard output. Otherwise,
Plane: is printed.
Following this,
if the Plane is equal to INVALID_PLANE
(see Planes Reference; Global Constants),
a message to this effect is printed to standard output.
Otherwise, normal and
point are shown using Point::show()
(see Point Reference; Showing). Finally,
distance is printed.
Point A(1, 3, 2.5); Rectangle r0(A, 5, 5, 10, 15, 6); Plane p = r0.get_plane(); -| p: normal: (-0.0582432, 0.984111, -0.167731) point: (-0.722481, 2.38245, -0.525176) distance == -2.47476 |
Class Path
is defined in paths.web
.
It is derived from Shape
using protected
derivation.
bool line_switch | Protected variable |
true if the Path was created using the constructor
Path(const Point& p0, const Point& p1) , directly or indirectly.
See Path Reference; Constructors and Setting Functions.
Point p0; Point p1(1, 1); Point p2(2, 3); Path q0(p0, p1); cout << q0.get_line_switch(); -| 1 Path q1; q1 = q0; cout << q1.get_line_switch(); -| 1 Path q2 = p0.draw(p1); cout << q2.get_line_switch(); -| 1 Path q3("..", false, &p1, &p2, &p0, 0); cout << q3.get_line_switch(); -| 0
Some |
bool cycle_switch | Protected variable |
true if the Path is cyclical, otherwise
false .
|
bool on_free_store | Protected variable |
true if the Path was dynamically allocated on the free
store. Otherwise false . Set to true only in
create_new<Path>() , which should be the only way Paths are
ever dynamically allocated.
See Path Reference; Constructors and Setting Functions.
|
bool do_output | Protected variable |
Used in Picture::output() . Set to false if the Path
isn't projectable using the arguments passed to
Picture::output() .
See Picture Reference; Outputting.
|
signed short fill_draw_value | Protected variable |
Set in the drawing and filling functions, and
used in Path::output() , to determine what MetaPost code to write
to out_stream .
See Path Reference; Drawing and Filling,
and Path Reference; Outputting.
|
const Color* draw_color | Protected variable |
Pointer to the Color used if the Path is drawn.
|
const Color* fill_color | Protected variable |
Pointer to the Color used if the Path is filled.
|
string dashed | Protected variable |
String written to out_stream for the "dash pattern" in a
MetaPost draw or undraw command. If and only if
dashed is not the empty string, "dashed
<dash pattern>" is written to out_stream .
Dash patterns have no meaning inside 3DLDF; |
string pen | Protected variable |
String written to out_stream for the pen to be used in a
MetaPost draw , undraw , filldraw , or
unfilldraw command. If and only if pen is not the
empty string, "withpen <...>" is written to
out_stream .
Pens have no meaning inside 3DLDF; |
bool arrow | Protected variable |
Indicates whether an arrow should be drawn when outputting a
Path . Set to true on a Path created on the free
store and put onto a Picture by drawarrow() .
|
valarray<real> projective_extremes | Protected variable |
Contains the maxima and minima of the x, y, and z-coordinates of the
projections of Points on a Path using a particular
Focus . Set in set_extremes() and used in
Picture::output() for surface hiding.
|
vector<Point*> points | Protected variable |
Pointers to the Points on the Path .
|
vector<string> connectors | Protected variable |
The connectors between the Points on the Path . Connectors
are simply strings in 3DLDF, they are written unchanged to
out_stream .
|
const Color* help_color | Public static variable |
Pointer to a const Color , which becomes the default for
draw_help() .
See Path Reference; Drawing and Filling.
Please note that |
string help_dash_pattern | Public static variable |
The default dash pattern for draw_help() .
|
bool do_help_lines | Public static variable |
true if help lines should be output, otherwise false .
If false , a call to draw_help() does not cause a copy of
the Path to be created and put onto a Picture .
See Path Reference; Drawing and Filling.
|
void Path (void) | Default constructor |
Creates an empty Path with no
Points and no connectors.
|
void Path (const Point& p0, const Point& p1) | Constructor |
Creates a line (more precisely, a line segment) between p0
and p1. The single
connector between the two Points is set to "--" and the
data member line_switch (of type bool ) is set to
true . There are certain operations on Paths that are only
applicable to lines, so it's necessary to store the information that a
Path is a line.36
Point A(-2, -2.5, -1); Point B(3, 2, 2.5) Path p(A, B); p.show("p:"); -| p: (-2, -2.5, -1) -- (3, 2, 2.5);
|
void set (const Point& p0, const Point& p1) | Setting function |
Corresponds to the constructor above.
Point P0(1, 2, 3); Point P1(3.5, -12, 75); Path q; q.set(P0, P1); q.show("q:"); -| q: (1, 2, 3) -- (3.5, -12, 75); |
void Path (string connector, bool cycle, Point* p, [...], 0) | Constructor |
For Paths with an arbitrary number of Points
and one type of connector.
connector is passed unchanged to cycle indicates whether the p is a pointer to the first It is admittedly a bit
awkward to have to type " Point P0; Point P1(2); Point P2(2,2); Point P3(0,2); Path p("..", true, &P0, &P1, &P2, &P3, 0); p.draw();
|
void set (string connector, bool cycle, Point* p, [...], 0) | Setting function |
Corresponds to the constructor above.
Point P[4]; P[0].set(2, 1, 3); P[3] = P[2] = P[1] = P[0]; P[3] *= P[2] *= P[1].rotate(3, 12, 18); P[3] *= P[2].shift(-2, -1, 3); P[3].shear(1.5, .5, 3.5); Path q("...", false, &P[0], &P[1], &P[2], &P[3], 0); q.show("q:"); -| q: (2, 1, 3) ... (0.92139, 1.51449, 3.29505) ... (-1.07861, 0.514487, 6.29505) ... (2.84065, -3.26065, 6.29505);
|
void Path (Point* first_point_ptr, char* s, Point* p, [...], 0) | Constructor |
Constructor for Paths with an arbitrary number of Points
and connectors. The first, required, argument is a pointer to a
Point , followed by pointers to char alternating with pointers to
Points .38
The last argument must be 0, i.e., the null pointer.
There is no need to indicate by means of an argument whether the
Point A; Point B(2, 0); Point C(3, 2); Point D(1, 3); Path p(&A, "..", &B, "..", &C, "--", &D, "...", 0);
|
void set (Point *first_point_ptr, string s, Point *p, [...], 0) | Setting function |
Corresponds to the constructor above. |
void Path (const Path& p) | Copy constructor |
Creates a new Path , making it a copy of p.
|
Path* create_new<Path> (const Path* p) | Template specializations |
Path* create_new<Path> (const Path& p) |
Pseudo-constructors for dynamic allocation of Paths .
They create a Path on the free store and allocate memory for it using
new(Path) . They return a pointer to the new Path .
If p is a non-zero pointer or a reference,
the new
|
void ~Path (void )
|
virtual Destructor |
All of the Points on a Path are created by
create_new<Point>() , which allocates them dynamically on
the free store. Therefore, the destructor calls delete() on all
of the pointers on points . Following this, it calls
points.clear() and connectors.clear() .
draw_color and fill_color may or may not have been
allocated on the free store, so ~Path() checks this first, and
deletes them, if they were. Then, it sets them to 0.
|
Transform operator*= (const Transform& t) | Virtual function |
Calls Point::operator*=( t) on each of the Points
on the Path .
See Point Reference; Operators.
This has the effect of
transforming the entire Path by t. Please note that
Path does not have a transform data member of its own.
|
void operator+= (const Point& pt) | Function |
Copies pt and pushes a pointer to the copy onto
points . The last connector
in the Path will be used to connect the new Point and the
previous one.
Point A(1, 2, 3); Point B(3, 4, 5); Path q; q += A; q += B; q.show("q:"); -| q: (1, 2, 3) -- (3, 4, 5); |
Path operator+ (const Point& pt) | const function |
Copies the Path and pt, and pushes a pointer to the copy of
pt onto points in the new Path . The
last connector in the new Path will be used to connect the new
Point and the previous one. The Path remains unchanged.
|
void operator&= (const Path& pa) | Function |
Concatenates two Paths . The result is assigned to *this .
Neither *this nor pa may be cyclical, i.e.,
cycle_switch must be false for both Paths .
|
Path operator& (const Path& pa) | const function |
Returns a Path representing the concatenation of *this and
pa. *this remains unchanged.
Neither *this nor pa may be cyclical, i.e.,
cycle_switch must be false for both Paths .
|
void operator+= (const string s) | Function |
Pushes s onto connectors .
|
Path append (const Path& pa, [string connector = "--", [bool assign = true ]])
|
Function |
Appends pa to *this using connector to join them and
returns the resulting Path . If
assign == true , then the return value is
assigned to *this , otherwise, *this remains unchanged.
If necessary, a Point A(-2, 2); Point B(-2, -2); Point C(2, -2); Point D(2, 2); Path q("--", false, &A, &B, &C, &D, 0); Point E(1, 2); Point F(0, 4); Point G(-.5, 3); Path r("..", false, &E, &F, &G, 0); q.append(r, "..", true); q += ".."; q += "--"; q.set_cycle(); q.show("q:"); -| q: (-2, 2, 0) -- (-2, -2, 0) -- (2, -2, 0) -- (2, 2, 0) .. (1, 2, 0) .. (0, 4, 0) .. (-0.5, 3, 0) -- cycle;
|
Shape* get_copy (void) | const virtual function |
Creates a copy of the Path using create_new<Path>() , which
returns a pointer to Path . get_copy() then
casts this pointer to a pointer to Shape and returns it.
This function is used when copying |
void clear (void) | Virtual function |
Does the same thing the destructor ~Path() does:
Calls delete() on the pointers to Points on points ,
clears points and connectors , deletes draw_color
and fill_color , if they point to Colors that were
allocated on the free store, and sets them to 0.
|
bool set_on_free_store ([bool b = true ])
|
Virtual function |
Sets on_free_store to b. This is used in the
template function create_new() .
See Path Reference; Constructors and Setting Functions.
|
void set_fill_draw_value (const signed short s) | Virtual function |
Sets fill_draw_value to s, which should be one of
Shape::DRAW , Shape::FILL , Shape::FILLDRAW ,
Shape::UNDRAW , Shape::UNFILL , or Shape::UNFILLDRAW .
|
void set_draw_color (const Color& c) | Virtual function |
void set_draw_color (const Color * c) | Virtual function |
Sets draw_color (a pointer to a const Color ) to &c
or c, depending on whether the
version with a reference argument or the version with a pointer argument
is used.
|
void set_fill_color (const Color& c) | Virtual function |
void set_fill_color (const Color* c) | Virtual function |
Sets fill_color (a pointer to a const Color ) to &c
or c, depending on whether the
version with a reference argument or the version with a pointer argument
is used.
|
void set_dash_pattern ([const string s = ""]) | Virtual function |
Sets dashed to s.
|
void set_pen ([const string s = ""]) | Virtual function |
Sets pen to s.
|
void set_connectors ([const string s = ".."]) | Virtual function |
Clears connectors and then pushes s onto it, making s
the only connector. Additional connectors can be added by using
Path::operator+=(const string) .
See Path Reference; Operators.
I plan to add a version of this function taking a vector of
|
Transform rotate (const real x, [const real y = 0, [const real z = 0]]) | Virtual function |
Creates a Transform t locally and calls
t.rotate( x, y, z) .
t is then applied to all of the Points on points .
The return value is t .
|
Transform scale (real x, [real y = 1, [real z = 1]]) | Function |
Creates a Transform t locally and calls
t.scale( x, y, z) .
t is then applied to all of the Points on points .
The return value is t .
The Point pt[8]; pt[0] = (-1, -1); for (int i = 1; i < 8; ++i) { pt[i] = pt[0]; pt[i].rotate(0, 0, i * 45); } Path p("--", true, &pt[0], &pt[1], &pt[2], &pt[3], &pt[4], &pt[5], &pt[6], &pt[7], 0); p.draw(); p.scale(2, 2); p.draw();
|
Transform shear (real xy, [real xz = 0, [real yx = 0, [real yz = 0, [real zx = 0, [real zy = 0]]]]]) | Function |
Creates a Transform t locally and calls
t.shear( xy, xz, yx, yz, zx, zy) .
t is then applied to all of the Points on points .
The return value is t .
Point p0; Point p1(1); Point p2(1, 1); Point p3(0, 1); Path q("--", true, &p0, &p1, &p2, &p3, 0); q.rotate(0, 45); q.shift(1); q.filldraw(black, light_gray); q.shear(1.5, 2, 2.5, 3, 3.5, 5); q.filldraw(black, light_gray);
|
Transform shift (real x, [real y = 0, [real z = 0]]) | Function |
Creates a Transform t locally and calls
t.shift( x, y, z) .
t is then applied to all of the Points on points .
The return value is t .
Shifts each of the default_focus.set(5, 10, -10, 0, 10, 10, 10); Point pt[6]; pt[0].set(-2, -2); pt[1].set(0, -3); pt[2].set(2, -2); pt[3].set(2, 2); pt[4].set(0, 3); pt[5].set(-2, 2); Path p("--", true, &pt[0], &pt[1], &pt[2], &pt[3], &pt[4], &pt[5], 0); p.draw(); p.shift(3, 3, 3); p.draw();
|
Transform shift (const Point& p) | Function |
Creates a Transform t locally and calls
t.shift( p) .
t is then applied to all of the Points on points .
The return value is t .
This version of default_focus.set(5, 10, -10, 0, 10, 10, 10); Point pt[6]; pt[0].set(-2, -2); pt[1].set(0, -3); pt[2].set(2, -2); pt[3].set(2, 2); pt[4].set(0, 3); pt[5].set(-2, 2); Path p("--", true, &pt[0], &pt[1], &pt[2], &pt[3], &pt[4], &pt[5], 0); p.draw(); Point s(1, 1, 1); p.shift(s); p.draw();
|
void shift_times (real x, [real y = 1, [real z = 1]]) | Virtual function |
void shift_times (const Point& @var{p}) | Virtual function |
Each of these functions calls the corresponding version of
Point::shift_times() on all of the
Points on points .
See Point Reference; Affine Transformations.
The return value is void ,
because there is no guarantee that all of the Points on a
Path will have identical transform members (although it's
likely).
Please note that |
Transform rotate (const Point& p0, const Point& p1, [const real angle = 180]) | Virtual function |
Creates a Transform t locally and calls
t.rotate( p0, p1, angle) .
t is then applied to all of the Points on points .
The return value is t .
|
Transform rotate (const Path& p, [const real angle = 180]) | Function |
If p.is_linear() returns true , this function
creates a Transform t locally and calls
t.rotate( p, angle) .
t is then applied to all of the Points on points .
The return value is t .
Otherwise, it issues an error message and returns
INVALID_TRANSFORM .
|
Transform align_with_axis ([const char axis = 'z']) | const function |
Transform align_with_axis (bool assign, [const char axis = 'z']) | Function |
Transform align_with_axis (const Point& p0, const Point& p1, const char axis) | Function |
These functions return the Transform which, if applied to the
Path , would align it with the major axis indicated by the
axis argument.
The first and second versions can only be called
for Point A(2, 3, 2); Point B(-1, 1, 3); Path p(A, B); Transform t = p.align_with_axis(true, 'z'); t.show("t:"); -| t: -0.316 0.507 -0.802 0 0 -0.845 -0.535 0 -0.949 -0.169 0.267 0 2.53 1.86 2.67 1 p *= t; p.show("p:"); -| p: (2.53, 1.86, 2.67) -- (-1.02, 1.23, 3.67); Point C(1); C *= t.inverse(); Path q; q += ".."; q += C; for (int i = 0; i < 15; ++i) { C.rotate(A, B, 360.0/16); q += C; } q.set_cycle(true); q.show("q:"); -| q: (1.68, 3, 1.05) .. (1.9, 2.68, 1.06) .. (2.13, 2.4, 1.21) .. (2.35, 2.22, 1.48) .. (2.51, 2.15, 1.83) .. (2.59, 2.22, 2.21) .. (2.58, 2.4, 2.55) .. (2.49, 2.68, 2.81) .. (2.32, 3, 2.95) .. (2.1, 3.32, 2.94) .. (1.87, 3.6, 2.79) .. (1.65, 3.78, 2.52) .. (1.49, 3.85, 2.17) .. (1.41, 3.78, 1.79) .. (1.42, 3.6, 1.45) .. (1.51, 3.32, 1.19) .. cycle; q.align_with_axis(A, B, 'z'); q.show("q:"); -| q: (1, 0, 0) .. (0.924, 0.383, 0) .. (0.707, 0.707, 0) .. (0.383, 0.924, 0) .. (0, 1, 0) .. (-0.383, 0.924, 0) .. (-0.707, 0.707, 0) .. (-0.924, 0.383, 0) .. (-1, 0, 0) .. (-0.924, -0.383, 0) .. (-0.707, -0.707, 0) .. (-0.383, -0.924, 0) .. (0, -1, 0) .. (0.383, -0.924, 0) .. (0.707, -0.707, 0) .. (0.924, -0.383, 0) .. cycle;
|
void apply_transform (void) | Virtual function |
Calls Point::apply_transform() on all of the Points on
points .
See Point Reference; Applying Transformations.
|
void draw ([const Color& ddraw_color = *Colors::default_color , [const string ddashed = "", [const string ppen = "", [Picture& picture = current_picture ]]]])
|
const virtual function |
void draw (Picture& picture, [const Color& ddraw_color = *Colors::default_color, [string ddashed = "", [string ppen = ""]]]) | const Virtual function |
Allocates a copy of the Path on the free store, puts a pointer to
the copy on picture.shapes , sets
its fill_draw_value to DRAW , and
the values of its
draw_color , dashed , and pen according to the
arguments.
The second version is convenient for passing a
All of the arguments to Point A; Point B(2); Point C(3, 3); Point D(1, 2); Point E(-1, 1); Path p("..", true, &A, &B, &C, &D, &E, 0); p.draw();
The arguments:
|
void draw_help ([const Color& ddraw_color = *help_color, [string ddashed = help_dash_pattern, [string ppen = "", [Picture& picture = current_picture ]]]])
|
const function |
void draw_help (Picture& picture, [const Color& ddraw_color = *help_color , [string ddashed = help_dash_pattern , [string ppen = ""]]])
|
const function |
This functions are for drawing help lines.
They are like draw() , except that draw_help() returns immediately,
if do_help_lines (a static data member in
Path ) is false .
Also, the defaults for ddraw_color and
ddashed differ from those for draw() .
|
void drawarrow ([const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]]])
|
const virtual function |
void drawarrow (Picture& picture, [const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = ""]]])
|
const virtual function |
Like draw() , except that the MetaPost command drawarrow is
written to out_stream when picture
is output.
The second version is convenient for passing a Picture argument
without having to specify all of the other arguments.
Point m; Point n(2, 2); m.dotlabel("$m$", "bot"); n.dotlabel("$n$"); m.drawarrow(n);
|
void draw_axes ([real dist = 2.5, [string pos_x = "bot", [string pos_y = "lft", [string pos_z = "bot", [const Color& ddraw_color = *Colors::default_color , [const string ddashed = "", [const string ppen = "", [const Point& shift_x = origin , [const Point& shift_y = origin , [const Point& shift_z = origin , [Picture& picture = current_picture ]]]]]]]]]]])
|
Non-member function |
void draw_axes (const Color& ddraw_color, [real dist = 2.5, [string pos_x = "bot", [string pos_y = "lft", [string pos_z = "bot", [const string ddashed = "", [const string ppen = "", [const Point& shift_x = origin , [const Point& shift_y = origin , [const Point& shift_z = origin , [Picture& picture = current_picture ]]]]]]]]]])
|
Non-member function |
These functions draw lines centered on the origin, and ending in arrows in the
directions of the positive x,
y, and z-axes, and labels them with the appropriate letters.
draw_axes() is used in
many of the figures in this handbook. It can be helpful in determining
whether a Focus has a good "up " direction.
See Focus Reference; Data Members.
In the first version, all of the arguments are optional. In the second
version, ddraw_color is required and has been moved to the front
of the argument list. This version is often convenient, when a
The arguments:
|
void fill ([const Color& ffill_color = *Colors::default_color , [Picture& picture = current_picture ]])
|
const function |
void fill (Picture& picture, [const Color& ffill_color = *Colors::default_color ])
|
Function |
Allocates a copy of the The second version is convenient for passing a
The arguments are similar to those of p.fill(gray);
|
void filldraw ([const Color& ddraw_color = *Colors::default_color , [const Color& ffill_color = *Colors::background_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]]]])
|
const function |
void filldraw (Picture& picture, [const Color& ddraw_color = *Colors::default_color , [const Color& ffill_color = *Colors::background_color , [string ddashed = "", [string ppen = ""]]]])
|
const function |
Allocates a copy of the Path on the free store, puts a pointer to
the copy onto picture.shapes , sets
its fill_draw_value to FILLDRAW ,
its draw_color and fill_color to
* ddraw_color and * ffill_color , respectively,
its dashed to ddashed, and its pen
to ppen.
The second version is convenient for passing a
The arguments are similar to those of 3DLDF's p.filldraw(black, gray, "", "pencircle scaled 2mm");
It can often be useful to draw the outline of a default_focus.set(3, 0, -10, 3, 10, 10, 10); Point p[8]; p[0] = p[1] = p[2] = p[3] = p[4] = p[5] = p[6] = p[7].set(-1,-1, 5); p[1] *= p[2] *= p[3] *= p[4] *= p[5] *= p[6] *= p[7].rotate(0, 0, 45); p[2] *= p[3] *= p[4] *= p[5] *= p[6] *= p[7].rotate(0, 0, 45); p[3] *= p[4] *= p[5] *= p[6] *= p[7].rotate(0, 0, 45); p[4] *= p[5] *= p[6] *= p[7].rotate(0, 0, 45); p[5] *= p[6] *= p[7].rotate(0, 0, 45); p[6] *= p[7].rotate(0, 0, 45); p[7].rotate(0, 0, 45); Path r0("..", true, &p[0], &p[1], &p[2], &p[3], &p[4], &p[5], &p[6], &p[7], 0); r0.filldraw(black, light_gray); r0.scale(2, .5); r0.shift(0, 0, -2.5); r0.filldraw(black, gray); r0.scale(.25, 3); r0.shift(0, 0, -2.5); r0.filldraw();
|
void undraw ([string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]])
|
Function |
void undraw (Picture& picture, [string ddashed = "", [string ppen = ""]]) | Function |
Allocates a copy of the Path on the free store, puts a pointer to
it on picture.shapes , sets
its fill_draw_value to UNDRAW , and
the values of its
dashed and pen according to the
arguments.
The second version is convenient for passing a
This function "undraws" a Undrawing is useful for removing a portion of a Point P0(1, 1); Point P1(2, 1); Point P2(2, 3); Point P3(-1, 1); Path p("--", false, &origin, &P0, &P1, &P2, &P3, 0); p.draw(black, "", "pencircle scaled 3mm"); p.undraw("", "pencircle scaled 1mm");
|
void unfill ([Picture& picture = current_picture ])
|
Function |
Allocates a copy of the Path on the free store, puts a pointer to
it on picture.shapes and sets
its fill_draw_value to UNFILL
This function is useful for removing a portion of a filled region. Point pt[4]; pt[0].set(-2, -2); pt[1].set(2, -2); pt[2].set(2, 2); pt[3].set(-2, 2); Path p("--", true, &pt[0], &pt[1], &pt[2], &pt[3], 0); p.draw(); p.dotlabel(); p.filldraw(black, gray); p.scale(.5, .5); p.unfill();
|
void unfilldraw ([const Color& ddraw_color = *Colors::background_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture]]]])
|
Function |
void unfilldraw (Picture& picture, [const Color& ddraw_color = *Colors::background_color , [string ddashed = "", [string ppen = ""]]])
|
Function |
Allocates a copy of the Path on the free store, puts a pointer to
it on picture.shapes , sets
its fill_draw_value to UNFILLDRAW , and
the values of its
draw_color , dashed , and pen according to the
arguments. While the default for ddraw_color is
*Colors::background_color , any other Color can be used,
so that unfilldraw() can unfill a Path and draw an outline
around it.
The second version is convenient for passing a
This function is similar to Point pt[6]; pt[0].set(-2, -2); pt[1].set(0, -3); pt[2].set(2, -2); pt[3].set(2, 2); pt[4].set(0, 3); pt[5].set(-2, 2); Path p("--", true, &pt[0], &pt[1], &pt[2], &pt[3], &pt[4], &pt[5], 0); p.fill(gray); p.scale(.5, .5); p.unfilldraw(black, "", "pensquare xscaled 3mm");
|
void label ([unsigned int i = 0, [string position_string = "top", [short text_short = 0, [bool dot = false , [Picture& picture = current_picture ]]]]])
|
const function |
void label (Picture& picture, [unsigned int i = 0, [string position_string = "top", [short text_short = 0, [bool dot = false ]]]])
|
const function |
Calls Point::label() on all of the Points on
points . They are numbered consecutively starting with i.
The other arguments are used for all of the Points , so it's not
possible to specify different positions for the labels for different
Points . dot will normally not be specified, unless a
picture argument is used in the first version. dotlabel()
calls label() with dot = true .
The second version is convenient for passing a
|
void dotlabel ([unsigned int i = 0, [string position_string = "top", [short text_short = 0, Picture& picture = current_picture ]]])
|
const function |
void dotlabel (Picture& picture, [unsigned int i = 0, [string position_string = "top", [short text_short = 0]]]) | const function |
Like label() , except that the Points are dotted.
|
void show ([string text = "", [char coords = 'w', [const bool do_persp = true , [const bool do_apply = true , [Focus* f = 0, [const unsigned short proj = Projections::PERSP , [const real factor = 1]]]]]]])
|
const function |
Prints information about the Path to standard output
(stdout ). text is simply printed out, unless it's the
empty string, in which case "Path:" is printed out.
coords indicates which set of coordinates should be shown. Valid values are
'w' for the world_coordinates , 'p' for the
projective_coordinates , 'u' for the
user_coordinates , and 'v' for the view_coordinates ,
whereby the latter two are currently not in use
(see Point Reference; Data Members).
If do_apply is true , apply_transform() is called
on each Point , updating its world_coordinates and
resetting its transform . Otherwise,
it's not.
The arguments do_persp, f, proj, and factor are only
relevant when showing projective_coordinates . If do_persp
is true , the Points are projected using the values of
f, proj, and factor
(see Path Reference; Outputting).
Otherwise, the values currently
stored in projective_coordinates are shown.
The Points and connectors are printed out alternately to standard
output, followed by the word "cycle", if cycle_switch = true .42
default_focus.set(0, 3, -10, 0, 3, 10, 10); Reg_Polygon r(origin, 5, 3, 45); r.fill(gray); Point p[10]; for (int i = 0; i < 5; ++i) p[i] = r.get_point(i); p[5] = Point::intersection_point(p[4], p[0], p[2], p[1]).pt; p[6] = Point::intersection_point(p[0], p[1], p[2], p[3]).pt; p[7] = Point::intersection_point(p[1], p[2], p[4], p[3]).pt; p[8] = Point::intersection_point(p[2], p[3], p[0], p[4]).pt; p[9] = Point::intersection_point(p[3], p[4], p[0], p[1]).pt; Path q("--", true, &p[0], &p[5], &p[1], &p[6], &p[2], &p[7], &p[3], &p[8], &p[4], &p[9], 0); q.draw(); q.show("q:"); -| q: fill_draw_value == 0 (0, 1.06066, 1.06066) -- (-2.30826, 2.24651, 2.24651) -- (-1.42658, 0.327762, 0.327762) -- (-3.73485, -0.858092, -0.858092) -- (-0.881678, -0.858092, -0.858092) -- (4.92996e-07, -2.77684, -2.77684) -- (0.881678, -0.858092, -0.858092) -- (3.73485, -0.858092, -0.858092) -- (1.42658, 0.327762, 0.327762) -- (2.30826, 2.24651, 2.24651) -- cycle; q.show("q:", 'p'); -| q: fill_draw_value == 0 Projective coordinates. (0, -1.75337, 0.0958948) -- (-1.88483, -0.615265, 0.183441) -- (-1.38131, -2.58743, 0.031736) -- (-4.08541, -4.22023, -0.0938636) -- (-0.964435, -4.22023, -0.0938636) -- (0, -7.99767, -0.384436) -- (0.964436, -4.22023, -0.0938636) -- (4.08541, -4.22023, -0.0938636) -- (1.38131, -2.58743, 0.031736) -- (1.88483, -0.615266, 0.183441) -- cycle;
|
void show_colors ([bool = false ])
|
Function |
Shows the values of draw_color and fill_color . These will
normally be 0, unless the Path is on a Picture .
|
bool is_on_free_store (void) | const function |
Returns true , if the Path was dynamically allocated on the
free store, otherwise false .
|
bool is_planar ([const bool verbose = false , [string text = ""]])
|
const virtual function |
Uses get_normal() to determine
whether the Path is planar or not. Returns true , if it is,
otherwise false . If verbose is true , text is written to
standard output, or "Path:", if text is the empty string,
followed by a message saying whether the Path is planar or not.
|
bool is_linear ([const bool verbose = false , [string text = ""]])
|
const function |
Returns true , if line_switch is true . Otherwise,
is_linear() uses get_normal() to determine whether the
Path is linear. If it is, is_linear() returns
true , otherwise false .
|
bool is_cycle (void) | Inline const function |
Returns true if the Path is cyclical, i.e.,
cycle_switch = true , otherwise false . Only cyclical
Paths are fillable.
|
int size (void) | Inline function |
Returns the number of Points on points , i.e.,
points.size() .
|
bool get_line_switch (void) | Inline const function |
Returns the value of line_switch . line_switch is only
true, if the Path was created, directly or indirectly, using the
constructor taking two Point arguments only.
See Path Reference; Constructors and Setting Functions.
|
real slope ([char a = 'x', [char b = 'y']]) | Function |
Returns the slope of the Path in the plane indicated by the
arguments, if is_linear() returns true . Otherwise,
slope() issues an error message and returns INVALID_REAL .
|
Path subpath (size_t start, size_t end, [const bool cycle = false, [const string connector = ""]]) | const function |
Returns a new Path using points[ start] through
points[ end - 1] . If cycle is true , then the new
Path will be a cycle, whether
*this is or not. One optional connector
argument can be used. If it is, it will be the only connector.
Otherwise, the appropriate connectors from *this are used.
start must be < end. It is not possible to
have start > end, even if |
const Point& get_point (const unsigned short a) | const function |
Returns the Point *points[ a] , if a <
points.size() and the Path is non-empty, otherwise
INVALID_POINT .
|
const Point& get_last_point (void) | const function |
Returns the Point pointed to by the last pointer on points .
Equivalent to get_point(get_size() - 1) , but more convenient to
type. Returns INVALID_POINT , if the Path is empty.
|
size_t get_size (void) | const inline virtual function |
Returns points.size() .
|
Line get_line (void) | const function |
Returns a Line corresponding to the Path , if the latter is
linear. Otherwise, INVALID_LINE is returned.
See Line Reference.
|
Point get_normal (void) | const virtual function |
Returns a Point representing a unit vector in the direction of the
normal to the plane of the Path , or INVALID_POINT , if
the Path is non-planar.
Point P(1, 1, 1); Rectangle r(P, 4, 4, 30, 30, 30); Point N = r.get_normal();
In 3DLDF, plane figures generally have constructors taking a |Point|
argument for the center, a variable number of |real| arguments for the
dimensions, and three |real| arguments for the rotation about the major
axes. The object is first created in the x-z plane, and the
|
Plane get_plane (void) | const virtual function |
Creates and returns a Plane p corresponding to the Path ,
if the latter is planar, otherwise INVALID_PLANE .
If the Path is planar, p.point will be the
Point pointed to by this->points[0] .
See Plane Reference.
Point P(1, 1, 1); Rectangle r(P, 4, 4, 45, 20, 15); Plane q = r.get_plane(); q.show("q:"); -| q: normal: (0.0505914, 0.745607, -0.664463) point: (0.0178869, -0.727258, -1.01297) distance == -0.131735
|
void set_cycle ([const bool c = true ])
|
Function |
Sets cycle_switch to c.
|
Path reverse (bool assign) | Function |
Path reverse (void) | const function |
These functions return a Path with the same Points and
connectors as *this , but in reversed order.
reverse() can only be applied to non-cyclical Paths . If
*this is a cycle, reverse() issues an error message and
returns *this unreversed.
If the first version is called with assign = |
bool project (const Focus& f, const unsigned short proj, real factor) | Function |
Calls Point::project( f, proj, factor) on the
Points on the Path .
If Point::project() fails (i.e., returns false ), for any of
the Points , this function
returns false . Otherwise, it returns true .
|
vector<Shape*> extract (const Focus& f, const unsigned short proj, real factor) | Function |
Checks that the Points on points can be projected using
the values for f, proj, and factor. If they can, a
vector<Shape*> containing only this is returned. Called in
Picture::output() .
|
bool set_extremes (void) | Virtual function |
Sets the appropriate elements in projective_extremes to the
minimum and maximum values of the x, y, and z-coordinates of
the Points on the Path . Used in Picture::output()
for determining whether a Path can be output using the arguments
passed to Picture::output() .
|
const valarray<real> get_extremes (void) | Inline const virtual function |
Returns projective_extremes . Used in Picture::output() .
|
real get_minimum_z (void) | const virtual function |
real get_mean_z (void) | const virtual function |
real get_maximum_z (void) | const virtual function |
These functions return the minimum, mean, or maximum value,
respectively, of the
z-coordinates of the Points on the Path .
Used in the surface hiding algorithm in Picture::output() .
|
void suppress_output (void) | Virtual function |
Called in Picture::output() .
Sets do_output to
false , if the Path cannot be output using the arguments
passed to Picture::output() .
|
void unsuppress_output (void) | Virtual function |
Called in Picture::output() . Resets do_output to
true after output() is called on the Shapes on
shapes in a Picture , so that the Path can be output
if Picture::output() is called again, with arguments that allow
the Path to be output.
|
void output (void) | Virtual function |
Called in Picture::output() . Writes the MetaPost code to
out_stream for drawing, filling, filldrawing, undrawing,
unfilling, or unfilldrawing the Path , if the latter was
projectable using the arguments passed to Picture::output() .
|
bool_point intersection_point (const Path& p, const bool trace) | Function |
Finds the intersection point, if any, of two linear Paths .
Let bp be the bool_point returned by
this function. bp.pt will contains the
intersection point, if it exists. If not, it will contain
INVALID_POINT . If the intersection point exists and lies on both
of the line segments represented by the Path and p ,
bp.b will be true , otherwise, false .
This function calls Point A(-1, -1, -1); Point B(1, 1, 1); Path p0(A, B); Point C(-2, 1, 1); Point D(1.75, 0.25, 0.25); Path p1(C, D); bool_point bp = p0.intersection_point(p1); bp.pt.dotlabel("$i$"); bp.pt.show("bp.pt:"); -| bp.pt: (0.5, 0.5, 0.5)
|
Class Polygon
is defined in polygons.web
, and
is derived from Path
, using public derivation.
Polygon
is mainly intended for use as a base class for more
specialized kinds of polygons. Currently, the classes
Reg_Polygon
(regular polygon) and Rectangle
are defined.
See Regular Polygon Reference, and Rectangle Reference.
Point center | Private variable |
The center of the Polygon , if it has one. However, a
Polygon need not have a center . If it doesn't,
center should be set to INVALID_POINT .
|
Transform operator*= (const Transform& t) | Virtual operator |
Multiplies a Polygon by the Transform t.
Similar to Path::operator*=(const Transform& t) , except that
center is transformed as well.
See Path Reference; Operators.
|
const Point& get_center (void) | Virtual function |
Point get_center (void) | const function |
These functions return center . If the Polygon doesn't
contain any Points , a warning is issued, and INVALID_POINT
is returned.
|
Transform rotate (const real x, [const real y = 0, [const real z = 0]]) | Virtual function |
Transform rotate (const Point& p0, const Point& p1, [const real angle = 180]) | Virtual function |
Transform rotate (const Path& p, [const real angle = 180]) | Virtual function |
Transform scale (real x, [real y = 1, [real z = 1]]) | Virtual function |
Transform shear (real xy, [real xz = 0, [real yx = 0, [real yz = 0, [real zx = 0, [real zy = 0]]]]]) | Virtual function |
Transform shift (real x, [real y = 0, [real z = 0]]) | Virtual function |
Transform shift (const Point& p) | Virtual function |
void shift_times (real x, [real y = 1, [real z = 1]]) | Virtual function |
void shift_times (const Point& p) | Virtual function |
The affine transformation functions for Polygon differ from the
Path versions only in that center is transformed as well.
See Path Reference; Affine Transformations.
Please note, that the classes currently derived from |
bool_point_pair intersection_points (const Point& p0, const Point& p1) | const function |
bool_point_pair intersection_points (const Path& p) | const function |
These functions find the intersections of the
Polygon and a line.
In the first version, the Point arguments are the end points of
the line. The argument to the second version must be a linear
Path .
A line and a regular polygon or rectangle43
can intersect at two points at most.
Let When the Point A(1, 1, 1); Reg_Polygon r(origin, 5, 3); Transform t; t.rotate(15, 12, 11); t.shift(A); Point P(-2, 0, -1); Point Q(2, 0, 1); P *= Q *= r *= t; bool_point_pair bpp = r.intersection_points(P, Q); bpp.first.pt.dotlabel("$f$", "rt"); bpp.second.pt.dotlabel("$s$");
In [next figure] , the lines BC and PQ are not coplanar with the Point B(r.get_point(3).mediate(r.get_point(4))); Point C(B); B.shift(0, 2, .5); C.shift(0, -2, -.5); Point P(-1, -2, -1); Point Q(0, 2, 1); B *= C *= P *= Q *= r *= t; bool_point_pair bpp = r.intersection_points(B, C); bpp.first.pt.dotlabel("$i_0$", "rt"); bpp = r.intersection_points(P, Q); bpp.first.pt.dotlabel("$i_1$", "rt");
In [next figure] , the intersection point of r with the line PQ does not lie on the line segment PQ. bpp = r.intersection_points(P, Q); bpp.first.pt.dotlabel("$i$", "rt"); cout << "bpp.first.b == " << bpp.first.b << endl << flush; -| bpp.first.b == 0
|
vector<Point> intersection_points (const Polygon& r) | const function |
Finds the intersection points of two Polygons .
Let v be the vector<Point> returned by
intersection_points() . If the Polygons are coplanar,
v
will contain the intersection points of the edges of the
Polygons , as in [next figure]
.
Rectangle r(origin, 4, 4); Reg_Polygon rp(origin, 5, 5, 0, 36); rp.shift(0, 0, .25); vector <Point> v = r.intersection_points(rp);
If the Point A(1, 1, 1); Rectangle r(A, 4, 4); Reg_Polygon p(A, 5, 5); p.rotate(90, 30); p.shift(2, 0, 3); vector <Point> v = r.intersection_points(p);
In [next figure]
, the Point A(1, 1, 1); Rectangle r(A, 4, 4); Reg_Polygon p(A, 5, 5); p.rotate(90, 30); p.shift(4, 3, 3); vector <Point> v = r.intersection_points(p); int i = 0; for (vector<Point>::iterator iter = v.begin(); iter != v.end(); ++iter) iter->dotlabel(i++, "bot");
|
Class Reg_Polygon
is defined in polygons.web
, and
is derived from Polygon
, using public derivation.
As noted above in Polygon Reference; Affine Transformations, class Reg_Polygon
,
like class Rectangle
,
currently inherits its transformation functions and
operator*=(const Transform&)
from Polygon
. Consequently,
the data members of a Reg_Polygon
, except for center
, are
not recalculated when it's transformed. I plan to change this soon! It
will also be necessary to add the function
Reg_Polygon::is_reg_polygonal()
, in order to test whether a
Reg_Polygon
is still regular and polygonal.
real internal_angle | Private variable |
The angle at the center of the Reg_Polygon of the triangle formed
by the center and two adjacent corners.
If n is the number of sides of a Reg_Polygon ,
internal_angle will be 360.0/n, so internal_angle
will be 120 for a regular triangle, 90 for a square, 72 for a pentagon,
etc.
|
real radius | Private variable |
The radius of the surrounding circle for a Reg_Polygon (Umkreis).
|
unsigned short sides | Private variable |
The number of sides of a Reg_Polygon .
|
bool on_free_store | Private variable |
true , if the Reg_Polygon was dynamically allocated on the
free store, otherwise false . Dynamic allocation of
Reg_Polygons should only be
performed by create_new<Reg_Polygon>() , which sets
on_free_store to true .
|
void Reg_Polygon (void) | Default constructor |
Creates an empty Reg_Polygon .
|
void Reg_Polygon (const Point& ccenter, const unsigned short ssides, const real ddiameter, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0]]]) | Constructor |
Creates a Reg_Polygon in the x-z plane, centered at the origin,
with the number of sides specified by ssides and with
radius = ddiameter / 2.
The Reg_Polygon r(origin, 3, 2.75, 10, 15, 12.5); r.draw();
|
void set (const Point& ccenter, const unsigned short ssides, const real ddiameter, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0]]]) | Setting function |
Corresponds to the constructor above.
A Reg_Polygon r; real j = .5; for (int i = 3; i <= 16; ++i) { r.set(origin, i, j); r.draw(); j += .5; }
|
Reg_Polygon* create_new<Reg_Polygon> (const Reg_Polygon* r) | Template specializations |
Reg_Polygon* create_new<Reg_Polygon> (const Reg_Polygon& r) |
Pseudo-constructors for dynamic allocation of Reg_Polygons .
They create a Reg_Polygon on the free store and allocate memory for it using
new(Reg_Polygon) . They return a pointer to the new Reg_Polygon .
If r is a non-zero pointer or a reference,
the new Reg_Polygon will be a copy of
r. If the new object is not meant to be a
copy of an existing one, 0 must be passed to
create_new<Reg_Polygon>() as its argument.
See Dynamic Allocation of Shapes, for more information.
|
const Reg_Polygon& operator= (const Reg_Polygon& p) | Operator |
Makes the Reg_Polygon a copy of p.
|
real get_radius (void) | const inline function |
Returns radius .
|
Circle in_circle (void) | const function |
Returns the enclosed Circle of the Reg_Polygon .
Point P(0, -1, 1); Reg_Polygon h(P, 6, 4, 15, 12, 11.5); h.filldraw(black, gray); Circle c = h.in_circle(); c.unfilldraw(black);
|
Circle draw_in_circle ([const Color& ddraw_color = *Colors::default_color , [const string ddashed = "", [const string] ppen = "", [Picture& picture = current_picture ]]])
|
const function |
Circle draw_in_circle ([Picture& picture = current_picture , [const Color& ddraw_color = *Colors::default_color , [const string ddashed = "", [const string] ppen = ""]]])
|
const function |
Draws and returns the enclosed Circle of the Reg_Polygon .
Point P(0, 1, 1); Reg_Polygon h(P, 7, 4, 80, 2, 5); h.draw(black, "evenly"); h.draw_in_circle();
|
Circle out_circle (void) | const function |
Returns the surrounding Circle of the Reg_Polygon .
Point P(0, -1, 1); Reg_Polygon h(P, 6, 4, 15, 12, 11.5); Circle c = h.out_circle(); c.filldraw(black, gray); h.unfilldraw(black);
|
Circle draw_out_circle ([const Color& ddraw_color = *Colors::default_color , [const string ddashed = "", [const string] ppen = "", [Picture& picture = current_picture ]]])
|
const function |
Circle draw_out_circle ([Picture& picture = current_picture , [const Color& ddraw_color = *Colors::default_color , [const string ddashed = "", [const string] ppen = ""]]])
|
const function |
Draws and returns the surrounding Circle of the Reg_Polygon .
Point P(0, 1, 1); Reg_Polygon h(P, 7, 4, 80, 2, 5); h.draw(black, "evenly"); h.draw_out_circle();
|
Class Rectangle
is defined in rectangs.web
, and
is derived from Polygon
, using public derivation.
As noted above in Polygon Reference; Affine Transformations, class Rectangle
,
like class Reg_Polygon
,
currently inherits its transformation functions and
operator*=(const Transform&)
from Polygon
. Consequently,
the data members of a Rectangle
, except for center
, are
not recalculated when it's transformed. I plan to change this soon! It
will also be necessary to add the function
Rectangle::is_rectangular()
, in order to test whether a
Rectangle
is still rectangular.
real axis_h | Private variables |
real axis_v |
The lengths of the horizontal and vertical axes, respectively, of the
Rectangle . Actually,
they are merely the horizontal and vertical axes by convention, since
there are no restrictions on the orientation of an Rectangle .
Please note that |
bool on_free_store | Private variable |
true , if the Rectangle was dynamically allocated on the
free store, otherwise false . Dynamic allocation of
Rectangles should only be
performed by create_new<Rectangle>() , which sets
on_free_store to true .
|
void Rectangle (void) | Default constructor |
Creates an empty Rectangle .
|
void Rectangle (const Point& ccenter, const real aaxis_h, const real aaxis_v, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0]]]) | Constructor |
Creates a Rectangle in the x-z plane, centered at the origin,
with width == aaxis_h
(in the + or - x
direction),
and height == aaxis_v
(in the
+ or - z
direction).
If one or more of the arguments
angle_x, angle_y, or angle_z are used, it is rotated
by those amounts around the appropriate axes.
Finally, the Rectangle is shifted such that
its center lies at ccenter.
Point C(-1, -1, 1); Rectangle r(C, 3, 4, 30, 30, 30);
|
void set (const Point& ccenter, const real aaxis_h, const real aaxis_v, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0]]]) | Setting function |
Corresponds to the constructor described above. |
void Rectangle (const Point& p0, const Point& p1, const Point& p2, const Point& p3) | Constructor |
Creates Rectangle using four Point
arguments. The order of the arguments must correspond with a path
around the Rectangle .
This function does not currently check that the arguments yield a valid
|
void set (const Point& pt0, const Point& pt1, const Point& pt2, const Point& pt3) | Setting function |
Corresponds to the constructor above. |
Rectangle* create_new<Rectangle> (const Rectangle* r) | Template specializations |
Rectangle* create_new<Rectangle> (const Rectangle& r) |
Pseudo-constructors for dynamic allocation of Rectangles .
They create a Rectangle on the free store and allocate memory for it using
new(Rectangle) . They return a pointer to the new Rectangle .
If r is a non-zero pointer or a reference,
the new |
const Rectangle& operator= (const Rectangle& r) | Assignment Operator |
Makes the Rectangle a copy of r.
|
Point corner (unsigned short c) | Function |
Returns the corner Point indicated by the argument c, which must be
between 0 and 3.
|
Point mid_point (unsigned short m) | const function |
Returns the mid-point of one of the sides. The argument c must be between 0 and 3. |
real get_axis_h (void) | const functions |
real get_axis_v (void) |
These functions return axis_h and axis_v , respectively.
Please note, that |
bool is_rectangular (void) | const function |
Returns true , if the Rectangle is rectangular, otherwise
false . Transformations, such as shearing, can cause
Rectangles to become non-rectangular.
|
Ellipse out_ellipse (void )
|
const function |
Returns the smallest Ellipse that surrounds the Rectangle .
Point P(-1, -1, 3); Rectangle r(P, 3, 4, 60, 30, 15); Ellipse e = r.out_ellipse(); e.filldraw(black, gray); r.unfilldraw(black);
|
Ellipse in_ellipse (void )
|
const function |
Returns the Ellipse enclosed by the Rectangle .
Point P(-1, -1, 3); Rectangle r(P, 3, 4, 60, 30, 15); Ellipse e = r.in_ellipse(); r.filldraw(black, gray); e.unfilldraw(black);
|
Ellipse draw_out_ellipse ([const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]]])
|
const function |
Draws the smallest Ellipse that surrounds the Rectangle .
The arguments are like those of Path::draw()
(see Path Reference; Drawing and Filling).
The return value is the surrounding Ellipse .
|
Ellipse draw_in_ellipse ([const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]]])
|
const function |
Draws the Ellipse enclosed by the Rectangle .
The arguments are like those of Path::draw()
(see Path Reference; Drawing and Filling).
The return value is the enclosed Ellipse .
|
Class Reg_Cl_Plane_Curve
is defined in curves.web
.
It is derived from Path
using public
derivation.
Reg_Cl_Plane_Curve
is not called
"Regular_Closed_Plane_Curve
" because the longer name
causes too many "Overfull boxes"44
in the CWEAVE output of the program code.
See CWEB Documentation.
Reg_Cl_Plane_Curve
is meant to be used as a base class; no
objects should be declared of type Reg_Cl_Plane_Curve
.
Currently, class Ellipses
is derived from
Reg_Cl_Plane_Curve
and class Circle
is derived from
Ellipse
.
At present, I have no fixed definition of what constitutes
"regularity" as far as Reg_Cl_Plane_Curves
are concerned.
Ellipses and circles are "regular" in the sense that they have axes of
symmetry. There must be an equation for a Reg_Cl_Plane_Curve
,
such as
x^2 + y^2 = r^2
for a circle.
A derived class should have a solve()
function that uses this
equation. Reg_Cl_Plane_Curve::intersection_points()
in turn uses
solve()
to find the intersection points of a line with the
Reg_Cl_Plane_Curve
. This way, the derived classes don't need
their own functions for finding their intersections with a line.
However, such functions can be added, if desired.
It is assumed that classes derived from Reg_Cl_Plane_Curve
are
fillable, which implies that they must be closed Paths
.
Reg_Cl_Plane_Curves
inherit their drawing and filling functions
from Path
.
The constructors and setting functions of classes derived from
Reg_Cl_Plane_Curve
must ensure that the resulting geometric
figures are planar, convex, and that the number of Points
they contain is
a multiple of 4. The latter assumption is of importance in
intersection_points()
, segment()
, half()
, and
quarter()
.
See Regular Closed Plane Curve Reference; Intersections, and
Regular Closed Plane Curve Reference; Segments.
Point center | Protected variable |
The center of the Reg_Cl_Plane_Curve , if it has one.
|
unsigned short number_of_points | Protected variable |
The number of Points on points in a
Reg_Cl_Plane_Curve .
|
bool is_quadratic (void) | const inline virtual functions |
bool is_cubic (void) | |
bool is_quartic (void) |
These functions all return false . They are intended to be
overloaded by member functions of derived classes.
|
real_triple get_coefficients (real Slope, real v_intercept) | const inline virtual function |
Returns a real_triple with all three values ==
INVALID_REAL . Intended to be overloaded by member functions of
derived classes.
|
pair<real, real> solve (char axis_unknown, real known) | const inline virtual function |
Returns a pair<real, real> with first =
second = INVALID_REAL .
Intended to be overloaded by member functions of
derived classes.
|
signed short location (Point ref_pt, Point p) | const virtual function |
Returns a signed short indicating the location of p with
respect to the Reg_Cl_Plane_Curve , which must be planar.
The Reg_Cl_Plane_Curve constructors should ensure that
Reg_Cl_Plane_Curves are, but there is no guarantee that they will
not have been manipulated into a non-planar state, by shearing, for
example.
The argument ref_pt is used within the function for
shifting a copy of the
|
Point angle_point (real angle) | Virtual function |
Returns INVALID_POINT . Intended to be overloaded by member functions of
derived classes.
|
bool_point_pair intersection_points (Point ref_pt, Point p0, Point p1) | const function |
bool_point_pair intersection_points (const Point& ref_pt, const Path& p) | const function |
The version of this function taking Point arguments finds the
intersection points, if any, of the
Reg_Cl_Plane_Curve and the line
p
that passes through the Points
p_0
and
p_1.
In the other version, the Path argument must be a linear
Path , and its first and last Points are passed to the
first version of this function as p0 and p1, respectively.
Let
C
be the In [next figure]
, the line AB
is normal to the
The line DE is skew to the plane of e, and intersects e at i_1, on the perimeter of e. Point p0(2, 2, 3); Ellipse e(p0, 3, 4, 30, -60, -5.2); Point p1 = p0.mediate(e.get_point(11), .5); Point A = e.get_normal(); A *= 2.5; A.shift(p1); Point B = A.mediate(p1, 2); bool_point_pair bpp = e.intersection_points(A, B); Point C(0, 2, 0); Point D(0, -3.5, 0); C *= D.rotate(2, 0, -5); C *= D.shift(e.get_point(4)); bpp = e.intersection_points(C, D);
In [next figure]
, q and e are coplanar. In this case,
only the intersections of q with the perimeter of e are returned by
A = p0.mediate(e.get_point(3), 1.5); B = p0.mediate(e.get_point(11), 1.5); Path q(A, B); bpp = e.intersection_points(q);
|
Path segment (unsigned int factor, [real angle = 0, [bool closed = true ]])
|
const function |
Returns a Path representing a segment of the Reg_Cl_Plane_Curve .
factor must be
>1 and <= number_of_points . If it is not, an error message is
issued and an empty Path is returned.
If angle is non-zero, the segment If closed is Circle c(origin, 4, 30, 30, 30); Path p = c.segment(3, 130); p.show("p:"); -| p: points.size() == 8 connectors.size() == 8(-0.00662541, -0.888379, -1.79185) .. (0.741088, -0.673392, -1.73128) .. (1.37598, -0.355887, -1.40714) .. (1.80139, 0.0157987, -0.868767) .. (1.95255, 0.385079, -0.198137) .. (1.80646, 0.695735, 0.502658) & (1.80646, 0.695735, 0.502658) -- (-0.00662541, -0.888379, -1.79185) & cycle;
|
Path half ([real angle = 0, [bool closed = true]]) | const inline function |
Returns a Path using half of the Points on the
Reg_Cl_Plane_Curve .
The effect of the arguments angle and closed is similar to
that in segment() , above.
Ellipse e(origin, 3, 5, 20, 15, 12.5); Path p = e.half(0, false);
|
Path quarter ([real angle = 0, [bool closed = true ]])
|
const inline function |
Returns a Path using a quarter of the Points on the
Reg_Cl_Plane_Curve .
The effect of the arguments angle and closed is similar to
that in segment() , above.
Ellipse e(origin, 3, 5, 60, 5, 2.5); Path p = e.quarter(180, false);
|
Class Ellipse
is defined in ellipses.web
.
It is derived from Reg_Cl_Plane_Curve
using public derivation.
Point focus0 | Protected variables |
Point focus1 |
The foci of the Ellipse . They are located on the major axis of
the Ellipse at a distance of linear_eccentricity from
center , on opposite sides of the minor axis.
|
real linear_eccentricity | Protected variable |
The linear eccentricity of the Ellipse e, such that
e = \sqrta^2 - b^2,
where a and b are half the lengths of the major
and minor axes, respectively. Let h stand for axis_h and v
for axis_v . If h>v, then a = h/2 and b = v/2. If v>h,
then a =v/2 and b = h/2. If h = v, then the Ellipse is
circular (but not an object of type Circle !), and a = b = v/2 = h/2.
The linear eccentricity is the distance along the major axis of the
|
real numerical_eccentricity | Protected variable |
The numerical eccentricity \epsilon of the Ellipse ,
such
that \epsilon = e/a < 1, where e is the linear eccentricity of the
Ellipse , and a is half the length of the major axis of the
Ellipse .
|
real axis_h | Protected variables |
real axis_v |
The horizontal and vertical axes, respectively, of the Ellipse .
Actually, they are only or vertical
horizontal by convention, since there are no restrictions on the
orientation of an |
unsigned short DEFAULT_NUMBER_OF_POINTS | Protected static variable |
The number of Points on an Ellipse , unless another number
is specified when an Ellipse constructor is invoked.
|
void Ellipse (void) | Default constructor |
Creates an empty Ellipse .
|
void Ellipse (const Point& ccenter, const real aaxis_h, const real aaxis_v, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0, [const unsigned short nnumber_of_points = DEFAULT_NUMBER_OF_POINTS]]]]) | Constructor |
Creates an Ellipse in the x-z plane, centered at the origin, with
its horizontal axis
== aaxis_h and its vertical axis == aaxis_v. If
any of the arguments angle_x, angle_y, or angle_z is
non-zero, the Ellipse is rotated about the x, y, and z-axis in
that order, by the amounts indicated by the corresponding arguments.
Finally, the Ellipse is shifted such that its
center comes to lie at ccenter.
Ellipse e(origin, 6, 4); e.draw();
Point P(1, 1, 1); Ellipse e(P, 6, 4, 15, 12, 11); e.draw();
|
void set (const Point& ccenter, const real aaxis_h, const real aaxis_v, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0, [const unsigned short nnumber_of_points = DEFAULT_NUMBER_OF_POINTS]]]]) | Setting function |
Corresponds to the constructor above. |
Ellipse* create_new<Ellipse> (const Ellipse* e) | Template specializations |
Ellipse* create_new<Ellipse> (const Ellipse& e) |
Pseudo-constructors for dynamic allocation of Ellipses .
They create a Ellipse on the free store and allocate memory for it using
new(Ellipse) . They return a pointer to the new Ellipse .
If e is a non-zero pointer or a reference,
the new |
Transform do_transform (const Transform& t, [bool check = false ])
|
Virtual function |
Performs a transformation on an Ellipse . The Points on
the Ellipse are multiplied by t.
Then, if check is true ,
is_elliptical() is called on the Ellipse .
If the transformation has caused it to
become non-elliptical, axis_h and axis_v are set to
INVALID_REAL , and a warning is issued to stderr .
center , focus0 , and focus1 are not set to
INVALID_POINT . They may may no longer really be
the center and foci of the (non-elliptical) Ellipse , but they may
have some use for the programmer and/or user.
If check is |
Ellipse& operator= (const Ellipse& e) | Assignment operator |
Makes the Ellipse a copy of e.
|
Transform operator*= (const Transform& t) | Virtual function |
Calls do_transform(t, true) , and returns the latter's return
value.
See Ellipse Reference; Performing Transformations.
|
void label ([const string pos = "top", [const bool dot = false , [Picture& picture = current_picture ]]])
|
const function |
Labels the Points on points , using lowercase letters.
pos is used to position all of the labels. It is currently not
possible to have different positions for the labels.
Ellipse e(origin, 6, 4); e.draw(); e.label();
|
void dotlabel ([string pos = "top", [Picture& picture = current_picture ]])
|
Inline const function |
Like label() , except that the Points are dotted.
Ellipse e(origin, 6, 4); e.draw(); e.dotlabel();
|
Transform rotate (const real x, [const real y = 0, [const real z = 0]]) | Virtual function |
Transform rotate (const Point& p0, const Point& p1, [const real angle = 180]) | Virtual function |
Transform rotate (const Path& p, [const real angle = 180]) | Virtual function |
Transform scale (real x, [real y = 1, [real z = 1]]) | Virtual function |
Transform shear (real xy, [real xz = 0, [real yx = 0, [real yz = 0, [real zx = 0, [real zy = 0]]]]]) | Virtual function |
Transform shift (real x, [real y = 0, [real z = 0]]) | Virtual function |
Transform shift (const Point& p) | Virtual function |
void shift_times (real x, [real y = 1, [real z = 1]]) | Virtual function |
void shift_times (const Point& p) | Virtual function |
These create a Transform t locally, and call
do_transform(t) .
See Ellipse Reference; Performing Transformations.
Rotating and shifting an If scaling or shearing is performed on an |
bool is_elliptical (void) | const function |
Returns true if the Ellipse is elliptical, otherwise
false .
Certain transformations, such as shearing and scaling, can cause
|
bool is_quadratic (void )
|
Inline const function |
Returns true , because the equation
for an ellipse in the x-y plane with its center at the
origin is the quadratic equation
x^2/a^2 + y^2/b^2 = 1
where a is half the horizontal axis
and b is half the vertical axis.
Ellipse e(origin, 5, 2, 90); e.draw(); Point P(e.angle_point(-35)); cout << ((P.get_x() * P.get_x()) / (e.get_axis_h()/2 * e.get_axis_h()/2)) + ((P.get_y() * P.get_y()) / (e.get_axis_v()/2 * e.get_axis_v()/2)); -| 1
|
bool is_cubic (void )
|
const virtual functions |
bool is_quartic (void )
|
These functions both return false , because the equation of an
ellipse is neither a cubic nor a quartic function.
|
Point& get_center (void )
|
Virtual function |
Point get_center (void )
|
const virtual function |
These functions return center .
|
const Point& get_focus (const unsigned short s) | Function |
Point get_focus (const unsigned short s) | const function |
These functions return focus0 or focus1 , depending on the
value of s, which must be 0 or 1. If s is not 0 or 1,
get_focus() returns INVALID_POINT .
|
real get_linear_eccentricity (void) | const function |
Returns linear_eccentricity .
|
real get_numerical_eccentricity (void) | const function |
Returns numerical_eccentricity .
|
real get_axis_v (void )
|
Function |
real get_axis_v (void )
|
const function |
Calculates and returns the value of axis_h .
If the |
real get_axis_h (void )
|
Function |
real get_axis_h (void )
|
const function |
Calculates and returns the value of axis_h .
If the |
signed short location (Point p) | const virtual function |
Returns a value l indicating the location of the Point argument
p with respect to the Ellipse .
Let e stand for the
Ellipse e(origin, 3, 5, 45, 15, 3); e.shift(2, 1, 1); Point A = e.get_point(7); cout << e.location(A); -| 0 Point B = center.mediate(e.get_point(2)); cout << e.location(B); -| 1 Point C = center.mediate(e.get_point(2), 1.5); cout << e.location(C); -| -1 Point D = A; D.shift(-2, 0, 4); e.location(D); -| WARNING! In Ellipse::location(): Point doesn't lie in plane of Ellipse. Returning -2. e.scale(1.5, 0, 1.5); e.location(A); -| WARNING! In Ellipse::do_transform(const Transform&): This transformation has made *this non-elliptical! ERROR! In Ellipse::location(): Ellipse is non-elliptical. Returning -3.
|
Point angle_point (real angle) | const function |
Returns a point on the Ellipse given an angle.
A Point p is set to the zeroth Point on the Ellipse
and rotated about the line from the center of the Ellipse in the
direction of the normal to the plane of the Ellipse .
Then, the intersection of the ray from the center through
p and the perimeter of the Ellipse is returned.
Ellipse e(origin, 6, 4); Point P = e.angle_point(135); current_picture.output(Projections::PARALLEL_X_Z);
[next figure] demonstrates, that the rotation is unfortunately not always in the direction one would prefer. I don't have a solution to this problem yet. Ellipse e(origin, 6, 4, 90); Point P = e.angle_point(135); Point Q = e.angle_point(-135);
|
bool_point_pair intersection_points (const Point& p0, const Point& p1) | const virtual function |
bool_point_pair intersection_points (const Path& p) | const virtual function |
These functions return the intersection points of a line with an
Ellipse . In the first version, the line is specified by the two
Point arguments.
In the second version, p.is_linear() must return true ,
otherwise, intersection_points() issues an error message and
returns INVALID_BOOL_POINT_PAIR .
If the line and the Ellipse e(origin, 5, 7, 30, 30, 30); e.shift(3, 0, 3); Point p0 = e.get_center().mediate(e.get_point(3)); Point normal = e.get_normal(); Point A = normal; A *= 2.5; A.shift(p0); Point B = normal; B *= -2.5; B.shift(p0); bool_point_pair bpp = e.intersection_points(A, B); bpp.first.pt.dotlabel("$i_0$", "rt"); Point C = e.get_point(15).mediate(e.get_point(11), 1.25); Point D = e.get_point(11).mediate(e.get_point(15), 1.5); Path q = C.draw(D); bpp = e.intersection_points(q); bpp.first.pt.dotlabel("$i_1$", "llft"); bpp.second.pt.dotlabel("$i_2$", "ulft");
|
bool_point_quadruple intersection_points (Ellipse e, [const real step = 3, [bool verbose = false ]])
|
const virtual function |
Returns the intersection points of two Ellipses . Two Ellipses
can intersect at at most four points.
Let bpq be the The step argument is used when the If the verbose argument is In [next figure]
, the Ellipse e(origin, 5, 2); Ellipse f(origin, 2, 5); bool_point_quadruple bpq = e.intersection_points(f); bpq.first.pt.dotlabel(1, "llft"); bpq.second.pt.dotlabel(2, "urt"); bpq.third.pt.dotlabel(3, "ulft"); bpq.fourth.pt.dotlabel(4, "lrt");
In [next figure] , e and f are coplanar, but don't lie in a major plane, have different centers, and only intersect at two points. Ellipse e(origin, 4, 2); Ellipse f(origin, 2, 5); f.shift(0, 0, 1); f.rotate(0, 15); f.shift(1, 0, 1); e *= f.shift(-.25, 1, -1); e *= f.rotate(10, -12.5, 3); bool_point_quadruple bpq = e.intersection_points(f, true); bpq.first.pt.dotlabel(1, "urt"); bpq.second.pt.dotlabel(2, "ulft");
If the planes of the In [next figure]
, the two Ellipse e(origin, 5, 3); Ellipse f(origin, 2, 5); f.rotate(0, 0, 30); f.rotate(0, 10); f.rotate(45); f.shift(1.5, 1); bool_point_quadruple bpq = e.intersection_points(f, true); bpq.first.pt.dotlabel(1); bpq.second.pt.dotlabel(2); bpq.third.pt.dotlabel(3, "rt"); bpq.fourth.pt.dotlabel(4, "urt"); -| First point lies on the perimeter of *this. First point lies inside e. Second point lies on the perimeter of *this. Second point lies outside e. Third point lies outside *this. Third point lies on the perimeter of e. Fourth point lies inside *this. Fourth point lies on the perimeter of e.
In [next figure]
, the two Ellipse e(origin, 5, 3); Ellipse f(origin, 2, 5, 45); f.shift(0, 2.5, 3); bool_point_quadruple bpq = e.intersection_points(f, true); bpq.first.pt.dotlabel(1); bpq.second.pt.dotlabel(2); -| First point lies on the perimeter of *this. First point lies outside e. Second point lies on the perimeter of *this. Second point lies outside e. Third intersection point is INVALID_POINT. Fourth intersection point is INVALID_POINT.
|
real_pair solve (char axis_unknown, real known) | const function |
Returns two possible values for either the horizontal or vertical
coordinate. This function assumes that the Ellipse lies in a major
plane with center at the origin. Code that calls it must ensure
that these conditions are fulfilled.
|
real_triple get_coefficients (real Slope, real v_intercept) | const function |
Let x and y stand for the x and y-coordinates of a point on an
ellipse in the x-y plane, a for half of the horizontal axis
( Further, let y = mx + i be the equation of a line in the x-y plane, where m is the slope and i the y-intercept. This function returns the coefficients of the quadratic equation that results from replacing y with mx + i in the equation for the ellipse x^2/a^2 + y^2/b^2 = 1namely x^2/a^2 + (mx + i)^2/b^2 - 1 = 0 == (b^2x + a^2m^2)x^2 + 2a^2imx + (a^2i^2 - a^2b^2) = 0.The coefficients are returned in the real_triple in the order
one would expect: r.first is the coefficient of x^2, r.second of
x and r.third of the constant term
(x^0 == 1).
|
Rectangle out_rectangle (void )
|
const function |
Returns the Rectangle that surrounds the Ellipse .
Ellipse e(origin, 3, 4, 45, 30, 17); e.shift(1, -1, 2); Rectangle r = e.out_rectangle(); r.filldraw(black, gray); e.unfilldraw(black);
|
Rectangle in_rectangle (void )
|
const function |
Returns the Rectangle enclosed within the Ellipse .
Rectangle r = e.in_rectangle(); e.filldraw(black, gray); r.unfilldraw(black);
|
Rectangle draw_out_rectangle ([const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]]])
|
const function |
Draws the Rectangle that surrounds the Ellipse . The arguments
are like those of Path::draw() .
The return value is the surrounding Rectangle .
See Path Reference; Drawing and Filling.
Ellipse e(origin, 2.5, 5, 10, 12, 15.5); e.shift(-1, 1, 1); e.draw_out_rectangle(black, "evenly", "pencircle scaled .3mm");
|
Rectangle draw_in_rectangle ([const Color& ddraw_color = *Colors::default_color , [string ddashed = "", [string ppen = "", [Picture& picture = current_picture ]]]])
|
const function |
Draws the Rectangle enclosed within the Ellipse . The arguments
are like those of Path::draw() .
The return value is the enclosed Rectangle .
See Path Reference; Drawing and Filling.
Ellipse e(origin, 3.5, 6, 10, 12, 15.5); e.shift(-1, 1, 1); e.draw_in_rectangle(black, "evenly", "pencircle scaled .3mm");
|
Class Circle
is defined in circles.web
.
It is derived from Ellipse
, using public derivation.
Since Circle
is just a special kind of Ellipse
, there is
often no need to define special functions for Circles
.
Currently, Circle
inherits the transformation functions and
operator*=(const Transform&)
from Ellipse
. Consequently,
the data member radius
, described below,
is not recalculated, when transformations
are performed on a Circle
. I plan to change this soon!
real radius | Private variable |
The radius of the Circle .
|
void Circle (void )
|
Default constructor |
Creates an empty Circle .
|
void Circle (const Point& ccenter, const real ddiameter, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0, [const unsigned short nnumber_of_points = DEFAULT_NUMBER_OF_POINTS ]]]])
|
Constructor |
Creates a Circle with radius ==
ddiameter/2 in the x-z plane and centered at the origin
with nnumber_of_points Points . If any of the arguments
angle_x, angle_y, or angle_z is
!= 0 ,
the Circle is rotated around the major axes by the angles
indicated by the arguments. Finally, the
Circle is shifted such that center comes to lie at
ccenter.
|
void set (const Point& ccenter, const real ddiameter, [const real angle_x = 0, [const real angle_y = 0, [const real angle_z = 0]]]) | Setting function |
Corresponds to the constructor above. |
Circle* create_new<Circle> (const Circle* c) | Template specializations |
Circle* create_new<Circle> (const Circle& c) |
Pseudo-constructors for dynamic allocation of Circles .
They create a Circle on the free store and allocate memory for it using
new(Circle) . They return a pointer to the new Circle .
If c is a non-zero pointer or a reference,
the new |
Circle& operator= (const Circle& c) | Assignment operator |
Makes the Circle a copy of c.
|
Circle& operator= (const Ellipse& e) | Assignment operator |
Makes the Circle a copy of e, if e is circular.
radius is set to e.axis_v / 2 and
*this is returned.
If e is not circular, this function issues an error message and returns |
bool is_circular (void) | const function |
Returns true if the Circle is circular, otherwise
false .
Certain transformations, such as shearing and scaling, can cause
Circle c(origin, 3, 90); cout << c.is_circular(); -| 1 Circle d = c; d.shift(2.5); d.scale(2, 3); cout << d.is_circular(); -| 0
|
real get_radius (void )
|
Inline function |
Returns radius .
|
real get_diameter (void )
|
Inline function |
Returns
2 * radius .
|
bool_point_quadruple intersection_points (const Circle& c, [const bool verbose = false ])
|
Virtual const function |
Returns the intersection points of two Circles .
If the If the Circle t(origin, 5, 90); Circle c(origin, 3, 90); c.shift(3); c.rotate(0, 0, 45); bool_point_quadruple bpq = t.intersection_points(c); bpq.first.pt.dotlabel("$f$"); bpq.second.pt.dotlabel("$s$");
|
There is no currently no class "Pattern
".
If it turns out to be
useful for this purpose, I will define a Pattern
class, and
perhaps additional derived classes.
3DLDF can be used to make perspective projections of plane tesselations and other two-dimensional patterns. These can be used for drawing tiled floors and other architectural items, among other things. While patterns can be generated by using the basic facilities of C++ and 3DLDF without any specially defined functions, it can be useful to define such functions.
3DLDF currently contains only one function for drawing patterns based on a plane tessellation. I plan to add more soon.
unsigned int hex_pattern_1 ([real diameter_outer = 5, [real diameter_middle = 0, [real diameter_inner = 0, [unsigned short first_row = 5, [unsigned short double_rows = 10, [unsigned short row_shift = 2, [Color draw_color_outer = *Colors::default_color , [Color fill_color_outer = *Colors::background_color , [Color draw_color_middle = *Colors::default_color , [Color fill_color_middle = *Colors::background_color , [Color draw_color_inner = *Colors::default_color , [Color fill_color_inner = *Colors::background_color , [string pen_outer = "pencircle scaled .5mm", [string pen_middle = "pencircle scaled .3mm", [string pen_inner = "pencircle scaled .3mm", [Picture& picture = current_picture , [unsigned int max_hexagons = 1000]]]]]]]]]]]]]]]]])
|
Function |
Draws a pattern consisting of hexagons forming a tesselation of the x-z
plane, with additional hexagons within them.
The arguments:
Draws a pattern in the x-z plane consisting of hexagons. The outer
hexagons form a tessellation. The middle and inner hexagons fit
within the outer hexagons. The hexagons are drawn in double rows.
The tessellation can be repeated by copying a
double row and shifting the copy to lie directly behind the first double
row. If the The return value of this function is the number of hexagons drawn. default_focus.set(0, 10, -10, 0, 10, 25, 10); hex_pattern_1(1, 0, 0, 5, 5);
default_focus.set(-5, 5, -10, 0, 10, 25, 10); hex_pattern_1(2, 1.5, 1, 2, 5, 2, black, gray, black, light_gray, black);
|
"A roulette is the curve generated by a point which is carried by a curve which rolls on a fixed curve. [...] The locus of a point carried by a circle rolling on a straight line is a trochoid. If the point is inside the circle the trochoid has inflexions; if it is outside the circle, but rigidly attached to it, the trochoid has loops. [...] In the particular case when the point is on the circumference of the rolling circle the roulette is a cycloid. When the circle rolls on the outside of another circle the corresponding curves are the epitrochoids and epicycloids; if it rolls on the inside, they are the hypotrochoids and hypocycloids."H. Martyn Cundy and A. P. Rollett, Mathematical Models, p. 46.
unsigned int epicycloid_pattern_1 (real diameter_inner, real diameter_outer_start, real diameter_outer_end, real step, int arc_divisions, unsigned int offsets, [vectorColors::default_color_vector ])
|
Function |
Draws a pattern consisting of epicycloids. The outer circle rolls
around the circumference of the inner circle and a Point on the
outer circle traces an epicycloid.
If offsets is greater than 1, the outer circle is rotated offset times around the center of the inner circle by 360 / offsets (starting from the outer circle's original position). From each of these new positions, an epicycloid is drawn. While diameter_outer_start is
greater than or equal to diameter_outer_end, the diameter of the
outer circle is reduced by step, and another set of epicycloids is
traced, as described above. Each time the diameter of
the outer circle is reduced, a new The arguments:
Example: epicycloid_pattern_1(5, 3, 3, 1, 72); current_picture.output(Projections::PARALLEL_X_Z);
Example: default_focus.set(2, 5, -10, 2, 5, 10, 10); epicycloid_pattern_1(5, 3, 3, 1, 36); current_picture.output();
|
Class Solid
is defined in solids.web
.
It's derived from Shape
using public derivation. It is intended
to be used as a base class for
more specialized classes representing solid figures, e.g., cuboids,
polyhedra, solids of rotation, etc.
bool on_free_store | Protected variable |
true , if the Solid was dynamically allocated on the free
store, otherwise false . Solids should only be allocated
on the free store by create_new<Solid>() , or analogous functions
for derived classes.
See Solid Reference; Constructors and Setting Functions.
|
Point center | Protected variable |
The center of the Solid . An object of a type derived from
Solid need not have a meaningful center . However, many
do, so it's convenient to be able to access it using the member
functions of Solid .
|
bool do_output | Protected variable |
Set to false in Picture::output() , if the Solid
cannot be projected using the arguments of that particular invocation of
output() . Reset to true at the end of
Picture::output() , so that the Solid will be tested for
projectability again, if output() is called on the
Picture again.
|
vector<Path*> paths | Protected variables |
vector<Circle*> circles | |
vector<Ellipse*> ellipses | |
vector <Reg_Polygon*> reg_polygons | |
vector<Rectangle*> rectangles |
Vectors of pointers to the Paths , Circles ,
Ellipses , Reg_Polygons , and Rectangles ,
respectively, belonging to the Solid , if any exist.
|
valarray<real> projective_extremes | Protected variable |
The maximum and minimum values for the x, y, and z-coordinates of the
Points belonging to the Solid . Used in
Picture::output() for testing whether a Solid is
projectable using a particular set of arguments.
|
unsigned short CIRCLE | Public static const variables |
unsigned short ELLIPSE | |
unsigned short PATH | |
unsigned short RECTANGLE | |
unsigned short REG_POLYGON |
Used as arguments in the functions get_shape_ptr() and
get_shape_center()
(see Returning Elements and Information).
|
void Solid (void )
|
Default constructor |
Creates an empty Solid .
|
void Solid (const Solid& s)
|
Copy constructor |
Creates a new Solid and makes it a copy of s.
|
Solid* create_new<Solid> (const Solid* s) | Template specializations |
Solid* create_new<Solid> (const Solid& s) |
Pseudo-constructors for dynamic allocation of Solids .
They create a Solid on the free store and allocate memory for it using
new(Solid) . They return a pointer to the new Solid .
If s is a non-zero pointer or a reference,
the new |
void ~Solid (void )
|
virtual Destructor |
This function currently has an empty definition, but its existence prevents GCC 3.3 from issuing the following warning: "`class Solid' has virtual functions but non-virtual destructor". |
const Solid& operator= (const Solid& s) | Virtual function |
Assignment operator. Makes *this a copy of s, discarding
the old contents of *this .
|
Transform operator*= (const Transform& t) | Virtual function |
Multiplication by a Transform . All of the Shapes that
make up the Solid are transformed by t.
|
Shape* get_copy (void )
|
const virtual function |
Dynamically allocates a new Solid on the free store, using
create_new<Solid>() , and makes it a copy of *this . Then, a
pointer to Shape is pointed at the copy and returned. Used for
putting Solids onto Picture::shapes in the drawing and
filling functions for Solid .
See Solid Reference; Drawing and Filling.
|
bool set_on_free_store ([bool b = true ])
|
Virtual function |
Sets on_free_store to b. This function is
called in the template function
create_new() .
See Solid Reference; Constructors and Setting Functions.
|
bool is_on_free_store (void )
|
const virtual function |
Returns the value of on_free_store ; true , if the
Solid was dynamically allocated on the free store, otherwise
false .
Solids , and objects of classes derived from Solid ,
should only ever be allocated on the free store by
a specialization of the template function create_new() .
See Solid Reference; Constructors and Setting Functions.
|
const Point& get_center (void) | const virtual function |
Returns center . If the Solid doesn't
have a meaningful center, the return value will probably be
INVALID_POINT .
|
const Point& get_shape_center (const unsigned short shape_type, const unsigned short s) | const virtual function |
Returns the center of a Shape belonging to the Solid .
Currently, the object can be a Circle , Ellipse ,
Rectangle , or Reg_Polygon , and it is accessed through a pointer
on one of the following vectors of pointers to Shape :
circles , ellipses ,
rectangles , or reg_polygons .
The type of
object is specified
using the shape_type argument.
The following public static const data members of Solid
can (and probably should) be passed as the shape_type argument:
CIRCLE , ELLIPSE , RECTANGLE , and
REG_POLYGON .
The argument s is used to index the vector. This function is called within the more specialized functions in this
section, namely: Dodecahedron d(origin, 3); d.filldraw(); Point C = d.get_shape_center(Solid::REG_POLYGON, 1); C.dotlabel("C");
Note that this function will have to be changed, if new vectors of
|
const Point& get_circle_center (const unsigned short s) | const virtual functions |
const Point& get_ellipse_center (const unsigned short s) | |
const Point& get_rectangle_center (const unsigned short s) | |
const Point& get_reg_polygon_center (const unsigned short s) |
These functions all return the center of the Shape pointed to by a pointer on
one of the vectors of Shapes belonging to the Solid . The argument s
indicates which element on the vector is to be accessed. For example,
get_rectangle_center(2) returns the center of the
Rectangle pointed to by rectangles[2] .
Cuboid c(origin, 3, 4, 5, 0, 30); c.draw(); for (int i = 0; i < 6; ++i) c.get_rectangle_center(i).label(i, "");
|
The functions in this section
all return const
pointers to Shape
, or one of its derived
classes. Therefore, they must be invoked in such a way, that
the const
qualifier is not discarded. See
the description of get_reg_polygon_ptr()
below, for an example.
Shape* get_shape_ptr (const unsigned short shape_type, const unsigned short s) | const virtual function |
Copies one of the objects belonging to the Solid , and returns a
pointer to Shape that points to the copy.
The object is found by dereferencing one of the pointers on one of the
vectors of pointers belonging to the Solid .
Currently, these
vectors are circles , ellipses , paths ,
rectangles , and reg_polygons . The argument
shape_type specifies the vector, and the
argument s specifies which element of the vector should be
accessed. The following public static const data members of
Solid can (and probably should) be passed as the shape_type
argument: CIRCLE , ELLIPSE , PATH , RECTANGLE ,
and REG_POLYGON .
This function was originally intended to be called within the more
specialized functions in this
section, namely: Icosahedron I(origin, 3); I.filldraw(); Reg_Polygon* t = static_cast<Reg_Polygon*>(I.get_shape_ptr(Solid::REG_POLYGON, 9)); t->fill(gray);
|
const Reg_Polygon* get_circle_ptr (const unsigned short s) | const virtual functions |
const Reg_Polygon* get_ellipse_ptr (const unsigned short s) | |
const Reg_Polygon* get_path_ptr (const unsigned short s) | |
const Reg_Polygon* get_rectangle_ptr (const unsigned short s) | |
const Reg_Polygon* get_reg_polygon_ptr (const unsigned short s) |
Each of these functions returns a pointer from one of the vectors of
Shape pointers belonging to the Solid . The argument s
specifies which element of the appropriate vector should be returned.
For example, get_reg_polygon_ptr(2) returns the Reg_Polygon*
in reg_polygons[2] .
Since these functions return Dodecahedron d(origin, 3); d.draw(); const Reg_Polygon* ptr = d.get_reg_polygon_ptr(0); ptr->draw(black, "evenly scaled 4", "pencircle scaled 1mm"); Reg_Polygon A = *d.get_reg_polygon_ptr(5); A.fill(gray);
|
void show ([string text = "", [char coords = 'w', [const bool do_persp = true , [const bool do_apply = true , [Focus* f = 0, [const unsigned short proj = Projections::PERSP , [const real factor = 1]]]]]]])
|
const virtual function |
Prints text and the value of on_free_store to the standard
output (stdout ), and then calls
show() on the objects pointed to by the pointers on
paths , circles , ellipses , reg_polygons , and
rectangles , unless the vectors are empty. The arguments are
passed to Path::show() , Ellipse::show() , etc. If a vector
is empty, a message to this effect is printed to the standard output.
|
Transform scale (real x, [real y = 0, [real z = 0]]) | Virtual functions |
Solid .
| |
Transform shear (real xy, [real xz = 0, [real yx = 0, [real yz = 0, [real zx = 0, [real zy = 0]]]]]) | |
Transform shift (real x, [real y = 0, [real z = 0]]) | |
Transform shift (const Point& pt) | |
Transform rotate (const real x, [const real y = 0, [const real z = 0]]) | |
Transform rotate (const Point& p0, const Point& p1, [const real angle = 180]) |
These functions perform the corresponding transformations on all of the
Shapes belonging to the Solid .
See Transform Reference; Affine Transformations.
|
void apply_transform (void )
|
Virtual function |
Calls apply_transform() on all of the Shapes belonging to
the Solid .
|
The functions in this section are are called, directly or indirectly, by
Picture::output()
.
See Picture Reference; Outputting.
void output (void )
|
Virtual function |
Writes the MetaPost code for drawing, filling, filldrawing, undrawing,
unfilling, or unfilldrawing the Solid to out_stream .
|
void suppress_output (void )
|
Virtual function |
Used in Picture::output() . Sets do_output to false , if the
Solid cannot be projected using a particular set of arguments to
Picture::output() .
|
void unsuppress_output (void )
|
Virtual function |
Used in Picture::output() . Resets do_output to true ,
so that the Solid will be tested for projectability again, if the
Picture it's on is output again.
|
vector<Shape*> extract (const Focus& f, const unsigned short proj, real factor) | Virtual function |
Tests whether all of the Shapes belonging to the Solid are
projectable, using the arguments passed to output() . If it is,
this function returns a
vector of pointers to Shape containing a single pointer to
the Solid . If not, an empty vector is returned.
|
bool set_extremes (void )
|
Virtual function |
Sets projective_extremes to contain the maximum and minimum
values for the x, y, and z-coordinates of the Points on the
Shape . Used for determining projectability of a Solid
using a particular set of arguments.
|
const valarray<real> get_extremes (void )
|
const inline virtual function |
Returns projective_extremes .
|
real get_minimum_z (void )
|
const virtual functions |
real get_maximum_z (void )
|
|
real get_mean_z (void )
|
Returns the minimum, maximum, or mean z-value, respectively, of the
Points belonging to the Solid .
Used for surface hiding.
See Surface Hiding.
|
void draw ([const vectorColors::default_color_vector , [const string ddashed = "", [const string ppen = "", [Picture& picture = current_picture ]]]])
|
const virtual function |
Draws the Solid .
This function allocates a new The Currently, a |
void fill ([const vectorColors::default_color_vector , [Picture& picture = current_picture ]])
|
const virtual function |
Fills the Solid .
This function allocates a new The |
void filldraw ([const vectorcurrent_picture ]]]]])
|
const virtual function |
Filldraws the Solid .
This function allocates a new The Currently, a |
void undraw ([const string ddashed = "", [const string ppen = "", [Picture& picture = current_picture ]]])
|
const virtual function |
Undraws the Solid .
This function allocates a new A |
void unfill ([Picture& picture = current_picture ])
|
const virtual function |
Unfills the Solid .
This function allocates a new |
void unfilldraw ([const string ddashed = "", [const string ppen = "", [Picture& picture = current_picture ]]])
|
const virtual function |
void undraw ([const string ddashed = "", [const string ppen = "", [Picture& picture = current_picture ]]])
|
const virtual function |
Unfilldraws the Solid .
This function allocates a new A |
void clear (void )
|
Virtual function |
Calls clear() on all the Shapes belonging to the
Solid .
Used in Picture::clear() for deallocating
and destroying Solids .
Currently, <Shape>. |
Class Solid_Faced
is defined in solfaced.web
.
It is derived from Solid
using public derivation.
Solid_Faced
currently has no member functions. It is intended
for use as a base class. The classes Cuboid
and
Polyhedron
are derived from Solid_Faced
.
See Cuboid Reference, and Polyhedron Reference.
unsigned short faces | Protected variable |
The number of faces of the Solid_Faced .
|
unsigned short vertices | Protected variable |
The number of vertices of the Solid_Faced .
|
unsigned short edges | Protected variable |
The number of edges of the Solid_Faced .
|
Class Cuboid
is defined in cuboid.web
.
It is derived from Solid_Faced
using public derivation.
real height | Protected variables |
real width | |
real depth |
The height, width, and depth of the Cuboid , respectively.
Please note, that " |
void Cuboid (void )
|
Default constructor |
Creates an empty Cuboid .
|
void Cuboid (const Cuboid& c) | Copy constructor |
Creates a new Cuboid and makes it a copy of c.
|
void Cuboid (const Point& c, const real h, const real w, const real d, [const real x = 0, [const real y = 0, [const real z = 0]]]) | Constructor |
Creates a Cuboid with center at the origin, with
height == h, width == w, and
depth == d. If x, y, or z is
non-zero, the Cuboid is rotated by the amounts indicated around
the corresponding main axes. Finally, the
Cuboid is shifted such that center comes to lie at
c.
Point P(-3, -2, 12); Cuboid c(P, 3, 5, 2.93, 35, 10, 60);
|
Cuboid* create_new<Cuboid> (const Cuboid* c) | Template specializations |
Cuboid* create_new<Cuboid> (const Cuboid& c) |
Pseudo-constructors for dynamic allocation of Cuboids .
They create a Cuboid on the free store and allocate memory for it using
new(Cuboid) . They return a pointer to the new Cuboid .
If c is a non-zero pointer or a reference,
the new |
void ~Cuboid (void )
|
Destructor |
Deallocates the Rectangles pointed to by the pointers on
rectangles (a Solid data member), and calls
rectangles.clear() . Cuboids consist entirely of
Rectangles , so nothing must be done to the other vectors.
|
void operator= (const Cuboid& c) | Assignment operator |
Makes the Cuboid a copy of c. The old contents of *this
are deallocated (where necessary) and discarded.
|
Class Polyhedron
is defined in polyhed.web
.
It is derived from Solid_Faced
using public derivation. It is
intended for use as a base class for specific types of polyhedra.
Currently, the classes Tetrahedron
, Dodecahedron
,
Icosahedron
, and Trunc_Octahedron
(truncated octahedron)
are derived from Polyhedron
.
There is a great deal of work left to do on the polyhedra.
unsigned short number_of_polygon_types | Protected variable |
The number of different types of polygon making up the faces of a
Polyhedron . The Platonic polyhedra have only one type of face,
while the Archimedean can have more.
|
real face_radius | Protected variable |
The radius of the sphere that touches the centers of the polygonal faces of the polyhedron (Inkugel, in German). |
real edge_radius | Protected variable |
The radius of the sphere that touches the centers of the edges of the polyhedron. |
real vertex_radius | Protected variable |
The radius of the sphere touching the vertices of the polyhedron (Umkugel, in German). |
3DLDF currently has classes for three of the five regular Platonic
polyhedra: Tetrahedron
, Dodecahedron
, and
Icosahedron
. There is no need for a special Cube
class,
because cubes can be created using Cuboid
with equal width,
height, and depth arguments (see Cuboid Reference). Octahedron
is
missing at the moment, but I plan to add it soon.
Class Tetrahedron
is defined in polyhed.web
.
It is derived from Polyhedron
using public derivation.
real dihedral_angle | Protected static const variable |
The angle in radians between the faces of the Tetrahedron , namely
70 degrees
32'
.
Only
the Platonic polyhedra have a single dihedral angle, so
dihedral_angle is not a member of
Polyhedron . This means that it must be a member of all of the
classes representing Platonic polyhedra.
|
real triangle_radius | Protected variable |
The radius of the circle enclosing a triangular face of the
Tetrahedron .
|
void Tetrahedron (void )
|
Default constructor |
Creates an empty Tetrahedron .
|
void Tetrahedron (const Point& p, const real diameter_of_triangle, [real angle_x = 0, [real angle_y = 0, [real angle_z = 0]]]) | Constructor |
Creates a Tetrahedron with its center at the origin.
The faces have enclosing circles of diameter
diameter_of_triangle. If any of angle_x, angle_y, or
angle_z is non-zero, the Tetrahedron is rotated by the
amounts specified around the corresponding axes. Finally, if p is
not the origin, the Tetrahedron is shifted such that
center comes to lie at p.
The center of a Tetrahedron t(origin, 3); t.draw();
Point P(1, 0, 1); Tetrahedron t(P, 2.75, 30, 32.5, 20); t.draw();
|
void set (const Point& p, const real diameter_of_triangle, [real angle_x = 0, [real angle_y = 0, [real angle_z = 0]]]) | Setting function |
Corresponds to the constructor above. |
vector<Reg_Polygon*> get_net (const real triangle_diameter) | Static function |
Returns the net of the Tetrahedron , i.e., the
two-dimensional pattern of triangles that can be folded into
a model of a tetrahedron.45
The net lies in the x-z plane. The triangles
have enclosing circles of diameter triangle_diameter. The center
of the middle triangle is at the origin.
vector<Reg_Polygon*> vrp = Tetrahedron::get_net(2); for (vector<Reg_Polygon*>::iterator iter = vrp.begin(); iter != vrp.end(); ++iter) { (**iter).draw(); }
This function is used in the non-default constructor.
See Polyhedron Reference; Regular Platonic Polyhedra; Tetrahedron; Constructors and Setting Functions.
The constructor starts with the net and rotates three of the triangles
about the adjacent vertices of the middle triangle. Currently, all of
the The |
void draw_net (const real triangle_diameter, [bool make_tabs = true ])
|
Static function |
Draws the net for a Tetrahedron in the x-y plane.
The triangles
have enclosing circles of diameter triangle_diameter. The
origin is used as the center of the middle triangle.
The centers of the triangles are numbered.
If the argument make_tabs is used, tabs for gluing and/or sewing a
cardboard model of the Tetrahedron together will be drawn, too.
The dots on the tabs mark where to stick the needle through, when sewing
the model together (I've had good results with sewing).
Tetrahedron::draw_net(3, true);
The net is drawn in the x-y plane, because it currently doesn't work to draw it in the x-z plane. I haven't gotten around to fixing this problem yet. |
Class Dodecahedron
is defined in polyhed.web
.
It is derived from Polyhedron
using public derivation.
Dodecahedra have 12 regular pentagonal faces.
real dihedral_angle | Protected static const variable |
The angle between the faces of the Dodecahedron ,
namely
116 degrees
34'
= \pi - \arctan(2).
|
real pentagon_radius | Protected variable |
The radius of the circle enclosing a pentagonal face of the
Dodecahedron .
|
void Dodecahedron (void )
|
Default constructor |
Creates an empty Dodecahedron .
|
void Dodecahedron (const Point& p, const real pentagon_diameter, [real angle_x = 0, [real angle_y = 0, [real angle_z = 0]]]) | Constructor |
Creates a Dodecahedron with its center at the origin, where the
pentagonal faces have enclosing circles of diameter
pentagon_diameter. If any of angle_x, angle_y, or
angle_z is non-zero, the Dodecahedron is rotated by the
amounts specified around the corresponding axes. Finally, if p is
not the origin, the Dodecahedron is shifted such that
center comes to lie at p.
Point P(-1, -2, 4); Dodecahedron d(P, 3, 12.5, 16, 2); d.draw();
d.filldraw();
|
vector<Reg_Polygon*> get_net (const real pentagon_diameter, [bool do_half = false]) | Static function |
Returns the net, i.e., the two-dimensional pattern of pentagons
that can be folded into a model of a dodecahedron. The net lies
in the x-z plane. The pentagons have enclosing circles of diameter
pentagon_diameter. The center of the center pentagon of the first
half of the net is at the origin. If the argument
do_half is true , only the first half of the
net is created. This is used in the non-default constructor.
See Polyhedron Reference; Regular Platonic Polyhedra; Dodecahedron; Constructors and Setting Functions.
vector<Reg_Polygon*> vrp = Dodecahedron::get_net(1); for(vector<Reg_Polygon*>::iterator iter = vrp.begin(); iter != vrp.end(); ++iter) (**iter).draw();
|
void draw_net (const real pentagon_diameter, [bool portrait = true , [bool make_tabs = true ]])
|
Static function |
Draws the net for a Dodecahedron in the x-z plane. The pentagons
have enclosing circles of diameter pentagon_diameter. The
origin is used as the center of the middle pentagon of the first half of
the net. The centers of the pentagons are numbered.
If the argument portrait is The argument make_tabs currently has no effect. When I get around to programming this, it will be used for specifying whether tabs for gluing and/or sewing a cardboard model should be drawn, too. Dodecahedron::draw_net(1, false);
|
Class Icosahedron
is defined in polyhed.web
.
It is derived from Polyhedron
using public derivation.
Icosahedra have 20 regular triangular faces.
real dihedral_angle | Protected static const variable |
The angle between the faces of the Icosahedron , namely
138 degrees
11'
= \pi - \arcsin(2/3).
|
real triangle_radius | Protected variable |
The radius of the circle enclosing a triangular face of
the Icosahedron .
|
void Icosahedron (void )
|
Default constructor |
Creates an empty Icosahedron .
|
void Icosahedron (const Point& p, const real diameter_of_triangle, [real angle_x = 0, [real angle_y = 0, [real angle_z = 0]]]) | Constructor |
Creates an Icosahedron with its center at the origin, where the
triangular faces have enclosing circles of diameter
diameter_of_triangle. If any of angle_x, angle_y, or
angle_z is non-zero, the Icosahedron is rotated by the
amounts specified around the corresponding axes. Finally, if p is
not the origin, the Icosahedron is shifted such that
center comes to lie at p.
Icosahedron i(origin, 3, 0, 10); i.draw();
i.filldraw();
|
vector<Reg_Polygon*> get_net (const real triangle_diameter, [bool do_half = false ])
|
Static function |
Returns the net, i.e., the two-dimensional pattern of triangles
that can be folded into a model of an icosahedron. The net lies
in the x-z plane. The triangles have enclosing circles of diameter
triangle_diameter.
If the argument do_half = true , only the first half of the
net is created. This is used in the non-default constructor.
See Polyhedron Reference; Regular Platonic Polyhedra; Icosahedron; Constructors and Setting Functions.
vector<Reg_Polygon*> vrp = Icosahedron::get_net(1.5); for (vector<Reg_Polygon*>::iterator iter = vrp.begin(); iter != vrp.end(); ++iter) (**iter).draw();
|
void draw_net (const real triangle_diameter, [bool portrait = true, [bool make_tabs = true ]])
|
Static function |
Draws the net for an Icosahedron in the x-z plane. The triangles
have enclosing circles of diameter triangle_diameter.
If the argument portrait is true (the default), the net
will be arranged for printing in portrait format. If it's false ,
it will be arranged for printing in landscape format.
In portrait format, the center of the bottom right triangle is at the
origin. In landscape format, the center of the bottom left
triangle is at the origin. The triangles are numbered.
The argument make_tabs currently has no effect. When I get around to programming this, it will be used for specifying whether tabs for gluing and/or sewing a cardboard model should be drawn, too. Icosahedron::draw_net(2, false);
|
Once I've added class Octahedron
, the only Platonic polyhedron I
haven't programmed yet, I plan to start adding classes
for the semi-regular Archimedean polyhedra.
Class Trunc_Octahedron
is defined in polyhed.web
.
It is derived from Polyhedron
using public derivation.
Trunc_Octahedron
does not yet have a functioning constructor, so
it cannot be used as yet.
real angle_hex_square | Protected static const variable |
The angle between the hexagonal and the square faces of the truncated octahedron, namely 125 degrees 16' . |
real angle_hex_hex | Protected static const variable |
The angle between the hexagonal faces of the truncated octahedron, namely 109 degrees 28' . |
real hexagon_radius | Protected variable |
The radius of the circle enclosing a hexagonal or square face of the
Trunc_Octahedron .
|
void Trunc_Octahedron (void )
|
Default constructor |
Creates an empty Trunc_Octahedron .
|
void Trunc_Octahedron (const Point& p, const real diameter_of_hexagon, [real angle_x = 0, [real angle_y = 0, [real angle_z = 0]]]) | Constructor |
This function does not yet exist!
When it does, it will create a Trunc_Octahedron with its center
at the origin, where the
hexagonal and square faces have enclosing circles of diameter
diameter_of_hexagon. If any of angle_x, angle_y, or
angle_z is non-zero, the Trunc_Octahedron will be rotated
by the amounts specified around the corresponding axes. Finally,
if p is not the origin, the Trunc_Octahedron will be
shifted such that center comes to lie at p.
|
vector<Reg_Polygon*> get_net (const real hexagon_diameter, [bool do_half = false ])
|
Static function |
This function does not yet exist!
When it does, it will return the net, i.e., the two-dimensional
pattern of hexagons and squares that can be folded into
a model of a truncated octahedron. The net will lie in the x-z plane.
The hexagons and squares will
have enclosing circles of diameter hexagon_diameter.
If the argument do_half is true , only the first half of the
net will be created. This will be used in the non-default constructor.
See Polyhedron Reference; Regular Platonic Polyhedra; Truncated Octahedron Constructors and Setting Functions.
|
double trunc (double d) | Function |
Defined in pspglb.web .
For some reason, when I compile 3DLDF using GNU CC on a PC Pentium II
XEON under Linux 2.4.4 i686, the standard library function
trunc() is not available. Therefore, I've had to write one.
This is a kludge!
Someday, I'll have to try to find a better solution to this problem.
|
pair<real, real> solve_quadratic (real a, real b, real c) | Function |
Defined in pspglb.web .
This function tries to find the solutions S_0 and S_1 to the
quadratic equation
ax^2 + bx + c according to the formulae
S_0 == -b + sqrt(b^2 - 4ac) / 2a) and
S_1 == -b - sqrt( b^2 - 4ac) / 2a.
Let r stand for the return value. If S_0 cannot be found,
r.first will be INVALID_REAL , otherwise S_0.
If S_1 cannot be found,
r.second will be INVALID_REAL , otherwise S_1.
(x + 4)(x + 2) = x^2 + 6x + 8 = 0 real_pair r = solve_quadratic(1, 6, 8); => r.first == -2 => r.second == -4 real_pair r = solve_quadratic(1, -2, 4); => r.first == INVALID_REAL => r.second == INVALID_REAL |
void persp_0 (const real front_corner_x, const real front_corner_z, const real side_lft, const real side_rt, const real angle_rt, const real f_2_cv, const real gl_2_cv, [const real horizon_lft = 6, [real horizon_rt = 0, [real gl_lft = 0, [real gl_rt = 0]]]]) | Function |
Defined in utility.web .
This function is used for the figure in The Perspective Projection, illustrating a perspective projection as it could be done
by hand. It draws a rectangle in the ground plane and the construction
lines used for putting it into perspective. It also labels the
vanishing and measuring points.
The arguments:
Example: persp_0(3, 2, 10, 5, 47.5, 7, 5, 8.5, 9.5, 8.5, 9.5);
|
Version 1.1.1 was the first version of 3DLDF since it became a GNU
package (the current version is 1.1.5.1). In previous versions,
recompilation was controlled by an
auxilliary program, which I wrote in C++
using CWEB. However,
in the course of making 3DLDF conformant to the
GNU Coding Standards46,
this has
been changed. Recompilation is now controlled by make
, as is
customary. The chapter "Compiling" in previous editions of this
manual, is therefore no longer needed.
Nonetheless, using CWEB still has consequences for the way recompilation
must be handled, and it was fairly tricky getting make
to work
for 3DLDF. Users who only put code in main.web
and/or change
code in existing files won't have to worry about this;
for others, this chapter explains how to add
files to 3DLDF.
Let's say you want to add a file widgets.web
that defines a
class Widget
, and that the latter needs access to
class Rectangle
, and is in turn required by class Ellipse
.
Code must be added to 3DLDF-1.1.5.1/CWEB/Makefile
for
ctangling widgets.web
, compiling widgets.cxx
, and linking
widgets.o
with the other object files to make the executable
3dldf
.
The best way to do this is to change
3DLDF-1.1.5.1/CWEB/Makefile.am
and use Automake
to generate a new Makefile.in
. Then, configure
can be
used to generate a new Makefile
. It would be possible to modify
Makefile
by hand, but I don't recommend it. The following
assumes that the user has access to Automake. If he or she is using a
GNU/Linux system, this is probably true.47
widgets.web
must be added between rectangs.web
and
ellipses.web
in the following variable declaration in
3DLDF-1.1.5.1/CWEB/Makefile.am
:
3dldf_SOME_CWEBS = pspglb.web io.web colors.web transfor.web \ shapes.web pictures.web points.web \ lines.web planes.web paths.web curves.web \ polygons.web rectangs.web ellipses.web \ circles.web patterns.web solids.web solfaced.web cuboid.web polyhed.web \ utility.web parser.web examples.web
Now, add widgets.o
between ellipses.o
and
rectangs.o
in the following variable declaration:
3dldf_OBS_REVERSED = main.o examples.o parser.o utility.o \ polyhed.o cuboid.o solfaced.o solids.o \ patterns.o circles.o ellipses.o rectangs.o \ polygons.o curves.o paths.o \ planes.o lines.o points.o pictures.o shapes.o transfor.o colors.o io.o pspglb.o
3dldf_OBS_REVERSED
is needed, because 3DLDF fails with
a "Segmentation fault", if
the executable is linked using $(3dldf_OBJECTS)
. This may cause
problems, if 3dldf
isn't built using the GNU C++
compiler
(GCC).
Now add a target for widgets.o
between the targets for
rectangs.o
and ellipses.o
, and add widgets.tim
after rectangs.tim
in the list of prerequisites for
ellipses.o
:
rectangs.o: loader.tim pspglb.tim io.tim colors.tim transfor.tim \ shapes.tim pictures.tim points.tim lines.tim planes.tim \ paths.tim curves.tim polygons.tim rectangs.cxx ellipses.o: loader.tim pspglb.tim io.tim colors.tim transfor.tim \ shapes.tim pictures.tim points.tim lines.tim planes.tim \ paths.tim curves.tim polygons.tim rectangs.tim ellipses.cxx
This is the result:
rectangs.o: loader.tim pspglb.tim io.tim colors.tim transfor.tim \ shapes.tim pictures.tim points.tim lines.tim planes.tim \ paths.tim curves.tim polygons.tim rectangs.cxx widgets.o: loader.tim pspglb.tim io.tim colors.tim transfor.tim \ shapes.tim pictures.tim points.tim lines.tim planes.tim \ paths.tim curves.tim polygons.tim rectangs.tim \ widgets.cxx ellipses.o: loader.tim pspglb.tim io.tim colors.tim transfor.tim \ shapes.tim pictures.tim points.tim lines.tim planes.tim \ paths.tim curves.tim polygons.tim rectangs.tim widgets.tim \ ellipses.cxx
In addition, widgets.tim
must be added to the list of prerequisites in all of the following
targets up to and including examples.o
.
3DLDF is a work-in-progress. In fact, it can never be finished, because the supply of interesting geometric constructions is inexhaustible. However, presently 3DLDF still has a number of major gaps.
If you're interesting in contributing to 3DLDF, with respect to one of the topics below and in the following sections, or if you have ideas of your own, see Contributing to 3DLDF.
3DLDF currently provides a set of basic plane and solid geometrical figures. However, some important ones are still missing. There are many useful geometrical data types and functions whose implementation would require no more than elementary geometry.
class Triangle
, which can be used for
calculating triangle solutions.
Conic_Section
and derive Ellipse
from it. This will be the first case of
multiple inheritance48
in 3DLDF, since Ellipse
is already
derived from Path
. See Ellipse Reference.
Add the classes Parabola
and Hyperbola
.
Ellipse
and a Circle
in a plane,
but I haven't had a chance to try implementing it yet.
If this works, I think it will make it possible to find the intersection of two coplanar ellipses algebraically, because it will be possible to transform them both such that one of them becomes circular.
Octahedron
will complete the set of regular Platonic
polyhedra.
Ellipsoid
and a derived class Sphere
.
Solid
and
Solid_Faced
.
In particular, it would help to store the vertices of
Polyhedra
as individual Points
, rather
than using Reg_Polygons
. I'd also
like to find a better way of generating Solids
, without using
rotations, if possible.
3D modelling software usually supports the creation and manipulation of various kinds of spline curves: Bézier curves, B-splines, and non-uniform rational B-splines or NURBS. These curves can be used for generating surfaces.50
paths
in Metafont and MetaPost are Bézier curves.
It would be possible to implement three-dimensional Bézier curves in
3DLDF, but unfortunately they are not projectively invariant:
Let c_0 represent a Bézier curve in three dimensions, P the control points of c_0, and t a projection transformation. Further, let Q represent the points generated from applying t to P, and c_1 the curve generated from Q. Finally, let R represent the points generated from applying t to all of the points on c_0, and c_2 the curve through R: c_1 \not\equiv c_2.
NURBS, on the other hand, are projectively invariant,51
so I will probably
concentrate on implementing them. On the other hand, it would be nice
to be able to implement Metafont's way of specifying paths
using `curl
', `tension
', and `dir
' in 3DLDF.
This may prove to be difficult or impossible. I do not yet know
whether Metafont's path
creation algorithm can be generalized to
three dimensions.52
Curves and surfaces are advanced topics, so it may be a while before I implement them in 3DLDF.
Shadows and reflections are closely related to transformations and projections. A shadow is the projection of the outline of an object onto a surface or surfaces, and reflection in a plane is an affine transformation.
3D rendering software generally implements shadows, or more generally, shading, reflections, and certain other effects using methods involving the calculation of individual pixel values. Surface hiding is also often implemented at the pixel level. 3DLDF does no scan converting ((see Accuracy), and hence no calculation of pixel values at all, so these methods cannot be used in 3DLDF at present.
However, it is possible to define functions for generating shadows and reflections within 3DLDF by other means.
I have defined the function Point::reflect()
for reflecting a
Point
in a Plane
, and have begun definining versions for
other classes.
However, in order for reflections to work, I must define functions for breaking up objects into smaller units. This is also necessary for surface hiding to work properly.
For MetaPost output, I will have to implement shadows, reflections, and surface hiding in this way. However, 3DLDF could be made to produce output in other formats. There are two possibilities: implementing rendering functionality within 3DLDF, or interfacing to existing rendering software. If I decide to do the latter, there are again two possibilities: having 3DLDF write output in a format that a renderer can input, or linking to a library supplied by a rendering package.
I haven't yet decided which course to pursue. However, in the long run, I'd like it to be possible to use 3DLDF for fancier graphics than is currently possible using MetaPost and PostScript alone.
When 3DLDF is run, there is only one thread of execution.
However, it could benefit from the use of multiple threads.
In particular, it may be faster and more efficient to have
Picture::output()
run in its own thread.
In this case, it will no longer be possible to share
current_picture
among figures.
It may also be
worthwhile to execute the code for "figures", i.e., the code
between beginfig()
and endfig()
, inclusive,
in their own threads. This will require some changes in the way data
are handled. For example, if non-constant objects are shared
among figures, there may be no advantage to multi-threading because of
the need to coordinate the access of the threads to the objects.
If threads are used, then non-constant objects should be
declared locally within the figure. They may be locally declared
copies of global objects. Alternatively, beginfig()
could be
changed so that objects could be passed to it as arguments, perhaps as
a vector<void*>
and/or a vector<Shape*>
.
Updated 16 January 2004.
3dldf_TEXINFOS
variable in
3DLDF-1.1.5.1/DOC/TEXINFO/Makefile.am
, and reordered the
filenames.
In release 1.1.5, I've tied up some loose ends. I wanted to do this before starting on the input routine.
const real
step argument to the version of
Ellipse::intersection_points()
that takes an Ellipse
argument.
See Ellipse Reference; Intersections.
real
to either float
or double
. This means that real
can now be made a synonym
for either float
or double
by using a typedef
declaration. real
is typedeffed to float
by default.
const bool ldf_real_float
and
extern const bool ldf_real_double
for use in non-conditionally compiled code.
They are set according to the values
of LDF_REAL_FLOAT
and LDF_REAL_DOUBLE
.
Transform::epsilon()
and Point::epsilon()
now return
different values, depending on the values of the preprocessor macros
LDF_REAL_FLOAT
and LDF_REAL_DOUBLE
. I have not yet tested
whether good values are returned when real
is double
.
MAX_REAL
and MAX_REAL_SQRT
are no longer constants.
Their values are set at the beginning of main()
. However,
users should not change their values. MAX_REAL
is the
second-largest float
or double
on a given machine. This
now works for all common architectures.
namespace System
containing the following functions:
get_endianness()
, is_big_endian()
,
is_little_endian()
, get_register_width()
,
is_32_bit()
, is_64_bit()
, and the template function
get_second_largest()
.
namespace System
and its functions are documented in
system.texi
, which is new in edition 1.1.5.1.
create_new_
<type>()
functions with the
template function create_new()
. The latter is documented in
creatnew.texi
, which is new in edition 1.1.5.1.
3DLDF-1.1.5.1/CWEB/cnepspng.el
to
the distribution. It contains the definitions of the Emacs-Lisp
functions convert-eps
and convert-eps-loop
.
See Running 3DLDF; Converting EPS Files; Emacs-Lisp Functions.
3DLDF-1.1.5.1/CWEB/exampman.web
and
3DLDF-1.1.5.1/CWEB/examples.mp
to the
distribution. They contain the C++
and MetaPost code,
respectively, for generating the illustrations in this manual.
magstep3
.
MAX_REAL
is now the second largest float value. However, the
calculation is system dependent, and will only work on 32-bit
little-endian architectures. I will start working on porting this
soon.
tsthdweb
, that caused files to be compiled more
often than necessary. It will be necessary to keep an eye on this.
Rectangle::is_rectangular()
.
mediate()
a member function of Point
.
3DLDF 1.1.1 was the first version of 3DLDF since it became a GNU
package (the current version is 1.1.5.1). It is now conformant
to the GNU Coding Standards, except that
a functioning 3DLDF.info
cannot be generated from
3DLDF.texi
. The
distribution now includes a configure
script,
Makefile.in
files, and other files generated by Autoconf and
Automake. Recompilation is now handled by make
rather than
the auxilliary program 3DLDFcpl
. The files
3DLDFcpl.web
and 3DLDFprc.web
have been removed from the
distribution.
The extension of the C++
files generated by ctangle
is
changed from c
to cxx
before they are compiled.
After ctangle
is run on a CWEB file, <
filename>.c
is compared to the old <
filename>.cxx
using diff
.
Whitespace, comments, and #line
preprocessor commands are
ignored. The <
filename>.c
is only renamed to
<
filename>.cxx
and compiled if they differ. This way,
changes to the TeX text only in a CWEB file no longer cause
recompilation and relinking.
The main Texinfo file is now called 3DLDF.texi
. It was formerly
called 3DLDFman.texi
. This is because Automake expects this
name. For this reason, the CWEB
file passed as an argument to cweave has been renamed
3DLDFprg.web
. It was formerly called 3DLDF.web
.
Cundy, H. Martyn and A.P. Rollet. Mathematical Models. Oxford 1961. Oxford University Press.
Unfortunately out of print.
Finston, Laurence D.
3DLDF: The Program.
Göttingen 2003.
Fischer, Gerd.
Ebene algebraische Kurven.
Vieweg Studium. Aufbaukurs Mathematik.
Friedr. Vieweg & Sohn Verlagsgesellschaft mbH.
Braunschweig/Wiesbaden 1994.
Gill, Robert W.
Creative Perspective.
London 1975.
Thames and Hudson Ltd.
ISBN 0-500-27056-2.
Harbison, Samuel P., and Guy L. Steele Jr.
C, A Reference Manual.
Prentice Hall.
Englewood Cliffs, New Jersey 1995.
ISBN 0-13-326232-4 {Case}.
ISBN~0-13-326224-3 {Paperback}.
Hobby, John D.
Smooth, Easy to Compute Interpolating Splines.
Discrete and Computational Geometery 1(2).
Springer-Verlag.
New York 1986.
Hobby, John D.
A User's Manual for MetaPost.
AT & T Bell Laboratories.
Murray Hill, NJ. No date.
Jones, Huw.
Computer Graphics through Key Mathematics.
Springer-Verlag London Limited 2001.
ISBN 1-85233-422-3.
Knuth, Donald Ervin.
Metafont: The Program. Computers and Typesetting; D.
Addison Wesley Publishing Company, Inc.
Reading, Massachusetts 1986.
ISBN 0-201-13438-1.
Knuth, Donald Ervin.
The METAFONTbook.
Computers and Typesetting; C.
Addison Wesley Publishing Company, Inc.
Reading, Massachusetts 1986.
Knuth, Donald Ervin.
TeX: The Program. Computers and Typesetting; B.
Addison Wesley Publishing Company, Inc.
Reading, Massachusetts 1986.
ISBN 0-201-13437-3.
Knuth, Donald E. The TeXbook.
Computers and Typesetting; A.
Addison Wesley Publishing Company, Inc.
Reading, Massachusetts 1986.
Knuth, Donald E. and Silvio Levy.
The CWEB System of Structured Documentation.
Version 3.64--February 2002.
Rokicki, Tomas.
Dvips: A DVI-to-PostScript Translator
for version 5.66a.
February 1997.
http://dante.ctan.org/CTAN/dviware/dvips/
Salomon, David.
Computer Graphics and Geometric Modeling.
Berlin 1999.
Springer-Verlag.
ISBN: 0-387-98682-0.
Stallman, Richard M. and Roland McGrath.
GNU Make. A Program for Directing Recompilation.
make Version 3.79.
Boston 2000.
Free Software Foundation, Inc.
ISBN: 1-882114-80-9.
Stallman, Richard M.
Using and Porting the GNU Compiler Collection.
For GCC Version 3.3.2.
Boston 2003.
Free Software Foundation, Inc.
Stroustrup, Bjarne.
The C++
Programming Language.
Special Edition.
Reading, Massachusetts 2000.
Addison-Wesley.
ISBN 0-201-70073-5.
Stroustrup, Bjarne.
The Design and Evolution of C++
.
Reading, Massachusetts 1994.
Addison-Wesley Publishing Company.
ISBN 0-201-54330-3.
Vredeman de Vries, Jan. Perspective. New York 1968. Dover Publications, Inc. Standard Book Number: 486-21086-4.
The beautiful perspective constructions in this volume are taken from the original work, first published by Henricus Hondius in Leiden in 1604 and 1605.
White, Gwen. Perspective. A Guide for Artists, Architects and Designers. London 1968 and 1982. B T Batsford Ltd. ISBN 0-7134-3412-0.
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angle
: Focus Data Members
angle_hex_hex
: Truncated Octahedron Data Members
angle_hex_square
: Truncated Octahedron Data Members
arrow
: Path Data Members
axis
: Focus Data Members
axis_h
: Ellipse Data Members, Rectangle Data Members
axis_v
: Ellipse Data Members, Rectangle Data Members
AXON
: Namespace Projections
background_color
: Namespace Colors
background_color_vector
: Namespace Colors
black
: Namespace Colors
blue
: Namespace Colors
blue_part
: Color Data Members
blue_violet
: Namespace Colors
bool_pair
: Typedefs and Utility Structures
bool_point
: Point Typedefs and Utility Structures
bool_point_pair
: Point Typedefs and Utility Structures
bool_point_quadruple
: Point Typedefs and Utility Structures
bool_real
: Typedefs and Utility Structures
bool_real_point
: Point Typedefs and Utility Structures
center
: Solid Data Members, Regular Closed Plane Curve Data Members, Polygon Data Members
CIRCLE
: Solid Data Members
Circle
: Circle Reference, Plane Figures
circles
: Solid Data Members
Color
: Color Reference
connectors
: Path Data Members
Cuboid
: Cuboid Reference, Cuboid Getstart
CURR_Y
: Point Data Members
CURR_Z
: Point Data Members
cyan
: Namespace Colors
cycle_switch
: Path Data Members
dashed
: Path Data Members
default_background
: Namespace Colors
default_color
: Namespace Colors
default_color_vector
: Namespace Colors
default_focus
: Focus Global Variables
DEFAULT_NUMBER_OF_POINTS
: Ellipse Data Members
depth
: Cuboid Data Members
dihedral_angle
: Icosahedron Data Members, Dodecahedron Data Members, Tetrahedron Data Members
direction
: Line Data Members, Focus Data Members
distance
: Planes Data Members, Focus Data Members
do_help_lines
: Path Data Members
do_labels
: Picture Data Members
DO_LABELS
: Label Data Members
do_output
: Solid Data Members, Path Data Members, Point Data Members
Dodecahedron
: Dodecahedron, Dodecahedron Getstart
dot
: Label Data Members
DRAW
: Shape Data Members
draw_color
: Path Data Members
DRAWDOT
: Shape Data Members
drawdot_color
: Point Data Members
drawdot_value
: Point Data Members
edge_radius
: Polyhedron Data Members
edges
: Solid_Faced Data Members
ELLIPSE
: Solid Data Members
Ellipse
: Ellipse Reference, Plane Figures
ellipses
: Solid Data Members
face_radius
: Polyhedron Data Members
faces
: Solid_Faced Data Members
FILL
: Shape Data Members
fill_color
: Path Data Members
fill_draw_value
: Path Data Members
FILLDRAW
: Shape Data Members
Focus
: Focus Reference
focus
: Focuses Getstart
focus0
: Ellipse Data Members
focus1
: Ellipse Data Members
gray
: Namespace Colors
green
: Namespace Colors
green_part
: Color Data Members
green_yellow
: Namespace Colors
height
: Cuboid Data Members
help_color
: Path Data Members, Namespace Colors
help_color_vector
: Namespace Colors
help_dash_pattern
: Path Data Members
hexagon_radius
: Truncated Octahedron Data Members
Icosahedron
: Icosahedron, Icosahedron Getstart
IDENTITY_TRANSFORM
: Transform Global Variables and Constants
in_stream
: I/O Global Variables
internal_angle
: Regular Polygon Data Members
INVALID_BOOL_POINT
: Point Global Constants and Variables
INVALID_BOOL_POINT_PAIR
: Point Global Constants and Variables
INVALID_BOOL_POINT_QUADRUPLE
: Point Global Constants and Variables
INVALID_BOOL_REAL_POINT
: Point Global Constants and Variables
INVALID_LINE
: Line Global Constants
INVALID_PLANE
: Planes Global Constants
INVALID_POINT
: Point Global Constants and Variables
INVALID_REAL
: Global Constants and Variables
INVALID_REAL_PAIR
: Global Constants and Variables
INVALID_REAL_SHORT
: Global Constants and Variables
INVALID_TRANSFORM
: Transform Global Variables and Constants
ISO
: Namespace Projections
Label
: Label Reference
labels
: Picture Data Members
ldf_real_double
: Global Constants and Variables
ldf_real_float
: Global Constants and Variables
light_gray
: Namespace Colors
Line
: Line Reference
line_switch
: Path Data Members
linear_eccentricity
: Ellipse Data Members
magenta
: Namespace Colors
matrix
: Transform Data Members
Matrix
: Typedefs and Utility Structures
MAX_REAL
: Global Constants and Variables
MAX_REAL_SQRT
: Global Constants and Variables
MAX_Z
: Namespace Sorting
MEAN_Z
: Namespace Sorting
measurement_units
: Point Data Members
measurement_units (Point)
: Declaring and Initializing Points
MIN_Z
: Namespace Sorting
name
: Color Data Members
NO_SORT
: Namespace Sorting
normal
: Planes Data Members
null_coordinates
: Global Constants and Variables
number_of_points
: Regular Closed Plane Curve Data Members
number_of_polygon_types
: Polyhedron Data Members
numerical_eccentricity
: Ellipse Data Members
on_free_store
: Solid Data Members, Rectangle Data Members, Regular Polygon Data Members, Path Data Members, Point Data Members, Color Data Members
orange
: Namespace Colors
orange_red
: Namespace Colors
origin
: Point Global Constants and Variables
out_stream
: I/O Global Variables, Pictures
PARALLEL_X_Y
: Namespace Projections
PARALLEL_X_Z
: Namespace Projections
PARALLEL_Z_Y
: Namespace Projections
PATH
: Solid Data Members
Path
: Path Reference, Paths
paths
: Solid Data Members
pen
: Path Data Members, Point Data Members
pentagon_radius
: Dodecahedron Data Members
persp
: Focus Data Members
PERSP
: Namespace Projections
PI
: Global Constants and Variables
Picture
: Picture Global Variables, Picture Reference, Pictures
pink
: Namespace Colors
Plane
: Plane Reference
point
: Planes Data Members
Point
: Point Reference, Declaring and Initializing Points
Point::measurement_units
: Declaring and Initializing Points
Point::projective_coordinates
: Declaring and Initializing Points
Point::user_coordinates
: Declaring and Initializing Points
Point::view_coordinates
: Declaring and Initializing Points
Point::world_coordinates
: Declaring and Initializing Points
point_pair
: Point Typedefs and Utility Structures
points
: Path Data Members
Polygon
: Polygon Reference, Plane Figures
Polyhedron
: Polyhedron Reference, Polyhedron Getstart
position
: Line Data Members, Focus Data Members, Label Data Members
projective_coordinates
: Point Data Members
projective_coordinates (Point)
: Declaring and Initializing Points
projective_extremes
: Solid Data Members, Path Data Members, Point Data Members
pt
: Label Data Members
purple
: Namespace Colors
radius
: Circle Data Members, Regular Polygon Data Members
real
: Typedefs and Utility Structures
real_pair
: Typedefs and Utility Structures
real_short
: Typedefs and Utility Structures
real_triple
: Typedefs and Utility Structures
RECTANGLE
: Solid Data Members
Rectangle
: Rectangle Reference, Plane Figures
rectangles
: Solid Data Members
red
: Namespace Colors
red_part
: Color Data Members
Reg_Cl_Plane_Curve
: Regular Closed Plane Curve Reference, Plane Figures
REG_POLYGON
: Solid Data Members
Reg_Polygon
: Regular Polygon Reference, Plane Figures
reg_polygons
: Solid Data Members
Shape
: Shape Reference
shapes
: Picture Data Members
short
: Regular Polygon Data Members
Solid
: Solid Reference
Solid_Faced
: Faced Solid Reference
Tetrahedron
: Tetrahedron, Tetrahedron Getstart
tex_stream
: I/O Global Variables
text
: Label Data Members
transform
: Focus Data Members, Point Data Members, Picture Data Members
Transform
: Transform Reference, Transforms
triangle_radius
: Icosahedron Data Members, Tetrahedron Data Members
Trunc_Octahedron
: Truncated Octahedron
Truncated Octahedron
: Truncated Octahedron
UNDRAW
: Shape Data Members
UNDRAWDOT
: Shape Data Members
UNFILL
: Shape Data Members
UNFILLDRAW
: Shape Data Members
up
: Focus Data Members
use_name
: Color Data Members
user_coordinates
: Point Data Members
user_coordinates (Point)
: Declaring and Initializing Points
user_transform
: Transform Global Variables and Constants
vertex_radius
: Polyhedron Data Members
vertices
: Solid_Faced Data Members
view_coordinates
: Point Data Members
view_coordinates (Point)
: Declaring and Initializing Points
violet
: Namespace Colors
violet_red
: Namespace Colors
white
: Namespace Colors
width
: Cuboid Data Members
world_coordinates
: Point Data Members
world_coordinates (Point)
: Declaring and Initializing Points
yellow
: Namespace Colors
yellow_green
: Namespace Colors
align_with_axis
: Aligning Paths with an Axis, Alignment with an Axis for Transforms
angle
: Vector Operations
angle_point
: Returning Elements and Information for Ellipses, Querying Regular Closed Plane Curves
append
: Appending to Paths
apply_transform
: Applying Transformations to Solids, Applying Transformations to Paths, Applying Transformations to Points, Applying Transformations to Shapes
beginfig
: I/O Functions
bool_point
: Point Typedefs and Utility Structures
bool_point::operator=
: Point Typedefs and Utility Structures
bool_point_quadruple
: Point Typedefs and Utility Structures
bool_point_quadruple::operator=
: Point Typedefs and Utility Structures
bool_real_point
: Point Typedefs and Utility Structures
bool_real_point::operator=
: Point Typedefs and Utility Structures
Circle
: Circle Constructors and Setting Functions
clean
: Modifying Points, Cleaning Transforms
clear
: Clearing Solids, Clearing Paths, Modifying Points, Modifying Pictures, Clearing Shapes
Color
: Color Constructors and Setting Functions
convert-eps
: Converting EPS Files ELISP
convert-eps-loop
: Converting EPS Files ELISP
corner
: Returning Points for Rectangles
create_new
: Dynamic Allocation of Shapes
create_new<Circle>
: Circle Constructors and Setting Functions
create_new<Color>
: Color Constructors and Setting Functions
create_new<Cuboid>
: Cuboid Constructors and Setting Functions
create_new<Ellipse>
: Ellipse Constructors and Setting Functions
create_new<Path>
: Path Constructors and Setting Functions
create_new<Point>
: Point Constructors and Setting Functions
create_new<Rectangle>
: Rectangle Constructors and Setting Functions
create_new<Reg_Polygon>
: Regular Polygon Constructors and Setting Functions
create_new<Solid>
: Solid Constructors and Setting Functions
cross_product
: Vector Operations
Cuboid
: Cuboid Constructors and Setting Functions
define_color_mp
: Defining and Initializing Colors
do_transform
: Performing Transformations on Ellipses
Dodecahedron
: Dodecahedron Constructors and Setting Functions
dot_product
: Vector Operations
dotlabel
: Labeling Ellipses, Labelling Paths, Labelling Points
draw
: Drawing and Filling Solids, Drawing and Filling Paths, Point Drawing Functions
draw_axes
: Drawing and Filling Paths
draw_help
: Drawing and Filling Paths, Point Drawing Functions
draw_in_circle
: Circles for Regular Polygons
draw_in_ellipse
: Ellipses for Rectangles
draw_in_rectangle
: Rectangles for Ellipses
draw_net
: Icosahedron Net, Dodecahedron Net, Tetrahedron Net
draw_out_circle
: Circles for Regular Polygons
draw_out_ellipse
: Ellipses for Rectangles
draw_out_rectangle
: Rectangles for Ellipses
drawarrow
: Drawing and Filling Paths, Point Drawing Functions
drawdot
: Point Drawing Functions
Ellipse
: Ellipse Constructors and Setting Functions
endfig
: I/O Functions
epicycloid_pattern_1
: Epicycloids
epsilon
: Returning Information for Points, Returning Information for Transforms
extract
: Outputting Solids, Outputting Paths, Outputting Points, Outputting Shapes
fill
: Drawing and Filling Solids, Drawing and Filling Paths
filldraw
: Drawing and Filling Solids, Drawing and Filling Paths
Focus
: Focus Constructors and Setting Functions
get_all_coords
: Returning Coordinates
get_axis_h
: Returning Elements and Information for Ellipses, Querying Rectangles
get_axis_v
: Returning Elements and Information for Ellipses, Querying Rectangles
get_blue_part
: Querying Colors
get_center
: Returning Elements and Information Solids, Returning Elements and Information for Ellipses, Querying Polygons
get_circle_center
: Getting Shape Centers Solids
get_circle_ptr
: Getting Shapes Solids
get_coefficients
: Solving Ellipses, Querying Regular Closed Plane Curves
get_coord
: Returning Coordinates
get_copy
: Copying Solids, Copying Paths, Copying Points, Copying Labels, Copying Shapes
get_diameter
: Querying Circles
get_direction
: Querying Focuses
get_distance
: Planes Returning Information, Querying Focuses
get_element
: Querying Transforms
get_ellipse_center
: Getting Shape Centers Solids
get_ellipse_ptr
: Getting Shapes Solids
get_endianness
: Endianness
get_extremes
: Outputting Solids, Outputting Paths, Outputting Points, Outputting Shapes
get_focus
: Returning Elements and Information for Ellipses
get_green_part
: Querying Colors
get_last_point
: Querying Paths
get_line
: Querying Paths, Points and Lines
get_line_switch
: Querying Paths
get_linear_eccentricity
: Returning Elements and Information for Ellipses
get_maximum_z
: Outputting Solids, Outputting Paths, Outputting Points, Outputting Shapes
get_mean_z
: Outputting Solids, Outputting Paths, Outputting Points, Outputting Shapes
get_minimum_z
: Outputting Solids, Outputting Paths, Outputting Points, Outputting Shapes
get_name
: Querying Colors
get_net
: Truncated Octahedron Net, Icosahedron Net, Dodecahedron Net, Tetrahedron Net
get_normal
: Querying Paths
get_numerical_eccentricity
: Returning Elements and Information for Ellipses
get_path
: Get Path
get_path_ptr
: Getting Shapes Solids
get_persp
: Querying Focuses
get_persp_element
: Querying Focuses
get_plane
: Querying Paths
get_point
: Querying Paths
get_position
: Querying Focuses
get_radius
: Querying Circles, Querying Regular Polygons
get_rectangle_center
: Getting Shape Centers Solids
get_rectangle_ptr
: Getting Shapes Solids
get_red_part
: Querying Colors
get_reg_polygon_center
: Getting Shape Centers Solids
get_reg_polygon_ptr
: Getting Shapes Solids
get_register_width
: Register Width
get_second_largest
: Get Second Largest Real
get_shape_center
: Getting Shape Centers Solids
get_shape_ptr
: Getting Shapes Solids
get_size
: Querying Paths
get_transform
: Querying Focuses, Querying Points
get_transform_element
: Querying Focuses
get_up
: Querying Focuses
get_use_name
: Querying Colors
get_w
: Returning Coordinates
get_x
: Returning Coordinates
get_y
: Returning Coordinates
get_z
: Returning Coordinates
half
: Regular Closed Plane Curve Segments
hex_pattern_1
: Plane Tesselations
Icosahedron
: Icosahedron Constructors and Setting Functions
in_circle
: Circles for Regular Polygons
in_ellipse
: Ellipses for Rectangles
in_rectangle
: Rectangles for Ellipses
initialize_colors
: Defining and Initializing Colors
initialize_io
: I/O Functions
intersection_line
: Plane Intersections
intersection_point
: Path Intersections, Plane Intersections, Point Intersections
intersection_points
: Circle Intersections, Ellipse Intersections, Regular Closed Plane Curve Intersections, Polygon Intersections
inverse
: Matrix Inversion
is_32_bit
: Register Width
is_64_bit
: Register Width
is_big_endian
: Endianness
is_circular
: Querying Circles
is_cubic
: Querying Ellipses, Querying Regular Closed Plane Curves
is_cycle
: Querying Paths
is_elliptical
: Querying Ellipses
is_identity
: Querying Points, Querying Transforms
is_in_triangle
: Querying Points
is_linear
: Querying Paths
is_little_endian
: Endianness
is_on_free_store
: Querying Solids, Querying Paths, Querying Points, Querying Shapes, Querying Colors
is_on_line
: Points and Lines
is_on_plane
: Querying Points
is_on_segment
: Points and Lines
is_planar
: Querying Paths
is_quadratic
: Querying Ellipses, Querying Regular Closed Plane Curves
is_quartic
: Querying Ellipses, Querying Regular Closed Plane Curves
is_rectangular
: Querying Rectangles
kill_labels
: Modifying Pictures
label
: Labeling Ellipses, Labelling Paths, Labelling Points
Line
: Line Constructors
location
: Returning Elements and Information for Ellipses, Querying Regular Closed Plane Curves
magnitude
: Vector Operations
mediate
: Points and Lines
mid_point
: Returning Points for Rectangles
modify
: Modifying Colors
operator!=
: Planes Operators, Point Operators, Color Operators
operator&
: Path Operators
operator&=
: Path Operators
operator*
: Point Operators, Transform Operators
operator*=
: Solid Operators, Ellipse Operators, Polygon Operators, Path Operators, Point Operators, Picture Operators, Transform Operators, Shape Operators
operator+
: Path Operators, Point Operators
operator+=
: Path Operators, Point Operators, Picture Operators
operator-
: Point Operators
operator-=
: Point Operators
operator/
: Point Operators
operator/=
: Point Operators
operator<<
: Outputting Points, Color Operators
operator=
: Cuboid Operators, Solid Operators, Circle Operators, Ellipse Operators, Rectangle Operators, Regular Polygon Operators, Planes Operators, Line Operators, Focus Operators, Point Operators, Picture Operators, Transform Operators, Color Operators
operator= (for Points)
: Setting and Assigning to Points
operator==
: Planes Operators, Point Operators, Color Operators
out_circle
: Circles for Regular Polygons
out_ellipse
: Ellipses for Rectangles
out_rectangle
: Rectangles for Ellipses
output
: Outputting Solids, Outputting Paths, Outputting Points, Picture Output Functions, Outputting Labels, Outputting Shapes
Path
: Path Constructors and Setting Functions
persp_0
: Perspective Functions
Picture
: Picture Constructors
Plane
: Planes Constructors
Point
: Point Constructors and Setting Functions
Point::intersection_points
: Intersections
Point::operator=
: Setting and Assigning to Points
Point::set
: Setting and Assigning to Points
project
: Outputting Paths, Projecting Points
quarter
: Regular Closed Plane Curve Segments
real_triple
: Typedefs and Utility Structures
Rectangle
: Rectangle Constructors and Setting Functions
Reg_Polygon
: Regular Polygon Constructors and Setting Functions
reset
: Resetting Transforms
reset_angle
: Modifying Focuses
reset_transform
: Modifying Points, Modifying Pictures
reverse
: Querying Paths
rotate
: Affine Transformations for Solids, Affine Transformations for Ellipses, Affine Transformations for Polygons, Affine Transformations for Paths, Affine Transformations for Points, Affine Transformations for Pictures, Affine Transformations for Transforms, Affine Transformations for Shapes
scale
: Affine Transformations for Solids, Affine Transformations for Ellipses, Affine Transformations for Polygons, Affine Transformations for Paths, Affine Transformations for Points, Affine Transformations for Pictures, Affine Transformations for Transforms, Affine Transformations for Shapes
segment
: Regular Closed Plane Curve Segments
set
: Tetrahedron Constructors and Setting Functions, Circle Constructors and Setting Functions, Ellipse Constructors and Setting Functions, Rectangle Constructors and Setting Functions, Regular Polygon Constructors and Setting Functions, Path Constructors and Setting Functions, Focus Constructors and Setting Functions, Point Constructors and Setting Functions, Color Constructors and Setting Functions
set (for Points)
: Setting and Assigning to Points
set_blue_part
: Modifying Colors
set_connectors
: Modifying Paths
set_cycle
: Querying Paths
set_dash_pattern
: Modifying Paths
set_draw_color
: Modifying Paths
set_element
: Setting Values Transforms
set_extremes
: Outputting Solids, Outputting Paths, Outputting Points, Outputting Shapes
set_fill_color
: Modifying Paths
set_fill_draw_value
: Modifying Paths
set_green_part
: Modifying Colors
set_name
: Modifying Colors
set_on_free_store
: Setting Solid Members, Modifying Paths, Modifying Points, Modifying Shapes
set_pen
: Modifying Paths
set_red_part
: Modifying Colors
set_transform
: Modifying Pictures
set_use_name
: Modifying Colors
shear
: Affine Transformations for Solids, Affine Transformations for Ellipses, Affine Transformations for Polygons, Affine Transformations for Paths, Affine Transformations for Points, Affine Transformations for Transforms, Affine Transformations for Shapes
shift
: Affine Transformations for Solids, Affine Transformations for Ellipses, Affine Transformations for Polygons, Affine Transformations for Paths, Affine Transformations for Points, Affine Transformations for Pictures, Affine Transformations for Transforms, Affine Transformations for Shapes
shift_times
: Affine Transformations for Ellipses, Affine Transformations for Polygons, Affine Transformations for Paths, Affine Transformations for Points, Affine Transformations for Transforms
show
: Showing Solids, Showing Paths, Planes Showing, Showing, Showing Focuses, Showing Points, Showing Pictures, Showing Transforms, Showing Shapes, Showing Colors
show_colors
: Showing Paths
show_transform
: Showing Points, Showing Pictures
size
: Querying Paths
slope
: Querying Paths, Points and Lines
Solid
: Solid Constructors and Setting Functions
solve
: Solving Ellipses, Querying Regular Closed Plane Curves
solve_quadratic
: Utility Functions
subpath
: Querying Paths
suppress_labels
: Picture Output Functions
suppress_output
: Outputting Solids, Outputting Paths, Outputting Points, Outputting Shapes
Tetrahedron
: Tetrahedron Constructors and Setting Functions
Transform
: Transform Constructors
trunc
: Utility Functions
Trunc_Octahedron
: Truncated Octahedron Constructors and Setting Functions
undraw
: Drawing and Filling Solids, Drawing and Filling Paths, Point Drawing Functions
undrawdot
: Point Drawing Functions
unfill
: Drawing and Filling Solids, Drawing and Filling Paths
unfilldraw
: Drawing and Filling Solids, Drawing and Filling Paths
unit_vector
: Vector Operations
unsuppress_labels
: Picture Output Functions
unsuppress_output
: Outputting Solids, Outputting Paths, Outputting Shapes
void
: Outputting Points
write_footers
: I/O Functions
~Cuboid
: Cuboid Constructors and Setting Functions
~Path
: Path Destructor
~Point
: Point Destructor
~Solid
: Solid Destructor
Points
: Drawing Points Intro
Paths
: Path Data Members
Points
, connecting: Drawing Points Intro
ctangle
creates
<
filename>.c
from
<filename>
.web
,
so the compiler must compile the C++
files
using the -x c++
option. Otherwise, it would handle them as if
they contained C code.
If you want to try generating the illustrations yourself, you
can save a little run-time by calling tex 3DLDF.texi
the
first time, rather than texi2dvi
. The latter program runs
TeX twice, because it needs two passes in order to generate the
contents, indexing, and cross reference information (and maybe some
other things, too).
Knuth, Donald E. The TeXbook. Computers and Typesetting; A. Addison-Wesley Publishing Company. Reading, Massachusetts 1986.
Rokicki, Tomas. Dvips: A DVI-to-PostScript Translator February 1997. Available from CTAN. See Sources of Information.
"<...> METAFONT deals only with numbers in a limited range: A numeric token must be less than 4096, and its value is always rounded to the nearest multiple of 1 / 65536." Knuth, The METAFONTbook, p. 50.
Scan conversion is the process of digitizing geometric data. The ultimate result is a 2 X 2 map of pixels, which can be used for printing or representing the projection on a computer screen. The number of pixels per a given unit of measurement is the resolution of a given output device, e.g., 300 pixels per inch.
Knuth, The METAFONTbook, Chapter 14, p. 127.
Flex is a program for generating text scanners and Bison is a parser generator. They are available from http://www.gnu.org.
Affine transformations are operations that have the property that parallelity of lines is maintained. That is, if two lines (each determined by two points) are parallel before the transformation, they will also be parallel after the transformation. Affine transformations are discussed in many books about computer graphics and geometry. For 3DLDF, I've mostly used Jones, Computer Graphics through Key Mathematics and Salomon, Computer Graphics and Geometric Modeling.
I try to avoid the use of preprocessor macros as much as possible, for the reasons given by Stroustrup in the The C++ Programming Language, section 7.8, pp. 160-163, and Design and Evolution of C++ , Chapter 18, pp. 423-426. However, conditional compilation is one of the tasks that only the preprocessor can perform.
It is unfortunate that the terms "array", "matrix", and "vector" have different meanings in C++ and in normal mathematical usage. However, in practice, these discrepancies turn out not to cause many problems. Stroustrup, The C++ Programming Language, section 22.4, p. 662.
In fact, none of the operations for transformations require all of the elements of a 4 X 4 matrix. In many 3D graphics programs, the matrix operations are modified to use smaller transformation matrices, which reduces the storage requirements of the program. This is a bit tricky, because the affine transformations and the perspective transformation use different elements of the matrix. I consider that the risk of something going wrong, possibly producing hard-to-find bugs, outweighs any benefits from saving memory (which is usually no longer at a premium, anyway). In addition, there may be some interesting non-affine transformations that would be worth implementing. Therefore, I've decided to use full 4 X 4 matrices in 3DLDF.
Pens are a concept from Metafont. In 3DLDF,
there is currently no type "Pen
". Pen arguments to functions
are simply strings
, and are written unaltered to out_stream
.
For more information about
Metafont's pens
, see
Knuth, The Metafontbook, Chapter 4.
Colors
are declared in the
namespace Colors
, so if you have
a "using
" declaration in the function where you use
drawdot()
, you can write "black
" instead of
"Colors::black
". For more information about namespaces, see
Stroustrup, The C++
Programming Language, Chapter 8.
"A reference is an alternative name for an object. The main use of references is for specifying arguments and return values for functions in general and for overloaded operators (Chapter 11) in particular." Stroustrup, The C++ Programming Language, section 5.5, p. 97.
I believe that counter-examples could probably constructed, but for the most common cases, the principle applies.
It's easy to forget to use Point*
arguments, rather
than plain Point
arguments, and to forget to end the list of
arguments with 0. If plain Point
arguments are used, compilation
fails with GCC. With the DEC compiler, compilation succeeds, but a
memory fault error occurs at run-time. If the argument list doesn't end
in 0, neither compiler signals an error, but a memory fault error always
occurs at run-time.
Knuth, The METAFONTbook, Chapter 14, p. 127.
Namespaces are described in Stroustrup, The C++ Programming Language, Chapter 8.
There are many books on linear perspective for artists. I've found Gwen White's Perspective. A Guide for Artists, Architects and Designers to be particularly good. Vredeman de Vries, Perspective contains beautiful examples of perspective constructions.
(I believe the following to be correct, but I'm not entirely sure.) Let vector v be the line of sight. By definition, the plane of projection will be a plane p, such that vector v is normal to p. Let q_0 and q_1 be planes such that q_0 == q_1 or q_0 || q_1, and q_0 is perpendicular to p. It follows that q_1 is perpendicular to p. Let l_0 and l_1 be lines, such that l_0 != l_1, l_0 || l_1, l_0 lies within q_0, l_1 lies within q_1, l_0 is perpendicular to vector v, and l_1 is perpendicular to vector v. Under these circumstances, the projections of l_0 and l_1 in p will also be parallel.
I believe this to be true, but I'm not certain.
The books on computer graphics and the fairly elementary mathematics books that I own or have referred to don't go into intersections very deeply. One that does is Fischer, Gerd. Ebene Algebraische Kurven, which is a bit over my head.
Stallman, Richard M. Using and Porting the GNU Compiler Collection, p. 285.
Hobby, A User's Manual for MetaPost, pp. 21-22.
Rokicki, Dvips: A DVI-to-PostScript Translator, p. 24.
Knuth, Donald E. The Metafontbook, p. 66.
If your system supplies an unsigned integer type with the same
length as long double
, then you can instantiate
get_second_largest<long double>()
and call
get_second_largest<long double>(LDBL_MAX)
. However, I doubt
that this amount of precision would be worthwhile. If it ever were
required, 3DLDF would have to be changed in other ways, too. In
particular, it would have to use more precise trigonometric functions
for rotations. See Accuracy.
For that matter, I haven't really tested whether 0.00001 is a
good value when real
is float
.
For a person, not in the sense of the program behaving unpredictably.
label()
and dotlabel()
are currently only defined for Point
and Path
(and the
latter's derived classes), i.e., not for Solid
and its derived
classes.
Actually, it's printed to standard output even if it is the empty string, you just don't see it.
It's unlikely that Points
will lie on a Plane
,
unless the user constructs the case specially.
In [next figure]
, the coordinates for B and C were found by using
Plane::intersection_point()
.
See Planes; Intersections.
For that matter, I haven't really tested whether 0.00001 is a
good value when real
is float
.
Stroustrup, The C++ Programming Language, p. 96.
It isn't sufficient to check whether a
Path
consists of only two Points
to determine whether it
is a line or not, since a connector with "curl
" could cause it
to be non-linear. On the other hand, Paths
containing only
colinear Points
and the connector "--"
are perfectly
legitimate lines. I'm in the process of changing all of the code that
tests for linearity by checking the value of line_switch
, so that
it uses is_linear()
instead. When I've done this, it may be
possible to eliminate line_switch
.
See Path Reference; Data Members, and
Path Reference; Querying.
Stroustrup, The C++ Programming Language, p. 88.
Where possible, I prefer to use the C++
data
type string
rather than char*
, however it was necessary to
use char*
here because 0 is not a valid string
, even
though string
may be implemented as char*
,
and 0 must be a valid argument, since it is needed to indicate the end
of the argument list.
Hobby, A User's Manual for MetaPost, p. 32.
Knuth, The METAFONTbook, Chapter 4, p. 21ff. Hobby, A User's Manual for MetaPost, p. 32.
The usual interpretation of ""
as a
position argument to a
labelling command would be to put it directly onto *(Label.pt)
,
which in this case would put it onto the arrowhead. Since this
will probably never be desirable, I've decided to use ""
to
suppress drawing axes. Formerly, draw_axes()
used three
additional arguments for this purpose.
The following example shows only one Point
per
line. In actual use, two Points
are shown, but this causes
overfull boxes in Texinfo.
Reg_Polygon
and Rectangle
are currently the only
classes derived from Polygon
.
If you don't know what "overfull boxes" are, don't worry about it. It has to do with TeX's line and page breaking algorithms. If you want to know more, see Knuth, Donald E., The TeXbook.
Albrecht Dürer invented this method of constructing polyhedra.
The GNU Coding Standards are available at http://www.gnu.org/prep/standards_toc.html.
Automake is available for downloading from http://ftp.gnu.org/gnu/automake/. The Automake website is at http://www.gnu.org/software/automake/.
Stroustrup, The C++ Programming Language, §15.2 "Multiple Inheritance", pp. 390-92.
Cundy and Rollet, Mathematical Models, Chapter 3, "Polyhedra", pp. 76-160.
Huw Jones, Computer Graphics through Key Mathematics, and David Salomon, Computer Graphics and Geometric Modeling, are my main sources of information about spline curves.
Jones, Huw. Computer Graphics through Key Mathematics, p. 282.
Knuth, Donald Ervin. The METAFONTbook, p. 130, and Hobby, John D. Smooth, Easy to Compute Interpolating Splines. Discrete and Computational Geometery 1(2).