maintainer:

• Ivica Ico Bukvic ico@vt.edu

Mailing List

• Downloads
• One Paragraph Overview
• Three Paragraph Overview
• Goals
• User Guide
• Relationship of Pd-L2Ork to Pure Data
• Build Guide
  • Gnu/Linux
  • OSX
  • Windows
• Code of Conduct
• Project Governance
• Contributor Guide
• Human Interface Guidelines
• Core Pd Notes
• GUI Message Spec

Pure Data (aka Pd) is a visual programming language. That means you can use it to create software graphically by drawing diagrams instead of writing lines of code. These diagrams show how data flows through the software, displaying on the screen what text-based languages require you to piece together in your mind.

Pd has been designed with an emphasis on generating sound, video, 2D/3D graphics, and connecting through sensors, input devices, and MIDI as well as OSC devices.

Pd has a special emphasis on generating audio and/or video in real time, with low latency. Much of its design focuses on receiving, manipulating, and delivering high-quality audio signals. Specifically, the software addresses the problem of how to do this efficiently and reliably on general purpose operating systems like OSX, Windows, Debian, etc.-- i.e., systems designed mainly for multi-tasking.

Pd can easily work over local and remote networks. It can be used to integrate wearable technology, motor systems, lighting rigs, and other equipment. Pd is also suitable for learning basic multimedia processing and visual programming methods, as well as for realizing complex systems for large-scale projects.

Pd-L2ork has the following goals:

1. Documentation. We like documentation. It's like code, except friendly.
2. Be reliable. Binary releases must be usable for performances and installations. The git repo must always be in a workable state that can be compiled. Regressions must be fixed quickly.
3. Be discoverable. Undocumented features are buggy. Missing help files are bugs. Patches for new functionality that lack documentation are spam.
4. Be consistent. Consistent interfaces are themselves a kind of documentation. We like documentation, so it follows that we like consistent interfaces.

For Pd-L2Ork website see:

http://l2ork.music.vt.edu/main/make-your-own-l2ork/software/

There are two maintained distributions of Pure Data:

1. This is the 2.x version of Pd-L2Ork. It ships with lots of external libraries and uses a modern GUI written using HTML5.
2. Pure Data "Vanilla". Miller Puckette's personal version which he hosts on his website and maintains. It doesn't come with external libraries pre-installed, but it does include an interface you can use to search and install external libraries maintained and packaged by other developers.

Windows and OSX:

Releases are provided on the L2Ork's webpage:

http://l2ork.music.vt.edu/main/make-your-own-l2ork/software/

Linux:

Releases for Debian/Ubuntu are provided on the L2Ork's webpage:

http://l2ork.music.vt.edu/main/make-your-own-l2ork/software/

Pd-L2Ork is usually built by just running make in the toplevel source directory after checking out the sources from its git repository. This works across all supported platforms (Linux, Mac and Windows at this time). The Makefile also offers the customary targets to clean (make clean, or make realclean to put the sources in pristine state again) and to roll a self-contained distribution tarball (make dist), as well as some other convenience targets (please check the comments at the beginning of the Makefile for more information).

However, to make this work, you will most likely have to install some prerequisites first: build tools such as a C/C++ compiler and the make program itself, as well as dependencies, the libraries that Pd-L2Ork needs. Detailed instructions for each of the supported platforms are given below.

Time to build: 10 minutes light install, 45 minutes to 1.5 hours full install Hard drive space required: roughly 2.5 GB

1. Install the dependencies (please note that the packages may be named slightly differently for different Linux distributions; the given names are for Debian/Ubuntu). If the command is successful, you will get a printout on the terminal where command was invoked showing bunch of packages being downloaded from the internet and then installed.

   IMPORTANT! If any of the libraries below are tagged as unavailable, note that none of them will be installed until you specify correct replacement library or remove the missing libraries from this list.

    sudo apt-get install bison flex automake libasound2-dev \
         libjack-jackd2-dev libtool libbluetooth-dev libgl1-mesa-dev \
         libglu1-mesa-dev libglew-dev libmagick++-dev libftgl-dev \
         libgmerlin-dev libgmerlin-avdec-dev libavifile-0.7-dev \
         libmpeg3-dev libquicktime-dev libv4l-dev libraw1394-dev \
         libdc1394-22-dev libfftw3-dev libvorbis-dev ladspa-sdk \
         dssi-dev tap-plugins invada-studio-plugins-ladspa blepvco \
         swh-plugins mcp-plugins cmt blop omins rev-plugins \
         dssi-utils vco-plugins wah-plugins fil-plugins \
         mda-lv2 libmp3lame-dev libspeex-dev libgsl0-dev \
         portaudio19-dev liblua5.3-dev python3-dev libsmpeg0 libjpeg-dev \
         flite1-dev libgsm1-dev libgtk2.0-dev git libstk0-dev \
         libfluidsynth-dev fluid-soundfont-gm byacc cmake ninja-build \
         patchelf gconf2 libnss3
   

2. Clone the Pd-L2Ork repository (2 to 10 minutes)

    git clone https://github.com/pd-l2ork/pd-l2ork.git
   

3. Compile the code (5 minutes [light] to 1.5 hours [full])

   • to build only the core: make light (5 minutes)
   • to build the core and all externals: make all (20 minutes to 1.5 hours)
   • to build everything except Gem: make incremental (10 to 20 minutes)

4. If you're using an apt-based Linux distribution and you have the necessary Debian packaging tools installed, there should now be an installer file in the main source directory, which can be installed as usual. Otherwise, run make install to install the software, and make uninstall to remove it again.

Time to build: 50 minutes to 1.5 hours
Hard drive space required: roughly 2 GB

1. Install Homebrew (15 minutes) (asks for password twice-- once for command line tools, once for homebrew)

2. Install the dependencies (10 minutes):

    brew install wget
    brew install autoconf
    brew install automake
    brew install libtool
    brew install fftw
    brew install python
    brew install lua
    brew install fluidsynth
    brew install faac
    brew install lame
    brew install libvorbis
    brew install speex
    brew install gsl
    brew install libquicktime
    brew install sdl2
    brew install pkg-config
    brew install gettext
    brew install freetype2
    brew install ftgl
    brew install jpeg
    brew install libtiff
    brew install sdl
    brew install glfw
    brew install ninja
    brew install cmake
    brew install lua
   

3. Clone the Pd-L2Ork repository (10 minutes)

    git clone https://github.com/pd-l2ork/pd-l2ork.git
   

4. Change to the source directory

    cd pd-l2ork
   

5. Build the OSX app and the installer disk image (.dmg file) (15 minutes)

    make
   

6. There should now be a .dmg file in your current directory, which lets you install the app in the usual way

Time to build: roughly 1.5 hours--30 minutes of this is for Gem alone
Hard drive space required to build: rougly 2.5 GB

Important note: We recommend doing the build under your msys2 home directory (usually /home/username in the msys2 shell). This directory should not have any spaces in it, which would otherwise cause trouble during the build. Never try using your Windows home directory for this purpose instead, since it will usually contain spaces, making the build fail.

1. Download and install msys2 (5 minutes)
   There are two installers-- one for 32-bit Windows systems (i686) and one for 64-bit Windows (x86_64). Be sure you know which version of Windows you are running and download the appropriate installer.
   Note: don't run the shell after installation finishes. You'll do that manually in step 3.

2. Download and install the inno setup Quickstart Pack which includes the Script Editor (5 minutes)

3. Run the "MSYS2 MinGW 32-bit" shell (less than a minute)
   msys2 adds three Start Menu items for different "flavors" of shell:

   • MSYS2 MinGW 32-bit <- click this one!
   • MSYS2 MinGW 64-bit
   • MSYS2 MSYS

4. Install the dependencies (5-10 minutes)
   Once the shell opens, we need to install the dependencies for building Pd-L2Ork. First we need to update all the packages:

    pacman -Syu
   

   After closing and reopening the shell as prompted, you may need to do it again:

    pacman -Syu
   

   Now everything should be up-to-date. Issue the following command:

    pacman -S autoconf automake git libtool \
      make mingw-w64-i686-dlfcn mingw-w64-i686-fftw \
      mingw-w64-i686-fluidsynth \
      mingw-w64-i686-SDL2 \
      mingw-w64-i686-ftgl mingw-w64-i686-fribidi \
      mingw-w64-i686-ladspa-sdk mingw-w64-i686-lame \
      mingw-w64-i686-libsndfile mingw-w64-i686-libvorbis \
      mingw-w64-i686-lua mingw-w64-i686-toolchain \
      mingw-w64-i686-libjpeg-turbo \
      mingw-w64-i686-speex \
      rsync unzip wget mingw-w64-i686-cmake \
      mingw-w64-i686-ninja \
      mingw-w64-i686-glfw mingw-w64-i686-pcre
   

5. Download the source code (3-6 minutes)
   Issue the following command to create a new directory "pd-l2ork" and clone the repository to it:

    git clone https://github.com/pd-l2ork/pd-l2ork.git
   

6. Enter the source directory (less than a minute)

    cd pd-l2ork
   

7. Install older versions of dlfcn and binutils packages that are included in the pd-l2ork git. This is due to newer packages misssing one critical library that prevents certain externals from building. For an experimental 64-bit version (currently unsupported) replace win32_inno with win64_inno:

    cd packages/win32_inno/msys
    pacman -U mingw-w64-i686-dlfcn-1.2.0-1-any.pkg.tar.xz \
      mingw-w64-i686-binutils-2.39-3-any.pkg.tar.zst
   

8. Finally, build Pd-L2Ork (45-80 minutes)

    cd ~/pd-l2ork
    make
   

9. Look in the top level source directory and double-click the setup file to start installing Pd-L2Ork on your system.

The instructions are exactly the same as for the 32 bit build (see above), but the build needs to be done using mingw64 instead of mingw32. That is:

• Install the mingw64 packages for the dependencies. See the i686 packages listed under dependencies above, and replace i686 with x86_64 in the package names when installing.

• Use the MSYS2 MinGW 64-bit shell (rather than the 32-bit shell) to do the build.

Please be kind, ask questions, and offer help wherever possible. Our community is small but nonetheless strong and its greatest strength is its collegiality.

Contributing is easy:

1. Join the development list: http://disis.music.vt.edu/cgi-bin/mailman/listinfo/l2ork-dev
2. Fork Pd-L2Ork using the gitlab UI and then try to build it from source for your own platform using the Build Guide above. If you run into problems ask on the development list for help.
3. Once you have successfully built Pd-L2Ork, install it and make sure it runs correctly.
4. Start making changes to the code with brief, clear commit messages.
5. One you are done fixing the bug or adding your feature, make a merge request in the Gitlab UI so we can merge the fix for the next release.

A few guidelines:

• There should be a short and clear commit message for each merge request.
• Short and clear title and description are required for each merge request.
• There should be a short branch name related to the issue, like "update-readme".
• No prototypes, please. Pd-L2Ork's biggest strength is that users can turn an idea into working code very quickly. But a prototyping language that is itself a prototype isn't very useful. That means Pd-L2Ork's core code and libraries must be stable, consistent, well-documented, and easy to use.
• Develop incrementally. Small, solid improvements to the software are preferable to large, disruptive ones.
• Try not to duplicate existing functionality. For backwards compatibility Pd-L2Ork ships many legacy libraries which unfortunately duplicate the same functionality. This makes it harder to learn how to use Pd, and makes it burdensome to read patches and keep track of all the disparate implementations.
• Keep dependencies to a minimum. Cross-platform dependency handling is unfortunately still an open research problem.

Pd is a multi-window application that consists of three parts:

1. A main window, called the "Pd Window" or "Console Window". This window displays informational and error messages for Pd programs.
2. One or more "canvas" windows-- aka "patch" windows, used to display the diagrams that make up a Pd program.
3. One or more dialog windows used to configure the various parts of Pd.

All should look simple and uncluttered. Although "canvas" windows cannot (yet) be traversed and edited using only the keyboard, all three parts of Pd should be designed so that they can be manipulated using only the keyboard.

It should also be possible to produce sound and interact when a new user runs program for the very first time. In every release, there should be a link at the bottom of the Console Window to a short game written in Pd that demonstrates one or more of the capabilities of the Pd environment. The game should be designed to be fun outside of its efficacy as a demonstration of Pd.

Pd ships with "DejaVu Sans Mono", which is used for the text in canvas windows. Fonts are sized to fit the hard-coded constraints in Pd Vanilla. This way box sizes will match as closely as possible across distributions and OSes.

These hard-coded sizes are maximum character widths and heights. No font fits these maximums exactly, so it's currently impossible to tell when looking at a Pd canvas whether the objects will collide on a system using a different font (or even a different font-rendering engine).

Dialogs and console button labels may use variable-width fonts. There is not yet a suggested default to use for these.

The console printout area currently uses "DejaVu Sans Mono". Errors are printed as a link so that the user can click them to highlight the corresponded canvas or object that triggered the error.

Nothing set in stone yet.

The following is adapted from Pd Vanilla's original source notes. (Found in pd/src/CHANGELOG.txt for some reason...)

Sections 2-3 below are quite old. Someone needs to check whether they even hold true for Pd Vanilla anymore.

First, the containment tree of things that can be sent messages ("pure data"). (note that t_object and t_text, and t_graph and t_canvas, should be unified...)

BEFORE 0.35:

m_pd.h      t_pd                        anything with a class
                t_gobj                  "graphic object"
                    t_text              text object
g_canvas.h
                    t_glist             list of graphic objects
g_canvas.c              t_canvas        Pd "document"

AFTER 0.35:

m_pd.h      t_pd                        anything with a class
                t_gobj                  "graphic object"
                    t_text              patchable object, AKA t_object
g_canvas.h              t_glist         list of graphic objects, AKA t_canvas

Other structures:

g_canvas.h  t_selection -- linked list of gobjs
            t_editor -- editor state, allocated for visible glists
m_imp.h     t_methodentry -- method handler
            t_widgetbehavior -- class-dependent editing behavior for gobjs
            t_parentwidgetbehavior -- objects' behavior on parent window
            t_class -- method definitions, instance size, flags, etc.

1.0 C coding style. The source should pass most "warnings" of C compilers (-Wall on Linux, for instance-- see the makefile.) Some informalities are intentional, for instance the loose use of function prototypes (see below) and uncast conversions from longer to shorter numerical formats. The code doesn't respect "const" yet.

1.1. Prefixes in structure elements. The names of structure elements always have a K&R-style prefix, as in ((t_atom)x)->a_type, where the a_ prefix indicates "atom." This is intended to enhance readability (although the convention arose from a limitation of early C compilers.) Common prefixes are:

• w_ (word)
• a_ (atom)
• s_ (symbol)
• ob_ (object)
• te_ (text object)
• g_ (graphical object)
• gl_ (glist, a list of graphical objects).

Also, global symbols sometimes get prefixes, as in s_float (the symbol whose string is "float"). Typedefs are prefixed by t_. Most private structures, i.e., structures whose definitions appear in a ".c" file, are prefixed by x_.

1.2. Function arguments. Many functions take as their first argument a pointer named x, which is a pointer to a structure suggested by the function prefix; e.g., canvas_dirty(x, n) where x points to a canvas (t_canvas *x).

1.3. Function Prototypes. Functions which are used in at least two different files (besides where they originate) are prototyped in the appropriate include file. Functions which are provided in one file and used in one other are prototyped right where they are used. This is just to keep the size of the ".h" files down for readability's sake.

1.4. Whacko private terminology. Some terms are lifted from other historically relevant programs, notably "ugen" (which is just a tilde object; see d_ugen.c.)

1.5. Spacing. Tabs are 8 spaces; indentation is 4 spaces. Indenting curly brackets are by themselves on their own lines, as in:

if (x)
{
    x = 0;
}

Lines should fit within 80 spaces.

2.0. Max patch-level compatibility. "Import" and "Export" functions are provided which aspire to strict compatibility with 0.26 patches (ISPW version), but which don't get anywhere close to that yet. Where possible, features appearing on the Mac will someday also be provided; for instance, the connect message on the Mac offers segmented patch cords; these will devolve into straight lines in Pd. Many, many UI objects in Opcode Max will not appear in Pd, at least at first.

3.0. Compatibility with Max 0.26 "externs"-- source-level compatibility. Pd objects follow the style of 0.26 objects as closely as possible, making exceptions in cases where the 0.26 model is clearly deficient. These are:

3.1. Anything involving the MacIntosh "Handle" data type is changed to use char * or void * instead.

3.2. Pd passes true single-precision floating-point arguments to methods; Max uses double. Typedefs are provided:

t_floatarg, t_intarg for arguments passed by the message system
t_float, t_int for the "word" union (in atoms, for example.)

3.3. Badly-named entities got name changes:

w_long --> w_int (in the "union word" structure)

3.4. Many library functions are renamed and have different arguments; I hope to provide an include file to alias them when compiling Max externs.

4.0. Function name prefixes. Many function names have prefixes which indicate what "package" they belong to. The exceptions are:

typedmess, vmess, getfn, gensym (m_class.c)
getbytes, freebytes, resizebytes (m_memory.c)
post, error, bug (s_print.c)

which are all frequently called and which don't fit into simple categories. Important packages are:

(pd-gui:)   pdgui -- everything
(pd:)       pd -- functions common to all "pd" objects
            obj -- fuctions common to all "patchable" objects ala Max
            sys -- "system" level functions
            binbuf -- functions manipulating binbufs
            class -- functions manipulating classes
            (other) -- functions common to the named Pd class

5.0. Source file prefixes.

PD:

s    system interface
m    message system
g    graphics stuff
d    DSP objects
x    control objects
z    other

PD-GUI:

gui    GUI front end

1. Brackets on the same line as declaration or expression: if (a) {
2. Single line comments only: //
3. Use double-quotes for strings
4. Use underscores to separate words of function names and variables

Purpose: a set of functions to communicate with the gui without putting language-specific strings (like tcl) into the C code. The new interface is a step toward separating some (but not all) of the GUI logic out from the C code. Of course the GUI can still be designed to parse and evaluate incoming messages as commands. But the idiosyncracies of the GUI toolkit can be limited to either the GUI code itself or to a small set of modular wrappers around sys_vgui.

The public interface consists of the following:

gui_vmess(const char *msg, const char *format, ...);

where const char *format consists of zero or more of the following:

• f - floating point value (t_float)
• i - integer (int)
• s - c string (`char* )
• x - hexadecimal integer value, with a precision of at least six digits. (hex value is preceded by an 'x', like x123456)

For some of Pd's internals like array visualization, the message length may vary. For these special cases, the following functions allow the developer to iteratively build up a message to send to the GUI.

gui_start_vmess(const char *msg, const char *format, ...);
gui_start_array();      // start an array
gui_f(t_float float);   // floating point array element (t_float)
gui_i(int int);         // integer array element (int)
gui_s(const char *str); // c string array element
gui_end_array();        // end an array
gui_end_vmess();        // terminate the message

The above will send a well-formed message to the GUI, where the number of array elements are limited by the amount of memory available to the GUI. Because of the complexity of this approach, it may only be used when it is necessary to send a variable length message to the GUI. (Some of the current code may violate this rule, but that can be viewed as a bug which needs to get fixed.)

The array element functions gui_f, gui_i, and gui_s may only be used inside an array. Arrays may be nested, but this adds complexity and should be avoided if possible.

The public functions above should fit any sensible message format. Unfortunately, Pd's message format (FUDI) is too simplistic to handle arbitrary c-strings and arrays, so it cannot be used here. (But if it happens to improve in the future it should be trivial to make a wrapper for the public interface above.)

The current wrapper was made with the assumption that there is a Javascript Engine at the other end of the message. Messages consist of a selector, followed by whitespace, followed by a comman-delimited list of valid Javascript primitives (numbers, strings, and arrays). For the arrays, Javascript's array notation is used. This is a highly idiosyncratic, quick-and-dirty approach. But the point is that the idiosyncracy exists in a single file of the source code, and can be easily made more modular (or replaced entirely by something else) without affecting any of the rest of the C code.