The purpose of this chapter is to describe Pd's design and how it is supposed to work. Practical details about how to obtain, install, and run Pd are described in the next chapter. To learn digital audio processing basics such as how to generate time-varying sounds that don't click or fold over, a good reference is Dodge and Jerse, Computer Music .
There are peak level and clip indicators for audio input and output; these report peak levels over all input and all output channels. Note that DC shows up as an input level; many cards have DC levels which show up in the 50s. To see an RMS audio level, select "test audio and MIDI" from the help window. The main window display is intended only to help you avoid clipping on input and output. You can turn the peak meters on and off using the control at bottom left.
At bottom right is a control to turn audio processing on and off globally. Turning audio off does not relinquish the audio devices, it just stops the computation. The "audio" menu is also provided, with accelerators "Control-." to turn audio computation off and "Control-/" to turn it on. When audio is on, Pd is computing audio samples in real time according to whatever patches you have open (visible or not.)
The DIO (Digital I/O) error indicator flashes if there is a synchronization error for audio input or output. Click there to see a list of recent errors. This indicator is normally red at startup, and will turn red whenever the computation runs late (so that the DAC FIFOs fill and/or the ADC FIFOs empty) or if audio input and output are not running at the same rate. See audio and MIDI support .
Pd documents are called "patches" or "canvases." Each open document has one main window and any number of subwindows. The subwindows can be opened and closed but are always running whether you can see them or not. Here is a simple Pd patch:
There are four text boxes in this patch: a number box (showing zero), an object box showing "print," and two comments. The number box and the object box are connected, the number box's output to the print box's input. Boxes may have zero or more inputs and/or outputs, with the inputs on top and the outputs on bottom.
Pd's printout appears on its standard output. Normally, you'll run Pd in a "shell" or "terminal" window which you'll keep open to see any printout or error messages.
Pd patches can have four types of boxes: object, message, GUI, and comment .
You make objects by typing text into object boxes. The text is divided into atoms separated by white space. The first atom specifies what type of object Pd will make, and the other atoms, called creation arguments , tell Pd how to initialize the object. If you type for example,
the "+" specifies the class of the object. In this case the object will be the kind that carries out addition, and the "13" initializes the amount to add. Atoms are either numbers or symbols like "+". The text you type into an object box determines how many and what kinds of inlets and outlets the object will have. Some classes (like "+" always have a fixed arrangement of inlets and outlets, and in the case of other classes, the inlets and outlets will depend on the creation arguments.
Here for example is a simple MIDI synthesizer:
This patch mixes control objects (notein, stripnote, and ftom) with tilde objects osc~, *~, and dac~. The control objects carry out their function sporadically, as a result of one or more type of event . In this case, incoming MIDI note messages set off the control computation. The result of the computation is, when the note happens to be a "note on" (and not a "note off", to compute the frequency in cycles per second and pass it on to the oscillator ("osc~").
The second half of the patch, the osc~, *~, and dac~ objects, compute audio samples, in the same way as an analog synthesizer works. The osc~ object is acting as the interface between the two regimes, in that it takes control messages to set its frequency but talks to "*~" using an audio signal. Audio signals aren't sporadic; they are continuous streams of numbers. As a result tilde objects act under very different rules from control objects. The audio portion of the patch is always running, whether MIDI messages arrive or not; the function of control computations is to insert calculations between the audio computation which may change audio computation parameters such as the frequency of an oscillator.
The third box shown is a GUI box. GUI boxes come in many forms including number boxes (as in this example), toggles, sliders, and so on. Whereas the appearance of an object or message box is static when a patch is running, a number box's contents (the text) changes to reflect the current value held by the box. You can also use a number box as a control by clicking and dragging up and down, or by typing values in it. (There are also shift- and alt-click actions; see getting help to find out how to look this up).
You can also create a "symbol" box which is like a number box but deals in symbols like "cat." You can type your own strings in (followed by "enter") or use it to display strings which arrive as messages to its inlet.
A patch can be in edit or run mode; this really only affects how mouse clicks affect the patch. In edit mode, clicking and dragging selects and moves boxes or makes and cuts connections; in run mode clicking on boxes sends them messages which they react to in different ways. In run mode, number and message boxes can be used as controls. Normally, when you are in a performance you will stay in run mode; to change the patch you go to edit mode.
You can create boxes (objects, messages, GUIs, and comments) using the "put" menu. Note the handy accelerators. Object and message boxes are empty at first; drag them where you want them and type in the text. The GUI objects (which come in several flavors) require no typing; just create and place them.
You will often find it more convenient to select a box and "duplicate" it (in the Edit menu) than to use the "Put" menu. If you select and duplicate several items, any connections between them will be duplicated as well.
To change a text item, you can select it and then edit the text. If you only click once, the entire text is selected and your typing will replace everything. Click again and drag to select a portion of the text to retype.
If there's more than a small amount of text (in a comment, for example) you might want to select the text and choose "text editor" from the Edit menu, which opens a text editing window with a copy of the text in it. Hitting "send" in that window is exactly equivalent to retyping the text into Pd; you can send it to more than one box in sequence if you want.
If you click a box and move the mouse without releasing the button this displaces the entire box. If you wish to displace a box which is already sepected, first deselect the box by clicking outside it; otherwise you will be selecting text instead of moving the box.
The updated text only becomes part of the patch when you deselect the object. Changing the text in an "object" box actually deletes the old object and creates a new one; the internal state of the old one is lost.
all the "clicking" mentioned above is done with the left mouse button. The right button, instead, gives a popup menu for "properties" and "help". Properties are enabled for number boxes and graphs (and in the future may be available for other things as well.) Selecting "help" on an object gets a Pd patch that demonstrates how to use it. "Help for the canvas as a whole (click outsize any object) gives a list of all built-in objects.
Control-q "quits" Pd, but asks you to comfirm the quit. To quit without having to confirm, use command-shift-Q.
In Pd, objects intercommunicate by sending messages and/or audio signals. Pd messages are sporadic, like MIDI messages or music N "Note cards."
When a message is passed to something (which is often an inlet of a box but could be anything that can receive a message), the selector of the message is checked against the receiver. If the receiver recognizes messages of that selector, it carries out some corresponding action. For instance, here is a "float" object:
The two rectangles at the top are usually both called "inlets" but the one at the left directs incoming messages to the "float" object itself, whereas the one at the right directs messages to an auxilliary "inlet" object. The float object proper (represented by the left-hand inlet) accepts messages with selector "float" and "bang". The right-hand inlet takes only the message selector "float". These two selectors, along with "symbol" and "list", are usually used to denote an object's main action, whatever it may be, so that objects can be interconnected with maximum flexibility.
It is possible to type messages which start with a number, which cannot be used as a selector. A single number is always given the "float" selector automatically, and a message with a number followed by other arguments is given the selector "list".
In Pd whenever a message is initiated, the receiver may then send out further messages in turn, and the receivers of those messages can send yet others. So each message sets off a tree of consequent messages. This tree is executed in depth first fashion. For instance in the patch below:
the order of arrival of messages is either A-B-C-D or A-C-D-B. The "C" message is not done until the "D" one is also, and the "A" is not done until all four are. It is indeterminate which of "B" or "C" is done first; this depends on what order you made the connections in (in Max, it's automatically sorted right to left).
Message-passing can give rise to infinite loops of the sort shown here:
Here the left-hand "+" can't finish processing until the right-hand one has been sent the result "2", which can't finish processing that until the left-hand one has been sent "3", and so on. Pd will print an error message reporting a "stack overflow" if this happens.
However, it is legal to make a loop if there is a "delay" object somewhere in it. When the "delay" receives a message it schedules a messsage for the future (even if the time delay is 0) and is then "finished;" Pd's internal scheduler will wake the delay back up later.
With few exceptions (notably "timer"), objects treat their leftmost inlet as "hot" in the sense that messages to right inlets can result in output messages. So the following is a legal (and reasonable) loop construct:
Here the "f" is an abbreviation for "float". Note that the "+ 1" output is connected to the right-hand inlet of "f". This "cold" inlet merely stores the value for the next time the "f" is sent the "bang" message. It is frequently desirable to send messages to two or more inlets of an object to specify its action. For instance, you can use "+" to add two numbers; but to do it correctly you must make sure the right hand inlet gets its value first. Otherwise, when the left hand side value comes in, "+" will carry out the addition (since the left hand inlet is the "hot" one) and will add this value to whatever was previously sitting in the right hand inlet.
Problems can arise when a single outlet is connected (either directly or through arbitrarily long chains of message passing) to different inlets of a single object. In this case it is indeterminate which order the two inlets will receive their messages. Suppose for example you wish to use "+" to double a number. The following is incorrect:
Here, I connected the left inlet before connecting the right hand one (although this is not evident in the appearance of the patch.) The "+" thus adds the new input (at left) to the previous input (at right).
The "trigger" object, abbreviated "t", can be used to split out connections from a single outlet in a determinate order. By convention, all objects in Pd, when sending messages out more than one outlet, do so from right to left. If you connect these to inlets of a second object without crossing wires, the second object will get its leftmost inlet last, which is usually what you want. Here is how to use "trigger" to disambiguate the previous example:
"Cold" (non-leftmost) inlets are almost universally used to store single values (either numbers or symbols.) With the exception of "line" and "line~", these values are "sticky," i.e., once you set the value it is good until the next time you set it. (The "line" exception is for sanity's sake.)
One more question sometimes comes up in execution order, which is the order in which two messages are sent to a single "cold" inlet. In this situation, since the messages are merged, the last value to be received is the value that is used in the computation.
The first of the message boxes above contains the single number 1.5; this message has an implicit selector of "float." The second is a list with three numbers in it, and in the third, the selector is "my" and the two arguments are the number 5 and the symbol "toes."
Multiple messages may be separated by commas as shown:
Here the three messages are the numbers 1, 2, and 3, and they are sent in sequence (with no intervening time between them, as with the "trigger" object, and having depth-first consequences so that whatever chain of actions depending on "1" takes place before anything depending on "2" and so on.)
Semicolons may also separate messages. A message following a semicolon must specify a symbol giving a destination (in other words, semicolons are like commas except that they clear the "current destination" so that the next message specifies a new one). The "current destination" is at first the message box's own outlet. In the example below, the leading semicolon immediately redirects messages from the outlet to an object named "fred" (which is here a receive object), and likewise the next message is sent to "sue."
Certain other objects (Pd windows, for example, and arrays) have Pd names and can be sent messages this way. Also, the special object "pd" is defined to which you may send messages to start and stop DSP.
You can put variables in message boxes as shown below:
Here, "$1", etc., refer to the arguments of the arriving message (and aren't defined if you send a "bang" message or if you click on the message box to activate it.) Dollar sign variables are either numbers or symbols depending on the incoming message; if symbols, you may even use them to specify variable message selectors or destinations.
Using Pd you can build audio patches which can synthesize musical sounds, analyze incoming sounds, process incoming sounds to produce transformed audio outputs, or integrate audio processing with other media. This section describes how Pd treats audio signals.
Pd's audio signals are internally kept as 32-bit floating point numbers, so you have all the dynamic range you could want. However, depending on your hardware, audio I/O is usually limited to 16 or 24 bits. Inputs all appear between the values of -1 and 1; and output values will be clipped to that range.
Pd assumes a sample rate of 44100 unless you override this in Pd's command line. Pd doesn't check that this matches the sample rate of audio input or output, nor does Pd attempt to set your computer's audio sample rate to its own. If the audio system is running at the wrong sample rate, audio output will be transposed (you can check this using the "test audio and MIDI" patch; see the help menu).
Pd can read or write samples to files either in 16-bit or 24-bit fixed point or in 32-bit floating point, in WAV, AIFF, or AU format, via the soundfiler, readsf, and writesf objects.
Inlets or outlets are configured in Pd either for messages or audio; it's an error to connect an audio outlet to a non-audio inlet or vice versa; usually these errors are detected at "sort time" when audio is started or the network changed with audio running. An object's leftmost inlet may accept both audio and messages; any other inlet is either one or the other. There is no quick way to tell whether an inlet or output is for audio or messages; consult the help window for the object.
The audio network, that is, the tilde objects and their interconnections, must be acyclic. If there are loops, you will see the error message at "sort time." When errors are reported at sort time there is no easy way to find the source of the error. You can build algorithms with feedback using nonlocal signal connections.
Your subpatches can have audio inlets and outlets via the inlet~ and outlet~ objects.
If you want to use a control value as a signal, you can use the sig~ object to convert it. The +~, -~, *~, /~, osc~, and phasor~ objects can be configured to take control or signal inputs.
The other direction, signal to control, requires that you specify at what moments you want the signal sampled. This is handled by the snapshot~ object, but you can also sample a signal with tabwrite~ and then get access it via tabread or tabread4 (note the missing tildes!). There are also analysis objects, the simplest of which is "env~", the envelope follower.
Larger block sizes than 64 should result in small increases in run-time efficiency. Also, the fft~ and related objects operate on blocks so that setting the block size also sets the number of FFT channels. You may wish to use block sizes smaller than 64 to gain finer resolutions of message/audio interaction, or to reduce "block delay" in feedback algorithms. At the (untested) extreme, setting the block size to one allows you to write your own recursive filters.
You can use switch~ to budget your DSP computations; for instance you might want to be able to switch between two synthesis algorithms. Put each algorithm in its own subpatch (which can have sub-sub patches in turn, for a voice bank for instance), and switch each one off as you switch the other one on. Beware of clicks; if you have a line~ controlling output level, give it time to ramp to zero before you switch it off or it will be stuck at a nonzero value for the next time it comes back on.
When a subpatch is switched off its audio outputs generate zeros; this costs a fairly small overhead; a cheaper way to get outputs is to use throw~ inside the switched module and catch~ outside it.
Send~ just saves a signal which may then be receive~d any number of times; but a receive~ can only pick up one send~ at a time (but you can switch between send~s if you want.)
Don't try to throw~ and catch~ or send~ and receive~ between windows with different block sizes. The only re-blocking mechanisms which are well tested are inlet~ and outlet~.
When you send a signal to a point that is earlier in the sorted list of tilde objects, the signal doesn't get there until the next cycle of DSP computation, one block later; so your signal will be delayed by one block (1.45 msec by default.) Delread~ and delwrite~ have this same restriction, but here the 1.45 msec figure gives the minimum attainable delay. For nonrecursive algorithms, a simple flanger for example, you might wish to ensure that your delread~ is sorted after your delwrite~. The only way to ensure this is to create the delread~ after you created the delwrite~; if things get out of whack, just delete and re-create the delread~.
In the intervals between, delays might time out or external conditions might arise (incoming MIDI, mouse clicks, or whatnot). These may cause a cascade of depth-first message passing; each such message cascade is completely run out before the next message or DSP tick is computed. Messages are never passed to objects during a DSP tick; the ticks are atomic and parameter changes sent to different objects in any given message cascade take effect simultaneously.
In the middle of a message cascade you may schedule another one at a delay of zero. This delayed cascade happens after the present cascade has finished, but at the same logical time.
The Pd scheduler maintains a (user-specified) lead on its computations; that is, it tries to keep ahead of real time by a small amount in order to be able to absorb unpredictable, momentary increases in computation time. This is specified using the "audiobuffer" or "frags" command line flags (see getting Pd to run ).
If Pd gets late with respect to real time, gaps (either occasional or frequent) will appear in both the input and output audio streams. On the other hand, disk strewaming objects will work correctly, so that you may use Pd as a batch program with soundfile input and/or output. The "-nogui" and "-send" startup flags are provided to aid in doing this.
Pd's "realtime" computations compete for CPU time with its own GUI, which runs as a separate process. A flow control mechanism will be provided someday to prevent this from causing trouble, but it is in any case wise to avoid having too much drawing going on while Pd is trying to make sound. If a subwindow is closed, Pd suspends sending the GUI update messages for it; but not so for miniaturized windows as of version 0.32. You should really close them when you aren't using them.
If a message cascade is started by an external event, a time tag is given it. These time tags are guaranteed to be consistent with the times at which timeouts are scheduled and DSP ticks are computed; i.e., time never decreases. (However, either Pd or a hardware driver may lie about the physical time an input arrives; this depends on the operating system.) "Timer" objects which meaure time intervals measure them in terms of the logical time stamps of the message cascades, so that timing a "delay" object always gives exactly the theoretical value. (There is, however, a "realtime" object that measures real time, with nondeterministic results.)
If two message cascades are scheduled for the same logical time, they are carried out in the order they were scheduled.
In an object box, as in a message box, the text specifies a message; but here the message is to be passed to Pd itself, once, and the message's effect is to create the object in question. When you open a file, all the objects created are created using their text as "creation messages." If you type a new message into an object box (or change it), the old object is destroyed and the message is used to create the new one.
The selector of the message (the first word in the message) is a selector which Pd interprets to mean which type of object to create. Any message arguments (called "creation arguments") are used to parametrize the object being created. Thus in "makenote 64 250" the selector "makenote" determines the class of object to create and the creation arguments 64 and 250 become the initial velocity and duration.
An exception is made for subpatches whose "state" is the configuration of the subpatch; as a special case, this configuration is restored when the patch is read from a file. Also, if you rename the subpatch, for instance typing "pd jane" instead of "pd spot," the contents of the patch are preserved and only the text in the object box and the window title of the subpatch are changed.
It is probably bad style to specify creation arguments ala "makenote 64 250" if you are going to override them later; this is confusing to anyone who tries to understand the patch.
Object boxes may have many different classes. The class is usually determined by the selector of the creation message, i.e., the first atom of the creation message which is usually a symbol.
Each class comes with a fixed collection of messages it may be sent. For esxample, the "float" or "f" object takes "bang" and "float." These messages are sent to "float" objects (objects whose class is float) via the leftmost, hot inlet. (The right inlet is a separate, auxiliary object.) Objects of class "float" respond to the message "bang" by outputting their current value, that is, by sending a "float" message to their outlet. They respond to "float" messages by setting their value and then outputting it.
Each other class (like "float") in Pd has its own protocol for responding to messages it is sent, and may take "float" and "bang" messages, or others in addition or instead of them.
Unless they arrange otherwise by defining a "list" method, objects respond to the "list" message by distributing the arguments of the message to their inlets, except for the first argument which is passed as a "float" or "symbol" message to the object proper.
Object boxes contain text wwhich forms a message to be sent to Pd to create and initialize the object. Here, $1, etc., are taken from the context in which the patch was loaded. When the patch is a new document or opened from a file the "$" variables are undefined. But if the patch is an abstraction (see the next section) they are taked from the abstractions' creation arguments.
Constructions such as "$1-x" are expanded by string concatentation. This is the mechanism for making local variables. In particular, $0 in an abstraction is a counter which is guaranteed to be unique to that abstraction, so sends and receives with names like "$0-bear" can be used as local send/receive pairs.
Note that the expansion of variables such as $0 and $1 only works at the beginning of the symbol; so, for instance, "rats-$1" will not be expanded. Occasionally you may want to have double or triple substitutions; this can be done one stage at a time by nesting abstractions (with each subpatch adding its own $-variable to the beginning of a symbol and passing that on as argument to a further anstraction.)
the box in the middle, if clicked on, opens the sub-patch shown here:
The contents of the subpatch are saved as part of the parent patch, in one file. If you make several copies of a subpatch you may change them individually.
The objects, "inlet,", "inlet~," "outlet," and "outlet~,", when put in a subpatch, create inlets and outlets for the object box containing the subpatch. This works equally for one-off subpatches and abstractions. The inlet~ and outlet~ versions create inlets and outlets for audio signals. You can't mix messages and audio in a subpatch inlet or outlet; they must be one or the other exclusively. Inlets and outlets appear on the invoking box in the same left-to-right order as they appear in the subpatch.
To make an abstraction, save a patch with a name such as "abstraction1.pd" and then invoke it as "abstraction1" in an object box:
Here we're invoking a separate file, "abstraction1.pd", which holds the patch shown here (the border is the same as for the subpatch above):
You may create many instances of "abstraction1" or invoke it from several different patches; and changing the contents of "abstraction1" will affect all invocations of it as they are created. An analogy from the "c" programming language is that one-off subpatches are like bracketed blocks of code and abstractions are like subroutines.
Abstractions are instantiated by typing the name of a patch (minus the ".pd" extension) into an object box. You may also type arguments; for instance if you have a file "my-abstraction.pd" you may type "my-abstraction 5" to set the variable $1 to 5. This is defined only for object boxes (not for messages) in the abstraction. (For message boxes, "$1", etc, have a different meaning as described above.) If you want to send a message with a $1 in the sense of a creation argument of an abstraction, you must generate it with an object box such as "float $1", "symbol $1", or perhaps "pack $1 $2", which may then be sent to a message box.
The corresponding feature in Max (both Opcode and Ircam) was the "#1" construct. In a Max abstraction, "#1", etc., are replaced by the creation argument. This has the disadvantage that you can't edit the abstraction as instantiated in the patch since the "#" variables are substituted. In Pd the "$" variables in object boxes are spelled literally as "$" variables so that it's meaningful to edit them from within their calling patch. On the Pd side, however, there is the disadvantage that it's confusing to have "$" expanded at a different time in an object box than in a message box. In an object box, the "$" argument is expanded at creation time, and in a message box, at message time.
where the patch "abstraction2.pd" contains:
Here, the number box in the abstraction shows up on the box that invoked the abstraction. The "graph on parent" flag is set in the abstraction (and is saved as part of the abstraction); to set it, open the "properties" dialog for the "abstraction2" canvas by right-clicking on any white space in the patch.
To open the subpatch, right click on the object and select "open". (On Macintoshes without a 2-button mouse, you can double-click in edit mode instead.) It doesn't work just to click on the object in run mode since clicks are sent to visible controls and/or arrays.
When the sub-patch is closed, all controls in it appear on the object instead; so the number box in the sub-patch in the example above is the same one as you see in the box. Only controls are made visible in this way
Arrays in Pd should be allocated (and possible read in from a file) before beginning to make sound, since memory allocation and disk operations may take long enough to cause audio buffer overruns or underruns. Pd provides two ways to define new arrays, as "graphs" and "tables". In either case the array has a pre-defined name and size (i.e., number of points). Elements of the array are stored as floating-point numbers, 4 bytes apiece
If you use an array to store a one-second sound at 44.1 kHz you will need 176 kilobytes, or a one-minute sound, 10.6 megabytes. To store a sound with two or more channels, use a separate array for each channel.
Arrays are also useful as transfer functions, for example for nonlinear distortion of an audio signal, or to map a control onto a synthesis parameter. In situations like this one typically uses much shorter arrays, of no more than a few hundered elements. They are also useful for storing measured spectra derived from the fft~ objects, and probably for many other uses.
Arrays usually appear within subpatches created to house them, whether in "graph on parent" form (so that you see them within a rectangle drawn on the containing patch), or as a regular subpatch (which you see as a text box.) In the "graph on parent" form, an array appears as shown:
Arrays are indexed from 0 to N-1 where N is the number of points in the array. You can read an array value using the tabread object:
Here we see that the third point of the array (index 2) has the value 0.4. To write into the array you can use the tabwrite object:
In this example, sending the message sets the third element to 0.5. (You may also send the two numbers to the two inlets separately.)
The two previous examples showed control operations to read and write from and to arrays. These may also be done using audio signals. For example, the patch below creates a 440 Hz. tone with "array1" as a waveform:
Here phasor~'s outputs a sawtooth wave, repeating 440 times per second, whose output range is from 0 to 1. The multiplier and adder adjust the range from 1 to 11, and then the values are used as indices for tabread4~, which is a 4-point interpolating table lookup module. (Much more detail is available in the audio example patches in the "pure documentation" series.)
To create a new array, select "array" from the "put" menu. Up will come a dialog window to set initial properties of the array. By default, a new graph is created to hold the array, but it may also be housed in the most recently created graph instead. Other properties may be specified there and/or changed later using the "properties" dialog.
If you select "properties" on an array in a graph, you two dialogs, one for the array and one for the graph. The array dialog looks like this:
You may use this to change the name and size, in addition to another property, "save contents". If "save contents" is selected, the array's values are stored in the containing patch; otherwise they're initialized to zero each time the patch is reloaded. If you intend to use arrays to store sounds, you will probably not wish to store them in the patch but as separate soundfiles. This will be more efficient, and you may also then use a sound editor to modify them outside Pd.
If you check "delete me" and then "OK", the array wil be deleted. This is an odd interface for deleting an object, and is only provided because Pd lacks a mechanism for selecting arrays (so that "cut" could serve).
The graph dialog (which also pops up) is shown here:
The X bounds initially range from 0 to the number of points in the table minus one (this is a good choice for arrays, although graphs holding other kinds of objects might require other X bounds.) The Y bounds should be chosen to reflect the natural range of the table, so that stored sounds would naturally range from -1 to 1, but a sequence of frequency values might range from 0 to 20,000. Finally, you choose the screen size of the graph, width and height, in screen pixels.
Many other operations are defined for arrays; see the related patches in the tutorial (starting at 2.control/15.array.pd) for more possibliities.
The original idea in developing Pd was to make a real-time computer music performance environment like Max, but somehow to include also a facility for making computer music scores with user-specifiable graphical representations. This idea has important precedents in Eric Lindemann's Animal and Bill Buxton's SSSP. An even earlier class of precedents lies in the rich variety of paper scores for electronic music before it became practical to offer a computer-based score editor. In this context, scores by Stockhausen ( Kontakte and Studie II) and Yuasa (Toward the Midnight Sun) come most prominently to mind, but also Xenakis's Mycenae-alpha, which, although it was realized using a computer, was scored on paper and only afterward laboriously transcribed into the computer.
Pd is designed to to offer an extremely unstructured environment for describing data structures and their graphical appearance. The underlying idea is to allow the user to display any kind of data he or she wants to, associating it in any way with the display. To accomplish this Pd introduces a graphical data structure, somewhat like a data structure out of the C programming language, but with a facility for attaching shapes and colors to the data, so that the user can visualize and/or edit it. The data itself can be edited from scratch or can be imported from files, generated algorithmically, or derived from analyses of incoming sounds or other data streams. Here is one simple example of a very short musical sketch realized using Pd:
The example, which only lasts a few seconds, is a polyphonic collection of time-varying noise bands. The graphical ``score" consists of six objects, each having a small grab point at left, a black shape to show dynamic, and a colored shape to show changing frequency and bandwidth. The horizontal axis represents time and the vertical axis, frequency (although, as explained later, this behavior isn't built into pd). The dynamic and frequency shapes aren't constrained to be connected or even to be proximate, but since they pertain to the same sound their horizontal positions line up. In this example the last (furthest-right) object is percussive (as seen by the black shape) and has a fixed frequency and bandwidth, whereas the large, articulated shape in the center has a complicated trajectory in both frequency and dynamic. The color of the frequency trace determines the voice number used to realize it.
Each object is thus composed of a combination of scalar values (color; aggregate position in X and Y coordinates) and array values (time/value pairs for the black traces and time/frequency/bandwidth triples for the colored ones.) This is all specified by the user using Pd's ``template" mechanism.
Here is the template associated with the graphical objects shown above:
Templates consist of a data structure definition (the "struct" object) and zero or more drawing instructions ("filledpolygon" and "plot"). The "struct" object gives the template the name, "template-toplevel." The data structure is defined to contain three floating point numbers named "x", "y", and "voiceno," and two arrays, one named "pitch" whose elements belong to another template named "template-pitch," and similarly for the array "amp."
In general, data structures are built from four data types: scalar floats and symbols, arrays (whose elements share another, specified template) and lists (whose elements may have a variety of templates). The contents of a Pd window themselves form a list. Pd's correlate of Max's "table" object is implemented as a top-level array whose elements are scalars containing a single floating-point number.
Data structures in Pd may nest arbitrarily deeply using the array and list types. For example, a collection of sinusoidal tracks from an analysis engine could be implemented as an array of arrays of (pitch, amplitude) pairs; this appears as example 12 in Pd's FFT object online tutorial.
After the "struct" object in the template shown above, the remaining three objects are drawing instructions , first for a rectangle ("filledpolygon"), and then for two arrays. The various graphical attributes that are specified for drawing instructions may be numerical constants or data structure field names; in the latter case the value varies depending on the data. For instance, the second creation argument to "plot" is the color. The first "plot" plots the "amp" field and the color is given as 0, or black. The second one plots "pitch" using the color "voiceno". In this way the color of the second trace is attached to the "voiceno" slot in the data structure, so that color will vary according to its "voiceno" slot.
Pd objects are provided to traverse lists and arrays, and to address elements of data structures for getting and setting. Here is a patch showing how these facilities could be used, for example, to sequence the graphical score shown above:
Pd has no built-in sequencer, nor even any notion that "x" values should be used as a time axis. (However, a "sort" function is provided, which reorders a list from left to right, on the assumption that users might often want to use Pd data collections as x-ordered sequences.) Recording sequences of events into lists, and/or playing the lists back as sequences, are functionalities that the user is expected to supply on top of Pd's offerings, which, it is hoped, would allow those functionalities within a much larger range of possibilities, to include random reorderings of events, score following, self-modifying scores, reactive improvisation, and perhaps much more.
Traversal of data is made possible by adding a new type of atom, "pointer", to the two previously defined types that make up messages, to wit, numbers and symbols. Unlike numbers and symbols, pointers have no printed form and thus can't be uttered in message boxes. Traversal objects such as "pointer" and "get" (among several others) can generate or use pointers. The pointer data type is also integrated into pipe-fitting objects such as "pack", "unpack", and "route".
In the patch shown above, the topmost "pointer" object holds a pointer to the next object to "play" (by sending it to one of the "voice" abstractions at bottom.) The pointer object takes a "traverse" message to set it to the head of the list (named "pd-data"), and "next" messages to move to (and output) the next datum in the list (i.e., the next in the list of six objects in the score). Another "pointer" object is also used, further down, as a storage cell for pointers just as "float" is for numbers.
The center of any sequencer is always the "delay" object, which must be fed the time difference between each event (including the non-event of hitting "start") and the next. As we extract each of the six objects in the score, we must wait the delay for playing that object, and then send its pointer to one of the "voice" abstractions to play it. However, we have to inspect the object itself to know the delay before playing it. So, in the loop, we peel off the first remaining object to play and inspect the time difference between it and the previous one, using this value to set the delay, but also storing the pointer in the lower "pointer" and "pack" objects.
The time difference needed to set the delay object is obtained using the "get template-toplevel x" object. (This is converted to incremental time ("-"), corrected for tempo, and fed to the delay.) Pd provides the "get" and "set" objects for reading and writing values from data structures. The two "get" objects shown here obtain the "x" and "voiceno" fields of the current object. The template name (template-toplevel) is supplied to the "get" objects so that they can look up the offset of the necessary field(s) in advance, for greater run-time efficiency.
Once the delay has expired, the object's pointer is recalled (the lower "pointer" object), and the voice number is recalled. This is packed with the pointer itself and routed, so that the pointer goes to the appropriate voice. The voice number is shown as the color of the frequency trace in "999" units (first digit red, second green, third blue) and the "route" is arbitrarily set up to select among the six primary and secondary colors plus black.
The details of extracting the pitch and dynamic breakpoints from the arrays defined in the template are managed in the "voice" abstraction. The "voice" abstraction receives a pointer to a given object and manages the sequencing of the arrays; so it contains two sequencers itself. The nesting of the overall structure of the sequencer patch mirrors the nesting of the original data structures. Finally, the voice abstraction puts its audio output on a summing bus.
More general patches can easily be constructed which access heterogeneous lists of objects (having different templates). In this way, an arbitrarily rich personal "score language" can be developed and sequenced.
In general, accessing or changing data is done via "pointers" to "scalars". Numbers and symbols withing scalars are accessed using the "get" object and changed, in the same way, using "set". Since lists and arrays are composed of scalars, every actual number or symbol in a data heap will be a number or symbol element of some scalar. To access them, it suffices to have objects to chase down elements of lists and arrays (given either a global name or a pointer to the containing scalar).
Lists are traversed in the way shown above; to get to a sublist of a scalar, the "get" object will provide a pointer, in the same way as it provides "float" or "symbol" elements of scalars. For arrays, an "element" object is provided which, given a scalar, a field name and a number, chases down the numbered, scalar, element of the named array field.
To alter "float" or "symbol" elements of scalars is straightforward using the "set" object, but arrays and lists can't be set by assignment; there is no suitable data type available withing messages. Lists could possibly be "settable" by passing pointers to other lists, but permitting this would have required either automatically doing deep copies of data structures to carry out the assignments, or else implementing a garbage collecting memory management system, either of which would be difficult to realize within real-time computation time constraints. Instead, all the data hanging from a scalar is considered as belonging to that scalar, and is left in memory until the scalar is deleted; the data may be changed atom by atom, but primitives are not provided which would imply unpredictable execution times.
The "getsize" and "setsize" objects are provided to access or change the number of elements in the array. For lists, an "append" object appends a new scalar for a given template to a list, after the element pointed to. (To insert a scalar at the beginning of a list, the pointer can be set to the "head" of the list, a formal location before the first list item.) Deletion is less flexible; the only operation is to delete an entire list. (There's no reason not to provide finer-grain deletion mechanisms except that it's not clear how to protect against stale pointers efficiently, except by voiding the entire collection of pointers into a list.)
The graphical score shown above can be edited by dragging breakpoints, or by adding and deleting them, using mouse clicks. Also, entire objects or collections of them may be copied, pasted, and dragged around the screen. Alternatively, there is an editable (or computer generate-able or parse-able) text representation for the data, which may be seen or changed in a dialog window or read and written to external text files.
Since the graphical presentation of data objects is determined by drawing instructions, the drawing instructions are interpreted backwards to alter data as a result of mouse operations. If a given graphical dimension is controlled by a variable, that variable is then controlled by dragging along that dimension; if the dimension is constant, it can't be altered by dragging.
Tricky situations can arise when the user changes the contents of templates. A change in drawing instructions can be accommodated by simply tracking down and redrawing all data objects using the template. However, changing the "struct" object itself make for less straightforward situations. The user might wish to reorder fields, delete them, add new ones, or rename them. When a "struct" object changes, Pd automatically conforms the data from the old structure to the new one. Fields with the same name as previously are maintained (reordering them as necessary); and if a field disappears but another of the same type appears, the new one(s) are taken to be renamings of the old one(s) in order of appearance. New fields which cannot be matched in this way with previously existing ones are assumed to be new and are initialized.
It can happen that two "struct" objects compete to define the same data structure, or that the user reads in data from a file which expects a different version of the structure, or alternatively, that the "struct" object for existing data objects disappears. For this reasn, Pd maintains a private representation of the last active version of a "struct" until all similarly named "structs," as well as all data using that "struct", have disappeared. If the user introduces a new version of the "struct" and only later deletes the "current" one, the data is only conformed to the new version once the old one is deleted. In this way we avoid getting into situations where data is left hanging without its structure definition, or where data ends up belonging to two or more structures of the same name. The worst that can happen is that data may lose their drawing instructions, in which case Pd supplies a simple default shape.
When examples get more complicated and/or dense than the one shown here, it becomes difficult to see and select specific features of a data collection; more work is needed to facilitate this. There should be some facility for turning drawing instructions on and off, or perhaps for switching between versions of a template, depending on the user's desired view. There should also be a callback facility in the template for when an object is edited with the mouse, so that the user can bind actions to mouse clicks.
More generally, the collection of traversal objects that Pd provides is adequate to support a variety of modes of data collection and use, such as analysis and sequencing. But the patches required to traverse the data collections are not always simple. It would be desirable to find a more straightforward mechanism than that provided by the "pointer", "get" and "set" objects.
The "data" facility, although part of the original plan for Pd, has only recently been implemented in its current form, and as (hopefully) the user base grows there will surely be occasions for many further extensions of the data handling primitives and the graphical presentation and editing functions.