SuperCollider REFERENCE

Server Command Reference

SuperCollider Server Synth Engine Command Reference

The following is a list of all server commands and their arguments.

Each command has a command number which can be sent to the server as a 32 bit integer instead of an OSC style string. Command numbers are listed at the end of this document.

If a command's description contains the word Asynchronous, then that command will be passed to a background thread to complete so as not to steal CPU time from the audio synthesis thread. All asynchronous commands send a reply to the client when they are completed. Many asynchronous commands can contain an OSC message or bundle to be executed upon completion. eg.

    ["/d_load", "synthdefs/void.scsyndef",
        ["/s_new", "void", 1001, 1, 0] // completion message
    ]

Master Controls

/quit

Quit program. Exits the synthesis server.

Asynchronous.
Replies to sender with /done just before completion.

/notify

Register to receive notifications from server
intone to receive notifications, zero to stop receiving them.

If argument is one, server will remember your return address and send you notifications. if argument is zero, server will stop sending you notifications.

Asynchronous.
Replies to sender with /done /notify clientID when complete. If this client has registered for notifications before, this may be the same ID. Otherwise it will be a new one. Clients can use this ID in multi-client situations to avoid conflicts in node IDs, bus indices, buffer numbers, etc.

/status

Query the status. Replies to sender with the following message:

/status.reply
int1. unused.
intnumber of unit generators.
intnumber of synths.
intnumber of groups.
intnumber of loaded synth definitions.
floataverage percent CPU usage for signal processing
floatpeak percent CPU usage for signal processing
doublenominal sample rate
doubleactual sample rate
NOTE: /status messages won't be posted, if the server is in /dumpOSC mode

/cmd

Plug-in defined command.
stringcommand name
...any arguments

Commands are defined by plug-ins.

/dumpOSC

Display incoming OSC messages.
intcode

Turns on and off printing of the contents of incoming Open Sound Control messages. This is useful when debugging your command stream.

The values for the code are as follows:
0turn dumping OFF.
1print the parsed contents of the message.
2print the contents in hexadecimal.
3print both the parsed and hexadecimal representations of the contents.

/sync

Notify when async commands have completed.
inta unique number identifying this command.

Replies with a /synced message when all asynchronous commands received before this one have completed. The reply will contain the sent unique ID.

Asynchronous.
Replies to sender with /synced, ID when complete.

/clearSched

Clear all scheduled bundles. Removes all bundles from the scheduling queue.

/error

Enable/disable error message posting.
intmode

Turn on or off error messages sent to the SuperCollider post window. Useful when sending a message, such as /n_free, whose failure does not necessarily indicate anything wrong.

The values for mode are as follows:
0turn off error posting until the next ['/error', 1] message.
1turn on error posting.

For convenience of client-side methods, you can also suppress errors temporarily, for the scope of a single bundle.
-1turn off locally in the bundle -- error posting reverts to the "permanent" setting for the next message or bundle.
-2turn on locally in the bundle.

These "temporary" states accumulate within a single bundle -- so if you have nested calls to methods that use bundle-local error suppression, error posting remains off until all the layers have been unwrapped. If you use ['/error', -1] within a self-bundling method, you should always close it with ['/error', -2] so that subsequent bundled messages will take the correct error posting status. However, even if this is not done, the next bundle or message received will begin with the standard error posting status, as set by modes 0 or 1.

Temporary error suppression may not affect asynchronous commands in every case.

Synth Definition Commands

/d_recv

Receive a synth definition file.
bytesbuffer of data.
bytesan OSC message to execute upon completion. (optional)

Loads a file of synth definitions from a buffer in the message. Resident definitions with the same names are overwritten.

Asynchronous.
Replies to sender with /done when complete.

/d_load

Load synth definition.
stringpathname of file. Can be a pattern like "synthdefs/perc-*"
bytesan OSC message to execute upon completion. (optional)

Loads a file of synth definitions. Resident definitions with the same names are overwritten.

Asynchronous.
Replies to sender with /done when complete.

/d_loadDir

Load a directory of synth definitions.
stringpathname of directory.
bytesan OSC message to execute upon completion. (optional)

Loads a directory of synth definitions files. Resident definitions with the same names are overwritten.

Asynchronous.
Replies to sender with /done when complete.

/d_free

Delete synth definition.
N * stringsynth def name

Removes a synth definition. The definition is removed immediately, and does not wait for synth nodes based on that definition to end.

Node Commands

/n_free

Delete a node.
N * intnode ID

Stops a node abruptly, removes it from its group, and frees its memory. A list of node IDs may be specified. Using this method can cause a click if the node is not silent at the time it is freed.

/n_run

Turn node on or off.
N *
intnode ID
intrun flag

Using this method to start and stop nodes can cause a click if the node is not silent at the time run flag is toggled.

/n_set

Set a node's control value(s).
intnode ID
N *
int or stringa control index or name
float or inta control value

Takes a list of pairs of control indices and values and sets the controls to those values. If the node is a group, then it sets the controls of every node in the group.

This message now supports array type tags ($[ and $]) in the control/value component of the OSC message. Arrayed control values are applied in the manner of n_setn (i.e., sequentially starting at the indexed or named control).

/n_setn

Set ranges of a node's control value(s).
intnode ID
N *
int or stringa control index or name
intnumber of sequential controls to change (M)
M * float or intcontrol value(s)

Set contiguous ranges of control indices to sets of values. For each range, the starting control index is given followed by the number of controls to change, followed by the values. If the node is a group, then it sets the controls of every node in the group.

/n_fill

Fill ranges of a node's control value(s).
intnode ID
N *
int or stringa control index or name
intnumber of values to fill (M)
float or intvalue

Set contiguous ranges of control indices to single values. For each range, the starting control index is given followed by the number of controls to change, followed by the value to fill. If the node is a group, then it sets the controls of every node in the group.

/n_map

Map a node's controls to read from a bus.
intnode ID
N *
int or stringa control index or name
intcontrol bus index

Takes a list of pairs of control names or indices and bus indices and causes those controls to be read continuously from a global control bus. If the node is a group, then it maps the controls of every node in the group. If the control bus index is -1 then any current mapping is undone. Any n_set, n_setn and n_fill command will also unmap the control.

/n_mapn

Map a node's controls to read from buses.
intnode ID
N *
int or stringa control index or name
intcontrol bus index
intnumber of controls to map

Takes a list of triplets of control names or indices, bus indices, and number of controls to map and causes those controls to be mapped sequentially to buses. If the node is a group, then it maps the controls of every node in the group. If the control bus index is -1 then any current mapping is undone. Any n_set, n_setn and n_fill command will also unmap the control.

/n_mapa

Map a node's controls to read from an audio bus.
intnode ID
N *
int or stringa control index or name
intcontrol bus index

Takes a list of pairs of control names or indices and audio bus indices and causes those controls to be read continuously from a global audio bus. If the node is a group, then it maps the controls of every node in the group. If the audio bus index is -1 then any current mapping is undone. Any n_set, n_setn and n_fill command will also unmap the control. For the full audio rate signal, the argument must have its rate set to \ar.

/n_mapan

Map a node's controls to read from audio buses.
intnode ID
N *
int or stringa control index or name
intcontrol bus index
intnumber of controls to map

Takes a list of triplets of control names or indices, audio bus indices, and number of controls to map and causes those controls to be mapped sequentially to buses. If the node is a group, then it maps the controls of every node in the group. If the audio bus index is -1 then any current mapping is undone. Any n_set, n_setn and n_fill command will also unmap the control. For the full audio rate signal, the argument must have its rate set to \ar.

/n_before

Place a node before another.
N *
intthe ID of the node to place (A)
intthe ID of the node before which the above is placed (B)

Places node A in the same group as node B, to execute immediately before node B.

/n_after

Place a node after another.
N *
intthe ID of the node to place (A)
intthe ID of the node after which the above is placed (B)

Places node A in the same group as node B, to execute immediately after node B.

/n_query

Get info about a node.
N * intnode ID

The server sends an /n_info message for each node to registered clients. See Node Notifications below for the format of the /n_info message.

/n_trace

Trace a node.
N * intnode IDs

Causes a synth to print out the values of the inputs and outputs of its unit generators for one control period. Causes a group to print the node IDs and names of each node in the group for one control period.

/n_order

Move and order a list of nodes.
intadd action (0,1,2 or 3 see below)
intadd target ID
N * intnode IDs

Move the listed nodes to the location specified by the target and add action, and place them in the order specified. Nodes which have already been freed will be ignored.

add actions:
0construct the node order at the head of the group specified by the add target ID.
1construct the node order at the tail of the group specified by the add target ID.
2construct the node order just before the node specified by the add target ID.
3construct the node order just after the node specified by the add target ID.

Synth Commands

/s_new

Create a new synth.
stringsynth definition name
intsynth ID
intadd action (0,1,2, 3 or 4 see below)
intadd target ID
N *
int or stringa control index or name
float or int or stringfloating point and integer arguments are interpreted as control value. a symbol argument consisting of the letter 'c' or 'a' (for control or audio) followed by the bus's index.

Create a new synth from a synth definition, give it an ID, and add it to the tree of nodes. There are four ways to add the node to the tree as determined by the add action argument which is defined as follows:

add actions:
0add the new node to the the head of the group specified by the add target ID.
1add the new node to the the tail of the group specified by the add target ID.
2add the new node just before the node specified by the add target ID.
3add the new node just after the node specified by the add target ID.
4the new node replaces the node specified by the add target ID. The target node is freed.

Controls may be set when creating the synth. The control arguments are the same as for the n_set command.

If you send /s_new with a synth ID of -1, then the server will generate an ID for you. The server reserves all negative IDs. Since you don't know what the ID is, you cannot talk to this node directly later. So this is useful for nodes that are of finite duration and that get the control information they need from arguments and buses or messages directed to their group. In addition no notifications are sent when there are changes of state for this node, such as /go, /end, /on, /off.

If you use a node ID of -1 for any other command, such as /n_map, then it refers to the most recently created node by /s_new (auto generated ID or not). This is how you can map the controls of a node with an auto generated ID. In a multi-client situation, the only way you can be sure what node -1 refers to is to put the messages in a bundle.

This message now supports array type tags ($[ and $]) in the control/value component of the OSC message. Arrayed control values are applied in the manner of n_setn (i.e., sequentially starting at the indexed or named control). See the Node Messaging helpfile.

/s_get

Get control value(s).
intsynth ID
N * int or stringa control index or name

Replies to sender with the corresponding /n_set command.

/s_getn

Get ranges of control value(s).
intsynth ID
N *
int or stringa control index or name
intnumber of sequential controls to get (M)

Get contiguous ranges of controls. Replies to sender with the corresponding /n_setn command.

/s_noid

Auto-reassign synth's ID to a reserved value.
N * intsynth IDs

This command is used when the client no longer needs to communicate with the synth and wants to have the freedom to reuse the ID. The server will reassign this synth to a reserved negative number. This command is purely for bookkeeping convenience of the client. No notification is sent when this occurs.

Group Commands

/g_new

Create a new group.
N *
intnew group ID
intadd action (0,1,2, 3 or 4 see below)
intadd target ID

Create a new group and add it to the tree of nodes. There are four ways to add the group to the tree as determined by the add action argument which is defined as follows (the same as for /s_new):

add actions:
0add the new group to the the head of the group specified by the add target ID.
1add the new group to the the tail of the group specified by the add target ID.
2add the new group just before the node specified by the add target ID.
3add the new group just after the node specified by the add target ID.
4the new node replaces the node specified by the add target ID. The target node is freed.

Multiple groups may be created in one command by adding arguments.

/p_new

Create a new parallel group.
N *
intnew group ID
intadd action (0,1,2, 3 or 4 see below)
intadd target ID

Create a new parallel group and add it to the tree of nodes. Parallel groups are relaxed groups, their child nodes are evaluated in unspecified order. There are four ways to add the group to the tree as determined by the add action argument which is defined as follows (the same as for /s_new):

add actions:
0add the new group to the the head of the group specified by the add target ID.
1add the new group to the the tail of the group specified by the add target ID.
2add the new group just before the node specified by the add target ID.
3add the new group just after the node specified by the add target ID.
4the new node replaces the node specified by the add target ID. The target node is freed.

Multiple groups may be created in one command by adding arguments.

/g_head

Add node to head of group.
N *
intgroup ID
intnode ID

Adds the node to the head (first to be executed) of the group.

/g_tail

Add node to tail of group.
N *
intgroup ID
intnode ID

Adds the node to the tail (last to be executed) of the group.

/g_freeAll

Delete all nodes in a group.
N * intgroup ID(s)

Frees all nodes in the group. A list of groups may be specified.

/g_deepFree

Free all synths in this group and all its sub-groups.
N * intgroup ID(s)

Traverses all groups below this group and frees all the synths. Sub-groups are not freed. A list of groups may be specified.

/g_dumpTree

Post a representation of this group's node subtree.
N *
intgroup ID
intflag; if not 0 the current control (arg) values for synths will be posted

Posts a representation of this group's node subtree, i.e. all the groups and synths contained within it, optionally including the current control values for synths.

/g_queryTree

Get a representation of this group's node subtree.
N *
intgroup ID
intflag: if not 0 the current control (arg) values for synths will be included

Request a representation of this group's node subtree, i.e. all the groups and synths contained within it. Replies to the sender with a /g_queryTree.reply message listing all of the nodes contained within the group in the following format:
intflag: if synth control values are included 1, else 0
intnode ID of the requested group
intnumber of child nodes contained within the requested group
then for each node in the subtree:
intnode ID
intnumber of child nodes contained within this node. If -1 this is a synth, if >=0 it's a group
then, if this node is a synth:
symbolthe SynthDef name for this node.
then, if flag (see above) is true:
intnumControls for this synth (M)
M *
symbol or intcontrol name or index
float or symbolvalue or control bus mapping symbol (e.g. 'c1')

N.B. The order of nodes corresponds to their execution order on the server. Thus child nodes (those contained within a group) are listed immediately following their parent. See the method Server:queryAllNodes for an example of how to process this reply.

Unit Generator Commands

/u_cmd

Send a command to a unit generator.
intnode ID
intunit generator index
stringcommand name
...any arguments

Sends all arguments following the command name to the unit generator to be performed. Commands are defined by unit generator plug ins.

Buffer Commands

Buffers are stored in a global array, indexed by integers starting at zero.

/b_alloc

Allocate buffer space.
intbuffer number
intnumber of frames
intnumber of channels (optional. default = 1 channel)
bytesan OSC message to execute upon completion. (optional)

Allocates zero filled buffer to number of channels and samples.

Asynchronous.
Replies to sender with /done /b_alloc bufNum when complete.

/b_allocRead

Allocate buffer space and read a sound file.
intbuffer number
stringpath name of a sound file.
intstarting frame in file (optional. default = 0)
intnumber of frames to read (optional. default = 0, see below)
bytesan OSC message to execute upon completion. (optional)

Allocates buffer to number of channels of file and number of samples requested, or fewer if sound file is smaller than requested. Reads sound file data from the given starting frame in the file. If the number of frames argument is less than or equal to zero, the entire file is read.

Asynchronous.
Replies to sender with /done /b_allocRead bufNum when complete.

/b_allocReadChannel

Allocate buffer space and read channels from a sound file.
intbuffer number
stringpath name of a sound file
intstarting frame in file
intnumber of frames to read
N *N >= 0
intsource file channel index

bytesan OSC message to execute upon completion. (optional)

As b_allocRead, but reads individual channels into the allocated buffer in the order specified.

Asynchronous.
Replies to sender with /done /b_allocReadChannel bufNum when complete.

/b_read

Read sound file data into an existing buffer.
intbuffer number
stringpath name of a sound file.
intstarting frame in file (optional. default = 0)
intnumber of frames to read (optional. default = -1, see below)
intstarting frame in buffer (optional. default = 0)
intleave file open (optional. default = 0)
bytesan OSC message to execute upon completion. (optional)

Reads sound file data from the given starting frame in the file and writes it to the given starting frame in the buffer. If number of frames is less than zero, the entire file is read. If reading a file to be used by DiskIn ugen then you will want to set "leave file open" to one, otherwise set it to zero.

Asynchronous.
Replies to sender with /done /b_read bufNum when complete.

/b_readChannel

Read sound file channel data into an existing buffer.
intbuffer number
stringpath name of a sound file
intstarting frame in file
intnumber of frames to read
intstarting frame in buffer
intleave file open
N *N >= 0
intsource file channel index

bytescompletion message

As b_read, but reads individual channels in the order specified. The number of channels requested must match the number of channels in the buffer.

Asynchronous.
Replies to sender with /done /b_readChannel bufNum when complete.

/b_write

Write sound file data.
intbuffer number
stringpath name of a sound file.
stringheader format.
stringsample format.
intnumber of frames to write (optional. default = -1, see below)
intstarting frame in buffer (optional. default = 0)
intleave file open (optional. default = 0)
bytesan OSC message to execute upon completion. (optional)

Write a buffer as a sound file.

Header format is one of:
"aiff", "next", "wav", "ircam"", "raw"
Sample format is one of:
"int8", "int16", "int24", "int32", "float", "double", "mulaw", "alaw"

Not all combinations of header format and sample format are possible. If number of frames is less than zero, all samples from the starting frame to the end of the buffer are written. If opening a file to be used by DiskOut ugen then you will want to set "leave file open" to one, otherwise set it to zero. If "leave file open" is set to one then the file is created, but no frames are written until the DiskOut ugen does so.

Asynchronous.
Replies to sender with /done /b_write bufNum when complete.

/b_free

Free buffer data.
intbuffer number
bytesan OSC message to execute upon completion. (optional)

Frees buffer space allocated for this buffer.

Asynchronous.
Replies to sender with /done /b_free bufNum when complete.

/b_zero

Zero sample data.
intbuffer number
bytesan OSC message to execute upon completion. (optional)

Sets all samples in the buffer to zero.

Asynchronous.
Replies to sender with /done /b_zero bufNum when complete.

/b_set

Set sample value(s).
intbuffer number
N *
inta sample index
floata sample value

Takes a list of pairs of sample indices and values and sets the samples to those values.

/b_setn

Set ranges of sample value(s).
intbuffer number
N *
intsample starting index
intnumber of sequential samples to change (M)
M * floata sample value

Set contiguous ranges of sample indices to sets of values. For each range, the starting sample index is given followed by the number of samples to change, followed by the values.

/b_fill

Fill ranges of sample value(s).
intbuffer number
N *
intsample starting index
intnumber of samples to fill (M)
floatvalue

Set contiguous ranges of sample indices to single values. For each range, the starting sample index is given followed by the number of samples to change, followed by the value to fill. This is only meant for setting a few samples, not whole buffers or large sections.

/b_gen

Call a command to fill a buffer.
intbuffer number
stringcommand name
...command arguments

Plug-ins can define commands that operate on buffers. The arguments after the command name are defined by the command. The currently defined buffer fill commands are listed below in a separate section.

Asynchronous.
Replies to sender with /done /b_gen bufNum when complete.

/b_close

Close soundfile.
intbuffer number

After using a buffer with DiskOut, close the soundfile and write header information.

Asynchronous.
Replies to sender with /done /b_close bufNum when complete.

/b_query

Get buffer info.
N * intbuffer number(s)

Responds to the sender with a /b_info message. The arguments to /b_info are as follows:
N *
intbuffer number
intnumber of frames
intnumber of channels
floatsample rate

/b_get

Get sample value(s).
intbuffer number
N * inta sample index

Replies to sender with the corresponding /b_set command.

/b_getn

Get ranges of sample value(s).
intbuffer number
N *
intstarting sample index
intnumber of sequential samples to get (M)

Get contiguous ranges of samples. Replies to sender with the corresponding /b_setn command. This is only meant for getting a few samples, not whole buffers or large sections.

Control Bus Commands

/c_set

Set bus value(s).
N *
inta bus index
float or inta control value

Takes a list of pairs of bus indices and values and sets the buses to those values.

/c_setn

Set ranges of bus value(s).
N *
intstarting bus index
intnumber of sequential buses to change (M)
M *
float or inta control value

Set contiguous ranges of buses to sets of values. For each range, the starting bus index is given followed by the number of channels to change, followed by the values.

/c_fill

Fill ranges of bus value(s).
N *
intstarting bus index
intnumber of buses to fill (M)
float or intvalue

Set contiguous ranges of buses to single values. For each range, the starting sample index is given followed by the number of buses to change, followed by the value to fill.

/c_get

Get bus value(s).
N * inta bus index

Takes a list of buses and replies to sender with the corresponding /c_set command.

/c_getn

Get ranges of bus value(s).
N *
intstarting bus index
intnumber of sequential buses to get (M)

Get contiguous ranges of buses. Replies to sender with the corresponding /c_setn command.

Non Real Time Mode Commands

/nrt_end

End real time mode, close file. Not yet implemented.

This message should be sent in a bundle in non real time mode. The bundle timestamp will establish the ending time of the file. This command will end non real time mode and close the sound file. Replies to sender with /done when complete.

Replies to Commands

These messages are sent by the server in response to some commands.

/done

An asynchronous message has completed.
stringthe name of the command
other(optional) some commands provide other information, for example a buffer index.

Sent in response to all asynchronous commands. Sent only to the sender of the original message.

/fail

An error occurred.
stringthe name of the command
stringthe error message.
other(optional) some commands provide other information, for example a buffer index.

There was a problem. Sent only to the sender of the original message.

/late

A command was received too late. not yet implemented
intthe high 32 bits of the original time stamp.
intthe low 32 bits of the original time stamp.
intthe high 32 bits of the time it was executed.
intthe low 32 bits of the time it was executed.

The command was received too late to be executed on time. Sent only to the sender of the original message.

Node Notifications from Server

These messages are sent as notification of some event to all clients who have registered via the /notify command.

All of these have the same arguments:
intnode ID
intthe node's parent group ID
intprevious node ID, -1 if no previous node.
intnext node ID, -1 if no next node.
int1 if the node is a group, 0 if it is a synth
The following two arguments are only sent if the node is a group:
intthe ID of the head node, -1 if there is no head node.
intthe ID of the tail node, -1 if there is no tail node.

/n_go

A node was started. This command is sent to all registered clients when a node is created.

/n_end

A node ended. This command is sent to all registered clients when a node ends and is deallocated.

/n_off

A node was turned off. This command is sent to all registered clients when a node is turned off.

/n_on

A node was turned on. This command is sent to all registered clients when a node is turned on.

/n_move

A node was moved. This command is sent to all registered clients when a node is moved.

/n_info

Reply to /n_query. This command is sent to all registered clients in response to an /n_query command.

Trigger Notification

These messages are sent as notification of some event to all clients who have registered via the /notify command.

/tr

A trigger message.
intnode ID
inttrigger ID
floattrigger value

This command is the mechanism that synths can use to trigger events in clients. The node ID is the node that is sending the trigger. The trigger ID and value are determined by inputs to the SendTrig unit generator which is the originator of this message.

Buffer Fill Commands

These are the currently defined fill routines for use with the /b_gen command.

Wave Fill Commands

There are three defined fill routines for sine waves.

The flags are defined as follows:
1normalize - Normalize peak amplitude of wave to 1.0.
2wavetable - If set, then the buffer is written in wavetable format so that it can be read by interpolating oscillators.
4clear - if set then the buffer is cleared before new partials are written into it. Otherwise the new partials are summed with the existing contents of the buffer.

These flags can be added together to create a unique single integer flag that describes the true/false combinations for these three options:
31 + 2normalize + wavetable
51 + 4normalize + clear
62 + 4wavetable + clear
71 + 2 + 4normalize + wavetable + clear

sine1
intflags, see above
N *
floatpartial amplitude

Fills a buffer with a series of sine wave partials. The first float value specifies the amplitude of the first partial, the second float value specifies the amplitude of the second partial, and so on.

sine2
intflags, see above
N *
floatpartial frequency (in cycles per buffer)
floatpartial amplitude

Similar to sine1 except that each partial frequency is specified explicitly instead of being an integer series of partials. Non-integer partial frequencies are possible.

sine3
intflags, see above
N *
floatpartial frequency (in cycles per buffer)
floatpartial amplitude
floatpartial phase

Similar to sine2 except that each partial may have a nonzero starting phase.

cheby
intflags, see above
N *
floatamplitude

Fills a buffer with a series of chebyshev polynomials, which can be defined as:

cheby(n) = amplitude * cos(n * acos(x))

The first float value specifies the amplitude for n = 1, the second float value specifies the amplitude for n = 2, and so on. To eliminate a DC offset when used as a waveshaper, the wavetable is offset so that the center value is zero.

Other Commands

copy
intsample position in destination
intsource buffer number
intsample position in source
intnumber of samples to copy

Copy samples from the source buffer to the destination buffer specified in the b_gen command. If the number of samples to copy is negative, the maximum number of samples possible is copied.

Asynchronous.
Replies to sender with /done when complete.

Command Numbers

These are the currently defined command numbers. More may be added to the end of the list in the future.

enum {
    cmd_none = 0,

    cmd_notify = 1,
    cmd_status = 2,
    cmd_quit = 3,
    cmd_cmd = 4,

    cmd_d_recv = 5,
    cmd_d_load = 6,
    cmd_d_loadDir = 7,
    cmd_d_freeAll = 8,

    cmd_s_new = 9,

    cmd_n_trace = 10,
    cmd_n_free = 11,
    cmd_n_run = 12,
    cmd_n_cmd = 13,
    cmd_n_map = 14,
    cmd_n_set = 15,
    cmd_n_setn = 16,
    cmd_n_fill = 17,
    cmd_n_before = 18,
    cmd_n_after = 19,

    cmd_u_cmd = 20,

    cmd_g_new = 21,
    cmd_g_head = 22,
    cmd_g_tail = 23,
    cmd_g_freeAll = 24,

    cmd_c_set = 25,
    cmd_c_setn = 26,
    cmd_c_fill = 27,

    cmd_b_alloc = 28,
    cmd_b_allocRead = 29,
    cmd_b_read = 30,
    cmd_b_write = 31,
    cmd_b_free = 32,
    cmd_b_close = 33,
    cmd_b_zero = 34,
    cmd_b_set = 35,
    cmd_b_setn = 36,
    cmd_b_fill = 37,
    cmd_b_gen = 38,

    cmd_dumpOSC = 39,

    cmd_c_get = 40,
    cmd_c_getn = 41,
    cmd_b_get = 42,
    cmd_b_getn = 43,
    cmd_s_get = 44,
    cmd_s_getn = 45,

    cmd_n_query = 46,
    cmd_b_query = 47,

    cmd_n_mapn = 48,
    cmd_s_noid = 49,

    cmd_g_deepFree = 50,
    cmd_clearSched = 51,

    cmd_sync = 52,

    cmd_d_free = 53,

    cmd_b_allocReadChannel = 54,
    cmd_b_readChannel = 55,

    cmd_g_dumpTree = 56,
    cmd_g_queryTree = 57,


    cmd_error = 58,

    cmd_s_newargs = 59,

    cmd_n_mapa = 60,
    cmd_n_mapan = 61,
    cmd_n_order = 62,

    NUMBER_OF_COMMANDS = 63
};

copyright © 2002 James McCartney - converted to ScDoc format 2011 by Jonatan Liljedahl