-- | Generic constructors for the command set implemented by the SuperCollider synthesis server. module Sound.SC3.Server.Command.Generic where import Data.List {- base -} import Data.Maybe {- base -} import Sound.OSC.Core {- hosc -} import Sound.SC3.Server.Command.Core import Sound.SC3.Server.Enum import Sound.SC3.Server.Utilities import Sound.SC3.UGen.Enum -- * Node commands -- | Place a node after another. n_after :: (Integral i) => [(i,i)] -> Message n_after = message "/n_after" . mk_duples int32 int32 -- | Place a node before another. n_before :: (Integral i) => [(i,i)] -> Message n_before = message "/n_before" . mk_duples int32 int32 -- | Fill ranges of a node's control values. n_fill :: (Integral i,Real n) => i -> [(String,i,n)] -> Message n_fill nid l = message "/n_fill" (int32 nid : mk_triples string int32 float l) -- | Delete a node. n_free :: (Integral i) => [i] -> Message n_free = message "/n_free" . map int32 n_map :: (Integral i) => i -> [(String,i)] -> Message n_map nid l = message "/n_map" (int32 nid : mk_duples string int32 l) -- | Map a node's controls to read from buses. n_mapn :: (Integral i) => i -> [(String,i,i)] -> Message n_mapn nid l = message "/n_mapn" (int32 nid : mk_triples string int32 int32 l) -- | Map a node's controls to read from an audio bus. n_mapa :: (Integral i) => i -> [(String,i)] -> Message n_mapa nid l = message "/n_mapa" (int32 nid : mk_duples string int32 l) -- | Map a node's controls to read from audio buses. n_mapan :: (Integral i) => i -> [(String,i,i)] -> Message n_mapan nid l = message "/n_mapan" (int32 nid : mk_triples string int32 int32 l) -- | Get info about a node. n_query :: (Integral i) => [i] -> Message n_query = message "/n_query" . map int32 -- | Turn node on or off. n_run :: (Integral i) => [(i,Bool)] -> Message n_run = message "/n_run" . mk_duples int32 (int32 . fromEnum) -- | Set a node's control values. n_set :: (Integral i,Real n) => i -> [(String,n)] -> Message n_set nid c = message "/n_set" (int32 nid : mk_duples string float c) -- | Set ranges of a node's control values. n_setn :: (Integral i,Real n) => i -> [(String,[n])] -> Message n_setn nid l = let f (s,d) = string s : int32 (length d) : map float d in message "/n_setn" (int32 nid : concatMap f l) -- | Trace a node. n_trace :: (Integral i) => [i] -> Message n_trace = message "/n_trace" . map int32 -- | Move an ordered sequence of nodes. n_order :: (Integral i) => AddAction -> i -> [i] -> Message n_order a n ns = message "/n_order" (int32 (fromEnum a) : int32 n : map int32 ns) -- * Synthesis node commands -- | Get control values. s_get :: (Integral i) => i -> [String] -> Message s_get nid i = message "/s_get" (int32 nid : map string i) -- | Get ranges of control values. s_getn :: (Integral i) => i -> [(String,i)] -> Message s_getn nid l = message "/s_getn" (int32 nid : mk_duples string int32 l) -- | Create a new synth. s_new :: (Integral i,Real n) => String -> i -> AddAction -> i -> [(String,n)] -> Message s_new n i a t c = message "/s_new" (string n : int32 i : int32 (fromEnum a) : int32 t : mk_duples string float c) -- | Auto-reassign synth's ID to a reserved value. s_noid :: (Integral i) => [i] -> Message s_noid = message "/s_noid" . map int32 -- * Group node commands -- | Free all synths in this group and all its sub-groups. g_deepFree :: (Integral i) => [i] -> Message g_deepFree = message "/g_deepFree" . map int32 -- | Delete all nodes in a group. g_freeAll :: (Integral i) => [i] -> Message g_freeAll = message "/g_freeAll" . map int32 -- | Add node to head of group. g_head :: (Integral i) => [(i,i)] -> Message g_head = message "/g_head" . mk_duples int32 int32 -- | Create a new group. g_new :: (Integral i) => [(i,AddAction,i)] -> Message g_new = message "/g_new" . mk_triples int32 (int32 . fromEnum) int32 -- | Add node to tail of group. g_tail :: (Integral i) => [(i,i)] -> Message g_tail = message "/g_tail" . mk_duples int32 int32 -- | Post a representation of a group's node subtree, optionally including the current control values for synths. g_dumpTree :: (Integral i) => [(i,Bool)] -> Message g_dumpTree = message "/g_dumpTree" . mk_duples int32 (int32 . fromEnum) -- | Request a representation of a group's node subtree, optionally including the current control values for synths. -- -- Replies to the sender with a @/g_queryTree.reply@ message listing all of the nodes contained within the group in the following format: -- -- > int32 - if synth control values are included 1, else 0 -- > int32 - node ID of the requested group -- > int32 - number of child nodes contained within the requested group -- > -- > For each node in the subtree: -- > [ -- > int32 - node ID -- > int32 - number of child nodes contained within this node. If -1 this is a synth, if >= 0 it's a group. -- > -- > If this node is a synth: -- > symbol - the SynthDef name for this node. -- > -- > If flag (see above) is true: -- > int32 - numControls for this synth (M) -- > [ -- > symbol or int: control name or index -- > float or symbol: value or control bus mapping symbol (e.g. 'c1') -- > ] * M -- > ] * the number of nodes in the subtree -- -- 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. g_queryTree :: (Integral i) => [(i,Bool)] -> Message g_queryTree = message "/g_queryTree" . mk_duples int32 (int32 . fromEnum) -- | Create a new parallel group (supernova specific). p_new :: (Integral i) => [(i,AddAction,i)] -> Message p_new = message "/p_new" . mk_triples int32 (int32 . fromEnum) int32 -- * Unit Generator commands -- | Send a command to a unit generator. u_cmd :: (Integral i) => i -> i -> String -> [Datum] -> Message u_cmd nid uid name arg = message "/u_cmd" ([int32 nid,int32 uid,string name] ++ arg) -- * Buffer commands -- | Allocates zero filled buffer to number of channels and samples. (Asynchronous) b_alloc :: (Integral i) => i -> i -> i -> Message b_alloc nid frames channels = message "/b_alloc" [int32 nid,int32 frames,int32 channels] -- | Allocate buffer space and read a sound file. (Asynchronous) b_allocRead :: (Integral i) => i -> String -> i -> i -> Message b_allocRead nid p f n = message "/b_allocRead" [int32 nid,string p,int32 f,int32 n] -- | Allocate buffer space and read a sound file, picking specific channels. (Asynchronous) b_allocReadChannel :: (Integral i) => i -> String -> i -> i -> [i] -> Message b_allocReadChannel nid p f n cs = message "/b_allocReadChannel" ([int32 nid,string p,int32 f,int32 n] ++ map int32 cs) -- | Close attached soundfile and write header information. (Asynchronous) b_close :: (Integral i) => i -> Message b_close nid = message "/b_close" [int32 nid] -- | Fill ranges of sample values. b_fill :: (Integral i,Real n) => i -> [(i,i,n)] -> Message b_fill nid l = message "/b_fill" (int32 nid : mk_triples int32 int32 float l) -- | Free buffer data. (Asynchronous) b_free :: (Integral i) => i -> Message b_free nid = message "/b_free" [int32 nid] -- | Call a command to fill a buffer. (Asynchronous) b_gen :: (Integral i) => i -> String -> [Datum] -> Message b_gen bid name arg = message "/b_gen" (int32 bid : string name : arg) -- | Call @sine1@ 'b_gen' command. b_gen_sine1 :: (Integral i,Real n) => i -> [B_Gen] -> [n] -> Message b_gen_sine1 z f n = b_gen z "sine1" (int32 (b_gen_flag f) : map float n) -- | Call @sine2@ 'b_gen' command. b_gen_sine2 :: (Integral i,Real n) => i -> [B_Gen] -> [(n,n)] -> Message b_gen_sine2 z f n = b_gen z "sine2" (int32 (b_gen_flag f) : mk_duples float float n) -- | Call @sine3@ 'b_gen' command. b_gen_sine3 :: (Integral i,Real n) => i -> [B_Gen] -> [(n,n,n)] -> Message b_gen_sine3 z f n = b_gen z "sine3" (int32 (b_gen_flag f) : mk_triples float float float n) -- | Call @cheby@ 'b_gen' command. b_gen_cheby :: (Integral i,Real n) => i -> [B_Gen] -> [n] -> Message b_gen_cheby z f n = b_gen z "cheby" (int32 (b_gen_flag f) : map float n) -- | Call @copy@ 'b_gen' command. b_gen_copy :: (Integral i) => i -> i -> i -> i -> Maybe i -> Message b_gen_copy z dst_ix src_b src_ix nf = let nf' = fromMaybe (-1) nf in b_gen z "copy" (map int32 [dst_ix,src_b,src_ix,nf']) -- | Get sample values. b_get :: (Integral i) => i -> [i] -> Message b_get nid i = message "/b_get" (int32 nid : map int32 i) -- | Get ranges of sample values. b_getn :: (Integral i) => i -> [(i,i)] -> Message b_getn nid l = message "/b_getn" (int32 nid : mk_duples int32 int32 l) -- | Request \/b_info messages. b_query :: (Integral i) => [i] -> Message b_query = message "/b_query" . map int32 -- | Read sound file data into an existing buffer. (Asynchronous) b_read :: (Integral i) => i -> String -> i -> i -> i -> Bool -> Message b_read nid p f n f' z = message "/b_read" [int32 nid,string p,int32 f,int32 n,int32 f',int32 (fromEnum z)] -- | Read sound file data into an existing buffer, picking specific channels. (Asynchronous) b_readChannel :: (Integral i) => i -> String -> i -> i -> i -> Bool -> [i] -> Message b_readChannel nid p f n f' z cs = message "/b_readChannel" ([int32 nid,string p,int32 f,int32 n,int32 f',int32 (fromEnum z)] ++ map int32 cs) -- | Set sample values. b_set :: (Integral i,Real n) => i -> [(i,n)] -> Message b_set nid l = message "/b_set" (int32 nid : mk_duples int32 float l) -- | Set ranges of sample values. b_setn :: (Integral i,Real n) => i -> [(i,[n])] -> Message b_setn nid l = let f (i,d) = int32 i : int32 (length d) : map float d in message "/b_setn" (int32 nid : concatMap f l) -- | Write sound file data. (Asynchronous) b_write :: (Integral i) => i -> String -> SoundFileFormat -> SampleFormat -> i -> i -> Bool -> Message b_write nid p h t f s z = message "/b_write" [int32 nid,string p,string (soundFileFormatString h),string (sampleFormatString t),int32 f,int32 s,int32 (fromEnum z)] -- | Zero sample data. (Asynchronous) b_zero :: (Integral i) => i -> Message b_zero nid = message "/b_zero" [int32 nid] -- * Control bus commands -- | Fill ranges of bus values. c_fill :: (Integral i,Real n) => [(i,i,n)] -> Message c_fill = message "/c_fill" . mk_triples int32 int32 float -- | Get bus values. c_get :: (Integral i) => [i] -> Message c_get = message "/c_get" . map int32 -- | Get ranges of bus values. c_getn :: (Integral i) => [(i,i)] -> Message c_getn = message "/c_getn" . mk_duples int32 int32 -- | Set bus values. c_set :: (Integral i,Real n) => [(i,n)] -> Message c_set = message "/c_set" . mk_duples int32 float -- | Set ranges of bus values. c_setn :: (Integral i,Real n) => [(i,[n])] -> Message c_setn l = let f (i,d) = int32 i : int32 (length d) : map float d in message "/c_setn" (concatMap f l) -- * Server operation commands -- | Request \/synced message when all current asynchronous commands complete. sync :: (Integral i) => i -> Message sync sid = message "/sync" [int32 sid] -- * Variants to simplify common cases -- | Pre-allocate for b_setn1, values preceding offset are zeroed. b_alloc_setn1 :: (Integral i,Real n) => i -> i -> [n] -> Message b_alloc_setn1 nid i xs = let k = i + genericLength xs xs' = genericReplicate i 0 ++ xs in withCM (b_alloc nid k 1) (b_setn1 nid 0 xs') -- | Get ranges of sample values. b_getn1 :: (Integral i) => i -> (i,i) -> Message b_getn1 nid = b_getn nid . return -- | Set single sample value. b_set1 :: (Integral i,Real n) => i -> i -> n -> Message b_set1 nid i x = b_set nid [(i,x)] -- | Set a range of sample values. b_setn1 :: (Integral i,Real n) => i -> i -> [n] -> Message b_setn1 nid i xs = b_setn nid [(i,xs)] -- | Variant on 'b_query'. b_query1 :: (Integral i) => i -> Message b_query1 = b_query . return -- | Set single bus values. c_set1 :: (Integral i,Real n) => i -> n -> Message c_set1 i x = c_set [(i,x)] -- | Set a single node control value. n_set1 :: (Integral i,Real n) => i -> String -> n -> Message n_set1 nid k n = n_set nid [(k,n)] -- | @s_new@ with no parameters. s_new0 :: (Integral i) => String -> i -> AddAction -> i -> Message s_new0 n i a t = s_new n i a t ([]::[(String,Double)]) -- * Buffer segmentation and indices -- | Segment a request for /m/ places into sets of at most /n/. -- -- > b_segment 1024 2056 == [8,1024,1024] -- > b_segment 1 5 == replicate 5 1 b_segment :: (Integral i) => i -> i -> [i] b_segment n m = let (q,r) = m `quotRem` n s = genericReplicate q n in if r == 0 then s else r : s -- | Variant of 'b_segment' that takes a starting index and returns -- /(index,size)/ duples. -- -- > b_indices 1 5 0 == zip [0..4] (replicate 5 1) -- > b_indices 1024 2056 16 == [(16,8),(24,1024),(1048,1024)] b_indices :: (Integral i) => i -> i -> i -> [(i,i)] b_indices n m k = let dx_d = scanl1 (+) s = b_segment n m i = 0 : dx_d s in zip (map (+ k) i) s -- * UGen commands. -- | Generate accumulation buffer given time-domain IR buffer and FFT size. pc_preparePartConv :: (Integral i) => i -> i -> i -> Message pc_preparePartConv b irb fft_size = b_gen b "PreparePartConv" (map int32 [irb, fft_size]) -- Local Variables: -- truncate-lines:t -- End: