Mercurial > audio-send
changeset 32:b8bc24918d63
moved ear.org into cortex
| author | Robert McIntyre <rlm@mit.edu> |
|---|---|
| date | Sat, 04 Feb 2012 01:43:33 -0700 |
| parents | 0e794e48a0cc |
| children | 3caceef436ea |
| files | org/ear.org org/send.org |
| diffstat | 2 files changed, 0 insertions(+), 963 deletions(-) [+] |
line wrap: on
line diff
1.1 --- a/org/ear.org Fri Feb 03 06:40:59 2012 -0700 1.2 +++ /dev/null Thu Jan 01 00:00:00 1970 +0000 1.3 @@ -1,952 +0,0 @@ 1.4 -#+title: Simulated Sense of Hearing 1.5 -#+author: Robert McIntyre 1.6 -#+email: rlm@mit.edu 1.7 -#+description: Simulating multiple listeners and the sense of hearing in jMonkeyEngine3 1.8 -#+keywords: simulated hearing, openal, clojure, jMonkeyEngine3, LWJGL, AI 1.9 -#+SETUPFILE: ../../aurellem/org/setup.org 1.10 -#+INCLUDE: ../../aurellem/org/level-0.org 1.11 -#+BABEL: :exports both :noweb yes :cache no :mkdirp yes 1.12 - 1.13 -* Hearing 1.14 - 1.15 -I want to be able to place ears in a similar manner to how I place 1.16 -the eyes. I want to be able to place ears in a unique spatial 1.17 -position, and receive as output at every tick the F.F.T. of whatever 1.18 -signals are happening at that point. 1.19 - 1.20 -Hearing is one of the more difficult senses to simulate, because there 1.21 -is less support for obtaining the actual sound data that is processed 1.22 -by jMonkeyEngine3. 1.23 - 1.24 -jMonkeyEngine's sound system works as follows: 1.25 - 1.26 - - jMonkeyEngine uses the =AppSettings= for the particular application 1.27 - to determine what sort of =AudioRenderer= should be used. 1.28 - - although some support is provided for multiple AudioRendering 1.29 - backends, jMonkeyEngine at the time of this writing will either 1.30 - pick no AudioRenderer at all, or the =LwjglAudioRenderer= 1.31 - - jMonkeyEngine tries to figure out what sort of system you're 1.32 - running and extracts the appropriate native libraries. 1.33 - - the =LwjglAudioRenderer= uses the [[http://lwjgl.org/][=LWJGL=]] (LightWeight Java Game 1.34 - Library) bindings to interface with a C library called [[http://kcat.strangesoft.net/openal.html][=OpenAL=]] 1.35 - - =OpenAL= calculates the 3D sound localization and feeds a stream of 1.36 - sound to any of various sound output devices with which it knows 1.37 - how to communicate. 1.38 - 1.39 -A consequence of this is that there's no way to access the actual 1.40 -sound data produced by =OpenAL=. Even worse, =OpenAL= only supports 1.41 -one /listener/, which normally isn't a problem for games, but becomes 1.42 -a problem when trying to make multiple AI creatures that can each hear 1.43 -the world from a different perspective. 1.44 - 1.45 -To make many AI creatures in jMonkeyEngine that can each hear the 1.46 -world from their own perspective, it is necessary to go all the way 1.47 -back to =OpenAL= and implement support for simulated hearing there. 1.48 - 1.49 -* Extending =OpenAL= 1.50 -** =OpenAL= Devices 1.51 - 1.52 -=OpenAL= goes to great lengths to support many different systems, all 1.53 -with different sound capabilities and interfaces. It accomplishes this 1.54 -difficult task by providing code for many different sound backends in 1.55 -pseudo-objects called /Devices/. There's a device for the Linux Open 1.56 -Sound System and the Advanced Linux Sound Architecture, there's one 1.57 -for Direct Sound on Windows, there's even one for Solaris. =OpenAL= 1.58 -solves the problem of platform independence by providing all these 1.59 -Devices. 1.60 - 1.61 -Wrapper libraries such as LWJGL are free to examine the system on 1.62 -which they are running and then select an appropriate device for that 1.63 -system. 1.64 - 1.65 -There are also a few "special" devices that don't interface with any 1.66 -particular system. These include the Null Device, which doesn't do 1.67 -anything, and the Wave Device, which writes whatever sound it receives 1.68 -to a file, if everything has been set up correctly when configuring 1.69 -=OpenAL=. 1.70 - 1.71 -Actual mixing of the sound data happens in the Devices, and they are 1.72 -the only point in the sound rendering process where this data is 1.73 -available. 1.74 - 1.75 -Therefore, in order to support multiple listeners, and get the sound 1.76 -data in a form that the AIs can use, it is necessary to create a new 1.77 -Device, which supports this features. 1.78 - 1.79 -** The Send Device 1.80 -Adding a device to OpenAL is rather tricky -- there are five separate 1.81 -files in the =OpenAL= source tree that must be modified to do so. I've 1.82 -documented this process [[./add-new-device.org][here]] for anyone who is interested. 1.83 - 1.84 - 1.85 -Onward to that actual Device! 1.86 - 1.87 -again, my objectives are: 1.88 - 1.89 - - Support Multiple Listeners from jMonkeyEngine3 1.90 - - Get access to the rendered sound data for further processing from 1.91 - clojure. 1.92 - 1.93 -** =send.c= 1.94 - 1.95 -** Header 1.96 -#+name: send-header 1.97 -#+begin_src C 1.98 -#include "config.h" 1.99 -#include <stdlib.h> 1.100 -#include "alMain.h" 1.101 -#include "AL/al.h" 1.102 -#include "AL/alc.h" 1.103 -#include "alSource.h" 1.104 -#include <jni.h> 1.105 - 1.106 -//////////////////// Summary 1.107 - 1.108 -struct send_data; 1.109 -struct context_data; 1.110 - 1.111 -static void addContext(ALCdevice *, ALCcontext *); 1.112 -static void syncContexts(ALCcontext *master, ALCcontext *slave); 1.113 -static void syncSources(ALsource *master, ALsource *slave, 1.114 - ALCcontext *masterCtx, ALCcontext *slaveCtx); 1.115 - 1.116 -static void syncSourcei(ALuint master, ALuint slave, 1.117 - ALCcontext *masterCtx, ALCcontext *ctx2, ALenum param); 1.118 -static void syncSourcef(ALuint master, ALuint slave, 1.119 - ALCcontext *masterCtx, ALCcontext *ctx2, ALenum param); 1.120 -static void syncSource3f(ALuint master, ALuint slave, 1.121 - ALCcontext *masterCtx, ALCcontext *ctx2, ALenum param); 1.122 - 1.123 -static void swapInContext(ALCdevice *, struct context_data *); 1.124 -static void saveContext(ALCdevice *, struct context_data *); 1.125 -static void limitContext(ALCdevice *, ALCcontext *); 1.126 -static void unLimitContext(ALCdevice *); 1.127 - 1.128 -static void init(ALCdevice *); 1.129 -static void renderData(ALCdevice *, int samples); 1.130 - 1.131 -#define UNUSED(x) (void)(x) 1.132 -#+end_src 1.133 - 1.134 -The main idea behind the Send device is to take advantage of the fact 1.135 -that LWJGL only manages one /context/ when using OpenAL. A /context/ 1.136 -is like a container that holds samples and keeps track of where the 1.137 -listener is. In order to support multiple listeners, the Send device 1.138 -identifies the LWJGL context as the master context, and creates any 1.139 -number of slave contexts to represent additional listeners. Every 1.140 -time the device renders sound, it synchronizes every source from the 1.141 -master LWJGL context to the slave contexts. Then, it renders each 1.142 -context separately, using a different listener for each one. The 1.143 -rendered sound is made available via JNI to jMonkeyEngine. 1.144 - 1.145 -To recap, the process is: 1.146 - - Set the LWJGL context as "master" in the =init()= method. 1.147 - - Create any number of additional contexts via =addContext()= 1.148 - - At every call to =renderData()= sync the master context with the 1.149 - slave contexts with =syncContexts()= 1.150 - - =syncContexts()= calls =syncSources()= to sync all the sources 1.151 - which are in the master context. 1.152 - - =limitContext()= and =unLimitContext()= make it possible to render 1.153 - only one context at a time. 1.154 - 1.155 -** Necessary State 1.156 -#+name: send-state 1.157 -#+begin_src C 1.158 -//////////////////// State 1.159 - 1.160 -typedef struct context_data { 1.161 - ALfloat ClickRemoval[MAXCHANNELS]; 1.162 - ALfloat PendingClicks[MAXCHANNELS]; 1.163 - ALvoid *renderBuffer; 1.164 - ALCcontext *ctx; 1.165 -} context_data; 1.166 - 1.167 -typedef struct send_data { 1.168 - ALuint size; 1.169 - context_data **contexts; 1.170 - ALuint numContexts; 1.171 - ALuint maxContexts; 1.172 -} send_data; 1.173 -#+end_src 1.174 - 1.175 -Switching between contexts is not the normal operation of a Device, 1.176 -and one of the problems with doing so is that a Device normally keeps 1.177 -around a few pieces of state such as the =ClickRemoval= array above 1.178 -which will become corrupted if the contexts are not done in 1.179 -parallel. The solution is to create a copy of this normally global 1.180 -device state for each context, and copy it back and forth into and out 1.181 -of the actual device state whenever a context is rendered. 1.182 - 1.183 -** Synchronization Macros 1.184 -#+name: sync-macros 1.185 -#+begin_src C 1.186 -//////////////////// Context Creation / Synchronization 1.187 - 1.188 -#define _MAKE_SYNC(NAME, INIT_EXPR, GET_EXPR, SET_EXPR) \ 1.189 - void NAME (ALuint sourceID1, ALuint sourceID2, \ 1.190 - ALCcontext *ctx1, ALCcontext *ctx2, \ 1.191 - ALenum param){ \ 1.192 - INIT_EXPR; \ 1.193 - ALCcontext *current = alcGetCurrentContext(); \ 1.194 - alcMakeContextCurrent(ctx1); \ 1.195 - GET_EXPR; \ 1.196 - alcMakeContextCurrent(ctx2); \ 1.197 - SET_EXPR; \ 1.198 - alcMakeContextCurrent(current); \ 1.199 - } 1.200 - 1.201 -#define MAKE_SYNC(NAME, TYPE, GET, SET) \ 1.202 - _MAKE_SYNC(NAME, \ 1.203 - TYPE value, \ 1.204 - GET(sourceID1, param, &value), \ 1.205 - SET(sourceID2, param, value)) 1.206 - 1.207 -#define MAKE_SYNC3(NAME, TYPE, GET, SET) \ 1.208 - _MAKE_SYNC(NAME, \ 1.209 - TYPE value1; TYPE value2; TYPE value3;, \ 1.210 - GET(sourceID1, param, &value1, &value2, &value3), \ 1.211 - SET(sourceID2, param, value1, value2, value3)) 1.212 - 1.213 -MAKE_SYNC( syncSourcei, ALint, alGetSourcei, alSourcei); 1.214 -MAKE_SYNC( syncSourcef, ALfloat, alGetSourcef, alSourcef); 1.215 -MAKE_SYNC3(syncSource3i, ALint, alGetSource3i, alSource3i); 1.216 -MAKE_SYNC3(syncSource3f, ALfloat, alGetSource3f, alSource3f); 1.217 - 1.218 -#+end_src 1.219 - 1.220 -Setting the state of an =OpenAL= source is done with the =alSourcei=, 1.221 -=alSourcef=, =alSource3i=, and =alSource3f= functions. In order to 1.222 -completely synchronize two sources, it is necessary to use all of 1.223 -them. These macros help to condense the otherwise repetitive 1.224 -synchronization code involving these similar low-level =OpenAL= functions. 1.225 - 1.226 -** Source Synchronization 1.227 -#+name: sync-sources 1.228 -#+begin_src C 1.229 -void syncSources(ALsource *masterSource, ALsource *slaveSource, 1.230 - ALCcontext *masterCtx, ALCcontext *slaveCtx){ 1.231 - ALuint master = masterSource->source; 1.232 - ALuint slave = slaveSource->source; 1.233 - ALCcontext *current = alcGetCurrentContext(); 1.234 - 1.235 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_PITCH); 1.236 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_GAIN); 1.237 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_MAX_DISTANCE); 1.238 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_ROLLOFF_FACTOR); 1.239 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_REFERENCE_DISTANCE); 1.240 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_MIN_GAIN); 1.241 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_MAX_GAIN); 1.242 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_CONE_OUTER_GAIN); 1.243 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_CONE_INNER_ANGLE); 1.244 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_CONE_OUTER_ANGLE); 1.245 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_SEC_OFFSET); 1.246 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_SAMPLE_OFFSET); 1.247 - syncSourcef(master,slave,masterCtx,slaveCtx,AL_BYTE_OFFSET); 1.248 - 1.249 - syncSource3f(master,slave,masterCtx,slaveCtx,AL_POSITION); 1.250 - syncSource3f(master,slave,masterCtx,slaveCtx,AL_VELOCITY); 1.251 - syncSource3f(master,slave,masterCtx,slaveCtx,AL_DIRECTION); 1.252 - 1.253 - syncSourcei(master,slave,masterCtx,slaveCtx,AL_SOURCE_RELATIVE); 1.254 - syncSourcei(master,slave,masterCtx,slaveCtx,AL_LOOPING); 1.255 - 1.256 - alcMakeContextCurrent(masterCtx); 1.257 - ALint source_type; 1.258 - alGetSourcei(master, AL_SOURCE_TYPE, &source_type); 1.259 - 1.260 - // Only static sources are currently synchronized! 1.261 - if (AL_STATIC == source_type){ 1.262 - ALint master_buffer; 1.263 - ALint slave_buffer; 1.264 - alGetSourcei(master, AL_BUFFER, &master_buffer); 1.265 - alcMakeContextCurrent(slaveCtx); 1.266 - alGetSourcei(slave, AL_BUFFER, &slave_buffer); 1.267 - if (master_buffer != slave_buffer){ 1.268 - alSourcei(slave, AL_BUFFER, master_buffer); 1.269 - } 1.270 - } 1.271 - 1.272 - // Synchronize the state of the two sources. 1.273 - alcMakeContextCurrent(masterCtx); 1.274 - ALint masterState; 1.275 - ALint slaveState; 1.276 - 1.277 - alGetSourcei(master, AL_SOURCE_STATE, &masterState); 1.278 - alcMakeContextCurrent(slaveCtx); 1.279 - alGetSourcei(slave, AL_SOURCE_STATE, &slaveState); 1.280 - 1.281 - if (masterState != slaveState){ 1.282 - switch (masterState){ 1.283 - case AL_INITIAL : alSourceRewind(slave); break; 1.284 - case AL_PLAYING : alSourcePlay(slave); break; 1.285 - case AL_PAUSED : alSourcePause(slave); break; 1.286 - case AL_STOPPED : alSourceStop(slave); break; 1.287 - } 1.288 - } 1.289 - // Restore whatever context was previously active. 1.290 - alcMakeContextCurrent(current); 1.291 -} 1.292 -#+end_src 1.293 -This function is long because it has to exhaustively go through all the 1.294 -possible state that a source can have and make sure that it is the 1.295 -same between the master and slave sources. I'd like to take this 1.296 -moment to salute the [[http://connect.creativelabs.com/openal/Documentation/Forms/AllItems.aspx][=OpenAL= Reference Manual]], which provides a very 1.297 -good description of =OpenAL='s internals. 1.298 - 1.299 -** Context Synchronization 1.300 -#+name: sync-contexts 1.301 -#+begin_src C 1.302 -void syncContexts(ALCcontext *master, ALCcontext *slave){ 1.303 - /* If there aren't sufficient sources in slave to mirror 1.304 - the sources in master, create them. */ 1.305 - ALCcontext *current = alcGetCurrentContext(); 1.306 - 1.307 - UIntMap *masterSourceMap = &(master->SourceMap); 1.308 - UIntMap *slaveSourceMap = &(slave->SourceMap); 1.309 - ALuint numMasterSources = masterSourceMap->size; 1.310 - ALuint numSlaveSources = slaveSourceMap->size; 1.311 - 1.312 - alcMakeContextCurrent(slave); 1.313 - if (numSlaveSources < numMasterSources){ 1.314 - ALuint numMissingSources = numMasterSources - numSlaveSources; 1.315 - ALuint newSources[numMissingSources]; 1.316 - alGenSources(numMissingSources, newSources); 1.317 - } 1.318 - 1.319 - /* Now, slave is guaranteed to have at least as many sources 1.320 - as master. Sync each source from master to the corresponding 1.321 - source in slave. */ 1.322 - int i; 1.323 - for(i = 0; i < masterSourceMap->size; i++){ 1.324 - syncSources((ALsource*)masterSourceMap->array[i].value, 1.325 - (ALsource*)slaveSourceMap->array[i].value, 1.326 - master, slave); 1.327 - } 1.328 - alcMakeContextCurrent(current); 1.329 -} 1.330 -#+end_src 1.331 - 1.332 -Most of the hard work in Context Synchronization is done in 1.333 -=syncSources()=. The only thing that =syncContexts()= has to worry 1.334 -about is automatically creating new sources whenever a slave context 1.335 -does not have the same number of sources as the master context. 1.336 - 1.337 -** Context Creation 1.338 -#+name: context-creation 1.339 -#+begin_src C 1.340 -static void addContext(ALCdevice *Device, ALCcontext *context){ 1.341 - send_data *data = (send_data*)Device->ExtraData; 1.342 - // expand array if necessary 1.343 - if (data->numContexts >= data->maxContexts){ 1.344 - ALuint newMaxContexts = data->maxContexts*2 + 1; 1.345 - data->contexts = realloc(data->contexts, newMaxContexts*sizeof(context_data)); 1.346 - data->maxContexts = newMaxContexts; 1.347 - } 1.348 - // create context_data and add it to the main array 1.349 - context_data *ctxData; 1.350 - ctxData = (context_data*)calloc(1, sizeof(*ctxData)); 1.351 - ctxData->renderBuffer = 1.352 - malloc(BytesFromDevFmt(Device->FmtType) * 1.353 - Device->NumChan * Device->UpdateSize); 1.354 - ctxData->ctx = context; 1.355 - 1.356 - data->contexts[data->numContexts] = ctxData; 1.357 - data->numContexts++; 1.358 -} 1.359 -#+end_src 1.360 - 1.361 -Here, the slave context is created, and it's data is stored in the 1.362 -device-wide =ExtraData= structure. The =renderBuffer= that is created 1.363 -here is where the rendered sound samples for this slave context will 1.364 -eventually go. 1.365 - 1.366 -** Context Switching 1.367 -#+name: context-switching 1.368 -#+begin_src C 1.369 -//////////////////// Context Switching 1.370 - 1.371 -/* A device brings along with it two pieces of state 1.372 - * which have to be swapped in and out with each context. 1.373 - */ 1.374 -static void swapInContext(ALCdevice *Device, context_data *ctxData){ 1.375 - memcpy(Device->ClickRemoval, ctxData->ClickRemoval, sizeof(ALfloat)*MAXCHANNELS); 1.376 - memcpy(Device->PendingClicks, ctxData->PendingClicks, sizeof(ALfloat)*MAXCHANNELS); 1.377 -} 1.378 - 1.379 -static void saveContext(ALCdevice *Device, context_data *ctxData){ 1.380 - memcpy(ctxData->ClickRemoval, Device->ClickRemoval, sizeof(ALfloat)*MAXCHANNELS); 1.381 - memcpy(ctxData->PendingClicks, Device->PendingClicks, sizeof(ALfloat)*MAXCHANNELS); 1.382 -} 1.383 - 1.384 -static ALCcontext **currentContext; 1.385 -static ALuint currentNumContext; 1.386 - 1.387 -/* By default, all contexts are rendered at once for each call to aluMixData. 1.388 - * This function uses the internals of the ALCdevice struct to temporally 1.389 - * cause aluMixData to only render the chosen context. 1.390 - */ 1.391 -static void limitContext(ALCdevice *Device, ALCcontext *ctx){ 1.392 - currentContext = Device->Contexts; 1.393 - currentNumContext = Device->NumContexts; 1.394 - Device->Contexts = &ctx; 1.395 - Device->NumContexts = 1; 1.396 -} 1.397 - 1.398 -static void unLimitContext(ALCdevice *Device){ 1.399 - Device->Contexts = currentContext; 1.400 - Device->NumContexts = currentNumContext; 1.401 -} 1.402 -#+end_src 1.403 - 1.404 -=OpenAL= normally renders all Contexts in parallel, outputting the 1.405 -whole result to the buffer. It does this by iterating over the 1.406 -Device->Contexts array and rendering each context to the buffer in 1.407 -turn. By temporally setting Device->NumContexts to 1 and adjusting 1.408 -the Device's context list to put the desired context-to-be-rendered 1.409 -into position 0, we can get trick =OpenAL= into rendering each slave 1.410 -context separate from all the others. 1.411 - 1.412 -** Main Device Loop 1.413 -#+name: main-loop 1.414 -#+begin_src C 1.415 -//////////////////// Main Device Loop 1.416 - 1.417 -/* Establish the LWJGL context as the master context, which will 1.418 - * be synchronized to all the slave contexts 1.419 - */ 1.420 -static void init(ALCdevice *Device){ 1.421 - ALCcontext *masterContext = alcGetCurrentContext(); 1.422 - addContext(Device, masterContext); 1.423 -} 1.424 - 1.425 - 1.426 -static void renderData(ALCdevice *Device, int samples){ 1.427 - if(!Device->Connected){return;} 1.428 - send_data *data = (send_data*)Device->ExtraData; 1.429 - ALCcontext *current = alcGetCurrentContext(); 1.430 - 1.431 - ALuint i; 1.432 - for (i = 1; i < data->numContexts; i++){ 1.433 - syncContexts(data->contexts[0]->ctx , data->contexts[i]->ctx); 1.434 - } 1.435 - 1.436 - if ((ALuint) samples > Device->UpdateSize){ 1.437 - printf("exceeding internal buffer size; dropping samples\n"); 1.438 - printf("requested %d; available %d\n", samples, Device->UpdateSize); 1.439 - samples = (int) Device->UpdateSize; 1.440 - } 1.441 - 1.442 - for (i = 0; i < data->numContexts; i++){ 1.443 - context_data *ctxData = data->contexts[i]; 1.444 - ALCcontext *ctx = ctxData->ctx; 1.445 - alcMakeContextCurrent(ctx); 1.446 - limitContext(Device, ctx); 1.447 - swapInContext(Device, ctxData); 1.448 - aluMixData(Device, ctxData->renderBuffer, samples); 1.449 - saveContext(Device, ctxData); 1.450 - unLimitContext(Device); 1.451 - } 1.452 - alcMakeContextCurrent(current); 1.453 -} 1.454 -#+end_src 1.455 - 1.456 -The main loop synchronizes the master LWJGL context with all the slave 1.457 -contexts, then walks each context, rendering just that context to it's 1.458 -audio-sample storage buffer. 1.459 - 1.460 -** JNI Methods 1.461 - 1.462 -At this point, we have the ability to create multiple listeners by 1.463 -using the master/slave context trick, and the rendered audio data is 1.464 -waiting patiently in internal buffers, one for each listener. We need 1.465 -a way to transport this information to Java, and also a way to drive 1.466 -this device from Java. The following JNI interface code is inspired 1.467 -by the way LWJGL interfaces with =OpenAL=. 1.468 - 1.469 -*** step 1.470 -#+name: jni-step 1.471 -#+begin_src C 1.472 -//////////////////// JNI Methods 1.473 - 1.474 -#include "com_aurellem_send_AudioSend.h" 1.475 - 1.476 -/* 1.477 - * Class: com_aurellem_send_AudioSend 1.478 - * Method: nstep 1.479 - * Signature: (JI)V 1.480 - */ 1.481 -JNIEXPORT void JNICALL Java_com_aurellem_send_AudioSend_nstep 1.482 -(JNIEnv *env, jclass clazz, jlong device, jint samples){ 1.483 - UNUSED(env);UNUSED(clazz);UNUSED(device); 1.484 - renderData((ALCdevice*)((intptr_t)device), samples); 1.485 -} 1.486 -#+end_src 1.487 -This device, unlike most of the other devices in =OpenAL=, does not 1.488 -render sound unless asked. This enables the system to slow down or 1.489 -speed up depending on the needs of the AIs who are using it to 1.490 -listen. If the device tried to render samples in real-time, a 1.491 -complicated AI whose mind takes 100 seconds of computer time to 1.492 -simulate 1 second of AI-time would miss almost all of the sound in 1.493 -its environment. 1.494 - 1.495 - 1.496 -*** getSamples 1.497 -#+name: jni-get-samples 1.498 -#+begin_src C 1.499 -/* 1.500 - * Class: com_aurellem_send_AudioSend 1.501 - * Method: ngetSamples 1.502 - * Signature: (JLjava/nio/ByteBuffer;III)V 1.503 - */ 1.504 -JNIEXPORT void JNICALL Java_com_aurellem_send_AudioSend_ngetSamples 1.505 -(JNIEnv *env, jclass clazz, jlong device, jobject buffer, jint position, 1.506 - jint samples, jint n){ 1.507 - UNUSED(clazz); 1.508 - 1.509 - ALvoid *buffer_address = 1.510 - ((ALbyte *)(((char*)(*env)->GetDirectBufferAddress(env, buffer)) + position)); 1.511 - ALCdevice *recorder = (ALCdevice*) ((intptr_t)device); 1.512 - send_data *data = (send_data*)recorder->ExtraData; 1.513 - if ((ALuint)n > data->numContexts){return;} 1.514 - memcpy(buffer_address, data->contexts[n]->renderBuffer, 1.515 - BytesFromDevFmt(recorder->FmtType) * recorder->NumChan * samples); 1.516 -} 1.517 -#+end_src 1.518 - 1.519 -This is the transport layer between C and Java that will eventually 1.520 -allow us to access rendered sound data from clojure. 1.521 - 1.522 -*** Listener Management 1.523 - 1.524 -=addListener=, =setNthListenerf=, and =setNthListener3f= are 1.525 -necessary to change the properties of any listener other than the 1.526 -master one, since only the listener of the current active context is 1.527 -affected by the normal =OpenAL= listener calls. 1.528 -#+name: listener-manage 1.529 -#+begin_src C 1.530 -/* 1.531 - * Class: com_aurellem_send_AudioSend 1.532 - * Method: naddListener 1.533 - * Signature: (J)V 1.534 - */ 1.535 -JNIEXPORT void JNICALL Java_com_aurellem_send_AudioSend_naddListener 1.536 -(JNIEnv *env, jclass clazz, jlong device){ 1.537 - UNUSED(env); UNUSED(clazz); 1.538 - //printf("creating new context via naddListener\n"); 1.539 - ALCdevice *Device = (ALCdevice*) ((intptr_t)device); 1.540 - ALCcontext *new = alcCreateContext(Device, NULL); 1.541 - addContext(Device, new); 1.542 -} 1.543 - 1.544 -/* 1.545 - * Class: com_aurellem_send_AudioSend 1.546 - * Method: nsetNthListener3f 1.547 - * Signature: (IFFFJI)V 1.548 - */ 1.549 -JNIEXPORT void JNICALL Java_com_aurellem_send_AudioSend_nsetNthListener3f 1.550 - (JNIEnv *env, jclass clazz, jint param, 1.551 - jfloat v1, jfloat v2, jfloat v3, jlong device, jint contextNum){ 1.552 - UNUSED(env);UNUSED(clazz); 1.553 - 1.554 - ALCdevice *Device = (ALCdevice*) ((intptr_t)device); 1.555 - send_data *data = (send_data*)Device->ExtraData; 1.556 - 1.557 - ALCcontext *current = alcGetCurrentContext(); 1.558 - if ((ALuint)contextNum > data->numContexts){return;} 1.559 - alcMakeContextCurrent(data->contexts[contextNum]->ctx); 1.560 - alListener3f(param, v1, v2, v3); 1.561 - alcMakeContextCurrent(current); 1.562 -} 1.563 - 1.564 -/* 1.565 - * Class: com_aurellem_send_AudioSend 1.566 - * Method: nsetNthListenerf 1.567 - * Signature: (IFJI)V 1.568 - */ 1.569 -JNIEXPORT void JNICALL Java_com_aurellem_send_AudioSend_nsetNthListenerf 1.570 -(JNIEnv *env, jclass clazz, jint param, jfloat v1, jlong device, 1.571 - jint contextNum){ 1.572 - 1.573 - UNUSED(env);UNUSED(clazz); 1.574 - 1.575 - ALCdevice *Device = (ALCdevice*) ((intptr_t)device); 1.576 - send_data *data = (send_data*)Device->ExtraData; 1.577 - 1.578 - ALCcontext *current = alcGetCurrentContext(); 1.579 - if ((ALuint)contextNum > data->numContexts){return;} 1.580 - alcMakeContextCurrent(data->contexts[contextNum]->ctx); 1.581 - alListenerf(param, v1); 1.582 - alcMakeContextCurrent(current); 1.583 -} 1.584 -#+end_src 1.585 - 1.586 -*** Initialization 1.587 -=initDevice= is called from the Java side after LWJGL has created its 1.588 -context, and before any calls to =addListener=. It establishes the 1.589 -LWJGL context as the master context. 1.590 - 1.591 -=getAudioFormat= is a convenience function that uses JNI to build up a 1.592 -=javax.sound.sampled.AudioFormat= object from data in the Device. This 1.593 -way, there is no ambiguity about what the bits created by =step= and 1.594 -returned by =getSamples= mean. 1.595 -#+name: jni-init 1.596 -#+begin_src C 1.597 -/* 1.598 - * Class: com_aurellem_send_AudioSend 1.599 - * Method: ninitDevice 1.600 - * Signature: (J)V 1.601 - */ 1.602 -JNIEXPORT void JNICALL Java_com_aurellem_send_AudioSend_ninitDevice 1.603 -(JNIEnv *env, jclass clazz, jlong device){ 1.604 - UNUSED(env);UNUSED(clazz); 1.605 - ALCdevice *Device = (ALCdevice*) ((intptr_t)device); 1.606 - init(Device); 1.607 -} 1.608 - 1.609 -/* 1.610 - * Class: com_aurellem_send_AudioSend 1.611 - * Method: ngetAudioFormat 1.612 - * Signature: (J)Ljavax/sound/sampled/AudioFormat; 1.613 - */ 1.614 -JNIEXPORT jobject JNICALL Java_com_aurellem_send_AudioSend_ngetAudioFormat 1.615 -(JNIEnv *env, jclass clazz, jlong device){ 1.616 - UNUSED(clazz); 1.617 - jclass AudioFormatClass = 1.618 - (*env)->FindClass(env, "javax/sound/sampled/AudioFormat"); 1.619 - jmethodID AudioFormatConstructor = 1.620 - (*env)->GetMethodID(env, AudioFormatClass, "<init>", "(FIIZZ)V"); 1.621 - 1.622 - ALCdevice *Device = (ALCdevice*) ((intptr_t)device); 1.623 - int isSigned; 1.624 - switch (Device->FmtType) 1.625 - { 1.626 - case DevFmtUByte: 1.627 - case DevFmtUShort: isSigned = 0; break; 1.628 - default : isSigned = 1; 1.629 - } 1.630 - float frequency = Device->Frequency; 1.631 - int bitsPerFrame = (8 * BytesFromDevFmt(Device->FmtType)); 1.632 - int channels = Device->NumChan; 1.633 - jobject format = (*env)-> 1.634 - NewObject( 1.635 - env,AudioFormatClass,AudioFormatConstructor, 1.636 - frequency, 1.637 - bitsPerFrame, 1.638 - channels, 1.639 - isSigned, 1.640 - 0); 1.641 - return format; 1.642 -} 1.643 -#+end_src 1.644 - 1.645 -** Boring Device management stuff 1.646 -This code is more-or-less copied verbatim from the other =OpenAL= 1.647 -backends. It's the basis for =OpenAL='s primitive object system. 1.648 -#+name: device-init 1.649 -#+begin_src C 1.650 -//////////////////// Device Initialization / Management 1.651 - 1.652 -static const ALCchar sendDevice[] = "Multiple Audio Send"; 1.653 - 1.654 -static ALCboolean send_open_playback(ALCdevice *device, 1.655 - const ALCchar *deviceName) 1.656 -{ 1.657 - send_data *data; 1.658 - // stop any buffering for stdout, so that I can 1.659 - // see the printf statements in my terminal immediately 1.660 - setbuf(stdout, NULL); 1.661 - 1.662 - if(!deviceName) 1.663 - deviceName = sendDevice; 1.664 - else if(strcmp(deviceName, sendDevice) != 0) 1.665 - return ALC_FALSE; 1.666 - data = (send_data*)calloc(1, sizeof(*data)); 1.667 - device->szDeviceName = strdup(deviceName); 1.668 - device->ExtraData = data; 1.669 - return ALC_TRUE; 1.670 -} 1.671 - 1.672 -static void send_close_playback(ALCdevice *device) 1.673 -{ 1.674 - send_data *data = (send_data*)device->ExtraData; 1.675 - alcMakeContextCurrent(NULL); 1.676 - ALuint i; 1.677 - // Destroy all slave contexts. LWJGL will take care of 1.678 - // its own context. 1.679 - for (i = 1; i < data->numContexts; i++){ 1.680 - context_data *ctxData = data->contexts[i]; 1.681 - alcDestroyContext(ctxData->ctx); 1.682 - free(ctxData->renderBuffer); 1.683 - free(ctxData); 1.684 - } 1.685 - free(data); 1.686 - device->ExtraData = NULL; 1.687 -} 1.688 - 1.689 -static ALCboolean send_reset_playback(ALCdevice *device) 1.690 -{ 1.691 - SetDefaultWFXChannelOrder(device); 1.692 - return ALC_TRUE; 1.693 -} 1.694 - 1.695 -static void send_stop_playback(ALCdevice *Device){ 1.696 - UNUSED(Device); 1.697 -} 1.698 - 1.699 -static const BackendFuncs send_funcs = { 1.700 - send_open_playback, 1.701 - send_close_playback, 1.702 - send_reset_playback, 1.703 - send_stop_playback, 1.704 - NULL, 1.705 - NULL, /* These would be filled with functions to */ 1.706 - NULL, /* handle capturing audio if we we into that */ 1.707 - NULL, /* sort of thing... */ 1.708 - NULL, 1.709 - NULL 1.710 -}; 1.711 - 1.712 -ALCboolean alc_send_init(BackendFuncs *func_list){ 1.713 - *func_list = send_funcs; 1.714 - return ALC_TRUE; 1.715 -} 1.716 - 1.717 -void alc_send_deinit(void){} 1.718 - 1.719 -void alc_send_probe(enum DevProbe type) 1.720 -{ 1.721 - switch(type) 1.722 - { 1.723 - case DEVICE_PROBE: 1.724 - AppendDeviceList(sendDevice); 1.725 - break; 1.726 - case ALL_DEVICE_PROBE: 1.727 - AppendAllDeviceList(sendDevice); 1.728 - break; 1.729 - case CAPTURE_DEVICE_PROBE: 1.730 - break; 1.731 - } 1.732 -} 1.733 -#+end_src 1.734 - 1.735 -* The Java interface, =AudioSend= 1.736 - 1.737 -The Java interface to the Send Device follows naturally from the JNI 1.738 -definitions. It is included here for completeness. The only thing here 1.739 -of note is the =deviceID=. This is available from LWJGL, but to only 1.740 -way to get it is reflection. Unfortunately, there is no other way to 1.741 -control the Send device than to obtain a pointer to it. 1.742 - 1.743 -#+include: "../java/src/com/aurellem/send/AudioSend.java" src java :exports code 1.744 - 1.745 -* Finally, Ears in clojure! 1.746 - 1.747 -Now that the infrastructure is complete (modulo a few patches to 1.748 -jMonkeyEngine3 to support accessing this modified version of =OpenAL= 1.749 -that are not worth discussing), the clojure ear abstraction is rather 1.750 -simple. Just as there were =SceneProcessors= for vision, there are 1.751 -now =SoundProcessors= for hearing. 1.752 - 1.753 -#+include "../../jmeCapture/src/com/aurellem/capture/audio/SoundProcessor.java" src java 1.754 - 1.755 -#+name: ears 1.756 -#+begin_src clojure 1.757 -(ns cortex.hearing 1.758 - "Simulate the sense of hearing in jMonkeyEngine3. Enables multiple 1.759 - listeners at different positions in the same world. Passes vectors 1.760 - of floats in the range [-1.0 -- 1.0] in PCM format to any arbitrary 1.761 - function." 1.762 - {:author "Robert McIntyre"} 1.763 - (:use (cortex world util sense)) 1.764 - (:import java.nio.ByteBuffer) 1.765 - (:import org.tritonus.share.sampled.FloatSampleTools) 1.766 - (:import com.aurellem.capture.audio.SoundProcessor) 1.767 - (:import javax.sound.sampled.AudioFormat)) 1.768 - 1.769 -(cortex.import/mega-import-jme3) 1.770 - 1.771 -(defn sound-processor 1.772 - "Deals with converting ByteBuffers into Vectors of floats so that 1.773 - the continuation functions can be defined in terms of immutable 1.774 - stuff." 1.775 - [continuation] 1.776 - (proxy [SoundProcessor] [] 1.777 - (cleanup []) 1.778 - (process 1.779 - [#^ByteBuffer audioSamples numSamples #^AudioFormat audioFormat] 1.780 - (let [bytes (byte-array numSamples) 1.781 - num-floats (/ numSamples (.getFrameSize audioFormat)) 1.782 - floats (float-array num-floats)] 1.783 - (.get audioSamples bytes 0 numSamples) 1.784 - (FloatSampleTools/byte2floatInterleaved 1.785 - bytes 0 floats 0 num-floats audioFormat) 1.786 - (continuation 1.787 - (vec floats)))))) 1.788 - 1.789 - 1.790 - 1.791 - 1.792 -;; Ears work the same way as vision. 1.793 - 1.794 -;; (hearing creature) will return [init-functions 1.795 -;; sensor-functions]. The init functions each take the world and 1.796 -;; register a SoundProcessor that does foureier transforms on the 1.797 -;; incommong sound data, making it available to each sensor function. 1.798 - 1.799 -(defn creature-ears 1.800 - "Return the children of the creature's \"ears\" node." 1.801 - ;;dylan 1.802 - ;;"The ear nodes which are children of the \"ears\" node in the 1.803 - ;;creature." 1.804 - [#^Node creature] 1.805 - (if-let [ear-node (.getChild creature "ears")] 1.806 - (seq (.getChildren ear-node)) 1.807 - (do (println-repl "could not find ears node") []))) 1.808 - 1.809 - 1.810 -;;dylan (defn follow-sense, adjoin-sense, attach-stimuli, 1.811 -;;anchor-qualia, augment-organ, with-organ 1.812 - 1.813 - 1.814 -(defn update-listener-velocity 1.815 - "Update the listener's velocity every update loop." 1.816 - [#^Spatial obj #^Listener lis] 1.817 - (let [old-position (atom (.getLocation lis))] 1.818 - (.addControl 1.819 - obj 1.820 - (proxy [AbstractControl] [] 1.821 - (controlUpdate [tpf] 1.822 - (let [new-position (.getLocation lis)] 1.823 - (.setVelocity 1.824 - lis 1.825 - (.mult (.subtract new-position @old-position) 1.826 - (float (/ tpf)))) 1.827 - (reset! old-position new-position))) 1.828 - (controlRender [_ _]))))) 1.829 - 1.830 -(import com.aurellem.capture.audio.AudioSendRenderer) 1.831 - 1.832 -(defn attach-ear 1.833 - [#^Application world #^Node creature #^Spatial ear continuation] 1.834 - (let [target (closest-node creature ear) 1.835 - lis (Listener.) 1.836 - audio-renderer (.getAudioRenderer world) 1.837 - sp (sound-processor continuation)] 1.838 - (.setLocation lis (.getWorldTranslation ear)) 1.839 - (.setRotation lis (.getWorldRotation ear)) 1.840 - (bind-sense target lis) 1.841 - (update-listener-velocity target lis) 1.842 - (.addListener audio-renderer lis) 1.843 - (.registerSoundProcessor audio-renderer lis sp))) 1.844 - 1.845 -(defn enable-hearing 1.846 - [#^Node creature #^Spatial ear] 1.847 - (let [hearing-data (atom [])] 1.848 - [(fn [world] 1.849 - (attach-ear world creature ear 1.850 - (fn [data] 1.851 - (reset! hearing-data (vec data))))) 1.852 - [(fn [] 1.853 - (let [data @hearing-data 1.854 - topology 1.855 - (vec (map #(vector % 0) (range 0 (count data)))) 1.856 - scaled-data 1.857 - (vec 1.858 - (map 1.859 - #(rem (int (* 255 (/ (+ 1 %) 2))) 256) 1.860 - data))] 1.861 - [topology scaled-data])) 1.862 - ]])) 1.863 - 1.864 -(defn hearing 1.865 - [#^Node creature] 1.866 - (reduce 1.867 - (fn [[init-a senses-a] 1.868 - [init-b senses-b]] 1.869 - [(conj init-a init-b) 1.870 - (into senses-a senses-b)]) 1.871 - [[][]] 1.872 - (for [ear (creature-ears creature)] 1.873 - (enable-hearing creature ear)))) 1.874 - 1.875 - 1.876 -#+end_src 1.877 - 1.878 -* Example 1.879 - 1.880 -#+name: test-hearing 1.881 -#+begin_src clojure :results silent 1.882 -(ns cortex.test.hearing 1.883 - (:use (cortex world util hearing)) 1.884 - (:import (com.jme3.audio AudioNode Listener)) 1.885 - (:import com.jme3.scene.Node 1.886 - com.jme3.system.AppSettings)) 1.887 - 1.888 -(defn setup-fn [world] 1.889 - (let [listener (Listener.)] 1.890 - (add-ear world listener #(println-repl (nth % 0))))) 1.891 - 1.892 -(defn play-sound [node world value] 1.893 - (if (not value) 1.894 - (do 1.895 - (.playSource (.getAudioRenderer world) node)))) 1.896 - 1.897 -(defn test-basic-hearing [] 1.898 - (let [node1 (AudioNode. (asset-manager) "Sounds/pure.wav" false false)] 1.899 - (world 1.900 - (Node.) 1.901 - {"key-space" (partial play-sound node1)} 1.902 - setup-fn 1.903 - no-op))) 1.904 - 1.905 -(defn test-advanced-hearing 1.906 - "Testing hearing: 1.907 - You should see a blue sphere flying around several 1.908 - cubes. As the sphere approaches each cube, it turns 1.909 - green." 1.910 - [] 1.911 - (doto (com.aurellem.capture.examples.Advanced.) 1.912 - (.setSettings 1.913 - (doto (AppSettings. true) 1.914 - (.setAudioRenderer "Send"))) 1.915 - (.setShowSettings false) 1.916 - (.setPauseOnLostFocus false))) 1.917 - 1.918 -#+end_src 1.919 - 1.920 -This extremely basic program prints out the first sample it encounters 1.921 -at every time stamp. You can see the rendered sound being printed at 1.922 -the REPL. 1.923 - 1.924 - - As a bonus, this method of capturing audio for AI can also be used 1.925 - to capture perfect audio from a jMonkeyEngine application, for use 1.926 - in demos and the like. 1.927 - 1.928 - 1.929 -* COMMENT Code Generation 1.930 - 1.931 -#+begin_src clojure :tangle ../../cortex/src/cortex/hearing.clj 1.932 -<<ears>> 1.933 -#+end_src 1.934 - 1.935 -#+begin_src clojure :tangle ../../cortex/src/cortex/test/hearing.clj 1.936 -<<test-hearing>> 1.937 -#+end_src 1.938 - 1.939 -#+begin_src C :tangle ../Alc/backends/send.c 1.940 -<<send-header>> 1.941 -<<send-state>> 1.942 -<<sync-macros>> 1.943 -<<sync-sources>> 1.944 -<<sync-contexts>> 1.945 -<<context-creation>> 1.946 -<<context-switching>> 1.947 -<<main-loop>> 1.948 -<<jni-step>> 1.949 -<<jni-get-samples>> 1.950 -<<listener-manage>> 1.951 -<<jni-init>> 1.952 -<<device-init>> 1.953 -#+end_src 1.954 - 1.955 -
2.1 --- a/org/send.org Fri Feb 03 06:40:59 2012 -0700 2.2 +++ /dev/null Thu Jan 01 00:00:00 1970 +0000 2.3 @@ -1,11 +0,0 @@ 2.4 -#+title: send.c 2.5 -#+author: Robert McIntyre 2.6 -#+email: rlm@mit.edu 2.7 -#+description: some code I wrote to extend open-al 2.8 -#+SETUPFILE: ../../aurellem/org/setup.org 2.9 -#+INCLUDE: ../../aurellem/org/level-0.org 2.10 - 2.11 - 2.12 -#+include /home/r/proj/audio-send/Alc/backends/send.c src C 2.13 - 2.14 -