• Home
  • Line#
  • Scopes#
  • Navigate#
  • Raw
  • Download
1 /*
2  * Copyright (C) 2015 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 
18 ////////////////////////////////////////////
19 /// Actual sles functions.
20 
21 
22 // Test program to record from default audio input and playback to default audio output.
23 // It will generate feedback (Larsen effect) if played through on-device speakers,
24 // or acts as a delay if played through headset.
25 
26 #include "sles.h"
27 #include <stdio.h>
28 #include <stdlib.h>
29 #include <stddef.h>
30 
31 #include <assert.h>
32 #include <pthread.h>
33 #include <stdio.h>
34 #include <stdlib.h>
35 #include <string.h>
36 #include <unistd.h>
37 
slesInit(sles_data ** ppSles,int samplingRate,int frameCount,int micSource,int numFramesToIgnore)38 int slesInit(sles_data ** ppSles, int samplingRate, int frameCount, int micSource,
39              int numFramesToIgnore) {
40     int status = SLES_FAIL;
41     if (ppSles != NULL) {
42         sles_data * pSles = (sles_data*) calloc(1, sizeof (sles_data));
43 
44         SLES_PRINTF("malloc %zu bytes at %p", sizeof(sles_data), pSles);
45         *ppSles = pSles;
46         if (pSles != NULL)
47         {
48             SLES_PRINTF("creating server. Sampling rate =%d, frame count = %d",samplingRate,
49                     frameCount);
50             status = slesCreateServer(pSles, samplingRate, frameCount, micSource,
51                                       numFramesToIgnore);
52             SLES_PRINTF("slesCreateServer =%d", status);
53         }
54     }
55     return status;
56 }
slesDestroy(sles_data ** ppSles)57 int slesDestroy(sles_data ** ppSles) {
58     int status = SLES_FAIL;
59     if (ppSles != NULL) {
60         slesDestroyServer(*ppSles);
61 
62         if (*ppSles != NULL)
63         {
64             free(*ppSles);
65             *ppSles = 0;
66         }
67         status = SLES_SUCCESS;
68     }
69     return status;
70 }
71 
72 #define ASSERT_EQ(x, y) do { if ((x) == (y)) ; else { fprintf(stderr, "0x%x != 0x%x\n", \
73         (unsigned) (x), (unsigned) (y)); assert((x) == (y)); } } while (0)
74 
75 
76 // Called after audio recorder fills a buffer with data
recorderCallback(SLAndroidSimpleBufferQueueItf caller __unused,void * context)77 static void recorderCallback(SLAndroidSimpleBufferQueueItf caller __unused, void *context) {
78     sles_data *pSles = (sles_data*) context;
79     if (pSles != NULL) {
80 
81 
82 
83         SLresult result;
84 
85         pthread_mutex_lock(&(pSles->mutex));
86         //ee  SLES_PRINTF("<R");
87 
88         // We should only be called when a recording buffer is done
89         assert(pSles->rxFront <= pSles->rxBufCount);
90         assert(pSles->rxRear <= pSles->rxBufCount);
91         assert(pSles->rxFront != pSles->rxRear);
92         char *buffer = pSles->rxBuffers[pSles->rxFront];
93 
94         // Remove buffer from record queue
95         if (++pSles->rxFront > pSles->rxBufCount) {
96             pSles->rxFront = 0;
97         }
98 
99         // Throw out first frames
100         if (pSles->numFramesToIgnore) {
101             SLuint32 framesToErase = pSles->numFramesToIgnore;
102             if (framesToErase > pSles->bufSizeInFrames) {
103                 framesToErase = pSles->bufSizeInFrames;
104             }
105             pSles->numFramesToIgnore -= framesToErase;
106             // FIXME: this assumes each sample is a short
107             memset(buffer, 0, framesToErase * pSles->channels * sizeof(short));
108         }
109 
110         ssize_t actual = audio_utils_fifo_write(&(pSles->fifo), buffer,
111                 (size_t) pSles->bufSizeInFrames);
112         if (actual != (ssize_t) pSles->bufSizeInFrames) {
113             write(1, "?", 1);
114         }
115 
116         // This is called by a realtime (SCHED_FIFO) thread,
117         // and it is unsafe to do I/O as it could block for unbounded time.
118         // Flash filesystem is especially notorious for blocking.
119         if (pSles->fifo2Buffer != NULL) {
120             actual = audio_utils_fifo_write(&(pSles->fifo2), buffer,
121                     (size_t) pSles->bufSizeInFrames);
122             if (actual != (ssize_t) pSles->bufSizeInFrames) {
123                 write(1, "?", 1);
124             }
125         }
126 
127         // Enqueue this same buffer for the recorder to fill again.
128         result = (*(pSles->recorderBufferQueue))->Enqueue(pSles->recorderBufferQueue, buffer,
129                 pSles->bufSizeInBytes);
130         ASSERT_EQ(SL_RESULT_SUCCESS, result);
131 
132         // Update our model of the record queue
133         SLuint32 rxRearNext = pSles->rxRear+1;
134         if (rxRearNext > pSles->rxBufCount) {
135             rxRearNext = 0;
136         }
137         assert(rxRearNext != pSles->rxFront);
138         pSles->rxBuffers[pSles->rxRear] = buffer;
139         pSles->rxRear = rxRearNext;
140 
141 
142 
143         //ee  SLES_PRINTF("r>");
144         pthread_mutex_unlock(&(pSles->mutex));
145 
146     } //pSles not null
147 }
148 
149 
150 // Called after audio player empties a buffer of data
playerCallback(SLBufferQueueItf caller __unused,void * context)151 static void playerCallback(SLBufferQueueItf caller __unused, void *context) {
152     sles_data *pSles = (sles_data*) context;
153     if (pSles != NULL) {
154 
155         SLresult result;
156 
157         pthread_mutex_lock(&(pSles->mutex));
158         //ee  SLES_PRINTF("<P");
159 
160         // Get the buffer that just finished playing
161         assert(pSles->txFront <= pSles->txBufCount);
162         assert(pSles->txRear <= pSles->txBufCount);
163         assert(pSles->txFront != pSles->txRear);
164         char *buffer = pSles->txBuffers[pSles->txFront];
165         if (++pSles->txFront > pSles->txBufCount) {
166             pSles->txFront = 0;
167         }
168 
169 
170         ssize_t actual = audio_utils_fifo_read(&(pSles->fifo), buffer, pSles->bufSizeInFrames);
171         if (actual != (ssize_t) pSles->bufSizeInFrames) {
172             write(1, "/", 1);
173             // on underrun from pipe, substitute silence
174             memset(buffer, 0, pSles->bufSizeInFrames * pSles->channels * sizeof(short));
175         }
176 
177         if (pSles->injectImpulse == -1) {
178             // Experimentally, a single frame impulse was insufficient to trigger feedback.
179             // Also a Nyquist frequency signal was also insufficient, probably because
180             // the response of output and/or input path was not adequate at high frequencies.
181             // This short burst of a few cycles of square wave at Nyquist/4 was found to work well.
182             for (unsigned i = 0; i < pSles->bufSizeInFrames / 8; i += 8) {
183                 for (int j = 0; j < 8; j++) {
184                     for (unsigned k = 0; k < pSles->channels; k++) {
185                         ((short *)buffer)[(i+j)*pSles->channels+k] = j < 4 ? 0x7FFF : 0x8000;
186                     }
187                 }
188             }
189             pSles->injectImpulse = 0;
190         }
191 
192         // Enqueue the filled buffer for playing
193         result = (*(pSles->playerBufferQueue))->Enqueue(pSles->playerBufferQueue, buffer,
194                 pSles->bufSizeInBytes);
195         ASSERT_EQ(SL_RESULT_SUCCESS, result);
196 
197         // Update our model of the player queue
198         assert(pSles->txFront <= pSles->txBufCount);
199         assert(pSles->txRear <= pSles->txBufCount);
200         SLuint32 txRearNext = pSles->txRear+1;
201         if (txRearNext > pSles->txBufCount) {
202             txRearNext = 0;
203         }
204         assert(txRearNext != pSles->txFront);
205         pSles->txBuffers[pSles->txRear] = buffer;
206         pSles->txRear = txRearNext;
207 
208 
209         //ee    SLES_PRINTF("p>");
210         pthread_mutex_unlock(&(pSles->mutex));
211 
212     } //pSles not null
213 }
214 
slesCreateServer(sles_data * pSles,int samplingRate,int frameCount,int micSource,int numFramesToIgnore)215 int slesCreateServer(sles_data *pSles, int samplingRate, int frameCount,
216                      int micSource, int numFramesToIgnore) {
217     int status = SLES_FAIL;
218 
219     if (pSles == NULL) {
220         return status;
221     }
222 
223     //        adb shell slesTest_feedback -r1 -t1 -s48000 -f240 -i300 -e3 -o/sdcard/log.wav
224     //            r1 and t1 are the receive and transmit buffer counts, typically 1
225     //            s is the sample rate, typically 48000 or 44100
226     //            f is the frame count per buffer, typically 240 or 256
227     //            i is the number of milliseconds before impulse.  You may need to adjust this.
228     //            e is number of seconds to record
229     //            o is output .wav file name
230 
231 
232     //        // default values
233     //        SLuint32 rxBufCount = 1;     // -r#
234     //        SLuint32 txBufCount = 1;     // -t#
235     //        SLuint32 bufSizeInFrames = 240;  // -f#
236     //        SLuint32 channels = 1;       // -c#
237     //        SLuint32 sampleRate = 48000; // -s#
238     //        SLuint32 exitAfterSeconds = 3; // -e#
239     //        SLuint32 freeBufCount = 0;   // calculated
240     //        SLuint32 bufSizeInBytes = 0; // calculated
241     //        int injectImpulse = 300; // -i#i
242     //
243     //        // Storage area for the buffer queues
244     //        char **rxBuffers;
245     //        char **txBuffers;
246     //        char **freeBuffers;
247     //
248     //        // Buffer indices
249     //        SLuint32 rxFront;    // oldest recording
250     //        SLuint32 rxRear;     // next to be recorded
251     //        SLuint32 txFront;    // oldest playing
252     //        SLuint32 txRear;     // next to be played
253     //        SLuint32 freeFront;  // oldest free
254     //        SLuint32 freeRear;   // next to be freed
255     //
256     //        audio_utils_fifo fifo; //(*)
257     //        SLAndroidSimpleBufferQueueItf recorderBufferQueue;
258     //        SLBufferQueueItf playerBufferQueue;
259 
260     // default values
261     pSles->rxBufCount = 1;     // -r#
262     pSles->txBufCount = 1;     // -t#
263     pSles->bufSizeInFrames = frameCount;//240;  // -f#
264     pSles->channels = 1;       // -c#
265     pSles->sampleRate = samplingRate;//48000; // -s#
266     pSles->exitAfterSeconds = 3; // -e#
267     pSles->freeBufCount = 0;   // calculated
268     pSles->bufSizeInBytes = 0; // calculated
269     pSles->injectImpulse = 300; // -i#i
270 
271     if (numFramesToIgnore > 0) {
272         pSles->numFramesToIgnore = numFramesToIgnore;
273     } else {
274         pSles->numFramesToIgnore = 0;
275     }
276 
277     // Storage area for the buffer queues
278     //        char **rxBuffers;
279     //        char **txBuffers;
280     //        char **freeBuffers;
281 
282     // Buffer indices
283 /*
284     pSles->rxFront;    // oldest recording
285     pSles->rxRear;     // next to be recorded
286     pSles->txFront;    // oldest playing
287     pSles->txRear;     // next to be played
288     pSles->freeFront;  // oldest free
289     pSles->freeRear;   // next to be freed
290 
291     pSles->fifo; //(*)
292 */
293     pSles->fifo2Buffer = NULL;
294 
295     // compute total free buffers as -r plus -t
296     pSles->freeBufCount = pSles->rxBufCount + pSles->txBufCount;
297     // compute buffer size
298     pSles->bufSizeInBytes = pSles->channels * pSles->bufSizeInFrames * sizeof(short);
299 
300     // Initialize free buffers
301     pSles->freeBuffers = (char **) calloc(pSles->freeBufCount+1, sizeof(char *));
302     unsigned j;
303     for (j = 0; j < pSles->freeBufCount; ++j) {
304         pSles->freeBuffers[j] = (char *) malloc(pSles->bufSizeInBytes);
305     }
306     pSles->freeFront = 0;
307     pSles->freeRear = pSles->freeBufCount;
308     pSles->freeBuffers[j] = NULL;
309 
310     // Initialize record queue
311     pSles->rxBuffers = (char **) calloc(pSles->rxBufCount+1, sizeof(char *));
312     pSles->rxFront = 0;
313     pSles->rxRear = 0;
314 
315     // Initialize play queue
316     pSles->txBuffers = (char **) calloc(pSles->txBufCount+1, sizeof(char *));
317     pSles->txFront = 0;
318     pSles->txRear = 0;
319 
320     size_t frameSize = pSles->channels * sizeof(short);
321 #define FIFO_FRAMES 1024
322     pSles->fifoBuffer = new short[FIFO_FRAMES * pSles->channels];
323     audio_utils_fifo_init(&(pSles->fifo), FIFO_FRAMES, frameSize, pSles->fifoBuffer);
324 
325     //        SNDFILE *sndfile;
326     //        if (outFileName != NULL) {
327     // create .wav writer
328     //            SF_INFO info;
329     //            info.frames = 0;
330     //            info.samplerate = sampleRate;
331     //            info.channels = channels;
332     //            info.format = SF_FORMAT_WAV | SF_FORMAT_PCM_16;
333     //            sndfile = sf_open(outFileName, SFM_WRITE, &info);
334     //            if (sndfile != NULL) {
335 #define FIFO2_FRAMES 65536
336     pSles->fifo2Buffer = new short[FIFO2_FRAMES * pSles->channels];
337     audio_utils_fifo_init(&(pSles->fifo2), FIFO2_FRAMES, frameSize, pSles->fifo2Buffer);
338     //            } else {
339     //                fprintf(stderr, "sf_open failed\n");
340     //            }
341     //        } else {
342     //            sndfile = NULL;
343     //        }
344 
345     SLresult result;
346 
347     // create engine
348     result = slCreateEngine(&(pSles->engineObject), 0, NULL, 0, NULL, NULL);
349     ASSERT_EQ(SL_RESULT_SUCCESS, result);
350     result = (*(pSles->engineObject))->Realize(pSles->engineObject, SL_BOOLEAN_FALSE);
351     ASSERT_EQ(SL_RESULT_SUCCESS, result);
352     SLEngineItf engineEngine;
353     result = (*(pSles->engineObject))->GetInterface(pSles->engineObject, SL_IID_ENGINE,
354             &engineEngine);
355     ASSERT_EQ(SL_RESULT_SUCCESS, result);
356 
357     // create output mix
358     result = (*engineEngine)->CreateOutputMix(engineEngine, &(pSles->outputmixObject), 0, NULL,
359             NULL);
360     ASSERT_EQ(SL_RESULT_SUCCESS, result);
361     result = (*(pSles->outputmixObject))->Realize(pSles->outputmixObject, SL_BOOLEAN_FALSE);
362     ASSERT_EQ(SL_RESULT_SUCCESS, result);
363 
364     // create an audio player with buffer queue source and output mix sink
365     SLDataSource audiosrc;
366     SLDataSink audiosnk;
367     SLDataFormat_PCM pcm;
368     SLDataLocator_OutputMix locator_outputmix;
369     SLDataLocator_BufferQueue locator_bufferqueue_tx;
370     locator_bufferqueue_tx.locatorType = SL_DATALOCATOR_BUFFERQUEUE;
371     locator_bufferqueue_tx.numBuffers = pSles->txBufCount;
372     locator_outputmix.locatorType = SL_DATALOCATOR_OUTPUTMIX;
373     locator_outputmix.outputMix = pSles->outputmixObject;
374     pcm.formatType = SL_DATAFORMAT_PCM;
375     pcm.numChannels = pSles->channels;
376     pcm.samplesPerSec = pSles->sampleRate * 1000;
377     pcm.bitsPerSample = SL_PCMSAMPLEFORMAT_FIXED_16;
378     pcm.containerSize = 16;
379     pcm.channelMask = pSles->channels == 1 ? SL_SPEAKER_FRONT_CENTER :
380             (SL_SPEAKER_FRONT_LEFT | SL_SPEAKER_FRONT_RIGHT);
381     pcm.endianness = SL_BYTEORDER_LITTLEENDIAN;
382     audiosrc.pLocator = &locator_bufferqueue_tx;
383     audiosrc.pFormat = &pcm;
384     audiosnk.pLocator = &locator_outputmix;
385     audiosnk.pFormat = NULL;
386     pSles->playerObject = NULL;
387     pSles->recorderObject = NULL;
388     SLInterfaceID ids_tx[1] = {SL_IID_BUFFERQUEUE};
389     SLboolean flags_tx[1] = {SL_BOOLEAN_TRUE};
390     result = (*engineEngine)->CreateAudioPlayer(engineEngine, &(pSles->playerObject),
391             &audiosrc, &audiosnk, 1, ids_tx, flags_tx);
392     if (SL_RESULT_CONTENT_UNSUPPORTED == result) {
393         fprintf(stderr, "Could not create audio player (result %x), check sample rate\n",
394                 result);
395         SLES_PRINTF("ERROR: Could not create audio player (result %x), check sample rate\n",
396                 result);
397         goto cleanup;
398     }
399     ASSERT_EQ(SL_RESULT_SUCCESS, result);
400     result = (*(pSles->playerObject))->Realize(pSles->playerObject, SL_BOOLEAN_FALSE);
401     ASSERT_EQ(SL_RESULT_SUCCESS, result);
402     SLPlayItf playerPlay;
403     result = (*(pSles->playerObject))->GetInterface(pSles->playerObject, SL_IID_PLAY,
404             &playerPlay);
405     ASSERT_EQ(SL_RESULT_SUCCESS, result);
406     result = (*(pSles->playerObject))->GetInterface(pSles->playerObject, SL_IID_BUFFERQUEUE,
407             &(pSles->playerBufferQueue));
408     ASSERT_EQ(SL_RESULT_SUCCESS, result);
409     result = (*(pSles->playerBufferQueue))->RegisterCallback(pSles->playerBufferQueue,
410             playerCallback, pSles);
411     ASSERT_EQ(SL_RESULT_SUCCESS, result);
412 
413     // Enqueue some zero buffers for the player
414     for (j = 0; j < pSles->txBufCount; ++j) {
415 
416         // allocate a free buffer
417         assert(pSles->freeFront != pSles->freeRear);
418         char *buffer = pSles->freeBuffers[pSles->freeFront];
419         if (++pSles->freeFront > pSles->freeBufCount) {
420             pSles->freeFront = 0;
421         }
422 
423         // put on play queue
424         SLuint32 txRearNext = pSles->txRear + 1;
425         if (txRearNext > pSles->txBufCount) {
426             txRearNext = 0;
427         }
428         assert(txRearNext != pSles->txFront);
429         pSles->txBuffers[pSles->txRear] = buffer;
430         pSles->txRear = txRearNext;
431         result = (*(pSles->playerBufferQueue))->Enqueue(pSles->playerBufferQueue,
432                 buffer, pSles->bufSizeInBytes);
433         ASSERT_EQ(SL_RESULT_SUCCESS, result);
434     }
435 
436     result = (*playerPlay)->SetPlayState(playerPlay, SL_PLAYSTATE_PLAYING);
437     ASSERT_EQ(SL_RESULT_SUCCESS, result);
438 
439     // Create an audio recorder with microphone device source and buffer queue sink.
440     // The buffer queue as sink is an Android-specific extension.
441 
442     SLDataLocator_IODevice locator_iodevice;
443     SLDataLocator_AndroidSimpleBufferQueue locator_bufferqueue_rx;
444     locator_iodevice.locatorType = SL_DATALOCATOR_IODEVICE;
445     locator_iodevice.deviceType = SL_IODEVICE_AUDIOINPUT;
446     locator_iodevice.deviceID = SL_DEFAULTDEVICEID_AUDIOINPUT;
447     locator_iodevice.device = NULL;
448     audiosrc.pLocator = &locator_iodevice;
449     audiosrc.pFormat = NULL;
450     locator_bufferqueue_rx.locatorType = SL_DATALOCATOR_ANDROIDSIMPLEBUFFERQUEUE;
451     locator_bufferqueue_rx.numBuffers = pSles->rxBufCount;
452     audiosnk.pLocator = &locator_bufferqueue_rx;
453     audiosnk.pFormat = &pcm;
454     {
455         SLInterfaceID ids_rx[2] = {SL_IID_ANDROIDSIMPLEBUFFERQUEUE,
456                 SL_IID_ANDROIDCONFIGURATION};
457         SLboolean flags_rx[2] = {SL_BOOLEAN_TRUE, SL_BOOLEAN_TRUE};
458         result = (*engineEngine)->CreateAudioRecorder(engineEngine, &(pSles->recorderObject),
459                 &audiosrc, &audiosnk, 2, ids_rx, flags_rx);
460         if (SL_RESULT_SUCCESS != result) {
461             fprintf(stderr, "Could not create audio recorder (result %x), "
462                     "check sample rate and channel count\n", result);
463             status = SLES_FAIL;
464 
465             SLES_PRINTF("ERROR: Could not create audio recorder (result %x), "
466                     "check sample rate and channel count\n", result);
467             goto cleanup;
468         }
469     }
470     ASSERT_EQ(SL_RESULT_SUCCESS, result);
471 
472     {
473         /* Get the Android configuration interface which is explicit */
474         SLAndroidConfigurationItf configItf;
475         result = (*(pSles->recorderObject))->GetInterface(pSles->recorderObject,
476                 SL_IID_ANDROIDCONFIGURATION, (void*)&configItf);
477         ASSERT_EQ(SL_RESULT_SUCCESS, result);
478         SLuint32 presetValue = micSource;
479         /* Use the configuration interface to configure the recorder before it's realized */
480         if (presetValue != SL_ANDROID_RECORDING_PRESET_NONE) {
481             result = (*configItf)->SetConfiguration(configItf, SL_ANDROID_KEY_RECORDING_PRESET,
482                     &presetValue, sizeof(SLuint32));
483             ASSERT_EQ(SL_RESULT_SUCCESS, result);
484         }
485 
486     }
487 
488     result = (*(pSles->recorderObject))->Realize(pSles->recorderObject, SL_BOOLEAN_FALSE);
489     ASSERT_EQ(SL_RESULT_SUCCESS, result);
490     SLRecordItf recorderRecord;
491     result = (*(pSles->recorderObject))->GetInterface(pSles->recorderObject, SL_IID_RECORD,
492             &recorderRecord);
493     ASSERT_EQ(SL_RESULT_SUCCESS, result);
494     result = (*(pSles->recorderObject))->GetInterface(pSles->recorderObject,
495             SL_IID_ANDROIDSIMPLEBUFFERQUEUE, &(pSles->recorderBufferQueue));
496     ASSERT_EQ(SL_RESULT_SUCCESS, result);
497     result = (*(pSles->recorderBufferQueue))->RegisterCallback(pSles->recorderBufferQueue,
498             recorderCallback, pSles);
499     ASSERT_EQ(SL_RESULT_SUCCESS, result);
500 
501     // Enqueue some empty buffers for the recorder
502     for (j = 0; j < pSles->rxBufCount; ++j) {
503 
504         // allocate a free buffer
505         assert(pSles->freeFront != pSles->freeRear);
506         char *buffer = pSles->freeBuffers[pSles->freeFront];
507         if (++pSles->freeFront > pSles->freeBufCount) {
508             pSles->freeFront = 0;
509         }
510 
511         // put on record queue
512         SLuint32 rxRearNext = pSles->rxRear + 1;
513         if (rxRearNext > pSles->rxBufCount) {
514             rxRearNext = 0;
515         }
516         assert(rxRearNext != pSles->rxFront);
517         pSles->rxBuffers[pSles->rxRear] = buffer;
518         pSles->rxRear = rxRearNext;
519         result = (*(pSles->recorderBufferQueue))->Enqueue(pSles->recorderBufferQueue,
520                 buffer, pSles->bufSizeInBytes);
521         ASSERT_EQ(SL_RESULT_SUCCESS, result);
522     }
523 
524     // Kick off the recorder
525     result = (*recorderRecord)->SetRecordState(recorderRecord, SL_RECORDSTATE_RECORDING);
526     ASSERT_EQ(SL_RESULT_SUCCESS, result);
527 
528     // Tear down the objects and exit
529     status = SLES_SUCCESS;
530     cleanup:
531     SLES_PRINTF("Finished initialization with status: %d", status);
532 
533     return status;
534 }
535 
slesProcessNext(sles_data * pSles,double * pSamples,long maxSamples)536 int slesProcessNext(sles_data *pSles, double *pSamples, long maxSamples) {
537     //int status = SLES_FAIL;
538 
539     SLES_PRINTF("slesProcessNext: pSles = %p, currentSample: %p,  maxSamples = %ld", pSles,
540             pSamples, maxSamples);
541 
542     int samplesRead = 0;
543 
544     int currentSample = 0;
545     double *pCurrentSample = pSamples;
546     int maxValue = 32768;
547 
548     if (pSles == NULL) {
549         return samplesRead;
550     }
551 
552     SLresult result;
553     for (int i = 0; i < 10; i++) {
554         usleep(100000);
555         if (pSles->fifo2Buffer != NULL) {
556             for (;;) {
557                 short buffer[pSles->bufSizeInFrames * pSles->channels];
558                 ssize_t actual = audio_utils_fifo_read(&(pSles->fifo2), buffer,
559                         pSles->bufSizeInFrames);
560                 if (actual <= 0)
561                     break;
562                 {
563                     for (int jj =0; jj<actual && currentSample < maxSamples; jj++) {
564                         *(pCurrentSample++) = ((double)buffer[jj])/maxValue;
565                         currentSample++;
566                     }
567                 }
568                 samplesRead +=actual;
569             }
570         }
571         if (pSles->injectImpulse > 0) {
572             if (pSles->injectImpulse <= 100) {
573                 pSles->injectImpulse = -1;
574                 write(1, "I", 1);
575             } else {
576                 if ((pSles->injectImpulse % 1000) < 100) {
577                     write(1, "i", 1);
578                 }
579                 pSles->injectImpulse -= 100;
580             }
581         } else if (i == 9) {
582             write(1, ".", 1);
583         }
584     }
585     SLBufferQueueState playerBQState;
586     result = (*(pSles->playerBufferQueue))->GetState(pSles->playerBufferQueue,
587             &playerBQState);
588     ASSERT_EQ(SL_RESULT_SUCCESS, result);
589     SLAndroidSimpleBufferQueueState recorderBQState;
590     result = (*(pSles->recorderBufferQueue))->GetState(pSles->recorderBufferQueue,
591             &recorderBQState);
592     ASSERT_EQ(SL_RESULT_SUCCESS, result);
593 
594     SLES_PRINTF("End of slesProcessNext: pSles = %p, samplesRead = %d, maxSamples= %ld", pSles,
595             samplesRead, maxSamples);
596 
597     return samplesRead;
598 }
599 
slesDestroyServer(sles_data * pSles)600 int slesDestroyServer(sles_data *pSles) {
601     int status = SLES_FAIL;
602 
603     SLES_PRINTF("Start slesDestroyServer: pSles = %p", pSles);
604     if (pSles == NULL) {
605         return status;
606     }
607 
608     if (NULL != pSles->playerObject) {
609 
610         SLES_PRINTF("stopping player...");
611         SLPlayItf playerPlay;
612         SLresult result = (*(pSles->playerObject))->GetInterface(pSles->playerObject,
613                 SL_IID_PLAY, &playerPlay);
614 
615         ASSERT_EQ(SL_RESULT_SUCCESS, result);
616 
617         //stop player and recorder if they exist
618         result = (*playerPlay)->SetPlayState(playerPlay, SL_PLAYSTATE_STOPPED);
619         ASSERT_EQ(SL_RESULT_SUCCESS, result);
620     }
621 
622     if (NULL != pSles->recorderObject) {
623         SLES_PRINTF("stopping recorder...");
624         SLRecordItf recorderRecord;
625         SLresult result = (*(pSles->recorderObject))->GetInterface(pSles->recorderObject,
626                 SL_IID_RECORD, &recorderRecord);
627         ASSERT_EQ(SL_RESULT_SUCCESS, result);
628 
629         result = (*recorderRecord)->SetRecordState(recorderRecord, SL_RECORDSTATE_STOPPED);
630         ASSERT_EQ(SL_RESULT_SUCCESS, result);
631     }
632 
633     usleep(1000);
634 
635     audio_utils_fifo_deinit(&(pSles->fifo));
636     delete[] pSles->fifoBuffer;
637 
638     SLES_PRINTF("slesDestroyServer 2");
639 
640     //        if (sndfile != NULL) {
641     audio_utils_fifo_deinit(&(pSles->fifo2));
642     delete[] pSles->fifo2Buffer;
643 
644     SLES_PRINTF("slesDestroyServer 3");
645 
646     //            sf_close(sndfile);
647     //        }
648     if (NULL != pSles->playerObject) {
649         (*(pSles->playerObject))->Destroy(pSles->playerObject);
650     }
651 
652     SLES_PRINTF("slesDestroyServer 4");
653 
654     if (NULL != pSles->recorderObject) {
655         (*(pSles->recorderObject))->Destroy(pSles->recorderObject);
656     }
657 
658     SLES_PRINTF("slesDestroyServer 5");
659 
660     (*(pSles->outputmixObject))->Destroy(pSles->outputmixObject);
661     SLES_PRINTF("slesDestroyServer 6");
662     (*(pSles->engineObject))->Destroy(pSles->engineObject);
663     SLES_PRINTF("slesDestroyServer 7");
664 
665     //        free(pSles);
666     //        pSles=NULL;
667 
668     status = SLES_SUCCESS;
669 
670     SLES_PRINTF("End slesDestroyServer: status = %d", status);
671     return status;
672 }
673 
674