blob: 1a51bb0bcd9e3e584025e5b438d741742839f7fc [file] [log] [blame]
/*
* Copyright (C) 2011 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* AAC ADTS Decode Test
First run the program from shell:
# slesTestDecodeAac /sdcard/myFile.adts
Expected output:
OpenSL ES test slesTestDecodeAac: decodes a file containing AAC ADTS data
Player created
Player realized
Enqueueing initial empty buffers to receive decoded PCM data 0 1
Enqueueing initial full buffers of encoded ADTS data 0 1
Starting to decode
Frame counters: encoded=4579 decoded=4579
These use adb on host to retrieve the decoded file:
% adb pull /sdcard/myFile.adts.raw myFile.raw
How to examine the output with Audacity:
Project / Import raw data
Select myFile.raw file, then click Open button
Choose these options:
Signed 16-bit PCM
Little-endian
1 Channel (Mono) / 2 Channels (Stereo) based on the PCM information obtained when decoding
Sample rate based on the PCM information obtained when decoding
Click Import button
*/
#define QUERY_METADATA
#include <assert.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <unistd.h>
#include <sys/time.h>
#include <fcntl.h>
#include <pthread.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <unistd.h>
#include <cpustats/CentralTendencyStatistics.h>
#include <SLES/OpenSLES.h>
#include <SLES/OpenSLES_Android.h>
/* Explicitly requesting SL_IID_ANDROIDBUFFERQUEUE and SL_IID_ANDROIDSIMPLEBUFFERQUEUE
* on the AudioPlayer object for decoding, and
* SL_IID_METADATAEXTRACTION for retrieving the format of the decoded audio.
*/
#define NUM_EXPLICIT_INTERFACES_FOR_PLAYER 4
/* Number of decoded samples produced by one AAC frame; defined by the standard */
#define SAMPLES_PER_AAC_FRAME 1024
/* Size of the encoded AAC ADTS buffer queue */
#define NB_BUFFERS_IN_ADTS_QUEUE 2 // 2 to 4 is typical
/* Size of the decoded PCM buffer queue */
#define NB_BUFFERS_IN_PCM_QUEUE 2 // 2 to 4 is typical
/* Size of each PCM buffer in the queue */
#define BUFFER_SIZE_IN_BYTES (2*sizeof(short)*SAMPLES_PER_AAC_FRAME)
/* Local storage for decoded PCM audio data */
int8_t pcmData[NB_BUFFERS_IN_PCM_QUEUE * BUFFER_SIZE_IN_BYTES];
/* destination for decoded data */
static FILE* outputFp;
#ifdef QUERY_METADATA
/* metadata key index for the PCM format information we want to retrieve */
static int channelCountKeyIndex = -1;
static int sampleRateKeyIndex = -1;
static int bitsPerSampleKeyIndex = -1;
static int containerSizeKeyIndex = -1;
static int channelMaskKeyIndex = -1;
static int endiannessKeyIndex = -1;
/* size of the struct to retrieve the PCM format metadata values: the values we're interested in
* are SLuint32, but it is saved in the data field of a SLMetadataInfo, hence the larger size.
* Note that this size is queried and displayed at l.XXX for demonstration/test purposes.
* */
#define PCM_METADATA_VALUE_SIZE 32
/* used to query metadata values */
static SLMetadataInfo *pcmMetaData = NULL;
/* we only want to query / display the PCM format once */
static bool formatQueried = false;
#endif
/* to signal to the test app that the end of the encoded ADTS stream has been reached */
bool eos = false;
bool endOfEncodedStream = false;
void *ptr;
unsigned char *frame;
size_t filelen;
size_t encodedFrames = 0;
size_t encodedSamples = 0;
size_t decodedFrames = 0;
size_t decodedSamples = 0;
size_t totalEncodeCompletions = 0; // number of Enqueue completions received
CentralTendencyStatistics frameStats;
size_t pauseFrame = 0; // pause after this many decoded frames, zero means don't pause
SLboolean createRaw = SL_BOOLEAN_TRUE; // whether to create a .raw file containing PCM data
/* constant to identify a buffer context which is the end of the stream to decode */
static const int kEosBufferCntxt = 1980; // a magic value we can compare against
/* protects shared variables */
pthread_mutex_t eosLock = PTHREAD_MUTEX_INITIALIZER;
pthread_cond_t eosCondition = PTHREAD_COND_INITIALIZER;
// These are extensions to OpenMAX AL 1.0.1 values
#define PREFETCHSTATUS_UNKNOWN ((SLuint32) 0)
#define PREFETCHSTATUS_ERROR ((SLuint32) (-1))
// Mutex and condition shared with main program to protect prefetch_status
static pthread_mutex_t mutex = PTHREAD_MUTEX_INITIALIZER;
static pthread_cond_t cond = PTHREAD_COND_INITIALIZER;
SLuint32 prefetch_status = PREFETCHSTATUS_UNKNOWN;
/* used to detect errors likely to have occured when the OpenSL ES framework fails to open
* a resource, for instance because a file URI is invalid, or an HTTP server doesn't respond.
*/
#define PREFETCHEVENT_ERROR_CANDIDATE \
(SL_PREFETCHEVENT_STATUSCHANGE | SL_PREFETCHEVENT_FILLLEVELCHANGE)
//-----------------------------------------------------------------
/* Exits the application if an error is encountered */
#define ExitOnError(x) ExitOnErrorFunc(x,__LINE__)
void ExitOnErrorFunc( SLresult result , int line)
{
if (SL_RESULT_SUCCESS != result) {
fprintf(stderr, "Error code %u encountered at line %d, exiting\n", result, line);
exit(EXIT_FAILURE);
}
}
//-----------------------------------------------------------------
/* Callback for "prefetch" events, here used to detect audio resource opening errors */
void PrefetchEventCallback(SLPrefetchStatusItf caller, void *pContext, SLuint32 event)
{
// pContext is unused here, so we pass NULL
assert(pContext == NULL);
SLpermille level = 0;
SLresult result;
result = (*caller)->GetFillLevel(caller, &level);
ExitOnError(result);
SLuint32 status;
result = (*caller)->GetPrefetchStatus(caller, &status);
ExitOnError(result);
printf("prefetch level=%d status=0x%x event=%d\n", level, status, event);
SLuint32 new_prefetch_status;
if ((PREFETCHEVENT_ERROR_CANDIDATE == (event & PREFETCHEVENT_ERROR_CANDIDATE))
&& (level == 0) && (status == SL_PREFETCHSTATUS_UNDERFLOW)) {
printf("PrefetchEventCallback: Error while prefetching data, exiting\n");
new_prefetch_status = PREFETCHSTATUS_ERROR;
} else if (event == SL_PREFETCHEVENT_STATUSCHANGE) {
new_prefetch_status = status;
} else {
return;
}
int ok;
ok = pthread_mutex_lock(&mutex);
assert(ok == 0);
prefetch_status = new_prefetch_status;
ok = pthread_cond_signal(&cond);
assert(ok == 0);
ok = pthread_mutex_unlock(&mutex);
assert(ok == 0);
}
//-----------------------------------------------------------------
/* Structure for passing information to callback function */
typedef struct CallbackCntxt_ {
#ifdef QUERY_METADATA
SLMetadataExtractionItf metaItf;
#endif
SLPlayItf playItf;
SLint8* pDataBase; // Base address of local audio data storage
SLint8* pData; // Current address of local audio data storage
} CallbackCntxt;
// used to notify when SL_PLAYEVENT_HEADATEND event is received
static pthread_mutex_t head_mutex = PTHREAD_MUTEX_INITIALIZER;
static pthread_cond_t head_cond = PTHREAD_COND_INITIALIZER;
static SLboolean head_atend = SL_BOOLEAN_FALSE;
//-----------------------------------------------------------------
/* Callback for SLPlayItf through which we receive the SL_PLAYEVENT_HEADATEND event */
void PlayCallback(SLPlayItf caller, void *pContext, SLuint32 event) {
SLmillisecond position;
SLresult res = (*caller)->GetPosition(caller, &position);
ExitOnError(res);
if (event & SL_PLAYEVENT_HEADATMARKER) {
printf("SL_PLAYEVENT_HEADATMARKER position=%u ms\n", position);
}
if (event & SL_PLAYEVENT_HEADATNEWPOS) {
printf("SL_PLAYEVENT_HEADATNEWPOS position=%u ms\n", position);
}
if (event & SL_PLAYEVENT_HEADATEND) {
printf("SL_PLAYEVENT_HEADATEND position=%u ms, all decoded data has been received\n",
position);
pthread_mutex_lock(&head_mutex);
head_atend = SL_BOOLEAN_TRUE;
pthread_cond_signal(&head_cond);
pthread_mutex_unlock(&head_mutex);
}
}
//-----------------------------------------------------------------
/* Callback for AndroidBufferQueueItf through which we supply ADTS buffers */
SLresult AndroidBufferQueueCallback(
SLAndroidBufferQueueItf caller,
void *pCallbackContext, /* input */
void *pBufferContext, /* input */
void *pBufferData, /* input */
SLuint32 dataSize, /* input */
SLuint32 dataUsed, /* input */
const SLAndroidBufferItem *pItems,/* input */
SLuint32 itemsLength /* input */)
{
// mutex on all global variables
pthread_mutex_lock(&eosLock);
SLresult res;
// for demonstration purposes:
// verify what type of information was enclosed in the processed buffer
if (NULL != pBufferContext) {
if (&kEosBufferCntxt == pBufferContext) {
fprintf(stdout, "EOS was processed\n");
}
}
++totalEncodeCompletions;
if (endOfEncodedStream) {
// we continue to receive acknowledgement after each buffer was processed
if (pBufferContext == (void *) &kEosBufferCntxt) {
printf("Received EOS completion after EOS\n");
} else if (pBufferContext == NULL) {
printf("Received ADTS completion after EOS\n");
} else {
fprintf(stderr, "Received acknowledgement after EOS with unexpected context %p\n",
pBufferContext);
}
} else if (filelen == 0) {
// signal EOS to the decoder rather than just starving it
printf("Enqueue EOS: encoded frames=%u, decoded frames=%u\n", encodedFrames, decodedFrames);
printf("You should now see %u ADTS completion%s followed by 1 EOS completion\n",
NB_BUFFERS_IN_ADTS_QUEUE - 1, NB_BUFFERS_IN_ADTS_QUEUE != 2 ? "s" : "");
SLAndroidBufferItem msgEos;
msgEos.itemKey = SL_ANDROID_ITEMKEY_EOS;
msgEos.itemSize = 0;
// EOS message has no parameters, so the total size of the message is the size of the key
// plus the size of itemSize, both SLuint32
res = (*caller)->Enqueue(caller, (void *)&kEosBufferCntxt /*pBufferContext*/,
NULL /*pData*/, 0 /*dataLength*/,
&msgEos /*pMsg*/,
sizeof(SLuint32)*2 /*msgLength*/);
ExitOnError(res);
endOfEncodedStream = true;
// verify that we are at start of an ADTS frame
} else if (!(filelen < 7 || frame[0] != 0xFF || (frame[1] & 0xF0) != 0xF0)) {
if (pBufferContext != NULL) {
fprintf(stderr, "Received acknowledgement before EOS with unexpected context %p\n",
pBufferContext);
}
unsigned framelen = ((frame[3] & 3) << 11) | (frame[4] << 3) | (frame[5] >> 5);
if (framelen <= filelen) {
// push more data to the queue
res = (*caller)->Enqueue(caller, NULL /*pBufferContext*/,
frame, framelen, NULL, 0);
ExitOnError(res);
frame += framelen;
filelen -= framelen;
++encodedFrames;
encodedSamples += SAMPLES_PER_AAC_FRAME;
frameStats.sample(framelen);
} else {
fprintf(stderr,
"partial ADTS frame at EOF discarded; offset=%u, framelen=%u, filelen=%u\n",
frame - (unsigned char *) ptr, framelen, filelen);
frame += filelen;
filelen = 0;
}
} else {
fprintf(stderr, "corrupt ADTS frame encountered; offset=%u, filelen=%u\n",
frame - (unsigned char *) ptr, filelen);
frame += filelen;
filelen = 0;
}
pthread_mutex_unlock(&eosLock);
return SL_RESULT_SUCCESS;
}
//-----------------------------------------------------------------
/* Callback for decoding buffer queue events */
void DecPlayCallback(
SLAndroidSimpleBufferQueueItf queueItf,
void *pContext)
{
// mutex on all global variables
pthread_mutex_lock(&eosLock);
CallbackCntxt *pCntxt = (CallbackCntxt*)pContext;
/* Save the decoded data to output file */
if (outputFp != NULL && fwrite(pCntxt->pData, 1, BUFFER_SIZE_IN_BYTES, outputFp)
< BUFFER_SIZE_IN_BYTES) {
fprintf(stderr, "Error writing to output file");
}
/* Re-enqueue the now empty buffer */
SLresult res;
res = (*queueItf)->Enqueue(queueItf, pCntxt->pData, BUFFER_SIZE_IN_BYTES);
ExitOnError(res);
/* Increase data pointer by buffer size, with circular wraparound */
pCntxt->pData += BUFFER_SIZE_IN_BYTES;
if (pCntxt->pData >= pCntxt->pDataBase + (NB_BUFFERS_IN_PCM_QUEUE * BUFFER_SIZE_IN_BYTES)) {
pCntxt->pData = pCntxt->pDataBase;
}
// Note: adding a sleep here or any sync point is a way to slow down the decoding, or
// synchronize it with some other event, as the OpenSL ES framework will block until the
// buffer queue callback return to proceed with the decoding.
#ifdef QUERY_METADATA
/* Example: query of the decoded PCM format */
if (!formatQueried) {
/* memory to receive the PCM format metadata */
union {
SLMetadataInfo pcmMetaData;
char withData[PCM_METADATA_VALUE_SIZE];
} u;
res = (*pCntxt->metaItf)->GetValue(pCntxt->metaItf, sampleRateKeyIndex,
PCM_METADATA_VALUE_SIZE, &u.pcmMetaData); ExitOnError(res);
// Note: here we could verify the following:
// u.pcmMetaData->encoding == SL_CHARACTERENCODING_BINARY
// u.pcmMetaData->size == sizeof(SLuint32)
// but the call was successful for the PCM format keys, so those conditions are implied
printf("sample rate = %d\n", *((SLuint32*)u.pcmMetaData.data));
res = (*pCntxt->metaItf)->GetValue(pCntxt->metaItf, channelCountKeyIndex,
PCM_METADATA_VALUE_SIZE, &u.pcmMetaData); ExitOnError(res);
printf("channel count = %d\n", *((SLuint32*)u.pcmMetaData.data));
res = (*pCntxt->metaItf)->GetValue(pCntxt->metaItf, bitsPerSampleKeyIndex,
PCM_METADATA_VALUE_SIZE, &u.pcmMetaData); ExitOnError(res);
printf("bits per sample = %d bits\n", *((SLuint32*)u.pcmMetaData.data));
res = (*pCntxt->metaItf)->GetValue(pCntxt->metaItf, containerSizeKeyIndex,
PCM_METADATA_VALUE_SIZE, &u.pcmMetaData); ExitOnError(res);
printf("container size = %d bits\n", *((SLuint32*)u.pcmMetaData.data));
res = (*pCntxt->metaItf)->GetValue(pCntxt->metaItf, channelMaskKeyIndex,
PCM_METADATA_VALUE_SIZE, &u.pcmMetaData); ExitOnError(res);
printf("channel mask = 0x%X (0x3=front left | front right, 0x4=front center)\n",
*((SLuint32*)u.pcmMetaData.data));
res = (*pCntxt->metaItf)->GetValue(pCntxt->metaItf, endiannessKeyIndex,
PCM_METADATA_VALUE_SIZE, &u.pcmMetaData); ExitOnError(res);
printf("endianness = %d (1=big, 2=little)\n", *((SLuint32*)u.pcmMetaData.data));
formatQueried = true;
}
#endif
++decodedFrames;
decodedSamples += SAMPLES_PER_AAC_FRAME;
/* Periodically ask for position and duration */
if ((decodedFrames % 1000 == 0) || endOfEncodedStream) {
SLmillisecond position;
res = (*pCntxt->playItf)->GetPosition(pCntxt->playItf, &position);
ExitOnError(res);
SLmillisecond duration;
res = (*pCntxt->playItf)->GetDuration(pCntxt->playItf, &duration);
ExitOnError(res);
if (duration == SL_TIME_UNKNOWN) {
printf("After %u encoded %u decoded frames: position is %u ms, duration is "
"unknown as expected\n",
encodedFrames, decodedFrames, position);
} else {
printf("After %u encoded %u decoded frames: position is %u ms, duration is "
"surprisingly %u ms\n",
encodedFrames, decodedFrames, position, duration);
}
}
if (endOfEncodedStream && decodedSamples >= encodedSamples) {
eos = true;
pthread_cond_signal(&eosCondition);
}
pthread_mutex_unlock(&eosLock);
}
//-----------------------------------------------------------------
/* Decode an audio path by opening a file descriptor on that path */
void TestDecToBuffQueue( SLObjectItf sl, const char *path, int fd)
{
// check what kind of object it is
int ok;
struct stat statbuf;
ok = fstat(fd, &statbuf);
if (ok < 0) {
perror(path);
return;
}
// verify that's it is a file
if (!S_ISREG(statbuf.st_mode)) {
fprintf(stderr, "%s: not an ordinary file\n", path);
return;
}
// map file contents into memory to make it easier to access the ADTS frames directly
ptr = mmap(NULL, statbuf.st_size, PROT_READ, MAP_FILE | MAP_PRIVATE, fd, (off_t) 0);
if (ptr == MAP_FAILED) {
perror(path);
return;
}
frame = (unsigned char *) ptr;
filelen = statbuf.st_size;
// create PCM .raw file
if (createRaw) {
size_t len = strlen((const char *) path);
char* outputPath = (char*) malloc(len + 4 + 1); // save room to concatenate ".raw"
if (NULL == outputPath) {
ExitOnError(SL_RESULT_RESOURCE_ERROR);
}
memcpy(outputPath, path, len + 1);
strcat(outputPath, ".raw");
outputFp = fopen(outputPath, "w");
if (NULL == outputFp) {
// issue an error message, but continue the decoding anyway
perror(outputPath);
}
} else {
outputFp = NULL;
}
SLresult res;
SLEngineItf EngineItf;
/* Objects this application uses: one audio player */
SLObjectItf player;
/* Interfaces for the audio player */
SLPlayItf playItf;
#ifdef QUERY_METADATA
/* to retrieve the decoded PCM format */
SLMetadataExtractionItf mdExtrItf;
#endif
/* to retrieve the PCM samples */
SLAndroidSimpleBufferQueueItf decBuffQueueItf;
/* to queue the AAC data to decode */
SLAndroidBufferQueueItf aacBuffQueueItf;
/* for prefetch status */
SLPrefetchStatusItf prefetchItf;
SLboolean required[NUM_EXPLICIT_INTERFACES_FOR_PLAYER];
SLInterfaceID iidArray[NUM_EXPLICIT_INTERFACES_FOR_PLAYER];
/* Get the SL Engine Interface which is implicit */
res = (*sl)->GetInterface(sl, SL_IID_ENGINE, (void*)&EngineItf);
ExitOnError(res);
/* Initialize arrays required[] and iidArray[] */
unsigned int i;
for (i=0 ; i < NUM_EXPLICIT_INTERFACES_FOR_PLAYER ; i++) {
required[i] = SL_BOOLEAN_FALSE;
iidArray[i] = SL_IID_NULL;
}
/* ------------------------------------------------------ */
/* Configuration of the player */
/* Request the AndroidSimpleBufferQueue interface */
required[0] = SL_BOOLEAN_TRUE;
iidArray[0] = SL_IID_ANDROIDSIMPLEBUFFERQUEUE;
/* Request the AndroidBufferQueue interface */
required[1] = SL_BOOLEAN_TRUE;
iidArray[1] = SL_IID_ANDROIDBUFFERQUEUESOURCE;
/* Request the PrefetchStatus interface */
required[2] = SL_BOOLEAN_TRUE;
iidArray[2] = SL_IID_PREFETCHSTATUS;
#ifdef QUERY_METADATA
/* Request the MetadataExtraction interface */
required[3] = SL_BOOLEAN_TRUE;
iidArray[3] = SL_IID_METADATAEXTRACTION;
#endif
/* Setup the data source for queueing AAC buffers of ADTS data */
SLDataLocator_AndroidBufferQueue loc_srcAbq = {
SL_DATALOCATOR_ANDROIDBUFFERQUEUE /*locatorType*/,
NB_BUFFERS_IN_ADTS_QUEUE /*numBuffers*/};
SLDataFormat_MIME format_srcMime = {
SL_DATAFORMAT_MIME /*formatType*/,
SL_ANDROID_MIME_AACADTS /*mimeType*/,
SL_CONTAINERTYPE_RAW /*containerType*/};
SLDataSource decSource = {&loc_srcAbq /*pLocator*/, &format_srcMime /*pFormat*/};
/* Setup the data sink, a buffer queue for buffers of PCM data */
SLDataLocator_AndroidSimpleBufferQueue loc_destBq = {
SL_DATALOCATOR_ANDROIDSIMPLEBUFFERQUEUE/*locatorType*/,
NB_BUFFERS_IN_PCM_QUEUE /*numBuffers*/ };
/* declare we're decoding to PCM, the parameters after that need to be valid,
but are ignored, the decoded format will match the source */
SLDataFormat_PCM format_destPcm = { /*formatType*/ SL_DATAFORMAT_PCM, /*numChannels*/ 1,
/*samplesPerSec*/ SL_SAMPLINGRATE_8, /*pcm.bitsPerSample*/ SL_PCMSAMPLEFORMAT_FIXED_16,
/*/containerSize*/ 16, /*channelMask*/ SL_SPEAKER_FRONT_LEFT,
/*endianness*/ SL_BYTEORDER_LITTLEENDIAN };
SLDataSink decDest = {&loc_destBq /*pLocator*/, &format_destPcm /*pFormat*/};
/* Create the audio player */
res = (*EngineItf)->CreateAudioPlayer(EngineItf, &player, &decSource, &decDest,
#ifdef QUERY_METADATA
NUM_EXPLICIT_INTERFACES_FOR_PLAYER,
#else
NUM_EXPLICIT_INTERFACES_FOR_PLAYER - 1,
#endif
iidArray, required);
ExitOnError(res);
printf("Player created\n");
/* Realize the player in synchronous mode. */
res = (*player)->Realize(player, SL_BOOLEAN_FALSE);
ExitOnError(res);
printf("Player realized\n");
/* Get the play interface which is implicit */
res = (*player)->GetInterface(player, SL_IID_PLAY, (void*)&playItf);
ExitOnError(res);
/* Enable callback when position passes through a marker (SL_PLAYEVENT_HEADATMARKER) */
res = (*playItf)->SetMarkerPosition(playItf, 5000);
ExitOnError(res);
/* Enable callback for periodic position updates (SL_PLAYEVENT_HEADATNEWPOS) */
res = (*playItf)->SetPositionUpdatePeriod(playItf, 3000);
ExitOnError(res);
/* Use the play interface to set up a callback for the SL_PLAYEVENT_HEAD* events */
res = (*playItf)->SetCallbackEventsMask(playItf,
SL_PLAYEVENT_HEADATMARKER | SL_PLAYEVENT_HEADATNEWPOS | SL_PLAYEVENT_HEADATEND);
ExitOnError(res);
res = (*playItf)->RegisterCallback(playItf, PlayCallback /*callback*/, NULL /*pContext*/);
ExitOnError(res);
/* Get the position before prefetch; should be zero */
SLmillisecond position;
res = (*playItf)->GetPosition(playItf, &position);
ExitOnError(res);
if (position == 0) {
printf("The position before prefetch is zero as expected\n");
} else if (position == SL_TIME_UNKNOWN) {
printf("That's surprising the position before prefetch is unknown");
} else {
printf("That's surprising the position before prefetch is %u ms\n", position);
}
/* Get the duration before prefetch; should be unknown */
SLmillisecond duration;
res = (*playItf)->GetDuration(playItf, &duration);
ExitOnError(res);
if (duration == SL_TIME_UNKNOWN) {
printf("The duration before prefetch is unknown as expected\n");
} else {
printf("That's surprising the duration before prefetch is %u ms\n", duration);
}
/* Get the buffer queue interface which was explicitly requested */
res = (*player)->GetInterface(player, SL_IID_ANDROIDSIMPLEBUFFERQUEUE, (void*)&decBuffQueueItf);
ExitOnError(res);
/* Get the Android buffer queue interface which was explicitly requested */
res = (*player)->GetInterface(player, SL_IID_ANDROIDBUFFERQUEUESOURCE, (void*)&aacBuffQueueItf);
ExitOnError(res);
/* Get the prefetch status interface which was explicitly requested */
res = (*player)->GetInterface(player, SL_IID_PREFETCHSTATUS, (void*)&prefetchItf);
ExitOnError(res);
#ifdef QUERY_METADATA
/* Get the metadata extraction interface which was explicitly requested */
res = (*player)->GetInterface(player, SL_IID_METADATAEXTRACTION, (void*)&mdExtrItf);
ExitOnError(res);
#endif
/* ------------------------------------------------------ */
/* Initialize the callback and its context for the buffer queue of the decoded PCM */
CallbackCntxt sinkCntxt;
sinkCntxt.playItf = playItf;
#ifdef QUERY_METADATA
sinkCntxt.metaItf = mdExtrItf;
#endif
sinkCntxt.pDataBase = (int8_t*)&pcmData;
sinkCntxt.pData = sinkCntxt.pDataBase;
res = (*decBuffQueueItf)->RegisterCallback(decBuffQueueItf, DecPlayCallback, &sinkCntxt);
ExitOnError(res);
/* Enqueue buffers to map the region of memory allocated to store the decoded data */
printf("Enqueueing initial empty buffers to receive decoded PCM data");
for(i = 0 ; i < NB_BUFFERS_IN_PCM_QUEUE ; i++) {
printf(" %d", i);
res = (*decBuffQueueItf)->Enqueue(decBuffQueueItf, sinkCntxt.pData, BUFFER_SIZE_IN_BYTES);
ExitOnError(res);
sinkCntxt.pData += BUFFER_SIZE_IN_BYTES;
if (sinkCntxt.pData >= sinkCntxt.pDataBase +
(NB_BUFFERS_IN_PCM_QUEUE * BUFFER_SIZE_IN_BYTES)) {
sinkCntxt.pData = sinkCntxt.pDataBase;
}
}
printf("\n");
/* ------------------------------------------------------ */
/* Initialize the callback for prefetch errors, if we can't open the resource to decode */
res = (*prefetchItf)->RegisterCallback(prefetchItf, PrefetchEventCallback, NULL);
ExitOnError(res);
res = (*prefetchItf)->SetCallbackEventsMask(prefetchItf, PREFETCHEVENT_ERROR_CANDIDATE);
ExitOnError(res);
/* Initialize the callback for the Android buffer queue of the encoded data */
res = (*aacBuffQueueItf)->RegisterCallback(aacBuffQueueItf, AndroidBufferQueueCallback, NULL);
ExitOnError(res);
/* Enqueue the content of our encoded data before starting to play,
we don't want to starve the player initially */
printf("Enqueueing initial full buffers of encoded ADTS data");
for (i=0 ; i < NB_BUFFERS_IN_ADTS_QUEUE ; i++) {
if (filelen < 7 || frame[0] != 0xFF || (frame[1] & 0xF0) != 0xF0) {
printf("\ncorrupt ADTS frame encountered; offset %zu bytes\n",
frame - (unsigned char *) ptr);
// Note that prefetch will detect this error soon when it gets a premature EOF
break;
}
unsigned framelen = ((frame[3] & 3) << 11) | (frame[4] << 3) | (frame[5] >> 5);
printf(" %d (%u bytes)", i, framelen);
res = (*aacBuffQueueItf)->Enqueue(aacBuffQueueItf, NULL /*pBufferContext*/,
frame, framelen, NULL, 0);
ExitOnError(res);
frame += framelen;
filelen -= framelen;
++encodedFrames;
encodedSamples += SAMPLES_PER_AAC_FRAME;
frameStats.sample(framelen);
}
printf("\n");
#ifdef QUERY_METADATA
/* ------------------------------------------------------ */
/* Get and display the metadata key names for the decoder */
// This is for test / demonstration purposes only where we discover the key and value sizes
// of a PCM decoder. An application that would want to directly get access to those values
// can make assumptions about the size of the keys and their matching values (all SLuint32),
// but it should not make assumptions about the key indices as these are subject to change.
// Note that we don't get the metadata values yet; that happens in the first decode callback.
SLuint32 itemCount;
res = (*mdExtrItf)->GetItemCount(mdExtrItf, &itemCount);
ExitOnError(res);
printf("itemCount=%u\n", itemCount);
SLuint32 keySize, valueSize;
SLMetadataInfo *keyInfo, *value;
for(i=0 ; i<itemCount ; i++) {
keyInfo = NULL; keySize = 0;
value = NULL; valueSize = 0;
res = (*mdExtrItf)->GetKeySize(mdExtrItf, i, &keySize);
ExitOnError(res);
res = (*mdExtrItf)->GetValueSize(mdExtrItf, i, &valueSize);
ExitOnError(res);
keyInfo = (SLMetadataInfo*) malloc(keySize);
if (NULL != keyInfo) {
res = (*mdExtrItf)->GetKey(mdExtrItf, i, keySize, keyInfo);
ExitOnError(res);
printf("key[%d] size=%d, name=%s \tvalue size=%d encoding=0x%X langCountry=%s\n",
i, keyInfo->size, keyInfo->data, valueSize, keyInfo->encoding,
keyInfo->langCountry);
/* find out the key index of the metadata we're interested in */
if (!strcmp((char*)keyInfo->data, ANDROID_KEY_PCMFORMAT_NUMCHANNELS)) {
channelCountKeyIndex = i;
} else if (!strcmp((char*)keyInfo->data, ANDROID_KEY_PCMFORMAT_SAMPLERATE)) {
sampleRateKeyIndex = i;
} else if (!strcmp((char*)keyInfo->data, ANDROID_KEY_PCMFORMAT_BITSPERSAMPLE)) {
bitsPerSampleKeyIndex = i;
} else if (!strcmp((char*)keyInfo->data, ANDROID_KEY_PCMFORMAT_CONTAINERSIZE)) {
containerSizeKeyIndex = i;
} else if (!strcmp((char*)keyInfo->data, ANDROID_KEY_PCMFORMAT_CHANNELMASK)) {
channelMaskKeyIndex = i;
} else if (!strcmp((char*)keyInfo->data, ANDROID_KEY_PCMFORMAT_ENDIANNESS)) {
endiannessKeyIndex = i;
} else {
printf("Unknown key %s ignored\n", (char *)keyInfo->data);
}
free(keyInfo);
}
}
if (channelCountKeyIndex != -1) {
printf("Key %s is at index %d\n",
ANDROID_KEY_PCMFORMAT_NUMCHANNELS, channelCountKeyIndex);
} else {
fprintf(stderr, "Unable to find key %s\n", ANDROID_KEY_PCMFORMAT_NUMCHANNELS);
}
if (sampleRateKeyIndex != -1) {
printf("Key %s is at index %d\n",
ANDROID_KEY_PCMFORMAT_SAMPLERATE, sampleRateKeyIndex);
} else {
fprintf(stderr, "Unable to find key %s\n", ANDROID_KEY_PCMFORMAT_SAMPLERATE);
}
if (bitsPerSampleKeyIndex != -1) {
printf("Key %s is at index %d\n",
ANDROID_KEY_PCMFORMAT_BITSPERSAMPLE, bitsPerSampleKeyIndex);
} else {
fprintf(stderr, "Unable to find key %s\n", ANDROID_KEY_PCMFORMAT_BITSPERSAMPLE);
}
if (containerSizeKeyIndex != -1) {
printf("Key %s is at index %d\n",
ANDROID_KEY_PCMFORMAT_CONTAINERSIZE, containerSizeKeyIndex);
} else {
fprintf(stderr, "Unable to find key %s\n", ANDROID_KEY_PCMFORMAT_CONTAINERSIZE);
}
if (channelMaskKeyIndex != -1) {
printf("Key %s is at index %d\n",
ANDROID_KEY_PCMFORMAT_CHANNELMASK, channelMaskKeyIndex);
} else {
fprintf(stderr, "Unable to find key %s\n", ANDROID_KEY_PCMFORMAT_CHANNELMASK);
}
if (endiannessKeyIndex != -1) {
printf("Key %s is at index %d\n",
ANDROID_KEY_PCMFORMAT_ENDIANNESS, endiannessKeyIndex);
} else {
fprintf(stderr, "Unable to find key %s\n", ANDROID_KEY_PCMFORMAT_ENDIANNESS);
}
#endif
// set the player's state to paused, to start prefetching
printf("Setting play state to PAUSED\n");
res = (*playItf)->SetPlayState(playItf, SL_PLAYSTATE_PAUSED);
ExitOnError(res);
// wait for prefetch status callback to indicate either sufficient data or error
printf("Awaiting prefetch complete\n");
pthread_mutex_lock(&mutex);
while (prefetch_status == PREFETCHSTATUS_UNKNOWN) {
pthread_cond_wait(&cond, &mutex);
}
pthread_mutex_unlock(&mutex);
if (prefetch_status == PREFETCHSTATUS_ERROR) {
fprintf(stderr, "Error during prefetch, exiting\n");
goto destroyRes;
}
printf("Prefetch is complete\n");
/* ------------------------------------------------------ */
/* Start decoding */
printf("Starting to decode\n");
res = (*playItf)->SetPlayState(playItf, SL_PLAYSTATE_PLAYING);
ExitOnError(res);
/* Decode until the end of the stream is reached */
printf("Awaiting notification that all encoded buffers have been enqueued\n");
pthread_mutex_lock(&eosLock);
while (!eos) {
if (pauseFrame > 0) {
if (decodedFrames >= pauseFrame) {
pauseFrame = 0;
printf("Pausing after decoded frame %u for 10 seconds\n", decodedFrames);
pthread_mutex_unlock(&eosLock);
res = (*playItf)->SetPlayState(playItf, SL_PLAYSTATE_PAUSED);
ExitOnError(res);
sleep(10);
printf("Resuming\n");
res = (*playItf)->SetPlayState(playItf, SL_PLAYSTATE_PLAYING);
ExitOnError(res);
pthread_mutex_lock(&eosLock);
} else {
pthread_mutex_unlock(&eosLock);
usleep(10*1000);
pthread_mutex_lock(&eosLock);
}
} else {
pthread_cond_wait(&eosCondition, &eosLock);
}
}
pthread_mutex_unlock(&eosLock);
printf("All encoded buffers have now been enqueued, but there's still more to do\n");
/* This just means done enqueueing; there may still more data in decode queue! */
pthread_mutex_lock(&head_mutex);
while (!head_atend) {
pthread_cond_wait(&head_cond, &head_mutex);
}
pthread_mutex_unlock(&head_mutex);
printf("Decode is now finished\n");
pthread_mutex_lock(&eosLock);
printf("Frame counters: encoded=%u decoded=%u\n", encodedFrames, decodedFrames);
printf("Sample counters: encoded=%u decoded=%u\n", encodedSamples, decodedSamples);
printf("Total encode completions received: actual=%u, expected=%u\n",
totalEncodeCompletions, encodedFrames+1/*EOS*/);
pthread_mutex_unlock(&eosLock);
/* Get the final position and duration */
res = (*playItf)->GetPosition(playItf, &position);
ExitOnError(res);
res = (*playItf)->GetDuration(playItf, &duration);
ExitOnError(res);
if (duration == SL_TIME_UNKNOWN) {
printf("The final position is %u ms, duration is unknown\n", position);
} else {
printf("The final position is %u ms, duration is %u ms\n", position, duration);
}
printf("Frame length statistics:\n");
printf(" n = %u frames\n", frameStats.n());
printf(" mean = %.1f bytes\n", frameStats.mean());
printf(" minimum = %.1f bytes\n", frameStats.minimum());
printf(" maximum = %.1f bytes\n", frameStats.maximum());
printf(" stddev = %.1f bytes\n", frameStats.stddev());
/* ------------------------------------------------------ */
/* End of decoding */
destroyRes:
/* Destroy the AudioPlayer object */
(*player)->Destroy(player);
if (outputFp != NULL) {
fclose(outputFp);
}
// unmap the ADTS AAC file from memory
ok = munmap(ptr, statbuf.st_size);
if (0 != ok) {
perror(path);
}
}
//-----------------------------------------------------------------
int main(int argc, char* const argv[])
{
SLresult res;
SLObjectItf sl;
printf("OpenSL ES test %s: decodes a file containing AAC ADTS data\n", argv[0]);
if (argc != 2) {
printf("Usage: \t%s source_file\n", argv[0]);
printf("Example: \"%s /sdcard/myFile.adts\n", argv[0]);
exit(EXIT_FAILURE);
}
// open pathname of encoded ADTS AAC file to get a file descriptor
int fd;
fd = open(argv[1], O_RDONLY);
if (fd < 0) {
perror(argv[1]);
return EXIT_FAILURE;
}
SLEngineOption EngineOption[] = {
{(SLuint32) SL_ENGINEOPTION_THREADSAFE, (SLuint32) SL_BOOLEAN_TRUE}
};
res = slCreateEngine( &sl, 1, EngineOption, 0, NULL, NULL);
ExitOnError(res);
/* Realizing the SL Engine in synchronous mode. */
res = (*sl)->Realize(sl, SL_BOOLEAN_FALSE);
ExitOnError(res);
TestDecToBuffQueue(sl, argv[1], fd);
/* Shutdown OpenSL ES */
(*sl)->Destroy(sl);
// close the file
(void) close(fd);
return EXIT_SUCCESS;
}