tests/sandbox/configbq.c - platform/frameworks/wilhelm - Git at Google

 /*
  * Copyright (C) 2010 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.
  */

 // Test various buffer queue configurations

 #include <assert.h>
 #include <math.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <unistd.h>

 #include <SLES/OpenSLES.h>

 typedef struct {
     SLuint8 numChannels;
     SLuint32 milliHz;
     SLuint8 bitsPerSample;
 } PCM;

 PCM formats[] = {
     {1, SL_SAMPLINGRATE_8,      8},
     {2, SL_SAMPLINGRATE_8,      8},
     {1, SL_SAMPLINGRATE_8,      16},
     {2, SL_SAMPLINGRATE_8,      16},
     {1, SL_SAMPLINGRATE_11_025, 8},
     {2, SL_SAMPLINGRATE_11_025, 8},
     {1, SL_SAMPLINGRATE_11_025, 16},
     {2, SL_SAMPLINGRATE_11_025, 16},
     {1, SL_SAMPLINGRATE_12,     8},
     {2, SL_SAMPLINGRATE_12,     8},
     {1, SL_SAMPLINGRATE_12,     16},
     {2, SL_SAMPLINGRATE_12,     16},
     {1, SL_SAMPLINGRATE_16,     8},
     {2, SL_SAMPLINGRATE_16,     8},
     {1, SL_SAMPLINGRATE_16,     16},
     {2, SL_SAMPLINGRATE_16,     16},
     {1, SL_SAMPLINGRATE_22_05,  8},
     {2, SL_SAMPLINGRATE_22_05,  8},
     {1, SL_SAMPLINGRATE_22_05,  16},
     {2, SL_SAMPLINGRATE_22_05,  16},
     {1, SL_SAMPLINGRATE_24,     8},
     {2, SL_SAMPLINGRATE_24,     8},
     {1, SL_SAMPLINGRATE_24,     16},
     {2, SL_SAMPLINGRATE_24,     16},
     {1, SL_SAMPLINGRATE_32,     8},
     {2, SL_SAMPLINGRATE_32,     8},
     {1, SL_SAMPLINGRATE_32,     16},
     {2, SL_SAMPLINGRATE_32,     16},
     {1, SL_SAMPLINGRATE_44_1,   8},
     {2, SL_SAMPLINGRATE_44_1,   8},
     {1, SL_SAMPLINGRATE_44_1,   16},
     {2, SL_SAMPLINGRATE_44_1,   16},
     {1, SL_SAMPLINGRATE_48,     8},
     {2, SL_SAMPLINGRATE_48,     8},
     {1, SL_SAMPLINGRATE_48,     16},
     {2, SL_SAMPLINGRATE_48,     16},
     {0, 0,                      0}
 };

 int main(int argc __unused, char **argv __unused)
 {
     SLresult result;
     SLObjectItf engineObject;

     // create engine
     result = slCreateEngine(&engineObject, 0, NULL, 0, NULL, NULL);
     assert(SL_RESULT_SUCCESS == result);
     SLEngineItf engineEngine;
     result = (*engineObject)->Realize(engineObject, SL_BOOLEAN_FALSE);
     assert(SL_RESULT_SUCCESS == result);
     result = (*engineObject)->GetInterface(engineObject, SL_IID_ENGINE, &engineEngine);
     assert(SL_RESULT_SUCCESS == result);

     // create output mix
     SLObjectItf outputMixObject;
     result = (*engineEngine)->CreateOutputMix(engineEngine, &outputMixObject, 0, NULL, NULL);
     assert(SL_RESULT_SUCCESS == result);
     result = (*outputMixObject)->Realize(outputMixObject, SL_BOOLEAN_FALSE);
     assert(SL_RESULT_SUCCESS == result);

     // loop over all formats
     PCM *format;
     float hzLeft = 440.0;   // A440 (Concert A)
     float hzRight = 440.0;
     for (format = formats; format->numChannels; ++format) {

         printf("Channels: %d, sample rate: %u, bits: %u\n", format->numChannels,
                 format->milliHz / 1000, format->bitsPerSample);

         // configure audio source
         SLDataLocator_BufferQueue loc_bufq;
         loc_bufq.locatorType = SL_DATALOCATOR_BUFFERQUEUE;
         loc_bufq.numBuffers = 1;
         SLDataFormat_PCM format_pcm;
         format_pcm.formatType = SL_DATAFORMAT_PCM;
         format_pcm.numChannels = format->numChannels;
         format_pcm.samplesPerSec = format->milliHz;
         format_pcm.bitsPerSample = format->bitsPerSample;
         format_pcm.containerSize = format->bitsPerSample;
         format_pcm.channelMask = 0;
         format_pcm.endianness = SL_BYTEORDER_LITTLEENDIAN;
         SLDataSource audioSrc;
         audioSrc.pLocator = &loc_bufq;
         audioSrc.pFormat = &format_pcm;

         // configure audio sink
         SLDataLocator_OutputMix loc_outmix;
         loc_outmix.locatorType = SL_DATALOCATOR_OUTPUTMIX;
         loc_outmix.outputMix = outputMixObject;
         SLDataSink audioSnk;
         audioSnk.pLocator = &loc_outmix;
         audioSnk.pFormat = NULL;

         // create audio player
         SLuint32 numInterfaces = 1;
         SLInterfaceID ids[1];
         SLboolean req[1];
         ids[0] = SL_IID_BUFFERQUEUE;
         req[0] = SL_BOOLEAN_TRUE;
         SLObjectItf playerObject;
         result = (*engineEngine)->CreateAudioPlayer(engineEngine, &playerObject, &audioSrc,
                 &audioSnk, numInterfaces, ids, req);
         if (SL_RESULT_SUCCESS != result) {
             printf("failed %u\n", result);
             continue;
         }

         // realize the player
         result = (*playerObject)->Realize(playerObject, SL_BOOLEAN_FALSE);
         assert(SL_RESULT_SUCCESS == result);

         // generate a sine wave buffer, ascending in half-steps for each format
 #define N (44100*4)
         static unsigned char buffer[N];
         unsigned i;
         for (i = 0; i < N; ) {
             float seconds = (((i * 8) / (format->bitsPerSample * format->numChannels)) * 1000.0) /
                     format->milliHz;
             short sampleLeft = sin(seconds * M_PI_2 * hzLeft) * 32767.0;
             short sampleRight = sin(seconds * M_PI_2 * hzRight) * 32767.0;
             if (2 == format->numChannels) {
                 if (8 == format->bitsPerSample) {
                     buffer[i++] = (sampleLeft + 32768) >> 8;
                     buffer[i++] = (sampleRight + 32768) >> 8;
                 } else {
                     assert(16 == format->bitsPerSample);
                     buffer[i++] = sampleLeft & 0xFF;
                     buffer[i++] = sampleLeft >> 8;
                     buffer[i++] = sampleRight & 0xFF;
                     buffer[i++] = sampleRight >> 8;
                 }
             } else {
                 assert(1 == format->numChannels);
                 // cast to int and divide by 2 are needed to prevent overflow
                 short sampleMono = ((int) sampleLeft + (int) sampleRight) / 2;
                 if (8 == format->bitsPerSample) {
                     buffer[i++] = (sampleMono + 32768) >> 8;
                 } else {
                     assert(16 == format->bitsPerSample);
                     buffer[i++] = sampleMono & 0xFF;
                     buffer[i++] = sampleMono >> 8;
                 }
             }
             if (seconds >= 1.0f)
                 break;
         }

         // get the buffer queue interface and enqueue a buffer
         SLBufferQueueItf playerBufferQueue;
         result = (*playerObject)->GetInterface(playerObject, SL_IID_BUFFERQUEUE,
                 &playerBufferQueue);
         assert(SL_RESULT_SUCCESS == result);
         result = (*playerBufferQueue)->Enqueue(playerBufferQueue, buffer, i);
         assert(SL_RESULT_SUCCESS == result);

         // get the play interface
         SLPlayItf playerPlay;
         result = (*playerObject)->GetInterface(playerObject, SL_IID_PLAY, &playerPlay);
         assert(SL_RESULT_SUCCESS == result);

         // set the player's state to playing
         result = (*playerPlay)->SetPlayState(playerPlay, SL_PLAYSTATE_PLAYING);
         assert(SL_RESULT_SUCCESS == result);

         // wait for the buffer to be played
         for (;;) {
             SLBufferQueueState state;
             result = (*playerBufferQueue)->GetState(playerBufferQueue, &state);
             assert(SL_RESULT_SUCCESS == result);
             if (state.count == 0)
                 break;
             usleep(20000);
         }

         // destroy audio player
         (*playerObject)->Destroy(playerObject);

         //usleep(1000000);
         hzLeft *= 1.05946309; // twelfth root of 2
         hzRight /= 1.05946309;
     }

     // destroy output mix
     (*outputMixObject)->Destroy(outputMixObject);

     // destroy engine
     (*engineObject)->Destroy(engineObject);

     return EXIT_SUCCESS;
 }
	/*
	* Copyright (C) 2010 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.
	*/

	// Test various buffer queue configurations

	#include <assert.h>
	#include <math.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <unistd.h>

	#include <SLES/OpenSLES.h>

	typedef struct {
	SLuint8 numChannels;
	SLuint32 milliHz;
	SLuint8 bitsPerSample;
	} PCM;

	PCM formats[] = {
	{1, SL_SAMPLINGRATE_8, 8},
	{2, SL_SAMPLINGRATE_8, 8},
	{1, SL_SAMPLINGRATE_8, 16},
	{2, SL_SAMPLINGRATE_8, 16},
	{1, SL_SAMPLINGRATE_11_025, 8},
	{2, SL_SAMPLINGRATE_11_025, 8},
	{1, SL_SAMPLINGRATE_11_025, 16},
	{2, SL_SAMPLINGRATE_11_025, 16},
	{1, SL_SAMPLINGRATE_12, 8},
	{2, SL_SAMPLINGRATE_12, 8},
	{1, SL_SAMPLINGRATE_12, 16},
	{2, SL_SAMPLINGRATE_12, 16},
	{1, SL_SAMPLINGRATE_16, 8},
	{2, SL_SAMPLINGRATE_16, 8},
	{1, SL_SAMPLINGRATE_16, 16},
	{2, SL_SAMPLINGRATE_16, 16},
	{1, SL_SAMPLINGRATE_22_05, 8},
	{2, SL_SAMPLINGRATE_22_05, 8},
	{1, SL_SAMPLINGRATE_22_05, 16},
	{2, SL_SAMPLINGRATE_22_05, 16},
	{1, SL_SAMPLINGRATE_24, 8},
	{2, SL_SAMPLINGRATE_24, 8},
	{1, SL_SAMPLINGRATE_24, 16},
	{2, SL_SAMPLINGRATE_24, 16},
	{1, SL_SAMPLINGRATE_32, 8},
	{2, SL_SAMPLINGRATE_32, 8},
	{1, SL_SAMPLINGRATE_32, 16},
	{2, SL_SAMPLINGRATE_32, 16},
	{1, SL_SAMPLINGRATE_44_1, 8},
	{2, SL_SAMPLINGRATE_44_1, 8},
	{1, SL_SAMPLINGRATE_44_1, 16},
	{2, SL_SAMPLINGRATE_44_1, 16},
	{1, SL_SAMPLINGRATE_48, 8},
	{2, SL_SAMPLINGRATE_48, 8},
	{1, SL_SAMPLINGRATE_48, 16},
	{2, SL_SAMPLINGRATE_48, 16},
	{0, 0, 0}
	};

	int main(int argc __unused, char **argv __unused)
	{
	SLresult result;
	SLObjectItf engineObject;

	// create engine
	result = slCreateEngine(&engineObject, 0, NULL, 0, NULL, NULL);
	assert(SL_RESULT_SUCCESS == result);
	SLEngineItf engineEngine;
	result = (*engineObject)->Realize(engineObject, SL_BOOLEAN_FALSE);
	assert(SL_RESULT_SUCCESS == result);
	result = (*engineObject)->GetInterface(engineObject, SL_IID_ENGINE, &engineEngine);
	assert(SL_RESULT_SUCCESS == result);

	// create output mix
	SLObjectItf outputMixObject;
	result = (*engineEngine)->CreateOutputMix(engineEngine, &outputMixObject, 0, NULL, NULL);
	assert(SL_RESULT_SUCCESS == result);
	result = (*outputMixObject)->Realize(outputMixObject, SL_BOOLEAN_FALSE);
	assert(SL_RESULT_SUCCESS == result);

	// loop over all formats
	PCM *format;
	float hzLeft = 440.0; // A440 (Concert A)
	float hzRight = 440.0;
	for (format = formats; format->numChannels; ++format) {

	printf("Channels: %d, sample rate: %u, bits: %u\n", format->numChannels,
	format->milliHz / 1000, format->bitsPerSample);

	// configure audio source
	SLDataLocator_BufferQueue loc_bufq;
	loc_bufq.locatorType = SL_DATALOCATOR_BUFFERQUEUE;
	loc_bufq.numBuffers = 1;
	SLDataFormat_PCM format_pcm;
	format_pcm.formatType = SL_DATAFORMAT_PCM;
	format_pcm.numChannels = format->numChannels;
	format_pcm.samplesPerSec = format->milliHz;
	format_pcm.bitsPerSample = format->bitsPerSample;
	format_pcm.containerSize = format->bitsPerSample;
	format_pcm.channelMask = 0;
	format_pcm.endianness = SL_BYTEORDER_LITTLEENDIAN;
	SLDataSource audioSrc;
	audioSrc.pLocator = &loc_bufq;
	audioSrc.pFormat = &format_pcm;

	// configure audio sink
	SLDataLocator_OutputMix loc_outmix;
	loc_outmix.locatorType = SL_DATALOCATOR_OUTPUTMIX;
	loc_outmix.outputMix = outputMixObject;
	SLDataSink audioSnk;
	audioSnk.pLocator = &loc_outmix;
	audioSnk.pFormat = NULL;

	// create audio player
	SLuint32 numInterfaces = 1;
	SLInterfaceID ids[1];
	SLboolean req[1];
	ids[0] = SL_IID_BUFFERQUEUE;
	req[0] = SL_BOOLEAN_TRUE;
	SLObjectItf playerObject;
	result = (*engineEngine)->CreateAudioPlayer(engineEngine, &playerObject, &audioSrc,
	&audioSnk, numInterfaces, ids, req);
	if (SL_RESULT_SUCCESS != result) {
	printf("failed %u\n", result);
	continue;
	}

	// realize the player
	result = (*playerObject)->Realize(playerObject, SL_BOOLEAN_FALSE);
	assert(SL_RESULT_SUCCESS == result);

	// generate a sine wave buffer, ascending in half-steps for each format
	#define N (44100*4)
	static unsigned char buffer[N];
	unsigned i;
	for (i = 0; i < N; ) {
	float seconds = (((i * 8) / (format->bitsPerSample * format->numChannels)) * 1000.0) /
	format->milliHz;
	short sampleLeft = sin(seconds * M_PI_2 * hzLeft) * 32767.0;
	short sampleRight = sin(seconds * M_PI_2 * hzRight) * 32767.0;
	if (2 == format->numChannels) {
	if (8 == format->bitsPerSample) {
	buffer[i++] = (sampleLeft + 32768) >> 8;
	buffer[i++] = (sampleRight + 32768) >> 8;
	} else {
	assert(16 == format->bitsPerSample);
	buffer[i++] = sampleLeft & 0xFF;
	buffer[i++] = sampleLeft >> 8;
	buffer[i++] = sampleRight & 0xFF;
	buffer[i++] = sampleRight >> 8;
	}
	} else {
	assert(1 == format->numChannels);
	// cast to int and divide by 2 are needed to prevent overflow
	short sampleMono = ((int) sampleLeft + (int) sampleRight) / 2;
	if (8 == format->bitsPerSample) {
	buffer[i++] = (sampleMono + 32768) >> 8;
	} else {
	assert(16 == format->bitsPerSample);
	buffer[i++] = sampleMono & 0xFF;
	buffer[i++] = sampleMono >> 8;
	}
	}
	if (seconds >= 1.0f)
	break;
	}

	// get the buffer queue interface and enqueue a buffer
	SLBufferQueueItf playerBufferQueue;
	result = (*playerObject)->GetInterface(playerObject, SL_IID_BUFFERQUEUE,
	&playerBufferQueue);
	assert(SL_RESULT_SUCCESS == result);
	result = (*playerBufferQueue)->Enqueue(playerBufferQueue, buffer, i);
	assert(SL_RESULT_SUCCESS == result);

	// get the play interface
	SLPlayItf playerPlay;
	result = (*playerObject)->GetInterface(playerObject, SL_IID_PLAY, &playerPlay);
	assert(SL_RESULT_SUCCESS == result);

	// set the player's state to playing
	result = (*playerPlay)->SetPlayState(playerPlay, SL_PLAYSTATE_PLAYING);
	assert(SL_RESULT_SUCCESS == result);

	// wait for the buffer to be played
	for (;;) {
	SLBufferQueueState state;
	result = (*playerBufferQueue)->GetState(playerBufferQueue, &state);
	assert(SL_RESULT_SUCCESS == result);
	if (state.count == 0)
	break;
	usleep(20000);
	}

	// destroy audio player
	(*playerObject)->Destroy(playerObject);

	//usleep(1000000);
	hzLeft *= 1.05946309; // twelfth root of 2
	hzRight /= 1.05946309;
	}

	// destroy output mix
	(*outputMixObject)->Destroy(outputMixObject);

	// destroy engine
	(*engineObject)->Destroy(engineObject);

	return EXIT_SUCCESS;
	}