/* * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ // SwitchingSampRate.cpp : Defines the entry point for the console // application. // #include #include "isac.h" #include "utility.h" #include "signal_processing_library.h" #define MAX_FILE_NAME 500 #define MAX_NUM_CLIENTS 2 #define NUM_CLIENTS 2 using namespace std; int main(int argc, char* argv[]) { char fileNameWB[MAX_FILE_NAME]; char fileNameSWB[MAX_FILE_NAME]; char outFileName[MAX_NUM_CLIENTS][MAX_FILE_NAME]; FILE* inFile[MAX_NUM_CLIENTS]; FILE* outFile[MAX_NUM_CLIENTS]; ISACStruct* codecInstance[MAX_NUM_CLIENTS]; WebRtc_Word32 resamplerState[MAX_NUM_CLIENTS][8]; enum IsacSamplingRate encoderSampRate[MAX_NUM_CLIENTS]; int minBn = 16000; int maxBn = 56000; int bnWB = 32000; int bnSWB = 56000; strcpy(outFileName[0], "switchSampRate_out1.pcm"); strcpy(outFileName[1], "switchSampRate_out2.pcm"); short clientCntr; unsigned int lenEncodedInBytes[MAX_NUM_CLIENTS]; unsigned int lenAudioIn10ms[MAX_NUM_CLIENTS]; unsigned int lenEncodedInBytesTmp[MAX_NUM_CLIENTS]; unsigned int lenAudioIn10msTmp[MAX_NUM_CLIENTS]; BottleNeckModel* packetData[MAX_NUM_CLIENTS]; char versionNumber[100]; short bottleneckChange[MAX_NUM_CLIENTS]; short samplesIn10ms[MAX_NUM_CLIENTS]; int bottleneck[MAX_NUM_CLIENTS]; printf("\n\n"); printf("____________________________________________\n\n"); WebRtcIsac_version(versionNumber); printf(" iSAC-swb version %s\n", versionNumber); printf("____________________________________________\n"); fileNameWB[0] = '\0'; fileNameSWB[0] = '\0'; // READ THE WIDEBAND AND SUPER-WIDEBAND FILE NAMES if(readParamString(argc, argv, "-wb", fileNameWB, MAX_FILE_NAME) <= 0) { printf("No wideband file is specified"); } if(readParamString(argc, argv, "-swb", fileNameSWB, MAX_FILE_NAME) <= 0) { printf("No super-wideband file is specified"); } // THE FIRST CLIENT STARTS IN WIDEBAND encoderSampRate[0] = kIsacWideband; OPEN_FILE_RB(inFile[0], fileNameWB); // THE SECOND CLIENT STARTS IN SUPER-WIDEBAND encoderSampRate[1] = kIsacSuperWideband; OPEN_FILE_RB(inFile[1], fileNameSWB); short codingMode = readSwitch(argc, argv, "-I"); for(clientCntr = 0; clientCntr < NUM_CLIENTS; clientCntr++) { codecInstance[clientCntr] = NULL; printf("\n"); printf("Client %d\n", clientCntr + 1); printf("---------\n"); printf("Starting %s", (encoderSampRate[clientCntr] == kIsacWideband) ? "wideband":"super-wideband"); bottleneckChange[clientCntr] = 2 * clientCntr - 1; // Open output File Name OPEN_FILE_WB(outFile[clientCntr], outFileName[clientCntr]); printf("Output File...................... %s\n", outFileName[clientCntr]); samplesIn10ms[clientCntr] = encoderSampRate[clientCntr] * 10; if(codingMode == 1) { bottleneck[clientCntr] = (clientCntr)? bnSWB:bnWB; } else { bottleneck[clientCntr] = (clientCntr)? minBn:maxBn; } printf("Bottleneck....................... %0.3f kbits/sec \n", bottleneck[clientCntr] / 1000.0); // coding-mode printf("Encoding Mode.................... %s\n", (codingMode == 1)? "Channel-Independent (Instantaneous)":"Adaptive"); lenEncodedInBytes[clientCntr] = 0; lenAudioIn10ms[clientCntr] = 0; lenEncodedInBytesTmp[clientCntr] = 0; lenAudioIn10msTmp[clientCntr] = 0; packetData[clientCntr] = (BottleNeckModel*)new(BottleNeckModel); if(packetData[clientCntr] == NULL) { printf("Could not allocate memory for packetData \n"); return -1; } memset(packetData[clientCntr], 0, sizeof(BottleNeckModel)); memset(resamplerState[clientCntr], 0, sizeof(WebRtc_Word32) * 8); } for(clientCntr = 0; clientCntr < NUM_CLIENTS; clientCntr++) { // Create if(WebRtcIsac_Create(&codecInstance[clientCntr])) { printf("Could not creat client %d\n", clientCntr + 1); return -1; } WebRtcIsac_SetEncSampRate(codecInstance[clientCntr], encoderSampRate[clientCntr]); WebRtcIsac_SetDecSampRate(codecInstance[clientCntr], encoderSampRate[clientCntr + (1 - ((clientCntr & 1)<<1))]); // Initialize Encoder if(WebRtcIsac_EncoderInit(codecInstance[clientCntr], codingMode) < 0) { printf("Could not initialize client, %d\n", clientCntr + 1); return -1; } // Initialize Decoder if(WebRtcIsac_DecoderInit(codecInstance[clientCntr]) < 0) { printf("Could not initialize decoder of client %d\n", clientCntr + 1); return -1; } // setup Rate if in Instantaneous mode if(codingMode != 0) { // ONLY Clients who are not in Adaptive mode if(WebRtcIsac_Control(codecInstance[clientCntr], bottleneck[clientCntr], 30) < 0) { printf("Could not setup bottleneck and frame-size for client %d\n", clientCntr + 1); return -1; } } } short streamLen; short numSamplesRead; short lenDecodedAudio; short senderIdx; short receiverIdx; printf("\n"); char rot[4] = {'\\', '|', '/', '-'}; unsigned int rotCntr = 0; short num10ms[MAX_NUM_CLIENTS]; memset(num10ms, 0, sizeof(short)*MAX_NUM_CLIENTS); FILE* arrivalTimeFile1 = fopen("arrivalTime1.dat", "wb"); FILE* arrivalTimeFile2 = fopen("arrivalTime2.dat", "wb"); short numPrint[MAX_NUM_CLIENTS]; memset(numPrint, 0, sizeof(short) * MAX_NUM_CLIENTS); // Audio Buffers short silence10ms[10 * 32]; memset(silence10ms, 0, 320 * sizeof(short)); short audioBuff10ms[10 * 32]; short audioBuff60ms[60 * 32]; short resampledAudio60ms[60 * 32]; unsigned short bitStream[600+600]; short speechType[1]; short numSampFreqChanged = 0; while(numSampFreqChanged < 10) { for(clientCntr = 0; clientCntr < NUM_CLIENTS; clientCntr++) { // Encoding/decoding for this pair of clients, if there is // audio for any of them //if(audioLeft[clientCntr] || audioLeft[clientCntr + 1]) //{ //for(pairCntr = 0; pairCntr < 2; pairCntr++) //{ senderIdx = clientCntr; // + pairCntr; receiverIdx = 1 - clientCntr;// + (1 - pairCntr); //if(num10ms[senderIdx] > 6) //{ // printf("Too many frames read for client %d", // senderIdx + 1); // return -1; //} numSamplesRead = (short)fread(audioBuff10ms, sizeof(short), samplesIn10ms[senderIdx], inFile[senderIdx]); if(numSamplesRead != samplesIn10ms[senderIdx]) { // file finished switch encoder sampling frequency. printf("Changing Encoder Sampling frequency in client %d to ", senderIdx+1); fclose(inFile[senderIdx]); numSampFreqChanged++; if(encoderSampRate[senderIdx] == kIsacWideband) { printf("super-wideband.\n"); OPEN_FILE_RB(inFile[senderIdx], fileNameSWB); encoderSampRate[senderIdx] = kIsacSuperWideband; } else { printf("wideband.\n"); OPEN_FILE_RB(inFile[senderIdx], fileNameWB); encoderSampRate[senderIdx] = kIsacWideband; } WebRtcIsac_SetEncSampRate(codecInstance[senderIdx], encoderSampRate[senderIdx]); WebRtcIsac_SetDecSampRate(codecInstance[receiverIdx], encoderSampRate[senderIdx]); samplesIn10ms[clientCntr] = encoderSampRate[clientCntr] * 10; numSamplesRead = (short)fread(audioBuff10ms, sizeof(short), samplesIn10ms[senderIdx], inFile[senderIdx]); if(numSamplesRead != samplesIn10ms[senderIdx]) { printf(" File %s for client %d has not enough audio\n", (encoderSampRate[senderIdx]==kIsacWideband)? "wideband":"super-wideband", senderIdx + 1); return -1; } } num10ms[senderIdx]++; // sanity check //if(num10ms[senderIdx] > 6) //{ // printf("Client %d has got more than 60 ms audio and encoded no packet.\n", // senderIdx); // return -1; //} // Encode streamLen = WebRtcIsac_Encode(codecInstance[senderIdx], audioBuff10ms, (short*)bitStream); WebRtc_Word16 ggg; if (streamLen > 0) { if(( WebRtcIsac_ReadFrameLen(codecInstance[receiverIdx], (short *) bitStream, &ggg))<0) printf("ERROR\n"); } // Sanity check if(streamLen < 0) { printf(" Encoder error in client %d \n", senderIdx + 1); return -1; } if(streamLen > 0) { // Packet generated; model sending through a channel, do bandwidth // estimation at the receiver and decode. lenEncodedInBytes[senderIdx] += streamLen; lenAudioIn10ms[senderIdx] += (unsigned int)num10ms[senderIdx]; lenEncodedInBytesTmp[senderIdx] += streamLen; lenAudioIn10msTmp[senderIdx] += (unsigned int)num10ms[senderIdx]; // Print after ~5 sec. if(lenAudioIn10msTmp[senderIdx] >= 100) { numPrint[senderIdx]++; printf(" %d, %6.3f => %6.3f ", senderIdx+1, bottleneck[senderIdx] / 1000.0, lenEncodedInBytesTmp[senderIdx] * 0.8 / lenAudioIn10msTmp[senderIdx]); if(codingMode == 0) { WebRtc_Word32 bn; WebRtcIsac_GetUplinkBw(codecInstance[senderIdx], &bn); printf("[%d] ", bn); } //WebRtc_Word16 rateIndexLB; //WebRtc_Word16 rateIndexUB; //WebRtcIsac_GetDownLinkBwIndex(codecInstance[receiverIdx], // &rateIndexLB, &rateIndexUB); //printf(" (%2d, %2d) ", rateIndexLB, rateIndexUB); cout << flush; lenEncodedInBytesTmp[senderIdx] = 0; lenAudioIn10msTmp[senderIdx] = 0; //if(senderIdx == (NUM_CLIENTS - 1)) //{ printf(" %0.1f \n", lenAudioIn10ms[senderIdx] * 10. /1000); //} // After ~20 sec change the bottleneck. // if((numPrint[senderIdx] == 4) && (codingMode == 0)) // { // numPrint[senderIdx] = 0; // if(codingMode == 0) // { // int newBottleneck = bottleneck[senderIdx] + // (bottleneckChange[senderIdx] * 1000); // if(bottleneckChange[senderIdx] > 0) // { // if(newBottleneck >maxBn) // { // bottleneckChange[senderIdx] = -1; // newBottleneck = bottleneck[senderIdx] + // (bottleneckChange[senderIdx] * 1000); // if(newBottleneck > minBn) // { // bottleneck[senderIdx] = newBottleneck; // } // } // else // { // bottleneck[senderIdx] = newBottleneck; // } // } // else // { // if(newBottleneck < minBn) // { // bottleneckChange[senderIdx] = 1; // newBottleneck = bottleneck[senderIdx] + // (bottleneckChange[senderIdx] * 1000); // if(newBottleneck < maxBn) // { // bottleneck[senderIdx] = newBottleneck; // } // } // else // { // bottleneck[senderIdx] = newBottleneck; // } // } // } // } } // model a channel of given bottleneck, to get the receive timestamp get_arrival_time(num10ms[senderIdx] * samplesIn10ms[senderIdx], streamLen, bottleneck[senderIdx], packetData[senderIdx], encoderSampRate[senderIdx]*1000, encoderSampRate[senderIdx]*1000); // Write the arrival time. if(senderIdx == 0) { fwrite(&(packetData[senderIdx]->arrival_time), sizeof(unsigned int), 1, arrivalTimeFile1); } else { fwrite(&(packetData[senderIdx]->arrival_time), sizeof(unsigned int), 1, arrivalTimeFile2); } // BWE if(WebRtcIsac_UpdateBwEstimate(codecInstance[receiverIdx], bitStream, streamLen, packetData[senderIdx]->rtp_number, packetData[senderIdx]->sample_count, packetData[senderIdx]->arrival_time) < 0) { printf(" BWE Error at client %d \n", receiverIdx + 1); return -1; } /**/ // Decode lenDecodedAudio = WebRtcIsac_Decode( codecInstance[receiverIdx], bitStream, streamLen, audioBuff60ms, speechType); if(lenDecodedAudio < 0) { printf(" Decoder error in client %d \n", receiverIdx + 1); return -1; } if(encoderSampRate[senderIdx] == kIsacWideband) { WebRtcSpl_UpsampleBy2(audioBuff60ms, lenDecodedAudio, resampledAudio60ms, resamplerState[receiverIdx]); fwrite(resampledAudio60ms, sizeof(short), lenDecodedAudio << 1, outFile[receiverIdx]); } else { fwrite(audioBuff60ms, sizeof(short), lenDecodedAudio, outFile[receiverIdx]); } num10ms[senderIdx] = 0; } //} //} } } }