/* * Copyright (c) 2012 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. */ // ReleaseTest-API.cpp : Defines the entry point for the console application. // #include #include #include #include #include #include /* include API */ #include "modules/audio_coding/codecs/isac/main/include/isac.h" #include "modules/audio_coding/codecs/isac/main/util/utility.h" #include "rtc_base/format_macros.h" /* Defines */ #define SEED_FILE \ "randseed.txt" /* Used when running decoder on garbage data \ */ #define MAX_FRAMESAMPLES \ 960 /* max number of samples per frame \ (= 60 ms frame & 16 kHz) or \ (= 30 ms frame & 32 kHz) */ #define FRAMESAMPLES_10ms 160 /* number of samples per 10ms frame */ #define SWBFRAMESAMPLES_10ms 320 //#define FS 16000 /* sampling frequency (Hz) */ #ifdef WIN32 #ifndef CLOCKS_PER_SEC #define CLOCKS_PER_SEC 1000 /* Runtime statistics */ #endif #endif using namespace std; int main(int argc, char* argv[]) { char inname[100], outname[100], bottleneck_file[100], vadfile[100]; FILE *inp, *outp, *f_bn = NULL, *vadp = NULL, *bandwidthp; int framecnt, endfile; size_t i; int errtype, VADusage = 0, packetLossPercent = 0; int16_t CodingMode; int32_t bottleneck = 0; int framesize = 30; /* ms */ int cur_framesmpls, err; /* Runtime statistics */ double starttime, runtime, length_file; size_t stream_len = 0; int declen = 0, declenTC = 0; bool lostFrame = false; int16_t shortdata[SWBFRAMESAMPLES_10ms]; int16_t vaddata[SWBFRAMESAMPLES_10ms * 3]; int16_t decoded[MAX_FRAMESAMPLES << 1]; int16_t decodedTC[MAX_FRAMESAMPLES << 1]; uint16_t streamdata[500]; int16_t speechType[1]; int16_t rateBPS = 0; int16_t fixedFL = 0; int16_t payloadSize = 0; int32_t payloadRate = 0; int setControlBWE = 0; short FL, testNum; char version_number[20]; FILE* plFile; int32_t sendBN; #if !defined(NDEBUG) FILE* fy; double kbps; #endif size_t totalbits = 0; int totalsmpls = 0; /* If use GNS file */ FILE* fp_gns = NULL; char gns_file[100]; size_t maxStreamLen30 = 0; size_t maxStreamLen60 = 0; short sampFreqKHz = 32; short samplesIn10Ms; short useAssign = 0; // FILE logFile; bool doTransCoding = false; int32_t rateTransCoding = 0; uint8_t streamDataTransCoding[1200]; size_t streamLenTransCoding = 0; FILE* transCodingFile = NULL; FILE* transcodingBitstream = NULL; size_t numTransCodingBytes = 0; /* only one structure used for ISAC encoder */ ISACStruct* ISAC_main_inst = NULL; ISACStruct* decoderTransCoding = NULL; BottleNeckModel BN_data; #if !defined(NDEBUG) fy = fopen("bit_rate.dat", "w"); fclose(fy); fy = fopen("bytes_frames.dat", "w"); fclose(fy); #endif /* Handling wrong input arguments in the command line */ if ((argc < 3) || (argc > 17)) { printf("\n\nWrong number of arguments or flag values.\n\n"); printf("\n"); WebRtcIsac_version(version_number); printf("iSAC-swb version %s \n\n", version_number); printf("Usage:\n\n"); printf("%s [-I] bottleneck_value infile outfile \n\n", argv[0]); printf("with:\n"); printf("[-FS num] : sampling frequency in kHz, valid values are\n"); printf(" 16 & 32, with 16 as default.\n"); printf("[-I] : if -I option is specified, the coder will use\n"); printf(" an instantaneous Bottleneck value. If not, it\n"); printf(" will be an adaptive Bottleneck value.\n"); printf("[-assign] : Use Assign API.\n"); printf("[-B num] : the value of the bottleneck provided either\n"); printf(" as a fixed value in bits/sec (e.g. 25000) or\n"); printf(" read from a file (e.g. bottleneck.txt)\n"); printf("[-INITRATE num] : Set a new value for initial rate. Note! Only\n"); printf(" used in adaptive mode.\n"); printf("[-FL num] : Set (initial) frame length in msec. Valid\n"); printf(" lengths are 30 and 60 msec.\n"); printf("[-FIXED_FL] : Frame length will be fixed to initial value.\n"); printf("[-MAX num] : Set the limit for the payload size of iSAC\n"); printf(" in bytes. Minimum 100 maximum 400.\n"); printf("[-MAXRATE num] : Set the maxrate for iSAC in bits per second.\n"); printf(" Minimum 32000, maximum 53400.\n"); printf("[-F num] : if -F option is specified, the test function\n"); printf(" will run the iSAC API fault scenario\n"); printf(" specified by the supplied number.\n"); printf(" F 1 - Call encoder prior to init encoder call\n"); printf(" F 2 - Call decoder prior to init decoder call\n"); printf(" F 3 - Call decoder prior to encoder call\n"); printf(" F 4 - Call decoder with a too short coded\n"); printf(" sequence\n"); printf(" F 5 - Call decoder with a too long coded\n"); printf(" sequence\n"); printf(" F 6 - Call decoder with random bit stream\n"); printf(" F 7 - Call init encoder/decoder at random\n"); printf(" during a call\n"); printf(" F 8 - Call encoder/decoder without having\n"); printf(" allocated memory for encoder/decoder\n"); printf(" instance\n"); printf(" F 9 - Call decodeB without calling decodeA\n"); printf(" F 10 - Call decodeB with garbage data\n"); printf("[-PL num] : if -PL option is specified \n"); printf("[-T rate file] : test trans-coding with target bottleneck\n"); printf(" 'rate' bits/sec\n"); printf(" the output file is written to 'file'\n"); printf("[-LOOP num] : number of times to repeat coding the input\n"); printf(" file for stress testing\n"); // printf("[-CE num] : Test of APIs used by Conference Engine.\n"); // printf(" CE 1 - getNewBitstream, getBWE \n"); // printf(" (CE 2 - RESERVED for transcoding)\n"); // printf(" CE 3 - getSendBWE, setSendBWE. \n"); // printf("-L filename : write the logging info into file // (appending)\n"); printf("infile : Normal speech input file\n"); printf("outfile : Speech output file\n"); exit(0); } /* Print version number */ printf("-------------------------------------------------\n"); WebRtcIsac_version(version_number); printf("iSAC version %s \n\n", version_number); /* Loop over all command line arguments */ CodingMode = 0; testNum = 0; useAssign = 0; // logFile = NULL; char transCodingFileName[500]; int16_t totFileLoop = 0; int16_t numFileLoop = 0; for (i = 1; i + 2 < static_cast(argc); i++) { if (!strcmp("-LOOP", argv[i])) { i++; totFileLoop = (int16_t)atol(argv[i]); if (totFileLoop <= 0) { fprintf(stderr, "Invalid number of runs for the given input file, %d.", totFileLoop); exit(0); } } if (!strcmp("-T", argv[i])) { doTransCoding = true; i++; rateTransCoding = atoi(argv[i]); i++; strcpy(transCodingFileName, argv[i]); } /*Should we use assign API*/ if (!strcmp("-assign", argv[i])) { useAssign = 1; } /* Set Sampling Rate */ if (!strcmp("-FS", argv[i])) { i++; sampFreqKHz = atoi(argv[i]); } /* Instantaneous mode */ if (!strcmp("-I", argv[i])) { printf("Instantaneous BottleNeck\n"); CodingMode = 1; } /* Set (initial) bottleneck value */ if (!strcmp("-INITRATE", argv[i])) { rateBPS = atoi(argv[i + 1]); setControlBWE = 1; if ((rateBPS < 10000) || (rateBPS > 32000)) { printf( "\n%d is not a initial rate. Valid values are in the range " "10000 to 32000.\n", rateBPS); exit(0); } printf("New initial rate: %d\n", rateBPS); i++; } /* Set (initial) framelength */ if (!strcmp("-FL", argv[i])) { framesize = atoi(argv[i + 1]); if ((framesize != 30) && (framesize != 60)) { printf( "\n%d is not a valid frame length. Valid length are 30 and 60 " "msec.\n", framesize); exit(0); } setControlBWE = 1; printf("Frame Length: %d\n", framesize); i++; } /* Fixed frame length */ if (!strcmp("-FIXED_FL", argv[i])) { fixedFL = 1; setControlBWE = 1; printf("Fixed Frame Length\n"); } /* Set maximum allowed payload size in bytes */ if (!strcmp("-MAX", argv[i])) { payloadSize = atoi(argv[i + 1]); printf("Maximum Payload Size: %d\n", payloadSize); i++; } /* Set maximum rate in bytes */ if (!strcmp("-MAXRATE", argv[i])) { payloadRate = atoi(argv[i + 1]); printf("Maximum Rate in kbps: %d\n", payloadRate); i++; } /* Test of fault scenarious */ if (!strcmp("-F", argv[i])) { testNum = atoi(argv[i + 1]); printf("Fault test: %d\n", testNum); if (testNum < 1 || testNum > 10) { printf( "\n%d is not a valid Fault Scenario number. Valid Fault " "Scenarios are numbered 1-10.\n", testNum); exit(0); } i++; } /* Packet loss test */ if (!strcmp("-PL", argv[i])) { if (isdigit(*argv[i + 1])) { packetLossPercent = atoi(argv[i + 1]); if ((packetLossPercent < 0) | (packetLossPercent > 100)) { printf("\nInvalid packet loss perentage \n"); exit(0); } if (packetLossPercent > 0) { printf("Simulating %d %% of independent packet loss\n", packetLossPercent); } else { printf("\nNo Packet Loss Is Simulated \n"); } } else { plFile = fopen(argv[i + 1], "rb"); if (plFile == NULL) { printf("\n couldn't open the frameloss file: %s\n", argv[i + 1]); exit(0); } printf("Simulating packet loss through the given channel file: %s\n", argv[i + 1]); } i++; } /* Random packetlosses */ if (!strcmp("-rnd", argv[i])) { srand((unsigned int)time(NULL)); printf("Random pattern in lossed packets \n"); } /* Use gns file */ if (!strcmp("-G", argv[i])) { sscanf(argv[i + 1], "%s", gns_file); fp_gns = fopen(gns_file, "rb"); if (fp_gns == NULL) { printf("Cannot read file %s.\n", gns_file); exit(0); } i++; } // make it with '-B' /* Get Bottleneck value */ if (!strcmp("-B", argv[i])) { i++; bottleneck = atoi(argv[i]); if (bottleneck == 0) { sscanf(argv[i], "%s", bottleneck_file); f_bn = fopen(bottleneck_file, "rb"); if (f_bn == NULL) { printf( "Error No value provided for BottleNeck and cannot read file " "%s.\n", bottleneck_file); exit(0); } else { printf("reading bottleneck rates from file %s\n\n", bottleneck_file); if (fscanf(f_bn, "%d", &bottleneck) == EOF) { /* Set pointer to beginning of file */ fseek(f_bn, 0L, SEEK_SET); if (fscanf(f_bn, "%d", &bottleneck) == EOF) { exit(0); } } /* Bottleneck is a cosine function * Matlab code for writing the bottleneck file: * BottleNeck_10ms = 20e3 + 10e3 * cos((0:5999)/5999*2*pi); * fid = fopen('bottleneck.txt', 'wb'); * fprintf(fid, '%d\n', BottleNeck_10ms); fclose(fid); */ } } else { printf("\nfixed bottleneck rate of %d bits/s\n\n", bottleneck); } } /* Run Conference Engine APIs */ // Do not test it in the first release // // if(!strcmp ("-CE", argv[i])) // { // testCE = atoi(argv[i + 1]); // if(testCE==1) // { // i++; // scale = (float)atof( argv[i+1] ); // } // else if(testCE == 2) // { // printf("\nCE-test 2 (transcoding) not implemented.\n"); // exit(0); // } // else if(testCE < 1 || testCE > 3) // { // printf("\n%d is not a valid CE-test number. Valid CE tests // are 1-3.\n", testCE); // exit(0); // } // printf("CE-test number: %d\n", testCE); // i++; // } } if (CodingMode == 0) { printf("\nAdaptive BottleNeck\n"); } switch (sampFreqKHz) { case 16: { printf("iSAC Wideband.\n"); samplesIn10Ms = FRAMESAMPLES_10ms; break; } case 32: { printf("iSAC Supper-Wideband.\n"); samplesIn10Ms = SWBFRAMESAMPLES_10ms; break; } default: printf("Unsupported sampling frequency %d kHz", sampFreqKHz); exit(0); } /* Get Input and Output files */ sscanf(argv[argc - 2], "%s", inname); sscanf(argv[argc - 1], "%s", outname); printf("\nInput file: %s\n", inname); printf("Output file: %s\n\n", outname); if ((inp = fopen(inname, "rb")) == NULL) { printf(" Error iSAC Cannot read file %s.\n", inname); cout << flush; exit(1); } if ((outp = fopen(outname, "wb")) == NULL) { printf(" Error iSAC Cannot write file %s.\n", outname); cout << flush; getc(stdin); exit(1); } if (VADusage) { if ((vadp = fopen(vadfile, "rb")) == NULL) { printf(" Error iSAC Cannot read file %s.\n", vadfile); cout << flush; exit(1); } } if ((bandwidthp = fopen("bwe.pcm", "wb")) == NULL) { printf(" Error iSAC Cannot read file %s.\n", "bwe.pcm"); cout << flush; exit(1); } starttime = clock() / (double)CLOCKS_PER_SEC; /* Runtime statistics */ /* Initialize the ISAC and BN structs */ if (testNum != 8) { if (!useAssign) { err = WebRtcIsac_Create(&ISAC_main_inst); WebRtcIsac_SetEncSampRate(ISAC_main_inst, sampFreqKHz * 1000); WebRtcIsac_SetDecSampRate(ISAC_main_inst, sampFreqKHz >= 32 ? 32000 : 16000); } else { /* Test the Assign functions */ int sss; void* ppp; err = WebRtcIsac_AssignSize(&sss); ppp = malloc(sss); err = WebRtcIsac_Assign(&ISAC_main_inst, ppp); WebRtcIsac_SetEncSampRate(ISAC_main_inst, sampFreqKHz * 1000); WebRtcIsac_SetDecSampRate(ISAC_main_inst, sampFreqKHz >= 32 ? 32000 : 16000); } /* Error check */ if (err < 0) { printf("\n\n Error in create.\n\n"); cout << flush; exit(EXIT_FAILURE); } } BN_data.arrival_time = 0; BN_data.sample_count = 0; BN_data.rtp_number = 0; /* Initialize encoder and decoder */ framecnt = 0; endfile = 0; if (doTransCoding) { WebRtcIsac_Create(&decoderTransCoding); WebRtcIsac_SetEncSampRate(decoderTransCoding, sampFreqKHz * 1000); WebRtcIsac_SetDecSampRate(decoderTransCoding, sampFreqKHz >= 32 ? 32000 : 16000); WebRtcIsac_DecoderInit(decoderTransCoding); transCodingFile = fopen(transCodingFileName, "wb"); if (transCodingFile == NULL) { printf("Could not open %s to output trans-coding.\n", transCodingFileName); exit(0); } strcat(transCodingFileName, ".bit"); transcodingBitstream = fopen(transCodingFileName, "wb"); if (transcodingBitstream == NULL) { printf("Could not open %s to write the bit-stream of transcoder.\n", transCodingFileName); exit(0); } } if (testNum != 1) { if (WebRtcIsac_EncoderInit(ISAC_main_inst, CodingMode) < 0) { printf("Error could not initialize the encoder \n"); cout << flush; return 0; } } if (testNum != 2) WebRtcIsac_DecoderInit(ISAC_main_inst); if (CodingMode == 1) { err = WebRtcIsac_Control(ISAC_main_inst, bottleneck, framesize); if (err < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); printf("\n\n Error in initialization (control): %d.\n\n", errtype); cout << flush; if (testNum == 0) { exit(EXIT_FAILURE); } } } if ((setControlBWE) && (CodingMode == 0)) { err = WebRtcIsac_ControlBwe(ISAC_main_inst, rateBPS, framesize, fixedFL); if (err < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); printf("\n\n Error in Control BWE: %d.\n\n", errtype); cout << flush; exit(EXIT_FAILURE); } } if (payloadSize != 0) { err = WebRtcIsac_SetMaxPayloadSize(ISAC_main_inst, payloadSize); if (err < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); printf("\n\n Error in SetMaxPayloadSize: %d.\n\n", errtype); cout << flush; exit(EXIT_FAILURE); } } if (payloadRate != 0) { err = WebRtcIsac_SetMaxRate(ISAC_main_inst, payloadRate); if (err < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); printf("\n\n Error in SetMaxRateInBytes: %d.\n\n", errtype); cout << flush; exit(EXIT_FAILURE); } } *speechType = 1; cout << "\n" << flush; length_file = 0; int16_t bnIdxTC = 0; int16_t jitterInfoTC = 0; while (endfile == 0) { /* Call init functions at random, fault test number 7 */ if (testNum == 7 && (rand() % 2 == 0)) { err = WebRtcIsac_EncoderInit(ISAC_main_inst, CodingMode); /* Error check */ if (err < 0) { errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); printf("\n\n Error in encoderinit: %d.\n\n", errtype); cout << flush; } WebRtcIsac_DecoderInit(ISAC_main_inst); } cur_framesmpls = 0; while (1) { int stream_len_int = 0; /* Read 10 ms speech block */ endfile = readframe(shortdata, inp, samplesIn10Ms); if (endfile) { numFileLoop++; if (numFileLoop < totFileLoop) { rewind(inp); framecnt = 0; fprintf(stderr, "\n"); endfile = readframe(shortdata, inp, samplesIn10Ms); } } if (testNum == 7) { srand((unsigned int)time(NULL)); } /* iSAC encoding */ if (!(testNum == 3 && framecnt == 0)) { stream_len_int = WebRtcIsac_Encode(ISAC_main_inst, shortdata, (uint8_t*)streamdata); if ((payloadSize != 0) && (stream_len_int > payloadSize)) { if (testNum == 0) { printf("\n\n"); } printf("\nError: Streamsize out of range %d\n", stream_len_int - payloadSize); cout << flush; } WebRtcIsac_GetUplinkBw(ISAC_main_inst, &sendBN); if (stream_len_int > 0) { if (doTransCoding) { int16_t indexStream; uint8_t auxUW8; /******************** Main Transcoding stream ********************/ WebRtcIsac_GetDownLinkBwIndex(ISAC_main_inst, &bnIdxTC, &jitterInfoTC); int streamLenTransCoding_int = WebRtcIsac_GetNewBitStream( ISAC_main_inst, bnIdxTC, jitterInfoTC, rateTransCoding, streamDataTransCoding, false); if (streamLenTransCoding_int < 0) { fprintf(stderr, "Error in trans-coding\n"); exit(0); } streamLenTransCoding = static_cast(streamLenTransCoding_int); auxUW8 = (uint8_t)(((streamLenTransCoding & 0xFF00) >> 8) & 0x00FF); if (fwrite(&auxUW8, sizeof(uint8_t), 1, transcodingBitstream) != 1) { return -1; } auxUW8 = (uint8_t)(streamLenTransCoding & 0x00FF); if (fwrite(&auxUW8, sizeof(uint8_t), 1, transcodingBitstream) != 1) { return -1; } if (fwrite(streamDataTransCoding, sizeof(uint8_t), streamLenTransCoding, transcodingBitstream) != streamLenTransCoding) { return -1; } WebRtcIsac_ReadBwIndex(streamDataTransCoding, &indexStream); if (indexStream != bnIdxTC) { fprintf(stderr, "Error in inserting Bandwidth index into transcoding " "stream.\n"); exit(0); } numTransCodingBytes += streamLenTransCoding; } } } else { break; } if (stream_len_int < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); fprintf(stderr, "Error in encoder: %d.\n", errtype); cout << flush; exit(0); } stream_len = static_cast(stream_len_int); cur_framesmpls += samplesIn10Ms; /* exit encoder loop if the encoder returned a bitstream */ if (stream_len != 0) break; } /* read next bottleneck rate */ if (f_bn != NULL) { if (fscanf(f_bn, "%d", &bottleneck) == EOF) { /* Set pointer to beginning of file */ fseek(f_bn, 0L, SEEK_SET); if (fscanf(f_bn, "%d", &bottleneck) == EOF) { exit(0); } } if (CodingMode == 1) { WebRtcIsac_Control(ISAC_main_inst, bottleneck, framesize); } } length_file += cur_framesmpls; if (cur_framesmpls == (3 * samplesIn10Ms)) { maxStreamLen30 = (stream_len > maxStreamLen30) ? stream_len : maxStreamLen30; } else { maxStreamLen60 = (stream_len > maxStreamLen60) ? stream_len : maxStreamLen60; } if (!lostFrame) { lostFrame = ((rand() % 100) < packetLossPercent); } else { lostFrame = false; } // RED. if (lostFrame) { int stream_len_int = WebRtcIsac_GetRedPayload( ISAC_main_inst, reinterpret_cast(streamdata)); if (stream_len_int < 0) { fprintf(stderr, "Error getting RED payload\n"); exit(0); } stream_len = static_cast(stream_len_int); if (doTransCoding) { int streamLenTransCoding_int = WebRtcIsac_GetNewBitStream( ISAC_main_inst, bnIdxTC, jitterInfoTC, rateTransCoding, streamDataTransCoding, true); if (streamLenTransCoding_int < 0) { fprintf(stderr, "Error in RED trans-coding\n"); exit(0); } streamLenTransCoding = static_cast(streamLenTransCoding_int); } } /* make coded sequence to short be inreasing */ /* the length the decoder expects */ if (testNum == 4) { stream_len += 10; } /* make coded sequence to long be decreasing */ /* the length the decoder expects */ if (testNum == 5) { stream_len -= 10; } if (testNum == 6) { srand((unsigned int)time(NULL)); for (i = 0; i < stream_len; i++) { streamdata[i] = rand(); } } if (VADusage) { readframe(vaddata, vadp, samplesIn10Ms * 3); } /* simulate packet handling through NetEq and the modem */ if (!(testNum == 3 && framecnt == 0)) { get_arrival_time(cur_framesmpls, stream_len, bottleneck, &BN_data, sampFreqKHz * 1000, sampFreqKHz * 1000); } if (VADusage && (framecnt > 10 && vaddata[0] == 0)) { BN_data.rtp_number--; } else { /* Error test number 10, garbage data */ if (testNum == 10) { /* Test to run decoder with garbage data */ for (i = 0; i < stream_len; i++) { streamdata[i] = (short)(streamdata[i]) + (short)rand(); } } if (testNum != 9) { err = WebRtcIsac_UpdateBwEstimate( ISAC_main_inst, reinterpret_cast(streamdata), stream_len, BN_data.rtp_number, BN_data.sample_count, BN_data.arrival_time); if (err < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); if (testNum == 0) { printf("\n\n"); } printf("Error: in decoder: %d.", errtype); cout << flush; if (testNum == 0) { printf("\n\n"); } } } /* Call getFramelen, only used here for function test */ err = WebRtcIsac_ReadFrameLen( ISAC_main_inst, reinterpret_cast(streamdata), &FL); if (err < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); if (testNum == 0) { printf("\n\n"); } printf(" Error: in getFrameLen %d.", errtype); cout << flush; if (testNum == 0) { printf("\n\n"); } } // iSAC decoding if (lostFrame) { declen = WebRtcIsac_DecodeRcu( ISAC_main_inst, reinterpret_cast(streamdata), stream_len, decoded, speechType); if (doTransCoding) { declenTC = WebRtcIsac_DecodeRcu(decoderTransCoding, streamDataTransCoding, streamLenTransCoding, decodedTC, speechType); } } else { declen = WebRtcIsac_Decode(ISAC_main_inst, reinterpret_cast(streamdata), stream_len, decoded, speechType); if (doTransCoding) { declenTC = WebRtcIsac_Decode(decoderTransCoding, streamDataTransCoding, streamLenTransCoding, decodedTC, speechType); } } if (declen < 0) { /* exit if returned with error */ errtype = WebRtcIsac_GetErrorCode(ISAC_main_inst); if (testNum == 0) { printf("\n\n"); } printf(" Error: in decoder %d.", errtype); cout << flush; if (testNum == 0) { printf("\n\n"); } } if (declenTC < 0) { if (testNum == 0) { printf("\n\n"); } printf(" Error: in decoding the transcoded stream"); cout << flush; if (testNum == 0) { printf("\n\n"); } } } /* Write decoded speech frame to file */ if ((declen > 0) && (numFileLoop == 0)) { if (fwrite(decoded, sizeof(int16_t), declen, outp) != static_cast(declen)) { return -1; } } if ((declenTC > 0) && (numFileLoop == 0)) { if (fwrite(decodedTC, sizeof(int16_t), declen, transCodingFile) != static_cast(declen)) { return -1; } } fprintf(stderr, "\rframe = %5d ", framecnt); fflush(stderr); framecnt++; /* Error test number 10, garbage data */ // if (testNum == 10) // { // /* Test to run decoder with garbage data */ // if ((seedfile = fopen(SEED_FILE, "a+t")) == NULL) { // fprintf(stderr, "Error: Could not open file %s\n", SEED_FILE); // } else { // fprintf(seedfile, "ok\n\n"); // fclose(seedfile); // } // } /* Error test number 10, garbage data */ // if (testNum == 10) { // /* Test to run decoder with garbage data */ // for (i = 0; i < stream_len; i++) { // streamdata[i] = (short) (streamdata[i] + (short) rand()); // } // } totalsmpls += declen; totalbits += 8 * stream_len; #if !defined(NDEBUG) kbps = ((double)sampFreqKHz * 1000.) / ((double)cur_framesmpls) * 8.0 * stream_len / 1000.0; // kbits/s fy = fopen("bit_rate.dat", "a"); fprintf(fy, "Frame %i = %0.14f\n", framecnt, kbps); fclose(fy); #endif } printf("\n"); printf("total bits = %" PRIuS " bits\n", totalbits); printf("measured average bitrate = %0.3f kbits/s\n", (double)totalbits * (sampFreqKHz) / totalsmpls); if (doTransCoding) { printf("Transcoding average bit-rate = %0.3f kbps\n", (double)numTransCodingBytes * 8.0 * (sampFreqKHz) / totalsmpls); fclose(transCodingFile); } printf("\n"); /* Runtime statistics */ runtime = (double)(clock() / (double)CLOCKS_PER_SEC - starttime); length_file = length_file / (sampFreqKHz * 1000.); printf("\n\nLength of speech file: %.1f s\n", length_file); printf("Time to run iSAC: %.2f s (%.2f %% of realtime)\n\n", runtime, (100 * runtime / length_file)); if (maxStreamLen30 != 0) { printf("Maximum payload size 30ms Frames %" PRIuS " bytes (%0.3f kbps)\n", maxStreamLen30, maxStreamLen30 * 8 / 30.); } if (maxStreamLen60 != 0) { printf("Maximum payload size 60ms Frames %" PRIuS " bytes (%0.3f kbps)\n", maxStreamLen60, maxStreamLen60 * 8 / 60.); } // fprintf(stderr, "\n"); fprintf(stderr, " %.1f s", length_file); fprintf(stderr, " %0.1f kbps", (double)totalbits * (sampFreqKHz) / totalsmpls); if (maxStreamLen30 != 0) { fprintf(stderr, " plmax-30ms %" PRIuS " bytes (%0.0f kbps)", maxStreamLen30, maxStreamLen30 * 8 / 30.); } if (maxStreamLen60 != 0) { fprintf(stderr, " plmax-60ms %" PRIuS " bytes (%0.0f kbps)", maxStreamLen60, maxStreamLen60 * 8 / 60.); } if (doTransCoding) { fprintf(stderr, " transcoding rate %.0f kbps", (double)numTransCodingBytes * 8.0 * (sampFreqKHz) / totalsmpls); } fclose(inp); fclose(outp); WebRtcIsac_Free(ISAC_main_inst); exit(0); }