zqz/platform-external-webrtc
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity

Formatting ACM tests

Browse Source 
Pure formatting of all files located in /webrtc/modules/audio_coding/main/test/

Smaller manual modifications done after using Eclipse formatting tool, like wrapping long lines (mostly comments).

BUG=issue1024

Review URL: https://webrtc-codereview.appspot.com/1342004

git-svn-id: http://webrtc.googlecode.com/svn/trunk@3946 4adac7df-926f-26a2-2b94-8c16560cd09d
This commit is contained in:
tina.legrand@webrtc.org
2013-05-03 07:34:12 +00:00
parent 03efc89151
commit d5726a1286
34 changed files with 4385 additions and 5230 deletions
Download Patch File Download Diff File Expand all files Collapse all files

635
webrtc/modules/audio_coding/main/test/utility.cc
View File

@ -23,413 +23,310 @@
namespace webrtc {
ACMTestTimer::ACMTestTimer() :
_msec(0),
_sec(0),
_min(0),
_hour(0)
{
return;
ACMTestTimer::ACMTestTimer()
: _msec(0),
_sec(0),
_min(0),
_hour(0) {
return;
}
ACMTestTimer::~ACMTestTimer()
{
return;
ACMTestTimer::~ACMTestTimer() {
return;
}
void ACMTestTimer::Reset()
{
_msec = 0;
_sec = 0;
_min = 0;
_hour = 0;
return;
void ACMTestTimer::Reset() {
_msec = 0;
_sec = 0;
_min = 0;
_hour = 0;
return;
}
void ACMTestTimer::Tick10ms()
{
_msec += 10;
Adjust();
return;
void ACMTestTimer::Tick10ms() {
_msec += 10;
Adjust();
return;
}
void ACMTestTimer::Tick1ms()
{
_msec++;
Adjust();
return;
void ACMTestTimer::Tick1ms() {
_msec++;
Adjust();
return;
}
void ACMTestTimer::Tick100ms()
{
_msec += 100;
Adjust();
return;
void ACMTestTimer::Tick100ms() {
_msec += 100;
Adjust();
return;
}
void ACMTestTimer::Tick1sec()
{
_sec++;
Adjust();
return;
void ACMTestTimer::Tick1sec() {
_sec++;
Adjust();
return;
}
void ACMTestTimer::CurrentTimeHMS(char* currTime)
{
sprintf(currTime, "%4lu:%02u:%06.3f", _hour, _min, (double)_sec + (double)_msec / 1000.);
return;
void ACMTestTimer::CurrentTimeHMS(char* currTime) {
sprintf(currTime, "%4lu:%02u:%06.3f", _hour, _min,
(double) _sec + (double) _msec / 1000.);
return;
}
void ACMTestTimer::CurrentTime(
unsigned long& h,
unsigned char& m,
unsigned char& s,
unsigned short& ms)
{
h = _hour;
m = _min;
s = _sec;
ms = _msec;
return;
void ACMTestTimer::CurrentTime(unsigned long& h, unsigned char& m,
unsigned char& s, unsigned short& ms) {
h = _hour;
m = _min;
s = _sec;
ms = _msec;
return;
}
void ACMTestTimer::Adjust()
{
unsigned int n;
if(_msec >= 1000)
{
n = _msec / 1000;
_msec -= (1000 * n);
_sec += n;
}
if(_sec >= 60)
{
n = _sec / 60;
_sec -= (n * 60);
_min += n;
}
if(_min >= 60)
{
n = _min / 60;
_min -= (n * 60);
_hour += n;
void ACMTestTimer::Adjust() {
unsigned int n;
if (_msec >= 1000) {
n = _msec / 1000;
_msec -= (1000 * n);
_sec += n;
}
if (_sec >= 60) {
n = _sec / 60;
_sec -= (n * 60);
_min += n;
}
if (_min >= 60) {
n = _min / 60;
_min -= (n * 60);
_hour += n;
}
}
int16_t ChooseCodec(CodecInst& codecInst) {
PrintCodecs();
//AudioCodingModule* tmpACM = AudioCodingModule::Create(0);
uint8_t noCodec = AudioCodingModule::NumberOfCodecs();
int8_t codecID;
bool outOfRange = false;
char myStr[15] = "";
do {
printf("\nChoose a codec [0]: ");
EXPECT_TRUE(fgets(myStr, 10, stdin) != NULL);
codecID = atoi(myStr);
if ((codecID < 0) || (codecID >= noCodec)) {
printf("\nOut of range.\n");
outOfRange = true;
}
} while (outOfRange);
CHECK_ERROR(AudioCodingModule::Codec((uint8_t )codecID, &codecInst));
return 0;
}
void PrintCodecs() {
uint8_t noCodec = AudioCodingModule::NumberOfCodecs();
int16_t
ChooseCodec(
CodecInst& codecInst)
{
CodecInst codecInst;
printf("No Name [Hz] [bps]\n");
for (uint8_t codecCntr = 0; codecCntr < noCodec; codecCntr++) {
AudioCodingModule::Codec(codecCntr, &codecInst);
printf("%2d- %-18s %5d %6d\n", codecCntr, codecInst.plname,
codecInst.plfreq, codecInst.rate);
}
PrintCodecs();
//AudioCodingModule* tmpACM = AudioCodingModule::Create(0);
uint8_t noCodec = AudioCodingModule::NumberOfCodecs();
int8_t codecID;
bool outOfRange = false;
char myStr[15] = "";
do
{
printf("\nChoose a codec [0]: ");
EXPECT_TRUE(fgets(myStr, 10, stdin) != NULL);
codecID = atoi(myStr);
if((codecID < 0) || (codecID >= noCodec))
{
printf("\nOut of range.\n");
outOfRange = true;
}
} while(outOfRange);
}
CHECK_ERROR(AudioCodingModule::Codec((uint8_t)codecID, &codecInst));
CircularBuffer::CircularBuffer(uint32_t len)
: _buff(NULL),
_idx(0),
_buffIsFull(false),
_calcAvg(false),
_calcVar(false),
_sum(0),
_sumSqr(0) {
_buff = new double[len];
if (_buff == NULL) {
_buffLen = 0;
} else {
for (uint32_t n = 0; n < len; n++) {
_buff[n] = 0;
}
_buffLen = len;
}
}
CircularBuffer::~CircularBuffer() {
if (_buff != NULL) {
delete[] _buff;
_buff = NULL;
}
}
void CircularBuffer::Update(const double newVal) {
assert(_buffLen > 0);
// store the value that is going to be overwritten
double oldVal = _buff[_idx];
// record the new value
_buff[_idx] = newVal;
// increment the index, to point to where we would
// write next
_idx++;
// it is a circular buffer, if we are at the end
// we have to cycle to the beginning
if (_idx >= _buffLen) {
// flag that the buffer is filled up.
_buffIsFull = true;
_idx = 0;
}
// Update
if (_calcAvg) {
// for the average we have to update
// the sum
_sum += (newVal - oldVal);
}
if (_calcVar) {
// to calculate variance we have to update
// the sum of squares
_sumSqr += (double) (newVal - oldVal) * (double) (newVal + oldVal);
}
}
void CircularBuffer::SetArithMean(bool enable) {
assert(_buffLen > 0);
if (enable && !_calcAvg) {
uint32_t lim;
if (_buffIsFull) {
lim = _buffLen;
} else {
lim = _idx;
}
_sum = 0;
for (uint32_t n = 0; n < lim; n++) {
_sum += _buff[n];
}
}
_calcAvg = enable;
}
void CircularBuffer::SetVariance(bool enable) {
assert(_buffLen > 0);
if (enable && !_calcVar) {
uint32_t lim;
if (_buffIsFull) {
lim = _buffLen;
} else {
lim = _idx;
}
_sumSqr = 0;
for (uint32_t n = 0; n < lim; n++) {
_sumSqr += _buff[n] * _buff[n];
}
}
_calcAvg = enable;
}
int16_t CircularBuffer::ArithMean(double& mean) {
assert(_buffLen > 0);
if (_buffIsFull) {
mean = _sum / (double) _buffLen;
return 0;
} else {
if (_idx > 0) {
mean = _sum / (double) _idx;
return 0;
} else {
return -1;
}
}
}
void
PrintCodecs()
{
uint8_t noCodec = AudioCodingModule::NumberOfCodecs();
int16_t CircularBuffer::Variance(double& var) {
assert(_buffLen > 0);
CodecInst codecInst;
printf("No Name [Hz] [bps]\n");
for(uint8_t codecCntr = 0; codecCntr < noCodec; codecCntr++)
{
AudioCodingModule::Codec(codecCntr, &codecInst);
printf("%2d- %-18s %5d %6d\n",
codecCntr, codecInst.plname, codecInst.plfreq, codecInst.rate);
}
}
CircularBuffer::CircularBuffer(uint32_t len):
_buff(NULL),
_idx(0),
_buffIsFull(false),
_calcAvg(false),
_calcVar(false),
_sum(0),
_sumSqr(0)
{
_buff = new double[len];
if(_buff == NULL)
{
_buffLen = 0;
}
else
{
for(uint32_t n = 0; n < len; n++)
{
_buff[n] = 0;
}
_buffLen = len;
}
}
CircularBuffer::~CircularBuffer()
{
if(_buff != NULL)
{
delete [] _buff;
_buff = NULL;
}
}
void
CircularBuffer::Update(
const double newVal)
{
assert(_buffLen > 0);
// store the value that is going to be overwritten
double oldVal = _buff[_idx];
// record the new value
_buff[_idx] = newVal;
// increment the index, to point to where we would
// write next
_idx++;
// it is a circular buffer, if we are at the end
// we have to cycle to the beginning
if(_idx >= _buffLen)
{
// flag that the buffer is filled up.
_buffIsFull = true;
_idx = 0;
}
// Update
if(_calcAvg)
{
// for the average we have to update
// the sum
_sum += (newVal - oldVal);
}
if(_calcVar)
{
// to calculate variance we have to update
// the sum of squares
_sumSqr += (double)(newVal - oldVal) * (double)(newVal + oldVal);
}
}
void
CircularBuffer::SetArithMean(
bool enable)
{
assert(_buffLen > 0);
if(enable && !_calcAvg)
{
uint32_t lim;
if(_buffIsFull)
{
lim = _buffLen;
}
else
{
lim = _idx;
}
_sum = 0;
for(uint32_t n = 0; n < lim; n++)
{
_sum += _buff[n];
}
}
_calcAvg = enable;
}
void
CircularBuffer::SetVariance(
bool enable)
{
assert(_buffLen > 0);
if(enable && !_calcVar)
{
uint32_t lim;
if(_buffIsFull)
{
lim = _buffLen;
}
else
{
lim = _idx;
}
_sumSqr = 0;
for(uint32_t n = 0; n < lim; n++)
{
_sumSqr += _buff[n] * _buff[n];
}
}
_calcAvg = enable;
}
int16_t
CircularBuffer::ArithMean(double& mean)
{
assert(_buffLen > 0);
if(_buffIsFull)
{
mean = _sum / (double)_buffLen;
return 0;
}
else
{
if(_idx > 0)
{
mean = _sum / (double)_idx;
return 0;
}
else
{
return -1;
}
}
}
int16_t
CircularBuffer::Variance(double& var)
{
assert(_buffLen > 0);
if(_buffIsFull)
{
var = _sumSqr / (double)_buffLen;
return 0;
}
else
{
if(_idx > 0)
{
var = _sumSqr / (double)_idx;
return 0;
}
else
{
return -1;
}
}
}
bool
FixedPayloadTypeCodec(const char* payloadName)
{
char fixPayloadTypeCodecs[NUM_CODECS_WITH_FIXED_PAYLOAD_TYPE][32] = {
"PCMU",
"PCMA",
"GSM",
"G723",
"DVI4",
"LPC",
"PCMA",
"G722",
"QCELP",
"CN",
"MPA",
"G728",
"G729"
};
for(int n = 0; n < NUM_CODECS_WITH_FIXED_PAYLOAD_TYPE; n++)
{
if(!STR_CASE_CMP(payloadName, fixPayloadTypeCodecs[n]))
{
return true;
}
}
return false;
}
DTMFDetector::DTMFDetector()
{
for(int16_t n = 0; n < 1000; n++)
{
_toneCntr[n] = 0;
}
}
DTMFDetector::~DTMFDetector()
{
}
int32_t DTMFDetector::IncomingDtmf(const uint8_t digitDtmf, const bool /* toneEnded */)
{
fprintf(stdout, "%d-",digitDtmf);
_toneCntr[digitDtmf]++;
if (_buffIsFull) {
var = _sumSqr / (double) _buffLen;
return 0;
}
void DTMFDetector::PrintDetectedDigits()
{
for(int16_t n = 0; n < 1000; n++)
{
if(_toneCntr[n] > 0)
{
fprintf(stdout, "%d %u msec, \n", n, _toneCntr[n]*10);
}
} else {
if (_idx > 0) {
var = _sumSqr / (double) _idx;
return 0;
} else {
return -1;
}
fprintf(stdout, "\n");
return;
}
}
void
VADCallback::Reset()
{
for(int n = 0; n < 6; n++)
{
_numFrameTypes[n] = 0;
bool FixedPayloadTypeCodec(const char* payloadName) {
char fixPayloadTypeCodecs[NUM_CODECS_WITH_FIXED_PAYLOAD_TYPE][32] = { "PCMU",
"PCMA", "GSM", "G723", "DVI4", "LPC", "PCMA", "G722", "QCELP", "CN",
"MPA", "G728", "G729" };
for (int n = 0; n < NUM_CODECS_WITH_FIXED_PAYLOAD_TYPE; n++) {
if (!STR_CASE_CMP(payloadName, fixPayloadTypeCodecs[n])) {
return true;
}
}
return false;
}
VADCallback::VADCallback()
{
for(int n = 0; n < 6; n++)
{
_numFrameTypes[n] = 0;
DTMFDetector::DTMFDetector() {
for (int16_t n = 0; n < 1000; n++) {
_toneCntr[n] = 0;
}
}
DTMFDetector::~DTMFDetector() {
}
int32_t DTMFDetector::IncomingDtmf(const uint8_t digitDtmf,
const bool /* toneEnded */) {
fprintf(stdout, "%d-", digitDtmf);
_toneCntr[digitDtmf]++;
return 0;
}
void DTMFDetector::PrintDetectedDigits() {
for (int16_t n = 0; n < 1000; n++) {
if (_toneCntr[n] > 0) {
fprintf(stdout, "%d %u msec, \n", n, _toneCntr[n] * 10);
}
}
fprintf(stdout, "\n");
return;
}
void
VADCallback::PrintFrameTypes()
{
fprintf(stdout, "No encoding.................. %d\n", _numFrameTypes[0]);
fprintf(stdout, "Active normal encoded........ %d\n", _numFrameTypes[1]);
fprintf(stdout, "Passive normal encoded....... %d\n", _numFrameTypes[2]);
fprintf(stdout, "Passive DTX wideband......... %d\n", _numFrameTypes[3]);
fprintf(stdout, "Passive DTX narrowband....... %d\n", _numFrameTypes[4]);
fprintf(stdout, "Passive DTX super-wideband... %d\n", _numFrameTypes[5]);
void VADCallback::Reset() {
for (int n = 0; n < 6; n++) {
_numFrameTypes[n] = 0;
}
}
int32_t
VADCallback::InFrameType(
int16_t frameType)
{
_numFrameTypes[frameType]++;
return 0;
VADCallback::VADCallback() {
for (int n = 0; n < 6; n++) {
_numFrameTypes[n] = 0;
}
}
} // namespace webrtc
void VADCallback::PrintFrameTypes() {
fprintf(stdout, "No encoding.................. %d\n", _numFrameTypes[0]);
fprintf(stdout, "Active normal encoded........ %d\n", _numFrameTypes[1]);
fprintf(stdout, "Passive normal encoded....... %d\n", _numFrameTypes[2]);
fprintf(stdout, "Passive DTX wideband......... %d\n", _numFrameTypes[3]);
fprintf(stdout, "Passive DTX narrowband....... %d\n", _numFrameTypes[4]);
fprintf(stdout, "Passive DTX super-wideband... %d\n", _numFrameTypes[5]);
}
int32_t VADCallback::InFrameType(int16_t frameType) {
_numFrameTypes[frameType]++;
return 0;
}
} // namespace webrtc