int main(int argc, char* argv[])
{
TAppEncTop cTAppEncTop;
// print information
fprintf( stdout, "\n" );
fprintf( stdout, "HM software: Encoder Version [%s] (including RExt)", NV_VERSION );
fprintf( stdout, NVM_ONOS );
fprintf( stdout, NVM_COMPILEDBY );
fprintf( stdout, NVM_BITS );
fprintf( stdout, "\n\n" );
// create application encoder class
cTAppEncTop.create();
// parse configuration
try
{
if(!cTAppEncTop.parseCfg( argc, argv ))
{
cTAppEncTop.destroy();
#if ENVIRONMENT_VARIABLE_DEBUG_AND_TEST
EnvVar::printEnvVar();
#endif
return 1;
}
}
catch (df::program_options_lite::ParseFailure &e)
{
std::cerr << "Error parsing option \""<< e.arg <<"\" with argument \""<< e.val <<"\"." << std::endl;
return 1;
}
#if PRINT_MACRO_VALUES
printMacroSettings();
#endif
#if ENVIRONMENT_VARIABLE_DEBUG_AND_TEST
EnvVar::printEnvVarInUse();
#endif
// starting time
Double dResult;
clock_t lBefore = clock();
// call encoding function
cTAppEncTop.encode();
// ending time
dResult = (Double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
// destroy application encoder class
cTAppEncTop.destroy();
return 0;
}
int main(int argc, char* argv[])
{
TAppEncTop cTAppEncTop;
// print information
fprintf( stdout, "\n" );
fprintf( stdout, "HM software: Encoder Version [%s]", NV_VERSION );
fprintf( stdout, NVM_ONOS );
fprintf( stdout, NVM_COMPILEDBY );
fprintf( stdout, NVM_BITS );
fprintf( stdout, "\n" );
// create application encoder class
cTAppEncTop.create();
// parse configuration
try
{
if(!cTAppEncTop.parseCfg( argc, argv ))
{
cTAppEncTop.destroy();
return 1;
}
}
catch (po::ParseFailure& e)
{
cerr << "Error parsing option \""<< e.arg <<"\" with argument \""<< e.val <<"\"." << endl;
return 1;
}
//Felipe: static classes initialization
// starting time
double dResult;
long lBefore = clock();
// call encoding function
cTAppEncTop.encode();
// ending time
dResult = (double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
//Felipe
finalizeStaticClasses();
// destroy application encoder class
cTAppEncTop.destroy();
return 0;
}
int main(int argc, char* argv[])
{
TAppEncTop cTAppEncTop;
// print information
fprintf( stdout, "\n" );
fprintf( stdout, "HM software: Encoder Version [%s]", NV_VERSION );
fprintf( stdout, NVM_ONOS );
fprintf( stdout, NVM_COMPILEDBY );
fprintf( stdout, NVM_BITS );
fprintf( stdout, "\n" );
//FELIPE BEGIN
FileWriter::init(PU_CHOICES_FILE, "outputs/pu_choices.txt");
FileWriter::init(PU_DECISION_PARAMS_FILE, "outputs/pu_params.txt");
StatsManager::init();
// create application encoder class
cTAppEncTop.create();
// parse configuration
if(!cTAppEncTop.parseCfg( argc, argv ))
{
cTAppEncTop.destroy();
return 1;
}
// starting time
double dResult;
long lBefore = clock();
// call encoding function
cTAppEncTop.encode();
// ending time
dResult = (double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
// destroy application encoder class
cTAppEncTop.destroy();
//FELIPE BEGIN
FileWriter::print(PU_CHOICES_FILE,"%s", StatsManager::reportPUChoices().c_str());
FileWriter::close(PU_CHOICES_FILE);
FileWriter::close(PU_DECISION_PARAMS_FILE);
return 0;
}
int main(int argc, char* argv[])
{
TAppEncTop cTAppEncTop;
// print information
fprintf( stdout, "\n" );
fprintf( stdout, "HM software: Encoder Version [%s]", NV_VERSION );
fprintf( stdout, NVM_ONOS );
fprintf( stdout, NVM_COMPILEDBY );
fprintf( stdout, NVM_BITS );
fprintf( stdout, "\n" );
// create application encoder class
cTAppEncTop.create();
// parse configuration
if(!cTAppEncTop.parseCfg( argc, argv ))
{
cTAppEncTop.destroy();
return 1;
}
// starting time
double dResult;
long lBefore = clock();
// call encoding function
cTAppEncTop.encode();
// ending time
dResult = (double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
// destroy application encoder class
cTAppEncTop.destroy();
return 0;
}
int main(int argc, char* argv[])
{
TAppEncTop cTAppEncTop;
nameFile = argv[9];
// print information
fprintf( stdout, "\n" );
fprintf( stdout, "HM software: Encoder Version [%s] (including RExt)", NV_VERSION );
fprintf( stdout, NVM_ONOS );
fprintf( stdout, NVM_COMPILEDBY );
fprintf( stdout, NVM_BITS );
fprintf( stdout, "\n\n" );
ofstream outfile;
outfile.open((nameFile + ".txt").c_str(),ios::out);
outfile.close();
// create application encoder class
cTAppEncTop.create();
// parse configuration
try
{
if(!cTAppEncTop.parseCfg( argc, argv ))
{
cTAppEncTop.destroy();
#if ENVIRONMENT_VARIABLE_DEBUG_AND_TEST
EnvVar::printEnvVar();
#endif
return 1;
}
}
catch (df::program_options_lite::ParseFailure &e)
{
std::cerr << "Error parsing option \""<< e.arg <<"\" with argument \""<< e.val <<"\"." << std::endl;
return 1;
}
#if PRINT_MACRO_VALUES
printMacroSettings();
#endif
#if ENVIRONMENT_VARIABLE_DEBUG_AND_TEST
EnvVar::printEnvVarInUse();
#endif
// starting time
Double dResult;
clock_t lBefore = clock();
// call encoding function
cTAppEncTop.encode();
// ending time
dResult = (Double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
ofstream timeTabs,countTabs;
timeTabs.open(("time_" + nameFile + ".csv").c_str(),ios::out);
countTabs.open(("count_" + nameFile + ".csv").c_str(),ios::out);
dResult = (Double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
// timeTabs << "Tempo;" << ((Double)(totalCount)) << endl;
// timeTabs << "Tempo intra;" << ((Double)(intraCount)) << endl;
// timeTabs << "Tempo intraCSC;" << ((Double)(intraCSCount)) << endl;
// timeTabs << "Tempo intraPCM;" << ((Double)(intraPCMCount)) << endl;
// timeTabs << "Tempo inter;" << ((Double)(interCount)) << endl;
// timeTabs << "Tempo intraBC;" << ((Double)(intraBCCount)) << endl;
// timeTabs << "Tempo hash inter;" << ((Double)(HashInterCount)) << endl;
// timeTabs << "Tempo palette;" <<((Double)(PalletMCount)) << endl;
timeTabs << ((Double)(totalCount)) << ";" << ((Double)(intraCount)) << ";" << ((Double)(interCount)) << ";" << ((Double)(intraBCCount)) << ";" << ((Double)(HashInterCount)) << ";" << ((Double)(PalletMCount));
//timeTabs << endl;
// countTabs << "Total CUs;" << totalCuCount << endl;
// countTabs << "Intra CUs;" << intraCuCount << endl;
// countTabs << "IntraBC CUs;" << ibcCuCount << endl;
// countTabs << "Palette CUs;" << pltCuCount << endl;
// countTabs << "Skip CUs;" << skipCount << endl;
// countTabs << "??? CUs;" << unIdCount << endl;
countTabs << totalCuCount << ";" << intraCuCount << ";" << ibcCuCount << ";" << pltCuCount << ";" << skipCount << ";" << unIdCount;
// destroy application encoder class
// destroy application encoder class
cTAppEncTop.destroy();
return 0;
}
/* return the encoded data in *pbuf and the size. Return < 0 if error */
int jctvc_encode_picture(uint8_t **pbuf, Image *img,
const HEVCEncodeParams *params)
{
TAppEncTop cTAppEncTop;
int argc;
char *argv[ARGV_MAX + 1];
char buf[1024], infilename[1024], outfilename[1024];
const char *str;
FILE *f;
uint8_t *out_buf;
int out_buf_len, i;
#ifdef WIN32
if (GetTempPath(sizeof(buf), buf) > sizeof(buf) - 1) {
fprintf(stderr, "Temporary path too long\n");
return -1;
}
#else
strcpy(buf, "/tmp/");
#endif
snprintf(infilename, sizeof(infilename), "%sout%d.yuv", buf, getpid());
snprintf(outfilename, sizeof(outfilename), "%sout%d.bin", buf, getpid());
save_yuv(img, infilename);
m_gcAnalyzeAll.clear();
m_gcAnalyzeI.clear();
m_gcAnalyzeP.clear();
m_gcAnalyzeB.clear();
m_gcAnalyzeAll_in.clear();
cTAppEncTop.create();
argc = 0;
add_opt(&argc, argv, "jctvc"); /* dummy executable name */
snprintf(buf, sizeof(buf),"--InputFile=%s", infilename);
add_opt(&argc, argv, buf);
snprintf(buf, sizeof(buf),"--BitstreamFile=%s", outfilename);
add_opt(&argc, argv, buf);
snprintf(buf, sizeof(buf),"--SourceWidth=%d", img->w);
add_opt(&argc, argv, buf);
snprintf(buf, sizeof(buf),"--SourceWidth=%d", img->w);
add_opt(&argc, argv, buf);
snprintf(buf, sizeof(buf),"--SourceHeight=%d", img->h);
add_opt(&argc, argv, buf);
snprintf(buf, sizeof(buf),"--InputBitDepth=%d", img->bit_depth);
add_opt(&argc, argv, buf);
switch(img->format) {
case BPG_FORMAT_GRAY:
str = "400";
break;
case BPG_FORMAT_420:
str = "420";
break;
case BPG_FORMAT_422:
str = "422";
break;
case BPG_FORMAT_444:
str = "444";
break;
default:
abort();
}
snprintf(buf, sizeof(buf),"--InputChromaFormat=%s", str);
add_opt(&argc, argv, buf);
snprintf(buf, sizeof(buf),"--QP=%d", params->qp);
add_opt(&argc, argv, buf);
snprintf(buf, sizeof(buf),"--SEIDecodedPictureHash=%d",
params->sei_decoded_picture_hash);
add_opt(&argc, argv, buf);
if (!params->verbose)
add_opt(&argc, argv, "--Verbose=0");
/* single frame */
add_opt(&argc, argv, "--FramesToBeEncoded=1");
/* no padding necessary (it is done before) */
add_opt(&argc, argv, "--ConformanceWindowMode=0");
/* dummy frame rate */
add_opt(&argc, argv, "--FrameRate=25");
/* general config */
add_opt(&argc, argv, "--Profile=main_444_16_intra");
add_opt(&argc, argv, "--QuadtreeTULog2MaxSize=5");
add_opt(&argc, argv, "--QuadtreeTUMaxDepthIntra=3");
add_opt(&argc, argv, "--IntraPeriod=1");
add_opt(&argc, argv, "--GOPSize=1");
add_opt(&argc, argv, "--TransformSkip=1");
add_opt(&argc, argv, "--TransformSkipFast=1");
/* Note: Format Range extension */
if (img->format == BPG_FORMAT_444) {
add_opt(&argc, argv, "--CrossComponentPrediction=1");
}
if (params->lossless) {
add_opt(&argc, argv, "--CostMode=lossless");
add_opt(&argc, argv, "--SAO=0");
add_opt(&argc, argv, "--LoopFilterDisable");
add_opt(&argc, argv, "--TransquantBypassEnableFlag");
add_opt(&argc, argv, "--CUTransquantBypassFlagForce");
add_opt(&argc, argv, "--ImplicitResidualDPCM");
add_opt(&argc, argv, "--GolombRiceParameterAdaptation");
add_opt(&argc, argv, "--HadamardME=0");
}
/* trailing NULL */
argv[argc] = NULL;
if (params->verbose >= 2) {
int i;
printf("Encode options:");
for(i = 0; i < argc; i++) {
printf(" %s", argv[i]);
}
printf("\n");
}
if(!cTAppEncTop.parseCfg( argc, argv )) {
fprintf(stderr, "Error while parsing options\n");
cTAppEncTop.destroy();
return -1;
}
cTAppEncTop.encode();
cTAppEncTop.destroy();
for(i = 0; i < argc; i++)
free(argv[i]);
unlink(infilename);
/* read output bitstream */
f = fopen(outfilename, "rb");
if (!f) {
fprintf(stderr, "Could not open '%s'\n", outfilename);
return -1;
}
fseek(f, 0, SEEK_END);
out_buf_len = ftell(f);
fseek(f, 0, SEEK_SET);
out_buf = (uint8_t *)malloc(out_buf_len);
if (fread(out_buf, 1, out_buf_len, f) != out_buf_len) {
fprintf(stderr, "read error\n");
fclose(f);
free(out_buf);
return -1;
}
fclose(f);
unlink(outfilename);
*pbuf = out_buf;
return out_buf_len;
}
//DANIEL END
int main(int argc, char* argv[])
{
TAppEncTop cTAppEncTop;
// print information
fprintf( stdout, "\n" );
fprintf( stdout, "HM software: Encoder Version [%s]", NV_VERSION );
fprintf( stdout, NVM_ONOS );
fprintf( stdout, NVM_COMPILEDBY );
fprintf( stdout, NVM_BITS );
fprintf( stdout, "\n" );
// create application encoder class
cTAppEncTop.create();
// parse configuration
if(!cTAppEncTop.parseCfg( argc, argv ))
{
cTAppEncTop.destroy();
return 1;
}
//DANIEL BEGIN
int file;
modes = fopen("modes", "w");
results = fopen("results","w");
if (mySearch)
{
input_modes = fopen("input_modes","r");
file = fscanf(input_modes,"%d",&level8);
file = fscanf(input_modes,"%d",&level16);
file = fscanf(input_modes,"%d",&level32);
file = fscanf(input_modes,"%d",&level64);
}
//DANIEL END
// starting time
double dResult;
long lBefore = clock();
//DANIEL BEGIN
double diff_time;
static struct timeval timer_start, timer_end;
gettimeofday(&timer_start, NULL);
//DANIEL END
// call encoding function
cTAppEncTop.encode();
// ending time
dResult = (double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
//DANIEL BEGIN
gettimeofday(&timer_end,NULL);
diff_time = timer_end.tv_sec - timer_start.tv_sec + (timer_end.tv_usec - timer_start.tv_usec) / 1000000.0;
// destroy application encoder class
cTAppEncTop.destroy();
//DANIEL BEGIN
fprintf(results,"%.3f\n",diff_time);
fclose(modes);
fclose(results);
if(mySearch)
fclose(input_modes);
//DANIEL END
return 0;
}
int main(int argc, char* argv[])
{
TAppEncTop cTAppEncTop;
//DI BEGIN
floatingClass acessAppEncTop;
//DI END
//DANIEL BEGIN
time_perCU = fopen("time_perCU.txt","w");
time_perTile = fopen("time_perTile.csv","w");
//DANIEL END
// print information
fprintf( stdout, "\n" );
fprintf( stdout, "HM software: Encoder Version [%s] (including RExt)", NV_VERSION );
fprintf( stdout, NVM_ONOS );
fprintf( stdout, NVM_COMPILEDBY );
fprintf( stdout, NVM_BITS );
fprintf( stdout, "\n\n" );
// create application encoder class
cTAppEncTop.create();
// parse configuration
try
{
if(!cTAppEncTop.parseCfg( argc, argv ))
{
cTAppEncTop.destroy();
#if RExt__ENVIRONMENT_VARIABLE_DEBUG_AND_TEST
EnvVar::printEnvVar();
#endif
return 1;
}
}
catch (df::program_options_lite::ParseFailure &e)
{
std::cerr << "Error parsing option \""<< e.arg <<"\" with argument \""<< e.val <<"\"." << std::endl;
return 1;
}
#if RExt__PRINT_MACRO_VALUES
printRExtMacroSettings();
#endif
#if RExt__ENVIRONMENT_VARIABLE_DEBUG_AND_TEST
EnvVar::printEnvVarInUse();
#endif
// starting time
Double dResult;
clock_t lBefore = clock();
// call encoding function
//DI BEGIN
//Adicionando parametros no encode
cTAppEncTop.encode(&acessAppEncTop);
printf("Dado TAppEncTop_v2: %d\n", acessAppEncTop.getMaxTlayer());
printf("Dado TEncTop_v2: %d\n", acessAppEncTop.getTestEncTop());
printf("Dado TEncGOP_v2: %d\n", acessAppEncTop.getTestGOP());
//DI END
// ending time
dResult = (Double)(clock()-lBefore) / CLOCKS_PER_SEC;
printf("\n Total Time: %12.3f sec.\n", dResult);
// destroy application encoder class
cTAppEncTop.destroy();
if(!flagUniformSpc) //Cauane
{
inputTileInfo.close();
}
return 0;
}
