void Transcode(CStdString &file)
{
OrkLogManager::Instance()->Initialize();
ObjectFactory::GetSingleton()->Initialize();
ConfigManager::Instance()->Initialize();
std::list<ACE_DLL> pluginDlls;
LoadPlugins(pluginDlls);
// Register in-built filters
FilterRef filter(new AlawToPcmFilter());
FilterRegistry::instance()->RegisterFilter(filter);
filter.reset(new UlawToPcmFilter());
FilterRegistry::instance()->RegisterFilter(filter);
filter.reset(new GsmToPcmFilter());
FilterRegistry::instance()->RegisterFilter(filter);
filter.reset(new IlbcToPcmFilter());
FilterRegistry::instance()->RegisterFilter(filter);
filter.reset(new AudioGainFilter());
FilterRegistry::instance()->RegisterFilter(filter);
filter.reset(new G722ToPcmFilter());
FilterRegistry::instance()->RegisterFilter(filter);
filter.reset(new SpeexDecoder() );
FilterRegistry::instance()->RegisterFilter(filter);
filter.reset(new G721CodecDecoder());
FilterRegistry::instance()->RegisterFilter(filter);
// Register in-built tape processors and build the processing chain
BatchProcessing::Initialize();
Reporting::Initialize();
TapeFileNaming::Initialize();
if (!ACE_Thread_Manager::instance()->spawn(ACE_THR_FUNC(BatchProcessing::ThreadHandler)))
{
LOG4CXX_INFO(LOG.rootLog, CStdString("Failed to create batch processing thread"));
}
// Transmit the tape to the BatchProcessing
CStdString ProcessorName("BatchProcessing");
TapeProcessorRef bp = TapeProcessorRegistry::instance()->GetNewTapeProcessor(ProcessorName);
CStdString portName("SinglePort");
AudioTapeRef tape(new AudioTape(portName, file));
bp->AddAudioTape(tape);
// Make sure it stops after processing
tape.reset();
bp->AddAudioTape(tape);
// Wait for completion
while(!Daemon::Singleton()->IsStopping())
{
ACE_OS::sleep(1);
}
}
int main () {
// test InstructionSet()
printf("\nInstructionSet = %i", InstructionSet());
// test cpuid_abcd
int abcd[4]; char s[16];
cpuid_abcd(abcd, 0);
*(int*)(s+0) = abcd[1]; // ebx
*(int*)(s+4) = abcd[3]; // edx
*(int*)(s+8) = abcd[2]; // ecx
s[12] = 0; // terminate string
printf("\nVendor string = %s", s);
// test ProcessorName()
printf("\nProcessorName = %s", ProcessorName());
// test CpuType
int vendor, family, model;
CpuType(&vendor, &family, &model);
printf("\nCpuType: vendor %i, family 0x%X, model 0x%X", vendor, family, model);
// test DataCacheSize
printf("\nData cache size: L1 %ikb, L2 %ikb, L3 %ikb",
(int)DataCacheSize(1)/1024, (int)DataCacheSize(2)/1024, (int)DataCacheSize(3)/1024);
// test ReadTSC()
ReadTSC();
int tsc = (int)ReadTSC();
tsc = (int)ReadTSC() - tsc;
printf("\nReadTSC takes %i clocks\n\n", tsc);
// test Round();
double d;
for (d = -1; d <= 1; d += 0.5) {
printf("Round %f = %i = %i\n", d, Round(d), Round(float(d)));
}
// Test memory and string functions
int i, n;
const int strsize = 256;
char string1[strsize], string2[strsize];
const char * teststring = "abcdefghijklmnopqrstuvwxyz ABCDEFGHIJKLMNOPQRSTUVWXYZ 1234567890 @`'{}[]()<>";
// Initialize strings
A_memset(string1, 0, strsize);
A_memset(string2, 0, strsize);
// Test A_strcpy, A_strcat, A_strlen
A_strcpy(string1, teststring);
n = strsize/(int)A_strlen(teststring);
for (i = 0; i < n-1; i++) {
A_strcat(string1, teststring);
}
if (A_strlen(string1) != n * A_strlen(teststring)) Failure("A_strcpy, A_strcat, A_strlen");
// Test A_stricmp
A_memcpy(string2, string1, strsize);
string2[4] ^= 0x20; string1[30] ^= 0x20; // Change case
if (A_stricmp(string1, string2) != 0) Failure("A_stricmp");
string2[8] += 2; // Make strings different
if (A_stricmp(string1, string2) >= 0) Failure("A_stricmp");
string2[7] -= 2; // Make strings different
if (A_stricmp(string1, string2) <= 0) Failure("A_stricmp");
// test A_strtolower and A_strtoupper
A_strcpy(string1, teststring);
A_strcpy(string2, teststring);
A_strtolower(string1);
A_strtoupper(string2);
printf("\nstring converted to lower and upper case:\n%s\n%s\n%s",
teststring, string1, string2);
// test strspn and strcspn
int n1, n2;
const int nset = 4;
const char * tset[] = {"abc", "", "01234567890123456789", "abcdefghijklmnopqrstuvwxyz"};
for (i = 0; i < nset; i++) {
n1 = A_strspn(teststring, tset[i]);
n2 = strspn(teststring, tset[i]);
if (n1 != n2) Failure("A_strspn");
n1 = A_strcspn(teststring, tset[i]);
n2 = strcspn(teststring, tset[i]);
if (n1 != n2) Failure("A_strcspn");
}
// Test A_memmove with overlapping source and destination
A_memcpy(string2, string1, strsize);
A_memcpy(string1+5, string1+12, 12);
memcpy (string2+5, string2+12, 12);
if (A_stricmp(string1, string2) != 0) Failure("memcpy");
A_memcpy(string1+5, string1+12, 130);
memcpy (string2+5, string2+12, 130);
if (A_stricmp(string1, string2) != 0) Failure("memcpy");
A_memmove(string1+5, string1+2, 12);
memmove (string2+5, string2+2, 12);
if (A_stricmp(string1, string2) != 0) Failure("A_memmove");
A_memmove(string1+3, string1+8, 12);
memmove (string2+3, string2+8, 12);
if (A_stricmp(string1, string2) != 0) Failure("A_memmove");
A_memmove(string1+41, string1+30, 100);
memmove (string2+41, string2+30, 100);
if (A_stricmp(string1, string2) != 0) Failure("A_memmove");
A_memmove(string1+32, string1+48, 177);
memmove (string2+32, string2+48, 177);
if (A_stricmp(string1, string2) != 0) Failure("A_memmove");
printf("\n\nTests passed OK\n");
return 0;
}
