namespace DataKinesis {
int Logger::runOnceInd = runOnce();
int Logger::runOnce() {
LOG(INFO) << "Registered logger";
el::Loggers::getLogger("Logger");
return 0;
}
Logger::Logger() {
LOG(INFO) << "Logger ctor";
}
Logger::Logger(int argc, char** argv) {
START_EASYLOGGINGPP(argc,argv);
LOG(INFO) << "Logger ctor(argc,argv)";
}
Logger::~Logger() {
LOG(INFO) << "Logger dtor";
}
void Logger::event(int a) {
VLOG(1) << "Logger::event start";
LOG(INFO) << "Process event["<<a<<"]";
VLOG(1) << "Logger::event end";
}
el::base::type::StoragePointer Logger::getStorage() {
return el::Helpers::storage();
}
}
void EventLoop::runForever()
{
m_stop = false;
while (!m_stop)
runOnce();
WARN << "Begin EventLoop Stop" ;
map<int, Handler*>::iterator iter = m_map.begin();
for(; iter!=m_map.end(); iter++)
{
Handler *handler = (*iter).second;
DEBUG << "Stop fd: " << handler->getSocket().fd();
m_selector->unRegisterEvent(handler, -1);
handler->onCloseEvent(CLSSIG);
}
WARN << "End EventLoop Stop" ;
m_map.clear();
}
void Primer::run()
{
bool end = false;
while (!end)
{
end = runOnce();
}
}
void SimpleEventLoop::doRun(bool breakAfterEvents) {
while (isRunning_) {
{
boost::unique_lock<boost::mutex> lock(eventAvailableMutex_);
while (!eventAvailable_) {
eventAvailableCondition_.wait(lock);
}
eventAvailable_ = false;
}
runOnce();
if (breakAfterEvents) {
return;
}
}
}
/*
* ======== VIDENCCOPY_TI_process ========
*/
XDAS_Int32 VIDENCCOPY_TI_process(IVIDENC_Handle h, XDM_BufDesc *inBufs,XDM_BufDesc *outBufs, IVIDENC_InArgs *inArgs, IVIDENC_OutArgs *outArgs)
{
XDAS_Int32 curBuf;
XDAS_UInt32 minSamples;
#ifdef USE_ACPY3
const Uint32 maxTransferChunkSize = 0xffff;
Uint32 thisTransferChunkSize = 0x0;
Uint32 remainingTransferChunkSize;
Uint32 thisTransferSrcAddr, thisTransferDstAddr;
ACPY3_Params params;
VIDENCCOPY_TI_Obj *videncObj = (VIDENCCOPY_TI_Obj *)h;
#endif
Log_print5(Diags_ENTRY, "[+E] VIDENCCOPY_TI_process(0x%x, 0x%x, 0x%x, "
"0x%x, 0x%x)",
(IArg)h, (IArg)inBufs, (IArg)outBufs, (IArg)inArgs, (IArg)outArgs);
/* validate arguments - this codec only supports "base" xDM. */
if ((inArgs->size != sizeof(*inArgs)) ||
(outArgs->size != sizeof(*outArgs))) {
Log_print2(Diags_ENTRY,
"[+E] VIDENCCOPY_TI_process, unsupported size (0x%x, 0x%x)",
(IArg)(inArgs->size), (IArg)(outArgs->size));
return (IVIDENC_EFAIL);
}
#ifdef USE_ACPY3
/*
* Activate Channel scratch DMA channels.
*/
//ACPY3_activate(videncObj->dmaHandle1D1D8B);
#endif
/* outArgs->bytesGenerated reports the total number of bytes generated */
outArgs->bytesGenerated = 0;
/*
* A couple constraints for this simple "copy" codec:
* - Video encoding presumes a single input buffer, so only one input
* buffer will be encoded, regardless of inBufs->numBufs.
* - Given a different size of an input and output buffers, only
* encode (i.e., copy) the lesser of the sizes.
*/
for (curBuf = 0; (curBuf < inBufs->numBufs) &&
(curBuf < outBufs->numBufs); curBuf++) {
/* there's an available in and out buffer, how many samples? */
minSamples = inBufs->bufSizes[curBuf] < outBufs->bufSizes[curBuf] ?
inBufs->bufSizes[curBuf] : outBufs->bufSizes[curBuf];
#ifdef USE_ACPY3
#if 0
thisTransferSrcAddr = (Uint32)inBufs->bufs[curBuf];
thisTransferDstAddr = (Uint32)outBufs->bufs[curBuf];
remainingTransferChunkSize = minSamples;
while (remainingTransferChunkSize > 0) {
if (remainingTransferChunkSize > maxTransferChunkSize) {
thisTransferChunkSize = maxTransferChunkSize;
}
else {
thisTransferChunkSize = remainingTransferChunkSize;
}
/* Configure the logical channel */
params.transferType = ACPY3_1D1D;
params.srcAddr = (void *)thisTransferSrcAddr;
params.dstAddr = (void *)thisTransferDstAddr;
params.elementSize = thisTransferChunkSize;
params.numElements = 1;
params.waitId = 0;
params.numFrames = 1;
remainingTransferChunkSize -= thisTransferChunkSize;
thisTransferSrcAddr += thisTransferChunkSize;
thisTransferDstAddr += thisTransferChunkSize;
/* Configure logical dma channel */
ACPY3_configure(videncObj->dmaHandle1D1D8B, ¶ms, 0);
/* Use DMA to copy data */
ACPY3_start(videncObj->dmaHandle1D1D8B);
/* wait for transfer to finish */
ACPY3_wait(videncObj->dmaHandle1D1D8B);
}
Log_print1(Diags_USER2, "[+2] VIDENCCOPY_TI_process> "
"ACPY3 Processed %d bytes.", (IArg)minSamples);
#endif
#else
Log_print3(Diags_USER2, "[+2] VIDENCCOPY_TI_process> "
"memcpy (0x%x, 0x%x, %d)",
(IArg)(outBufs->bufs[curBuf]), (IArg)(inBufs->bufs[curBuf]),
(IArg)minSamples);
/* process the data: read input, produce output */
memcpy(outBufs->bufs[curBuf], inBufs->bufs[curBuf], minSamples);
#endif
outArgs->bytesGenerated += minSamples;
}
#ifdef USE_ACPY3
/*
* Deactivate Channel scratch DMA channels.
*/
//ACPY3_deactivate(videncObj->dmaHandle1D1D8B);
//videncObj->p_data //avi mem
runOnce(videncObj->p_data, videncObj->p_ddr_data, videncObj->p_DARAM0, videncObj->dmaHandle1D1D8B);
DspModule(inBufs->bufs[0], outBufs->bufs[0]);
//memcpy(outBufs->bufs[0] + 8,&(videncObj->p_DARAM0),4);
runOver();
#endif
/* Fill out the rest of the outArgs struct */
outArgs->extendedError = 0;
outArgs->encodedFrameType = 0; /* TODO */
outArgs->inputFrameSkip = IVIDEO_FRAME_ENCODED;
outArgs->reconBufs.numBufs = 0; /* important: indicate no reconBufs */
return (IVIDENC_EOK);
}
#include "mylib.hpp"
#include "easylogging++.h"
INITIALIZE_EASYLOGGINGPP
int MyLib::runOnceHelper = runOnce();
int MyLib::runOnce() {
LOG(INFO) << "Registering logger [mylib]";
el::Loggers::getLogger("mylib");
return 0;
}
MyLib::MyLib() {
LOG(INFO) << "---MyLib Constructor () ---";
}
MyLib::MyLib(int argc, char** argv) {
START_EASYLOGGINGPP(argc, argv);
LOG(INFO) << "---MyLib Constructor(int, char**) ---";
}
MyLib::~MyLib() {
LOG(INFO) << "---MyLib Destructor---";
}
void MyLib::event(int a) {
VLOG(1) << "MyLib::event start";
LOG(INFO) << "Processing event [" << a << "]";
VLOG(1) << "MyLib::event end";
int Runtime::runShell(const char *startupBas, int fontScale, int debugPort) {
logEntered();
os_graphics = 1;
os_color_depth = 16;
opt_interactive = true;
opt_usevmt = 0;
opt_file_permitted = 1;
opt_graphics = true;
opt_pref_bpp = 0;
opt_nosave = true;
_output->setTextColor(DEFAULT_FOREGROUND, DEFAULT_BACKGROUND);
_output->setFontSize(getStartupFontSize(_window));
_initialFontSize = _output->getFontSize();
if (fontScale != 100) {
_fontScale = fontScale;
int fontSize = (_initialFontSize * _fontScale / 100);
_output->setFontSize(fontSize);
}
SDL_Init(SDL_INIT_AUDIO);
SDL_AudioSpec desiredSpec;
desiredSpec.freq = FREQUENCY;
desiredSpec.format = AUDIO_S16SYS;
desiredSpec.channels = 1;
desiredSpec.samples = 2048;
desiredSpec.callback = audio_callback;
SDL_AudioSpec obtainedSpec;
SDL_OpenAudio(&desiredSpec, &obtainedSpec);
net_init();
if (debugPort > 0) {
appLog("Debug active on port %d\n", debugPort);
g_lock = SDL_CreateMutex();
g_cond = SDL_CreateCond();
opt_trace_on = 1;
g_debugBreak = SDL_TRUE;
SDL_Thread *thread =
SDL_CreateThread(debugThread, "DBg", (void *)(intptr_t)debugPort);
SDL_DetachThread(thread);
}
if (startupBas != NULL) {
String bas = startupBas;
if (opt_ide == IDE_INTERNAL) {
runEdit(bas.c_str());
} else {
runOnce(bas.c_str());
}
while (_state == kRestartState) {
_state = kActiveState;
if (_loadPath.length() != 0) {
bas = _loadPath;
}
runOnce(bas.c_str());
}
} else {
runMain(MAIN_BAS);
}
if (debugPort > 0) {
SDL_DestroyCond(g_cond);
SDL_DestroyMutex(g_lock);
}
debugStop();
net_close();
SDL_CloseAudio();
_state = kDoneState;
logLeaving();
return _fontScale;
}
Tactic* Tactic::run(){
if (timesToRun < 1){
return runOnce();
}
else return runNTimes(timesToRun);
}
void TestRunner::doRuns(const size_t num_runs, const bool measure_cache_misses) {
for (size_t run = 0; run < num_runs; ++run) {
run_stats_.push_back(runOnce(measure_cache_misses));
}
}
