void OfficeInputStream::initialize(const char *fileName, DocumentCache *cache) {
PDFInputStream::initialize(NULL, cache);
if (statusCode != 0) {
int convTime = currentTimeMillis();
pid_t child = fork();
char *oldPath, *newPath;
switch (child) {
case -1:
statusCode = 1;
break;
case 0:
#if 0
oldPath = getenv("PATH");
if (oldPath == NULL)
newPath = duplicateString(getenv("HOME"));
else
newPath = concatenateStrings(getenv("HOME"), ":", oldPath);
setenv("PATH", newPath, 1);
setenv("WUMPUS_CONVERSION_TARGET", tempFileName, 1);
statusCode = executeCommand(OOFFICE, "-headless", "-p", fileName, NULL, INPUT_CONVERSION_TIMEOUT);
#else
oldPath = concatenateStrings(tempFileName, ".ps");
statusCode = executeCommand(
"abiword", "--disable-crash-dialog", "-p", oldPath, fileName, INPUT_CONVERSION_TIMEOUT);
if (statusCode == 0)
statusCode = executeCommand(
"ps2pdf", oldPath, tempFileName, INPUT_CONVERSION_TIMEOUT);
if (statusCode == 0)
statusCode = executeCommand(
"rm", oldPath, NULL, INPUT_CONVERSION_TIMEOUT);
free(oldPath);
#endif
exit(statusCode);
default:
waitpid(child, &statusCode, 0);
break;
} // end switch (child)
if (statusCode == 0) {
char *tempFile = duplicateString(tempFileName);
PDFInputStream::initialize(tempFile, NULL);
unlink(tempFile);
free(tempFile);
if ((statusCode == 0) && (cache != NULL)) {
convTime = currentTimeMillis() - convTime;
if (convTime < 0)
convTime += 24 * 3600 * 1000;
cache->addDocumentTextFromFile(originalFileName, tempFileName, convTime);
}
}
} // end if (statusCode != 0)
if (statusCode != 0) {
inputFile = -1;
unlink(tempFileName);
}
} // end of initialize(char*, DocumentCache*)
void PSInputStream::initialize(const char *fileName, DocumentCache *cache) {
PDFInputStream::initialize(NULL, cache);
if (statusCode != 0) {
int convTime = currentTimeMillis();
statusCode = executeCommand((char*)PS2PDF, fileName, tempFileName,
INPUT_CONVERSION_TIMEOUT);
if (statusCode == 0) {
char *tempFile = duplicateString(tempFileName);
PDFInputStream::initialize(tempFile, NULL);
unlink(tempFile);
free(tempFile);
if ((statusCode == 0) && (cache != NULL)) {
convTime = currentTimeMillis() - convTime;
if (convTime < 0)
convTime += 24 * 3600 * 1000;
cache->addDocumentTextFromFile(originalFileName, tempFileName, convTime);
}
}
} // end if (statusCode != 0)
if (statusCode != 0) {
inputFile = -1;
unlink(tempFileName);
}
} // end of initialize(char*, DocumentCache*)
static void testRusefiMethods(const int count) {
time_t start, time;
int tempi = 1;
start = currentTimeMillis();
for (int i = 0; i < count; i++)
tempi += getBaseTableFuel(testEngine.engineConfiguration, 4020, 2.21111);
time = currentTimeMillis() - start;
if (tempi != 0)
scheduleMsg(logger, "Finished %d iterations of getBaseFuel in %dms", count, time);
// start = currentTimeMillis();
// for (int i = 0; i < count; i++)
// tempi += getFuelMs(1200, NULL); // todo
// time = currentTimeMillis() - start;
// if (tempi != 0)
// scheduleMsg(logger, "Finished %d iterations of getFuelMs in %dms", count, time);
start = currentTimeMillis();
for (int i = 0; i < count; i++) {
testEngine.updateSlowSensors();
tempi += testEngine.engineState.clt;
}
time = currentTimeMillis() - start;
if (tempi != 0)
scheduleMsg(logger, "Finished %d iterations of updateSlowSensors in %dms", count, time);
}
/**
* Main program.
*/
int main
(int argc,
char **argv)
{
int i, r, c;
long long int t1, t2;
// Initialize MPI middleware.
MPI_Init (&argc, &argv);
world = MPI_COMM_WORLD;
MPI_Comm_size (world, &size);
MPI_Comm_rank (world, &rank);
// Parse command line arguments.
if (argc != 2) usage();
sscanf (argv[1], "%d", &n);
// Allocate distance matrix.
allocateDistanceMatrix();
// Run Floyd's Algorithm.
// for i = 0 to N-1
// for r = 0 to N-1
// for c = 0 to N-1
// D[r,c] = min (D[r,c], D[r,i] + D[i,c])
t1 = currentTimeMillis();
for (i = 0; i < n; ++ i)
{
double *d_i;
if (i < 0 || i >= n) outOfBounds();
d_i = d[i];
for (r = 0; r < n; ++ r)
{
double *d_r;
if (r < 0 || r >= n) outOfBounds();
d_r = d[r];
for (c = 0; c < n; ++ c)
{
double d_r_c, d_r_i, d_i_c;
if (c < 0 || c >= n) outOfBounds();
d_r_c = d_r[c];
if (i < 0 || i >= n) outOfBounds();
d_r_i = d_r[i];
if (c < 0 || c >= n) outOfBounds();
d_i_c = d_i[c];
if (c < 0 || c >= n) outOfBounds();
d_r[c] = min (d_r_c, d_r_i + d_i_c);
}
}
}
t2 = currentTimeMillis();
// Print running time.
printf ("%lld msec\n", t2-t1);
// Finalize MPI middleware.
MPI_Finalize();
}
void render() {
if (initialized == false) {
glEnable(GL_CULL_FACE);
glEnable(GL_DEPTH_TEST);
spherePositionsId = createSpherePositions();
sphereNormalsId = createSphereNormals(positions);
createProgram();
startTimeMillis = currentTimeMillis();
initialized = true;
}
frameCount++;
totalFrameCount++;
long now = currentTimeMillis();
long elapsed = now - startTimeMillis;
static long lastTimerCall = 0;
if ((now - lastTimerCall) > 250) {
timer(0);
lastTimerCall = now;
}
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
glUseProgram(programId);
//
// calculate the ModelViewProjection and ModelViewProjection matrices
//
matrix44 tmp, mv, mvp, frustumMat, translateMat, rotateMat1, rotateMat2;
frustum(frustumMat, left, right, bottom / aspectRatio, top / aspectRatio, nearPlane, farPlane);
translate(translateMat, 0.0f, 0.0f, -3.0f);
rotate(rotateMat1, 1.0f * elapsed / 50, 1.0f, 0.0f, 0.0f);
rotate(rotateMat2, 1.0f * elapsed / 100, 0.0f, 1.0f, 0.0f);
multm(tmp, rotateMat1, rotateMat2);
multm(mv, translateMat, tmp);
multm(mvp, frustumMat, mv);
// set the uniforms before rendering
GLuint mvpMatrixUniform = glGetUniformLocation(programId, "mvpMatrix");
GLuint mvMatrixUniform = glGetUniformLocation(programId, "mvMatrix");
GLuint colorUniform = glGetUniformLocation(programId, "color");
GLuint ambientUniform = glGetUniformLocation(programId, "ambient");
GLuint lightDirUniform = glGetUniformLocation(programId, "lightDir");
glUniformMatrix4fv(mvpMatrixUniform, 1, false, mvp);
glUniformMatrix4fv(mvMatrixUniform, 1, false, mv);
glUniform3f(lightDirUniform, 1.0f, -1.0f, -1.0f);
glUniform4f(colorUniform, 0.5f, 0.5f, 0.5f, 1.0f);
glUniform4f(ambientUniform, 0.1f, 0.1f, 0.1f, 1.0f);
// render!
renderSphere();
// display rendering buffer
SDL_GL_SwapBuffers();
}
void WriteManager::run() {
{
Synchronized sync(transactionsLock);
//swap the assignment and update queue
volatile std::queue<NetworkTableEntry*>* tmp = incomingAssignmentQueue;
incomingAssignmentQueue = outgoingAssignmentQueue;
outgoingAssignmentQueue = tmp;
tmp = incomingUpdateQueue;
incomingUpdateQueue = outgoingUpdateQueue;
outgoingUpdateQueue = tmp;
}
bool wrote = false;
NetworkTableEntry* entry;
while(!((std::queue<NetworkTableEntry*>*)outgoingAssignmentQueue)->empty()){
entry = ((std::queue<NetworkTableEntry*>*)outgoingAssignmentQueue)->front();
((std::queue<NetworkTableEntry*>*)outgoingAssignmentQueue)->pop();
{
Synchronized sync(entryStore.LOCK);
entry->MakeClean();
wrote = true;
receiver.offerOutgoingAssignment(entry);
}
}
while(!((std::queue<NetworkTableEntry*>*)outgoingUpdateQueue)->empty()){
entry = ((std::queue<NetworkTableEntry*>*)outgoingUpdateQueue)->front();
((std::queue<NetworkTableEntry*>*)outgoingUpdateQueue)->pop();
{
Synchronized sync(entryStore.LOCK);
entry->MakeClean();
wrote = true;
receiver.offerOutgoingUpdate(entry);
}
}
if(wrote){
receiver.flush();
lastWrite = currentTimeMillis();
}
else if(currentTimeMillis()-lastWrite>keepAliveDelay)
receiver.ensureAlive();
sleep_ms(20);
}
void
Animation::rewind()
{
forward = false;
if (timer != NULL) {
int elapsed = currentTimeMillis() - started;
int remaining = duration - elapsed;
started = currentTimeMillis() - remaining;
} else {
updateValue(1.);
started = currentTimeMillis();
timer = new Timer(10, Animation_TimerCallback, (void*)this);
}
}
void GLTouchScreen::checkTimeout() {
uint64_t time = currentTimeMillis();
if ((touchTimeout != 0) && (touchTimeout <= time)){
touchTimeout = 0;
touchCancel = true;
}
}
void DrawBlock(int x, int y, Block* block, bool falling)
{
if (block->type < 0)
return;
const int y_cutoff = PANEL_START_Y+(PANEL_HEIGHT*BLOCK_SIZE);
int draw_height = y_cutoff - y;
if (draw_height > BLOCK_SIZE)
draw_height = BLOCK_SIZE;
if (draw_height <= 0)
return;
int color;
BITMAP* bmp;
if (falling)
bmp = falling_block_bitmaps[block->type][falling_block_frame];
else if (block->popping && (((unsigned)currentTimeMillis() % (POP_FLASH_TIME*2)) < POP_FLASH_TIME)) {
bmp = popping_block_bitmaps[block->type];
}
else
bmp = block_bitmaps[block->type];
masked_blit(bmp, buffer, 0, 0, x, y, BLOCK_SIZE, draw_height);
}
/**
* 'Write' command receives a single value at a given offset
* @note Writing values one by one is pretty slow
*/
void handleWriteValueCommand(ts_channel_s *tsChannel, ts_response_format_e mode, uint16_t page, uint16_t offset,
uint8_t value) {
tsState.writeValueCommandCounter++;
currentPageId = page;
tunerStudioDebug("got W (Write)"); // we can get a lot of these
#if EFI_TUNER_STUDIO_VERBOSE
// scheduleMsg(logger, "Page number %d\r\n", pageId); // we can get a lot of these
#endif
// int size = sizeof(TunerStudioWriteValueRequest);
// scheduleMsg(logger, "Reading %d\r\n", size);
if (offset > getTunerStudioPageSize(currentPageId)) {
tunerStudioError("ERROR: out of range2");
scheduleMsg(&tsLogger, "ERROR offset %d", offset);
offset = 0;
return;
}
efitimems_t nowMs = currentTimeMillis();
if (nowMs - previousWriteReportMs > 5) {
previousWriteReportMs = nowMs;
scheduleMsg(&tsLogger, "page %d offset %d: value=%d", currentPageId, offset, value);
}
getWorkingPageAddr(currentPageId)[offset] = value;
yellowMagic(currentPageId, offset, 1);
// scheduleMsg(logger, "va=%d", configWorkingCopy.boardConfiguration.idleValvePin);
}
void writeToFlash(void) {
#if EFI_INTERNAL_FLASH
persistentState.size = PERSISTENT_SIZE;
persistentState.version = FLASH_DATA_VERSION;
scheduleMsg(&logger, "flash compatible with %d", persistentState.version);
crc_t result = flashStateCrc(&persistentState);
persistentState.value = result;
scheduleMsg(&logger, "Reseting flash: size=%d", PERSISTENT_SIZE);
flashErase(FLASH_ADDR, PERSISTENT_SIZE);
scheduleMsg(&logger, "Flashing with CRC=%d", result);
efitimems_t nowMs = currentTimeMillis();
result = flashWrite(FLASH_ADDR, (const char *) &persistentState, PERSISTENT_SIZE);
scheduleMsg(&logger, "Flash programmed in (ms): %d", currentTimeMillis() - nowMs);
scheduleMsg(&logger, "Flashing result: %d", result);
#endif /* EFI_INTERNAL_FLASH */
}
bool GLTouchScreen::canStartMouse() {
if (touchTime == 0) {
if (mouseRepeatTime == 0)
return true;
else {
uint64_t time = currentTimeMillis();
return (time >= mouseRepeatTime + 200);
}
} else {
uint64_t time = currentTimeMillis();
if (mouseRepeatTime == 0)
return (time >= (touchTime + 1000));
else
return ((time >= (touchTime + 1000)) &&
(time >= mouseRepeatTime + 200));
}
}
// todo: re-use primary firmware implementation?
int warning(obd_code_e code, const char *fmt, ...) {
int now = currentTimeMillis() / 1000;
if (absI(now - timeOfPreviousWarning) < 10)
return TRUE; // we just had another warning, let's not spam
timeOfPreviousWarning = now;
printf("Warning: %s\r\n", fmt);
return FALSE;
}
void GLTouchScreen::onMouseOut(MotionEvent* event) {
if (mouseDown) {
mouseDown = false;
mouseTime = currentTimeMillis();
MotionPointer* pointer = event->getPointer(0);
analyze(pointer->x, pointer->y);
}
}
void GLTouchScreen::onTouchEnd(MotionEvent* event) {
checkTimeout();
if (touchDown) {
touchDown = false;
touchTime = currentTimeMillis();
MotionPointer* pointer = event->getPointer(0);
analyze(pointer->x, pointer->y);
}
}
void
Animation::restart()
{
forward = true;
updateValue(0.);
started = currentTimeMillis();
if (timer == NULL) {
timer = new Timer(10, Animation_TimerCallback, (void*)this);
}
}
/**
* 'Burn' command is a command to commit the changes
*/
void handleBurnCommand(ts_channel_s *tsChannel, ts_response_format_e mode, uint16_t page) {
efitimems_t nowMs = currentTimeMillis();
tsState.burnCommandCounter++;
tunerStudioDebug("got B (Burn)");
currentPageId = page;
#if EFI_TUNER_STUDIO_VERBOSE
// pointless since we only have one page now
// scheduleMsg(logger, "Page number %d", currentPageId);
#endif
// todo: how about some multi-threading?
memcpy(&persistentState.persistentConfiguration, &configWorkingCopy, sizeof(persistent_config_s));
requestBurn();
tunerStudioWriteCrcPacket(tsChannel, TS_RESPONSE_BURN_OK, NULL, 0);
scheduleMsg(&tsLogger, "BURN in %dms", currentTimeMillis() - nowMs);
}
static bool renderGL(void)
{
static const GLfloat verts[3][2] = {
{ -0.5, -0.5 },
{ 0.5, -0.5 },
{ 0.0, 0.5 }
};
static const GLfloat colors[3][4] = {
{ 1, 0, 0, 1.0 },
{ 0, 1, 0, 1.0 },
{ 0, 0, 1, 1.0 }
};
GLfloat angle;
GLfloat matrix[4][4] = {
{ 1, 0, 0, 0 },
{ 0, 1, 0, 0 },
{ 0, 0, 1, 0 },
{ 0, 0, 0, 1 }
};
static const uint32_t speed_div= 5;
EGLint rect[4];
glViewport( 0, 0, gDisplayWidth, gDisplayHeight );
glClearColor(0.0f, 0.0f, 0.0f, 0.0f);
glClear(GL_COLOR_BUFFER_BIT);
gCurrTime= currentTimeMillis();
angle= ((gCurrTime-gStartTime) / speed_div) % 360 * M_PI / 180.0;
matrix[0][0]= (1.0/3.0)*cos(angle);
matrix[0][2]= (1.0/3.0)*sin(angle);
matrix[1][1]= (1.0/3.0);
matrix[2][0]= -(1.0/3.0)*sin(angle);
matrix[2][2]= (1.0/3.0)*cos(angle);
glUniform4f(gOffset, -0.3333+gCol*0.3333, 0.3333-gRow*0.3333, 0, 0 );
glUniformMatrix4fv(gXform, 1, GL_FALSE, (GLfloat *)matrix);
glVertexAttribPointer(gPos, 2, GL_FLOAT, GL_FALSE, 0, verts);
glVertexAttribPointer(gColor, 4, GL_FLOAT, GL_FALSE, 0, colors);
glEnableVertexAttribArray(gPos);
glEnableVertexAttribArray(gColor);
glDrawArrays(GL_TRIANGLES, 0, 3);
glDisableVertexAttribArray(gPos);
glDisableVertexAttribArray(gColor);
GLenum err= glGetError();
if ( err != GL_NO_ERROR )
{
printf( "renderGL: glGetError() = %X\n", err );
}
}
static void printGpsInfo(void) {
scheduleMsg(&logging, "GPS RX %s", hwPortname(boardConfiguration->gps_rx_pin));
scheduleMsg(&logging, "GPS TX %s", hwPortname(boardConfiguration->gps_tx_pin));
scheduleMsg(&logging, "m=%d,e=%d: vehicle speed = %f\r\n", gpsMesagesCount, uartErrors, getCurrentSpeed());
float sec = currentTimeMillis() / 1000.0;
scheduleMsg(&logging, "communication speed: %f", gpsMesagesCount / sec);
print("GPS latitude = %f\r\n", GPSdata.latitude);
print("GPS longitude = %f\r\n", GPSdata.longitude);
}
void writeToFlashNow(void) {
scheduleMsg(logger, " !!!!!!!!!!!!!!!!!!!! BE SURE NOT WRITE WITH IGNITION ON !!!!!!!!!!!!!!!!!!!!");
persistentState.size = PERSISTENT_SIZE;
persistentState.version = FLASH_DATA_VERSION;
scheduleMsg(logger, "flash compatible with %d", persistentState.version);
crc_t crcResult = flashStateCrc(&persistentState);
persistentState.value = crcResult;
scheduleMsg(logger, "Reseting flash: size=%d", PERSISTENT_SIZE);
flashErase(FLASH_ADDR, PERSISTENT_SIZE);
scheduleMsg(logger, "Flashing with CRC=%d", crcResult);
efitimems_t nowMs = currentTimeMillis();
int result = flashWrite(FLASH_ADDR, (const char *) &persistentState, PERSISTENT_SIZE);
scheduleMsg(logger, "Flash programmed in %dms", currentTimeMillis() - nowMs);
bool isSuccess = result == FLASH_RETURN_SUCCESS;
if (isSuccess) {
scheduleMsg(logger, FLASH_SUCCESS_MSG);
} else {
scheduleMsg(logger, "Flashing failed");
}
maxLockTime = 0;
}
//Funcion do GET
void doGet(int socket, const char *localFilename, unsigned long size) {
u_int writeBytes = 0;
char *readBuffer;
u_int readBytes = 0;
u_long totalReadBytes = 0;
int fd;
int localError;
u_long start;
u_long end;
debug(4,"Doing Get for: %s (%li)",localFilename,size);
fd = open(localFilename,O_WRONLY | O_CREAT | O_TRUNC, S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH );
if(fd == -1) {
//Error al crear el archivo local.
localError = errno;
debug(1,"Can't create Local File (%s)",strerror(localError));
return;
}
readBuffer = (char *) malloc(102400);
start = currentTimeMillis();
while(totalReadBytes < size) {
readBytes = read(socket,readBuffer,102400);
if(readBytes > 0) {
writeBytes = 0;
while(writeBytes < readBytes) {
writeBytes += write(fd,readBuffer+writeBytes,readBytes-writeBytes);
}
}
totalReadBytes += readBytes;
end = currentTimeMillis();
if(end>start)
debug(4,"Get %lu/%lu ( %0.0f%% ) speed %lukbps",totalReadBytes,size,(((float)totalReadBytes/(float)size)*100),(totalReadBytes/(end-start)*1000/1024));
}
free(readBuffer);
close(fd);
}
static void testSystemCalls(const int count) {
time_t start, time;
long result = 0;
start = currentTimeMillis();
for (int i = 0; i < count / 2; i++) {
// setPinValue(&testOutput, 0);
// setPinValue(&testOutput, 1);
}
time = currentTimeMillis() - start;
// Finished 100000 iterations of 'setPinValue()' in 120ms
// prin("Finished %d iterations of 'setPinValue()' in %dms\r\n", count, time);
start = currentTimeMillis();
for (int i = 0; i < count; i++)
result += chTimeNow();
time = currentTimeMillis() - start;
if (result != 0) {
// Finished 100000 iterations of 'chTimeNow()' in 33ms
scheduleMsg(logger, "Finished %d iterations of 'chTimeNow()' in %dms", count, time);
}
start = currentTimeMillis();
for (int i = 0; i < count; i++) {
chSysLock()
;
result += chTimeNow();
chSysUnlock()
;
}
time = currentTimeMillis() - start;
if (result != 0) {
// Finished 100000 iterations of 'chTimeNow()' with chSysLock in 144ms
scheduleMsg(logger, "Finished %d iterations of 'chTimeNow()' with chSysLock in %dms", count, time);
}
start = currentTimeMillis();
for (int i = 0; i < count; i++)
result += currentTimeMillis();
time = currentTimeMillis() - start;
if (result != 0)
scheduleMsg(logger, "Finished %d iterations of 'currentTimeMillis' in %dms", count, time);
}
void ThreadScheduler::RunOnTaskThread(task_func* func, long millis, ...){
va_list ap;
va_start(ap, millis);
WaitingFuncTask task = WaitingFuncTask();
task.func = func;
va_copy(task.args, ap);
va_end(ap);
task.at = currentTimeMillis() + millis;
waitingFuncTasks.push_back(task);
std::sort(waitingFuncTasks.begin(), waitingFuncTasks.end(), func_less_than_key());
}
int ThreadScheduler::Wait(lua_State* L, long millis){
long curTime = currentTimeMillis();
Task tsk = Task();
tsk.origin = L;
tsk.at = curTime + millis;
tsk.start = curTime;
tsk.ref = -1;
enqueue_task(tsk);
return lua_yield(L, 2);
}
static void autoIdle() {
efitimems_t now = currentTimeMillis();
percent_t newValue = idlePositionController.getIdle(getRpmE(engine), now PASS_ENGINE_PARAMETER);
if (currentIdleValve != newValue) {
currentIdleValve = newValue;
// todo: looks like in auto mode stepper value is not set, only solenoid?
setIdleValvePwm(newValue);
}
}
/**
* 'Burn' command is a command to commit the changes
*/
void handleBurnCommand(ts_response_format_e mode, uint16_t page) {
efitimems_t nowMs = currentTimeMillis();
tsState.burnCommandCounter++;
tunerStudioDebug("got B (Burn)");
tsState.currentPageId = page;
#if EFI_TUNER_STUDIO_VERBOSE
// pointless since we only have one page now
// scheduleMsg(&logger, "Page number %d", tsState.currentPageId);
#endif
// todo: how about some multi-threading?
memcpy(&persistentState.persistentConfiguration, &configWorkingCopy, sizeof(persistent_config_s));
#if EFI_INTERNAL_FLASH
setNeedToWriteConfiguration();
#endif
incrementGlobalConfigurationVersion();
tunerStudioWriteCrcPacket(TS_RESPONSE_BURN_OK, NULL, 0);
scheduleMsg(&logger, "burned in (ms): %d", currentTimeMillis() - nowMs);
}
static int recordCallback(const void *input_buffer,
void *output_buffer,
unsigned long frames_per_buffer,
const PaStreamCallbackTimeInfo* time_info,
PaStreamCallbackFlags status_flags,
void *user_data)
{
(void)output_buffer;
(void)time_info;
(void)status_flags;
RecordCallbackMetadata * meta_data = (RecordCallbackMetadata *)user_data;
meta_data->num_frames += frames_per_buffer;
long current_time = currentTimeMillis();
long delta = current_time - meta_data->start_time;
if (delta >= INPUT_FORMAT_CHECK_INTERVAL) {
printf("time delta: %lu, frames_per_buffer: %lu, frame delta: %lu, InputUnderflow: %d, InputOverflow: %d, OutputUnderflow: %d, OutputOverflow: %d, outputtonow: %f, nowtoinput: %f\n",
delta,
frames_per_buffer,
meta_data->num_frames,
(status_flags & paInputUnderflow) != 0,
(status_flags & paInputOverflow) != 0,
(status_flags & paOutputUnderflow) != 0,
(status_flags & paOutputOverflow) != 0,
time_info->outputBufferDacTime - time_info->currentTime,
time_info->currentTime - time_info->inputBufferAdcTime
);
meta_data->num_frames = 0;
meta_data->start_time = current_time;
}
CircularBuffer * buffer = meta_data->buffer;
const NUMERIC * reader = (const NUMERIC*)input_buffer;
if (meta_data->stripe_input) {
CircularBuffer_produce_blocking_striped(buffer,
reader,
frames_per_buffer,
meta_data->number_of_channels,
meta_data->enabled_channels);
} else {
CircularBuffer_produce_blocking(buffer, reader, frames_per_buffer * meta_data->number_of_channels);
}
return paContinue;
}
static void updateTriggerShapeIfNeeded(PwmConfig *state) {
if (atTriggerVersion < engine->triggerCentral.triggerShape.version) {
atTriggerVersion = engine->triggerCentral.triggerShape.version;
scheduleMsg(logger, "Stimulator: updating trigger shape: %d/%d %d", atTriggerVersion,
getGlobalConfigurationVersion(), currentTimeMillis());
TriggerShape *s = &engine->triggerCentral.triggerShape;
pin_state_t *pinStates[PWM_PHASE_MAX_WAVE_PER_PWM] = { s->wave.waves[0].pinStates, s->wave.waves[1].pinStates,
s->wave.waves[2].pinStates };
copyPwmParameters(state, s->getSize(), s->wave.switchTimes, PWM_PHASE_MAX_WAVE_PER_PWM, pinStates);
state->safe.periodNt = -1; // this would cause loop re-initialization
}
}
static void updateTriggerShapeIfNeeded(PwmConfig *state) {
if (emulatorConfigVersion.isOld()) {
scheduleMsg(logger, "Stimulator: updating trigger shape: %d/%d %d", emulatorConfigVersion.getVersion(),
getGlobalConfigurationVersion(), currentTimeMillis());
applyNonPersistentConfiguration(logger PASS_ENGINE_PARAMETER);
TriggerShape *s = &engine->triggerShape;
pin_state_t *pinStates[PWM_PHASE_MAX_WAVE_PER_PWM] = { s->wave.waves[0].pinStates, s->wave.waves[1].pinStates,
s->wave.waves[2].pinStates };
copyPwmParameters(state, s->getSize(), s->wave.switchTimes, PWM_PHASE_MAX_WAVE_PER_PWM, pinStates);
state->safe.periodNt = -1; // this would cause loop re-initialization
}
}
void processGET(int socket, const char *localFilename, unsigned long size) {
u_int writeBytes = 0,readBytes = 0;
char *readBuffer;
u_long totalReadBytes = 0;
int fileDesc,localError;
u_long inicio,fin;
//Mostramos el GET con el nombre del archivo local y su tamaño en bytes
fprintf(stderr,"Doing GET for: %s (%li Bytes)",localFilename,size); //abrimos el archivo recibido
fileDesc = open(localFilename,O_WRONLY | O_CREAT | O_TRUNC, S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH );
if(fileDesc == -1) {
//Error al crear el archivo local.
localError = errno;
fprintf(stderr,"Can't create Local File (%s)",strerror(localError));
return;
}
//Si no hubo error en la transferencia del archivo, lo escribimos en un archivo después de leerlo
readBuffer = (char *) malloc(102400);
inicio = currentTimeMillis(); //comienza la cuenta de milisegundos
while(totalReadBytes < size) {
readBytes = read(socket,readBuffer,102400);
if(readBytes > 0) {
writeBytes = 0;
while(writeBytes < readBytes) {
writeBytes += write(fileDesc,readBuffer+writeBytes,readBytes-writeBytes);
}
}
totalReadBytes += readBytes;
fin = currentTimeMillis(); //termina la cuenta
if(fin>inicio) //Imprimimos la informacion de la transferencia del archivo
fprintf(stderr,"Get %lu/%lu ( %0.0f%% ) speed %lukbps",totalReadBytes,size,(((float)totalReadBytes/(float)size)*100),(totalReadBytes/(fin-inicio)*1000/1024));
}
free(readBuffer); //liberamos el bufer
close(fileDesc); //y cerramos el archivo
}
