#include "TbRawStream.h"
#include <cmath>
DECLARE_TOOL_FACTORY(TbRawStream)
const int64_t TbRawStream::m_tenSeconds = 256 * std::pow(10, 11);
const int64_t TbRawStream::m_maxTimeDifference = pow(2, 40);
//=============================================================================
// Standard constructor
//=============================================================================
TbRawStream::TbRawStream(const std::string& type, const std::string& name,
const IInterface* parent)
: GaudiTool(type, name, parent),
m_hitCache(), m_trgCache() {
declareInterface<TbRawStream>(this);
}
bool TbRawStream::setMSB(uint64_t msb) {
uint64_t currentTime = (m_lsb + (msb << 32)) << 12;
const int64_t timeDifference = currentTime - m_timer;
if (timeDifference > m_tenSeconds) {
// Detected jump of greater than 10s
// warning() << "Jump detected - this is okay, probably means "
// << "a bit has been updated between LSB and MSB" << endmsg;
if (msb > 0) msb -= 1;
currentTime = (m_lsb + (msb << 32)) << 12;
}
if (timeDifference > m_maxTimeDifference ||
timeDifference < -m_maxTimeDifference) {
// warning << "Current global time = " <<
// m_timer*25*pow(10,-6)/4096 << " clock is trying to update to " <<
// currentTime*25*pow(10,-6)/4096 << endmsg;
return false;
}
m_timer = currentTime;
// info() << "Current global time: " <<
// currentTime*25/(4096*pow(10,9)) << " s" <<endmsg;
return true;
}
void TbRawStream::fastForward(const uint64_t timeToSkipTo) {
// Go one second before we need to
const double coarse_time = timeToSkipTo * 25 / (4096 * pow(10, 9));
coarseFastForward(coarse_time);
fineFastForward(timeToSkipTo);
}
//=============================================================================
// Binary search of the stream to find a particular time
//=============================================================================
void TbRawStream::coarseFastForward(const double timeToSkipTo) {
info() << "Skipping forward to time = " << timeToSkipTo << endmsg;
// Need to work out which file to read first
if (m_files.size() > 1) {
for (auto it = m_files.begin(), end = m_files.end(); it != end; ++it) {
m_currentFile = it;
(*it)->initialise();
const double timeInSeconds = getCurrentTime() * 25 / pow(10, 9);
if (timeInSeconds > timeToSkipTo) {
(*it)->reset();
m_currentFile--;
break;
}
(*it)->reset();
}
}
(*m_currentFile)->initialise();
uint64_t dt = (*m_currentFile)->nPackets() / 2;
uint64_t pos = dt;
uint64_t timer = 0;
double timeInSeconds = 0;
while (!eos() && fabs(timeToSkipTo - timeInSeconds) > 0.6 && dt > 1) {
// Scroll to the new position
(*m_currentFile)->setOffset(pos);
dt /= 2;
timer = getCurrentTime();
timeInSeconds = timer * 25 / pow(10, 9);
pos = timeToSkipTo > timeInSeconds ? (pos + dt) : (pos - dt);
}
if (dt <= 1) info() << "Binary search has failed!" << endmsg;
m_timer = timer << 12;
}
void TbRawStream::fineFastForward(const uint64_t timeToSkipTo) {
uint64_t currentTime(0);
while (!eos() && currentTime < timeToSkipTo) {
const uint64_t data_packet = getNext();
const unsigned int header = data_packet >> 60;
if (header == 0xA || header == 0xB) {
uint64_t global_time = timer();
uint64_t packet_time = (0xFFFF & data_packet) << 26;
const int diff =
(0x3 & (global_time >> 40)) - (0x3 & (packet_time >> 40));
constexpr uint64_t one = (uint64_t)(1) << 40;
if (diff == 1 || diff == -3)
global_time = global_time - one;
else if (diff == -1 || diff == 3)
global_time = global_time + one;
} else if (header == 0x4) {
addTimingPacket(data_packet);
currentTime = m_timer;
}
}
}
uint64_t TbRawStream::getCurrentTime() {
m_lsb = 0;
uint64_t currentTime = 0;
bool gotTime = false;
while (!eos() && !gotTime) {
// measures the current time in the stream//
const uint64_t data_packet = getNext();
const unsigned int header = data_packet >> 60;
if (header == 0x4 && (0xF & (data_packet >> 54)) != 0xF) {
const unsigned int subheader = 0xF & (data_packet >> 56);
if (subheader == 0x4) {
m_lsb = 0xFFFFFFFF & (data_packet >> 16);
} else if (subheader == 0x5 && m_lsb != 0) {
const uint64_t msb = 0xFFFFFFFF & (data_packet >> 16);
currentTime = (m_lsb + (msb << 32));
gotTime = true;
}
}
}
return currentTime;
}
int TbRawStream::addTimingPacket(const uint64_t data_packet) {
const unsigned int subheader = 0xF & (data_packet >> 56);
int state = 1;
if (subheader == 0x5) {
// info() << "Current msb = Setting msb of clock: 0x" <<
// std::hex << data_packet << std::dec <<endmsg;
if (setMSB(0xFFFFFFFF & (data_packet >> 16)) == 0) state = 2;
} else if (subheader == 0x4) {
// info() << "Setting lsb of stream: 0x" << std::hex <<
// data_packet << ", current = " << m_lsb << std::dec << endmsg;
setLSB(0xFFFFFFFF & (data_packet >> 16));
} else {
state = 0;
}
return state;
}
void TbRawStream::prepare() {
m_currentFile = m_files.begin();
(*m_currentFile)->initialise();
m_size = 0;
for (const auto& raw_file : m_files) m_size = m_size + raw_file->nPackets();
//info() << "Stream = " << m_size << " 8-byte packets" << endmsg;
unsigned int header(0);
// Find the first pixel hit
unsigned int prep_packets(0);
while (!eos() && !(header == 0xA || header == 0xB)) {
uint64_t packet = getNext();
// info() << std::hex << packet << endmsg;
header = 0xF & (packet >> 60);
++prep_packets;
}
// for (unsigned int i = 0; i < 100; ++i) {
// info() << std::hex << "0x" << getNext() << std::dec << endmsg;
// }
// info() << "Number of prep packets skipped = " << prep_packets << endmsg;
m_size = m_size - prep_packets + 1;
getPrevious();
}
template <>
std::vector<LHCb::TbHit*>* TbRawStream::cache() {
return &m_hitCache;
}
template <>
std::vector<LHCb::TbTrigger*>* TbRawStream::cache() {
return &m_trgCache;
}
void TbRawStream::insert(LHCb::TbHit* packet) { m_hitCache.push_back(packet); }
void TbRawStream::insert(LHCb::TbTrigger* packet) {
m_trgCache.push_back(packet);
}
iaro