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f1724.cc
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#include "f1724.hh"
#include "MongoLog.hh"
#include "StraxFormatter.hh"
#include <chrono>
#include <cmath>
using std::vector;
constexpr double PI() {return std::acos(-1.);}
// redeclare all the static members
std::thread f1724::sGeneratorThread;
std::mutex f1724::sMutex;
std::random_device f1724::sRD;
std::mt19937_64 f1724::sGen;
std::uniform_real_distribution<> f1724::sFlatDist;
long f1724::sClock;
int f1724::sEventCounter;
std::atomic_bool f1724::sRun, f1724::sReady;
fax_options_t f1724::sFaxOptions;
int f1724::sNumPMTs;
vector<f1724*> f1724::sRegistry;
vector<f1724::pmt_pos_t> f1724::sPMTxy;
std::condition_variable f1724::sCV;
std::shared_ptr<MongoLog> f1724::sLog;
f1724::pmt_pos_t f1724::PMTiToXY(int i) {
pmt_pos_t ret{0.,0.,0};
if (i == 0) {
return ret;
}
if (i < 7) {
ret.x = std::cos((i-1)*PI()/3.);
ret.y = std::sin((i-1)*PI()/3.);
return ret;
}
int ring = 2;
// how many total PMTs are contained in a radius r? aka which ring is this PMT in
while (i > 3*ring*(ring+1)) ring++;
int i_in_ring = i - (1 + 3*ring*(ring-1));
int side = i_in_ring / ring;
int side_i = i_in_ring % ring;
double ref_angle = PI()/3*side;
double offset_angle = ref_angle + 2*PI()/3;
double x_c = ring*std::cos(ref_angle), y_c = ring*std::sin(ref_angle);
ret.x = x_c + side_i*std::cos(offset_angle);
ret.y = y_c + side_i*std::sin(offset_angle);
return ret;
}
f1724::f1724(std::shared_ptr<MongoLog>& log, std::shared_ptr<Options>& opts, int bid, unsigned) : V1724(log, opts, bid, 0){
//fLog->Entry(MongoLog::Warning, "Initializing fax digitizer");
fSPEtemplate = {0.0, 0.0, 0.0, 2.81e-2, 7.4, 6.07e1, 3.26e1, 1.33e1, 7.60, 5.71,
7.75, 4.46, 3.68, 3.31, 2.97, 2.74, 2.66, 2.48, 2.27, 2.15, 2.03, 1.93, 1.70,
1.68, 1.26, 7.86e-1, 5.36e-1, 4.36e-1, 3.11e-1, 2.15e-1};
fEventCounter = 0;
fSeenUnder5 = true;
fSeenOver15 = false;
fSimulateCrashes = true;
fFailProb = 1e-4;
fCrashProb = 1e-6;
fError = 0;
}
f1724::~f1724() {
End();
}
int f1724::Init(int, int) {
if (fOptions->GetFaxOptions(fFaxOptions)) {
return -1;
}
fGen = std::mt19937_64(fRD());
fFlatDist = std::uniform_real_distribution<>(0., 1.);
GlobalInit(fFaxOptions, fLog);
Reset();
sRegistry.emplace_back(this);
unsigned n_chan = GetNumChannels();
fBLoffset = fBLslope = fNoiseRMS = fBaseline = vector<double>(n_chan, 0);
std::generate_n(fBLoffset.begin(), n_chan, [&]{return 17000 + 400*fFlatDist(fGen);});
std::generate_n(fBLslope.begin(), n_chan, [&]{return -0.27 + 0.01*fFlatDist(fGen);});
std::exponential_distribution<> noise(1);
std::generate_n(fNoiseRMS.begin(), n_chan, [&]{return 4*noise(fGen);});
std::generate_n(fBaseline.begin(), n_chan, [&]{return 13600 + 50*fFlatDist(fGen);});
return 0;
}
int f1724::End() {
AcquisitionStop(true);
return 0;
}
int f1724::WriteRegister(unsigned int reg, unsigned int val) {
if (reg == 0x8020 || (reg & 0x1020) == 0x1020) { // min record length
} else if (reg == 0x8038 || (reg & 0x1038) == 0x1038) { // pre-trigger
} else if (reg == 0x8060 || (reg & 0x1060) == 0x1060) { // trigger threshold
} else if (reg == 0x8078 || (reg & 0x1078) == 0x1078) { // samples under threshold
} else if (reg == 0x807C || (reg & 0x107C) == 0x107C) { // max tail
} else if (reg == 0x8098 || (reg & 0x1098) == 0x1098) { // DC offset
if (reg == 0x8098) std::fill_n(fBaseline.begin(), fBaseline.size(), val&0xFFFF);
else fBaseline[(reg>>8)&0xF] = (val&0xFFFF);
}
return 0;
}
unsigned int f1724::ReadRegister(unsigned int) {
return 0;
}
int f1724::Read(std::unique_ptr<data_packet>& outptr) {
if (fBufferSize == 0) return 0;
const std::lock_guard<std::mutex> lk(fBufferMutex);
int retwords = fBuffer.size();
auto [ht, cc] = GetClockInfo(fBuffer);
outptr = std::make_unique<data_packet>(std::move(fBuffer), ht, cc);
fBufferSize = 0;
return retwords;
}
int f1724::SWTrigger() {
ConvertToDigiFormat(GenerateNoise(fSPEtemplate.size(), 0xFF), 0xFF, sClock);
return 0;
}
void f1724::GlobalInit(fax_options_t& fax_options, std::shared_ptr<MongoLog>& log) {
if (sReady == false) {
sGen = std::mt19937_64(sRD());
sFlatDist = std::uniform_real_distribution<>(0., 1.);
sFaxOptions = fax_options;
sLog = log;
sLog->Entry(MongoLog::Local, "f1724 global init");
sReady = true;
sRun = false;
sClock = 0;
sEventCounter = 0;
sNumPMTs = (1+3*fax_options.tpc_size*(fax_options.tpc_size+1))*2;
int PMTsPerArray = sNumPMTs/2;
sPMTxy.reserve(sNumPMTs);
for (int p = 0; p < sNumPMTs; p++)
sPMTxy.emplace_back(PMTiToXY(p % PMTsPerArray));
sGeneratorThread = std::thread(&f1724::GlobalRun);
} else
sLog->Entry(MongoLog::Local, "f1724 global already init");
}
void f1724::GlobalDeinit() {
if (sGeneratorThread.joinable()) {
sLog->Entry(MongoLog::Local, "f1724::deinit");
sRun = sReady = false;
sCV.notify_one();
sGeneratorThread.join();
sLog.reset();
sRegistry.clear();
sPMTxy.clear();
}
}
uint32_t f1724::GetAcquisitionStatus() {
uint32_t ret = 0;
ret |= 0x4*(sRun == true); // run status
ret |= 0x8*(fBufferSize > 0); // event ready
ret |= 0x80; // no PLL unlock
ret |= 0x100*(sRun == true || sReady == true); // board is ready
ret |= 0x8000*(sRun == true); // S-IN
return ret;
}
int f1724::SoftwareStart() {
fLastClockTime = std::chrono::high_resolution_clock::now();
if (sReady == true) {
sRun = true;
sReady = false;
sCV.notify_one();
}
fGeneratorThread = std::thread(&f1724::Run, this);
return 0;
}
int f1724::SINStart() {
return SoftwareStart();
}
int f1724::AcquisitionStop(bool i_mean_it) {
if (!i_mean_it) return 0;
GlobalDeinit();
sRun = false;
fCV.notify_one();
if (fGeneratorThread.joinable()) fGeneratorThread.join();
Reset();
return 0;
}
int f1724::Reset() {
const std::lock_guard<std::mutex> lg(fBufferMutex);
fBuffer.clear();
fEventCounter = 0;
fBufferSize = 0;
return 0;
}
int f1724::GetClockCounter(uint32_t timestamp) {
// Waveform generation is asynchronous, so we need different logic here
// from a hardware digitizer
if (timestamp > fLastClock) {
// Case 1. This is over 15s but fSeenUnder5 is true. Give 1 back
if(timestamp >= 15e8 && fSeenUnder5 && fRolloverCounter != 0)
return fRolloverCounter-1;
// Case 2. This is over 5s and fSeenUnder5 is true.
else if(fSeenUnder5 && 5e8 <= timestamp && timestamp < 15e8){
fSeenUnder5 = false;
fLastClock = timestamp;
return fRolloverCounter;
}
// Case 3. This is over 15s and fSeenUnder5 is false
else if(timestamp >= 15e8 && !fSeenUnder5){
fSeenOver15 = true;
fLastClock = timestamp;
return fRolloverCounter;
}
// Case 4. Anything else where the clock is progressing correctly
else{
fLastClock = timestamp;
return fRolloverCounter;
}
}
// Second, is this number less than the previous?
else if(timestamp < fLastClock){
// Case 1. Genuine clock reset. under 5s is false and over 15s is true
if(timestamp < 5e8 && !fSeenUnder5 && fSeenOver15){
fSeenUnder5 = true;
fSeenOver15 = false;
fLog->Entry(MongoLog::Local, "Bd %i rollover %i (%x/%x)",
fBID, fRolloverCounter, timestamp, fLastClock);
fLastClock = timestamp;
fRolloverCounter++;
return fRolloverCounter;
}
// Case 2: Any other jitter within the 21 seconds, just return
else{
return fRolloverCounter;
}
}
// timestamps are the same???
else
return fRolloverCounter;
}
std::tuple<double, double, double> f1724::GenerateEventLocation() {
double offset = 0.5; // min number of PMTs between S1 and S2 to prevent overlap
double z = -1.*sFlatDist(sGen)*((2*sFaxOptions.tpc_size+1)-offset)-offset;
double r = sFlatDist(sGen)*sFaxOptions.tpc_size; // no, this isn't uniform
double theta = sFlatDist(sGen)*2*PI();
return {r*std::cos(theta), r*std::sin(theta), z};
}
vector<int> f1724::GenerateEventSize(double, double, double z) {
int s1 = sFlatDist(sGen)*19+11;
std::normal_distribution<> s2_over_s1{100, 20};
double elivetime_loss_fraction = std::exp(z/sFaxOptions.e_absorbtion_length);
int s2 = s1*s2_over_s1(sGen)*elivetime_loss_fraction;
return {0, s1, s2};
}
vector<f1724::hit_t> f1724::MakeHitpattern(int s_i, int photons, double x, double y, double z) {
double signal_width = s_i == 1 ? 40 : 1000.+200.*std::sqrt(std::abs(z));
vector<hit_t> ret(photons);
vector<double> hit_prob(sNumPMTs, 0.);
std::discrete_distribution<> hitpattern;
double top_fraction(0);
int TopPMTs = sNumPMTs/2;
int tpc_length = 2*sFaxOptions.tpc_size + 1;
if (s_i == 1) {
top_fraction = (0.4-0.1)/(0+tpc_length)*z+0.4; // 10% at bottom, 40% at top
std::fill_n(hit_prob.begin(), TopPMTs, top_fraction/TopPMTs);
} else {
top_fraction = 0.65;
// let's go with a Gaussian probability, because why not
double gaus_width = 2*1.3*1.3; // PMTs wide
auto gen = [&](auto& p){
return std::exp(-(std::pow(p.x-x, 2)+std::pow(p.y-y, 2))/gaus_width);
};
std::transform(sPMTxy.begin(), sPMTxy.begin()+TopPMTs, hit_prob.begin(), gen);
// normalize
double total_top_prob = std::accumulate(hit_prob.begin(),hit_prob.begin()+TopPMTs,0.);
std::transform(hit_prob.begin(), hit_prob.begin()+TopPMTs, hit_prob.begin(),
[&](double x){return top_fraction*x/total_top_prob;});
}
// bottom array probability simpler to calculate
std::fill(hit_prob.begin()+TopPMTs, hit_prob.end(), (1.-top_fraction)/TopPMTs);
hitpattern.param(std::discrete_distribution<>::param_type(hit_prob.begin(), hit_prob.end()));
std::generate_n(ret.begin(), photons,
[&]{return hit_t{hitpattern(sGen), f1724::sFlatDist(sGen)*signal_width};});
return ret;
}
void f1724::SendToWorkers(const vector<f1724::hit_t>& hits, long ts) {
vector<vector<hit_t>> hits_per_board(sRegistry.size());
int n_boards = sRegistry.size();
for (auto& hit : hits) {
hits_per_board[hit.pmt_i%n_boards].emplace_back(hit_t{hit.pmt_i/n_boards, hit.time});
}
for (unsigned i = 0; i < sRegistry.size(); i++)
if (hits_per_board[i].size() > 0)
sRegistry[i]->ReceiveFromGenerator(std::move(hits_per_board[i]), ts);
return;
}
void f1724::ReceiveFromGenerator(vector<hit_t> hits, long ts) {
{
std::lock_guard<std::mutex> lk(fMutex);
fProtoPulse = std::move(hits);
fTimestamp = ts;
}
fCV.notify_one();
}
void f1724::MakeWaveform(std::vector<hit_t>& hits, long timestamp) {
int mask = 0;
double last_hit_time = 0, first_hit_time = 1e9;
for (auto& hit : hits) {
mask |= (1<<hit.pmt_i);
last_hit_time = std::max(last_hit_time, hit.time);
first_hit_time = std::min(first_hit_time, hit.time);
}
timestamp += first_hit_time;
// which channels contribute?
vector<int> pmt_to_ch(GetNumChannels(), -1);
int j = 0;
for(unsigned ch = 0; ch < pmt_to_ch.size(); ch++) {
if (mask & (1<<ch)) {
pmt_to_ch[ch] = j++;
}
}
int wf_length = fSPEtemplate.size() + last_hit_time/fSampleWidth;
wf_length += wf_length % 2 ? 1 : 2; // ensure an even number of samples with room
auto wf = GenerateNoise(wf_length, mask);
std::normal_distribution<> hit_scale{1., 0.15};
int offset = 0;
double scale;
for (auto& hit : hits) {
offset = hit.time/fSampleWidth;
scale = hit_scale(fGen);
for (unsigned i = 0; i < fSPEtemplate.size(); i++) {
wf[pmt_to_ch[hit.pmt_i]][offset+i] -= fSPEtemplate[i]*scale;
}
}
ConvertToDigiFormat(wf, mask, timestamp);
return;
}
void f1724::ConvertToDigiFormat(const vector<vector<double>>& wf, int mask, long ts) {
const int overhead_per_channel = 2, overhead_per_event = 4;
double fail = 1;
std::u32string buffer;
char32_t word = 0;
for (auto& ch : wf) word += ch.size(); // samples
char32_t words_this_event = word/2 + overhead_per_channel*wf.size() + overhead_per_event;
buffer.reserve(words_this_event);
word = words_this_event | 0xA0000000;
buffer += word;
word = mask;
if (fSimulateCrashes && ((fail = fFlatDist(fGen)) < fFailProb)) {
word |= (1 << 26); // set the FAIL bit
fError = 1;
if (fail < fCrashProb)
throw std::runtime_error("Oops, I crashed");
}
buffer += (char32_t)mask;
word = fEventCounter.load();
fEventCounter++;
buffer += word;
char32_t timestamp = (ts/fClockCycle)&0x7FFFFFFF;
//fLog->Entry(MongoLog::Local, "Bd %i ts %lx/%08x", fBID, ts, timestamp);
buffer += timestamp;
int32_t sample;
for (auto& ch_wf : wf) {
word = ch_wf.size()/2 + overhead_per_channel; // size is in samples
buffer += word;
buffer += timestamp;
for (unsigned i = 0; i < ch_wf.size(); i += 2) {
sample = std::max(ch_wf[i], 0.);
word = sample & 0x3FFF;
sample = std::max(ch_wf[i+1], 0.);
word |= (sample << 16)&0x3FFF0000;
buffer += word;
} // loop over samples
} // loop over channels
{
const std::lock_guard<std::mutex> lg(fBufferMutex);
fBuffer.append(buffer);
fBufferSize = fBuffer.size();
}
return;
}
vector<vector<double>> f1724::GenerateNoise(int length, int mask) {
vector<vector<double>> ret;
unsigned n_chan = GetNumChannels();
ret.reserve(n_chan);
for (unsigned i = 0; i < n_chan; i++) {
if (mask & (1<<i)) {
ret.emplace_back(length, 0);
std::normal_distribution<> noise{fBaseline[i], fNoiseRMS[i]};
std::generate(ret.back().begin(), ret.back().end(), [&]{return noise(fGen);});
}
}
return ret;
}
void f1724::Run() {
while (sRun == true) {
std::unique_lock<std::mutex> lk(fMutex);
fCV.wait(lk, [&]{return fProtoPulse.size() > 0 || sRun == false;});
if (fProtoPulse.size() > 0 && sRun == true) {
MakeWaveform(fProtoPulse, fTimestamp.load());
fProtoPulse.clear();
} else {
}
lk.unlock();
}
}
void f1724::GlobalRun() {
std::exponential_distribution<> rate(sFaxOptions.rate/1e9); // Hz to /ns
double x, y, z, t_max;
long time_to_next;
vector<int> photons; // S1 = 1
vector<hit_t> hits;
sClock = (0.5+sFlatDist(sGen))*10000;
sEventCounter = 0;
{
std::unique_lock<std::mutex> lg(sMutex);
sCV.wait(lg, []{return sReady == false;});
}
sLog->Entry(MongoLog::Local, "f1724::GlobalRun");
auto t_start = std::chrono::high_resolution_clock::now();
while (sRun == true) {
std::tie(x,y,z) = GenerateEventLocation();
photons = GenerateEventSize(x, y, z);
for (const auto s_i : {1,2}) {
hits = MakeHitpattern(s_i, photons[s_i], x, y, z);
// split hitpattern and issue to digis
SendToWorkers(hits, sClock);
t_max = 0;
for (auto& hit : hits) {
t_max = std::max(t_max, hit.time);
}
time_to_next = (s_i == 1 ? std::abs(z/sFaxOptions.drift_speed) : rate(sGen)) + t_max;
sClock += time_to_next;
std::this_thread::sleep_for(std::chrono::nanoseconds(time_to_next));
}
sEventCounter++;
}
auto t_end = std::chrono::high_resolution_clock::now();
sLog->Entry(MongoLog::Local, "Generation lasted %lx/%lx", sClock,
std::chrono::duration_cast<std::chrono::nanoseconds>(t_end-t_start).count());
sLog->Entry(MongoLog::Local, "f1724::GlobalRun finished");
}