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DTC.cc
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2 
3 #include <vector>
4 #include <iterator>
5 #include <algorithm>
6 #include <numeric>
7 
8 using namespace std;
9 using namespace edm;
10 
11 namespace trackerDTC {
12 
13  DTC::DTC(const ParameterSet& iConfig,
14  const Setup& setup,
15  int dtcId,
16  const std::vector<std::vector<TTStubRef>>& stubsDTC)
17  : setup_(&setup),
18  enableTruncation_(iConfig.getParameter<bool>("EnableTruncation")),
19  region_(dtcId / setup.numDTCsPerRegion()),
20  board_(dtcId % setup.numDTCsPerRegion()),
21  modules_(setup.dtcModules(dtcId)),
22  input_(setup.dtcNumRoutingBlocks(), Stubss(setup.dtcNumModulesPerRoutingBlock())),
23  lost_(setup.numOverlappingRegions()) {
24  // count number of stubs on this dtc
25  auto acc = [](int& sum, const vector<TTStubRef>& stubsModule) { return sum += stubsModule.size(); };
26  const int nStubs = accumulate(stubsDTC.begin(), stubsDTC.end(), 0, acc);
27  stubs_.reserve(nStubs);
28  // convert and assign Stubs to DTC routing block channel
29  for (int modId = 0; modId < setup.numModulesPerDTC(); modId++) {
30  const vector<TTStubRef>& ttStubRefs = stubsDTC[modId];
31  if (ttStubRefs.empty())
32  continue;
33  // Module which produced this ttStubRefs
34  SensorModule* module = modules_.at(modId);
35  // DTC routing block id [0-1]
36  const int blockId = modId / setup.dtcNumModulesPerRoutingBlock();
37  // DTC routing blockc channel id [0-35]
38  const int channelId = modId % setup.dtcNumModulesPerRoutingBlock();
39  // convert TTStubs and fill input channel
40  Stubs& stubs = input_[blockId][channelId];
41  for (const TTStubRef& ttStubRef : ttStubRefs) {
42  stubs_.emplace_back(iConfig, setup, module, ttStubRef);
43  Stub& stub = stubs_.back();
44  if (stub.valid())
45  // passed pt and eta cut
46  stubs.push_back(&stub);
47  }
48  // sort stubs by bend
49  sort(stubs.begin(), stubs.end(), [](Stub* lhs, Stub* rhs) { return abs(lhs->bend()) < abs(rhs->bend()); });
50  // truncate stubs if desired
51  if (!enableTruncation_ || (int)stubs.size() <= setup.numFramesFE())
52  continue;
53  // begin of truncated stubs
54  const auto limit = next(stubs.begin(), setup.numFramesFE());
55  // copy truncated stubs into lost output channel
56  for (int region = 0; region < setup.numOverlappingRegions(); region++)
57  copy_if(
58  limit, stubs.end(), back_inserter(lost_[region]), [region](Stub* stub) { return stub->inRegion(region); });
59  // remove truncated stubs form input channel
60  stubs.erase(limit, stubs.end());
61  }
62  }
63 
64  // board level routing in two steps and products filling
65  void DTC::produce(TTDTC& productAccepted, TTDTC& productLost) {
66  // router step 1: merges stubs of all modules connected to one routing block into one stream
67  Stubs lost;
68  Stubss blockStubs(setup_->dtcNumRoutingBlocks());
69  for (int routingBlock = 0; routingBlock < setup_->dtcNumRoutingBlocks(); routingBlock++)
70  merge(input_[routingBlock], blockStubs[routingBlock], lost);
71  // copy lost stubs during merge into lost output channel
72  for (int region = 0; region < setup_->numOverlappingRegions(); region++) {
73  auto inRegion = [region](Stub* stub) { return stub->inRegion(region); };
74  copy_if(lost.begin(), lost.end(), back_inserter(lost_[region]), inRegion);
75  }
76  // router step 2: merges stubs of all routing blocks and splits stubs into one stream per overlapping region
77  Stubss regionStubs(setup_->numOverlappingRegions());
78  split(blockStubs, regionStubs);
79  // fill products
80  produce(regionStubs, productAccepted);
81  produce(lost_, productLost);
82  }
83 
84  // router step 1: merges stubs of all modules connected to one routing block into one stream
86  // for each input one fifo
87  Stubss stacks(inputs.size());
88  // clock accurate firmware emulation, each while trip describes one clock tick
89  while (!all_of(inputs.begin(), inputs.end(), [](const Stubs& channel) { return channel.empty(); }) or
90  !all_of(stacks.begin(), stacks.end(), [](const Stubs& channel) { return channel.empty(); })) {
91  // fill fifos
92  for (int iInput = 0; iInput < (int)inputs.size(); iInput++) {
93  Stubs& input = inputs[iInput];
94  Stubs& stack = stacks[iInput];
95  if (input.empty())
96  continue;
97  Stub* stub = pop_front(input);
98  if (stub) {
99  if (enableTruncation_ && (int)stack.size() == setup_->dtcDepthMemory() - 1)
100  // kill current first stub when fifo overflows
101  lost.push_back(pop_front(stack));
102  stack.push_back(stub);
103  }
104  }
105  // route stub from a fifo to output if possible
106  bool nothingToRoute(true);
107  for (int iInput = inputs.size() - 1; iInput >= 0; iInput--) {
108  Stubs& stack = stacks[iInput];
109  if (stack.empty())
110  continue;
111  nothingToRoute = false;
112  output.push_back(pop_front(stack));
113  // only one stub can be routed to output per clock tick
114  break;
115  }
116  // each clock tick output will grow by one, if no stub is available then by a gap
117  if (nothingToRoute)
118  output.push_back(nullptr);
119  }
120  // truncate if desired
121  if (enableTruncation_ && (int)output.size() > setup_->numFramesIO()) {
122  const auto limit = next(output.begin(), setup_->numFramesIO());
123  copy_if(limit, output.end(), back_inserter(lost), [](Stub* stub) { return stub; });
124  output.erase(limit, output.end());
125  }
126  // remove all gaps between end and last stub
127  for (auto it = output.end(); it != output.begin();)
128  it = (*--it) ? output.begin() : output.erase(it);
129  }
130 
131  // router step 2: merges stubs of all routing blocks and splits stubs into one stream per overlapping region
133  int region(0);
134  auto regionMask = [&region](Stub* stub) { return stub && stub->inRegion(region) ? stub : nullptr; };
135  for (Stubs& output : outputs) {
136  // copy of masked inputs for each output
137  Stubss streams(inputs.size());
138  int i(0);
139  for (Stubs& input : inputs) {
140  Stubs& stream = streams[i++];
141  transform(input.begin(), input.end(), back_inserter(stream), regionMask);
142  for (auto it = stream.end(); it != stream.begin();)
143  it = (*--it) ? stream.begin() : stream.erase(it);
144  }
146  }
147  }
148 
149  // conversion from Stubss to TTDTC
150  void DTC::produce(const Stubss& stubss, TTDTC& product) {
151  int channel(0);
152  auto toFrame = [&channel](Stub* stub) {
153  return stub ? make_pair(stub->ttStubRef(), stub->frame(channel)) : TTDTC::Frame();
154  };
155  for (const Stubs& stubs : stubss) {
157  stream.reserve(stubs.size());
158  transform(stubs.begin(), stubs.end(), back_inserter(stream), toFrame);
159  product.setStream(region_, board_, channel++, stream);
160  }
161  }
162 
163  // pop_front function which additionally returns copy of deleted front
165  Stub* stub = deque.front();
166  deque.pop_front();
167  return stub;
168  }
169 
170 } // namespace trackerDTC
TTDTC
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