d0/d31/readoutdatacontainers__test_8cxx_source.html

 /**

  * @file   readoutdatacontainers_test.cxx

  * @brief  Unit test for `ReadoutDataContainers.h` library.

  * @author Gianluca Petrillo (petrillo@slac.stanford.edu)

  * @date   September 7, 2019

  */


 // Boost libraries

 #define BOOST_TEST_MODULE (readout data containers test)

 #include <boost/test/unit_test.hpp>


 // LArSoft libraries

 #include "larcorealg/Geometry/ReadoutDataContainers.h"

 #include "larcorealg/CoreUtils/counter.h"

 #include "larcoreobj/SimpleTypesAndConstants/readout_types.h"


 //------------------------------------------------------------------------------

 template <typename T>

 struct Summer {


   T sum = T { 0 };


   void operator() (T v) { sum += v; }


   T get() const { return sum; }

   void reset() { sum = T{0}; }


 }; // struct Summer


 //------------------------------------------------------------------------------

 void TPCsetDataContainerTest(

   readout::TPCsetDataContainer<int> data, // copy is intentional

   std::size_t const NCryostats,

   std::size_t const NTPCsets

 ) {


   std::size_t const N = NCryostats * NTPCsets;


   BOOST_TEST(!data.empty());

   BOOST_TEST(data.size() == N);

   BOOST_TEST(data.capacity() >= N);


   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       BOOST_TEST((data[{ c, s }]) == 0);


   BOOST_TEST(data.firstID() == readout::TPCsetID(0, 0));

   BOOST_TEST(data.lastID() == readout::TPCsetID(1, 2));


   std::size_t expected_index = 0U;


   // simple R/W iteration test

   for (auto& value: data) {

     static_assert(std::is_same_v<decltype(value), decltype(data)::reference>);


     readout::TPCsetID const expected_ID = data.mapper().ID(expected_index);

     BOOST_TEST(value == data[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(data.size() == expected_index);


   // ID/data pair R/W iteration test

   expected_index = 0U;

   for (auto&& [ ID, value ]: data.items()) {

     static_assert(std::is_same_v<decltype(ID), readout::TPCsetID>);

     static_assert(std::is_same_v<decltype(value), decltype(data)::reference>);


     readout::TPCsetID const expected_ID = data.mapper().ID(expected_index);

     BOOST_TEST(ID == expected_ID);

     BOOST_TEST(value == data[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(data.size() == expected_index);


   BOOST_TEST( data.hasTPCset({ 0,  0}));

   BOOST_TEST( data.hasTPCset({ 0,  1}));

   BOOST_TEST( data.hasTPCset({ 0,  2}));

   BOOST_TEST(!data.hasTPCset({ 0,  3}));

   BOOST_TEST(!data.hasTPCset({ 0,  4}));

   BOOST_TEST( data.hasTPCset({ 1,  0}));

   BOOST_TEST( data.hasTPCset({ 1,  1}));

   BOOST_TEST( data.hasTPCset({ 1,  2}));

   BOOST_TEST(!data.hasTPCset({ 1,  3}));

   BOOST_TEST(!data.hasTPCset({ 1,  4}));

   BOOST_TEST(!data.hasTPCset({ 2,  0}));

   BOOST_TEST(!data.hasTPCset({ 2,  1}));

   BOOST_TEST(!data.hasTPCset({ 2,  2}));

   BOOST_TEST(!data.hasTPCset({ 2,  3}));

   BOOST_TEST(!data.hasTPCset({ 2,  4}));


   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 0,  0}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 0,  1}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 0,  2}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 0,  3}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 0,  4}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 1,  0}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 1,  1}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 1,  2}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 1,  3}));

   BOOST_TEST( data.hasCryostat(readout::TPCsetID{ 1,  4}));

   BOOST_TEST(!data.hasCryostat(readout::TPCsetID{ 2,  0}));

   BOOST_TEST(!data.hasCryostat(readout::TPCsetID{ 2,  1}));

   BOOST_TEST(!data.hasCryostat(readout::TPCsetID{ 2,  2}));

   BOOST_TEST(!data.hasCryostat(readout::TPCsetID{ 2,  3}));

   BOOST_TEST(!data.hasCryostat(readout::TPCsetID{ 2,  4}));


   data[{0, 0}] = 4;

   BOOST_TEST((data[{0, 0}]) == 4);

   BOOST_TEST(data.at({0, 0}) == 4);

   data[{0, 0}] = 5;

   BOOST_TEST((data[{0, 0}]) == 5);

   BOOST_TEST(data.at({0, 0}) == 5);


   data[{0, 1}] = 6;

   BOOST_TEST((data[{0, 1}]) == 6);

   BOOST_TEST(data.at({0, 1}) == 6);


   BOOST_TEST((data[{0, 0}]) ==  5);


   data[{0, 2}] = 7;

   BOOST_TEST((data[{0, 2}]) == 7);

   BOOST_TEST(data.at({0, 2}) == 7);


   BOOST_TEST((data[{0, 0}]) ==  5);

   BOOST_TEST((data[{0, 1}]) ==  6);


   data[{1, 0}] = 15;

   BOOST_TEST((data[{1, 0}]) == 15);

   BOOST_TEST(data.at({1, 0}) == 15);


   BOOST_TEST((data[{0, 0}]) ==  5);

   BOOST_TEST((data[{0, 1}]) ==  6);

   BOOST_TEST((data[{0, 2}]) ==  7);


   data[{1, 1}] = 16;

   BOOST_TEST((data[{1, 1}]) == 16);

   BOOST_TEST(data.at({1, 1}) == 16);


   BOOST_TEST((data[{0, 0}]) ==  5);

   BOOST_TEST((data[{0, 1}]) ==  6);

   BOOST_TEST((data[{0, 2}]) ==  7);

   BOOST_TEST((data[{1, 0}]) == 15);


   data[{1, 2}] = 17;

   BOOST_TEST((data[{1, 2}]) == 17);

   BOOST_TEST(data.at({1, 2}) == 17);


   BOOST_TEST((data[{0, 0}]) ==  5);

   BOOST_TEST((data[{0, 1}]) ==  6);

   BOOST_TEST((data[{0, 2}]) ==  7);

   BOOST_TEST((data[{1, 0}]) == 15);

   BOOST_TEST((data[{1, 1}]) == 16);


   BOOST_CHECK_THROW(data.at({0, 3}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 4}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 3}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 4}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 3}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 4}), std::out_of_range);


   BOOST_TEST(data.first() == 5);

   data.first() = -5;

   BOOST_TEST((data[{0, 0}]) == -5);

   BOOST_TEST(data.first() == -5);

   data.first() =  5;


   BOOST_TEST(data.last() == 17);

   data.last() = -17;

   BOOST_TEST((data[{1U, 2U}]) == -17);

   BOOST_TEST(data.last() == -17);

   data.last() =  17;


   auto const& constData = data;


   BOOST_TEST

     (std::addressof(constData.first()) == std::addressof(data.first()));

   BOOST_TEST

     (std::addressof(constData.last()) == std::addressof(data.last()));


   BOOST_TEST((constData[{0, 0}]) == (data[{0, 0}]));

   BOOST_TEST((constData[{0, 1}]) == (data[{0, 1}]));

   BOOST_TEST((constData[{0, 2}]) == (data[{0, 2}]));

   BOOST_TEST((constData[{1, 0}]) == (data[{1, 0}]));

   BOOST_TEST((constData[{1, 1}]) == (data[{1, 1}]));

   BOOST_TEST((constData[{1, 2}]) == (data[{1, 2}]));

   BOOST_TEST(constData.at({0, 0}) == data.at({0, 0}));

   BOOST_TEST(constData.at({0, 1}) == data.at({0, 1}));

   BOOST_TEST(constData.at({0, 2}) == data.at({0, 2}));

   BOOST_TEST(constData.at({1, 0}) == data.at({1, 0}));

   BOOST_TEST(constData.at({1, 1}) == data.at({1, 1}));

   BOOST_TEST(constData.at({1, 2}) == data.at({1, 2}));


   BOOST_CHECK_THROW(constData.at({0, 3}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 4}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 3}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 4}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 3}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 4}), std::out_of_range);


   auto const cb = constData.begin();

   auto const ce = constData.end();

   BOOST_TEST(static_cast<size_t>(ce - cb) == N);


   // simple read-only iteration test

   expected_index = 0U;

   for (auto& value: constData) {

     static_assert(std::is_same_v

       <decltype(value), std::decay_t<decltype(constData)>::const_reference>

       );


     readout::TPCsetID const expected_ID = constData.mapper().ID(expected_index);

     BOOST_TEST(value == constData[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(constData.size() == expected_index);


   // ID/data pair read-only iteration test

   expected_index = 0U;

   for (auto&& [ ID, value ]: constData.items()) {

     static_assert(std::is_same_v<decltype(ID), readout::TPCsetID>);

     static_assert(std::is_same_v

       <decltype(value), std::decay_t<decltype(constData)>::const_reference>

       );


     readout::TPCsetID const expected_ID = constData.mapper().ID(expected_index);

     BOOST_TEST(ID == expected_ID);

     BOOST_TEST(value == constData[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(constData.size() == expected_index);


   data.fill(14);

   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       BOOST_TEST((data[{ c, s }]) == 14);


   data.apply([](int& v){ v *= 2; });

   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       BOOST_TEST((data[{ c, s }]) == 28);


   Summer<int> summer;

   static_assert(std::is_same_v<decltype(data.apply(summer)), Summer<int>&>);

   data.apply(summer);

   BOOST_TEST(summer.get() == N * 28);


   summer.reset();

   static_assert

     (std::is_same_v<decltype(constData.apply(summer)), Summer<int>&>);

   constData.apply(summer);

   BOOST_TEST(summer.get() == N * 28);


   auto summer1 = data.apply(Summer<int>{});

   BOOST_TEST(summer1.get() == N * 28);


   auto summer2 = constData.apply(Summer<int>{});

   BOOST_TEST(summer2.get() == N * 28);


   data.reset();

   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       BOOST_TEST((data[{ c, s }]) == 0);


   data.clear();

   BOOST_TEST(data.empty());


 } // TPCsetDataContainerTest()


 //------------------------------------------------------------------------------

 void ROPDataContainerTest(

   readout::ROPDataContainer<int> data, // copy is intentional

   std::size_t const NCryostats,

   std::size_t const NTPCsets,

   std::size_t const NROPs

 ) {


   std::size_t const N = NCryostats * NTPCsets * NROPs;


   BOOST_TEST(!data.empty());

   BOOST_TEST(data.size() == N);

   BOOST_TEST(data.capacity() >= N);


   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       for (auto r: util::counter<unsigned int>(NROPs))

         BOOST_TEST((data[{ c, s, r }]) == 0);


   BOOST_TEST(data.firstID() == readout::ROPID(0, 0, 0));

   BOOST_TEST(data.lastID() == readout::ROPID(1, 2, 1));


   std::size_t expected_index = 0U;


   // simple R/W iteration test

   for (auto& value: data) {

     static_assert(std::is_same_v<decltype(value), decltype(data)::reference>);


     readout::ROPID const expected_ID = data.mapper().ID(expected_index);

     BOOST_TEST(value == data[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(data.size() == expected_index);


   // ID/data pair R/W iteration test

   expected_index = 0U;

   for (auto&& [ ID, value ]: data.items()) {

     static_assert(std::is_same_v<decltype(ID), readout::ROPID>);

     static_assert(std::is_same_v<decltype(value), decltype(data)::reference>);


     readout::ROPID const expected_ID = data.mapper().ID(expected_index);

     BOOST_TEST(ID == expected_ID);

     BOOST_TEST(value == data[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(data.size() == expected_index);


   BOOST_TEST( data.hasROP({ 0, 0, 0}));

   BOOST_TEST( data.hasROP({ 0, 0, 1}));

   BOOST_TEST(!data.hasROP({ 0, 0, 2}));

   BOOST_TEST( data.hasROP({ 0, 1, 0}));

   BOOST_TEST( data.hasROP({ 0, 1, 1}));

   BOOST_TEST(!data.hasROP({ 0, 1, 2}));

   BOOST_TEST( data.hasROP({ 0, 2, 0}));

   BOOST_TEST( data.hasROP({ 0, 2, 1}));

   BOOST_TEST(!data.hasROP({ 0, 2, 2}));

   BOOST_TEST(!data.hasROP({ 0, 3, 0}));

   BOOST_TEST(!data.hasROP({ 0, 3, 1}));

   BOOST_TEST(!data.hasROP({ 0, 3, 2}));

   BOOST_TEST(!data.hasROP({ 0, 4, 0}));

   BOOST_TEST(!data.hasROP({ 0, 4, 1}));

   BOOST_TEST(!data.hasROP({ 0, 4, 2}));

   BOOST_TEST( data.hasROP({ 1, 0, 0}));

   BOOST_TEST( data.hasROP({ 1, 0, 1}));

   BOOST_TEST(!data.hasROP({ 1, 0, 2}));

   BOOST_TEST( data.hasROP({ 1, 1, 0}));

   BOOST_TEST( data.hasROP({ 1, 1, 1}));

   BOOST_TEST(!data.hasROP({ 1, 1, 2}));

   BOOST_TEST( data.hasROP({ 1, 2, 0}));

   BOOST_TEST( data.hasROP({ 1, 2, 1}));

   BOOST_TEST(!data.hasROP({ 1, 2, 2}));

   BOOST_TEST(!data.hasROP({ 1, 3, 0}));

   BOOST_TEST(!data.hasROP({ 1, 3, 1}));

   BOOST_TEST(!data.hasROP({ 1, 3, 2}));

   BOOST_TEST(!data.hasROP({ 1, 4, 0}));

   BOOST_TEST(!data.hasROP({ 1, 4, 1}));

   BOOST_TEST(!data.hasROP({ 1, 4, 2}));

   BOOST_TEST(!data.hasROP({ 2, 0, 0}));

   BOOST_TEST(!data.hasROP({ 2, 0, 1}));

   BOOST_TEST(!data.hasROP({ 2, 0, 2}));

   BOOST_TEST(!data.hasROP({ 2, 1, 0}));

   BOOST_TEST(!data.hasROP({ 2, 1, 1}));

   BOOST_TEST(!data.hasROP({ 2, 1, 2}));

   BOOST_TEST(!data.hasROP({ 2, 2, 0}));

   BOOST_TEST(!data.hasROP({ 2, 2, 1}));

   BOOST_TEST(!data.hasROP({ 2, 2, 2}));

   BOOST_TEST(!data.hasROP({ 2, 3, 0}));

   BOOST_TEST(!data.hasROP({ 2, 3, 1}));

   BOOST_TEST(!data.hasROP({ 2, 3, 2}));

   BOOST_TEST(!data.hasROP({ 2, 4, 0}));

   BOOST_TEST(!data.hasROP({ 2, 4, 1}));

   BOOST_TEST(!data.hasROP({ 2, 4, 2}));


   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 0, 0}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 0, 1}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 0, 2}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 1, 0}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 1, 1}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 1, 2}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 2, 0}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 2, 1}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 0, 2, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 0, 3, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 0, 3, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 0, 3, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 0, 4, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 0, 4, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 0, 4, 2}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 0, 0}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 0, 1}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 0, 2}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 1, 0}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 1, 1}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 1, 2}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 2, 0}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 2, 1}));

   BOOST_TEST( data.hasTPCset(readout::ROPID{ 1, 2, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 1, 3, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 1, 3, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 1, 3, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 1, 4, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 1, 4, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 1, 4, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 0, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 0, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 0, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 1, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 1, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 1, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 2, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 2, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 2, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 3, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 3, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 3, 2}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 4, 0}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 4, 1}));

   BOOST_TEST(!data.hasTPCset(readout::ROPID{ 2, 4, 2}));


   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 0, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 0, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 0, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 1, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 1, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 1, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 2, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 2, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 2, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 3, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 3, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 3, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 4, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 4, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 0, 4, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 0, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 0, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 0, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 1, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 1, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 1, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 2, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 2, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 2, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 3, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 3, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 3, 2}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 4, 0}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 4, 1}));

   BOOST_TEST( data.hasCryostat(readout::ROPID{ 1, 4, 2}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 0, 0}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 0, 1}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 0, 2}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 1, 0}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 1, 1}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 1, 2}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 2, 0}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 2, 1}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 2, 2}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 3, 0}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 3, 1}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 3, 2}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 4, 0}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 4, 1}));

   BOOST_TEST(!data.hasCryostat(readout::ROPID{ 2, 4, 2}));


   data[{0, 0, 0}] = 4;

   BOOST_TEST(  (data[{0, 0, 0}]) ==   4);

   BOOST_TEST(data.at({0, 0, 0}) ==    4);

   data[{0, 0, 0}] = 5;

   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(data.at({0, 0, 0}) ==    5);


   data[{0, 0, 1}] = 6;

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(data.at({0, 0, 1}) ==    6);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);


   data[{0, 1, 0}] = 15;

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(data.at({0, 1, 0}) ==   15);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);


   data[{0, 1, 1}] = 16;

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(data.at({0, 1, 1}) ==   16);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);


   data[{0, 2, 0}] = 25;

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);

   BOOST_TEST(data.at({0, 2, 0}) ==   25);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);


   data[{0, 2, 1}] = 26;

   BOOST_TEST(  (data[{0, 2, 1}]) ==  26);

   BOOST_TEST(data.at({0, 2, 1}) ==   26);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);


   data[{1, 0, 0}] = 105;

   BOOST_TEST(  (data[{1, 0, 0}]) == 105);

   BOOST_TEST(data.at({1, 0, 0}) ==  105);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);

   BOOST_TEST(  (data[{0, 2, 1}]) ==  26);


   data[{1, 0, 1}] = 106;

   BOOST_TEST(  (data[{1, 0, 1}]) == 106);

   BOOST_TEST(data.at({1, 0, 1}) ==  106);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);

   BOOST_TEST(  (data[{0, 2, 1}]) ==  26);

   BOOST_TEST(  (data[{1, 0, 0}]) == 105);


   data[{1, 1, 0}] = 115;

   BOOST_TEST(  (data[{1, 1, 0}]) == 115);

   BOOST_TEST(data.at({1, 1, 0}) ==  115);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);

   BOOST_TEST(  (data[{0, 2, 1}]) ==  26);

   BOOST_TEST(  (data[{1, 0, 0}]) == 105);

   BOOST_TEST(  (data[{1, 0, 1}]) == 106);


   data[{1, 1, 1}] = 116;

   BOOST_TEST(  (data[{1, 1, 1}]) == 116);

   BOOST_TEST(data.at({1, 1, 1}) ==  116);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);

   BOOST_TEST(  (data[{0, 2, 1}]) ==  26);

   BOOST_TEST(  (data[{1, 0, 0}]) == 105);

   BOOST_TEST(  (data[{1, 0, 1}]) == 106);

   BOOST_TEST(  (data[{1, 1, 0}]) == 115);


   data[{1, 2, 0}] = 125;

   BOOST_TEST(  (data[{1, 2, 0}]) == 125);

   BOOST_TEST(data.at({1, 2, 0}) ==  125);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);

   BOOST_TEST(  (data[{0, 2, 1}]) ==  26);

   BOOST_TEST(  (data[{1, 0, 0}]) == 105);

   BOOST_TEST(  (data[{1, 0, 1}]) == 106);

   BOOST_TEST(  (data[{1, 1, 0}]) == 115);

   BOOST_TEST(  (data[{1, 1, 1}]) == 116);


   data[{1, 2, 1}] = 126;

   BOOST_TEST(  (data[{1, 2, 1}]) == 126);

   BOOST_TEST(data.at({1, 2, 1}) ==  126);


   BOOST_TEST(  (data[{0, 0, 0}]) ==   5);

   BOOST_TEST(  (data[{0, 0, 1}]) ==   6);

   BOOST_TEST(  (data[{0, 1, 0}]) ==  15);

   BOOST_TEST(  (data[{0, 1, 1}]) ==  16);

   BOOST_TEST(  (data[{0, 2, 0}]) ==  25);

   BOOST_TEST(  (data[{0, 2, 1}]) ==  26);

   BOOST_TEST(  (data[{1, 0, 0}]) == 105);

   BOOST_TEST(  (data[{1, 0, 1}]) == 106);

   BOOST_TEST(  (data[{1, 1, 0}]) == 115);

   BOOST_TEST(  (data[{1, 1, 1}]) == 116);

   BOOST_TEST(  (data[{1, 2, 0}]) == 125);


   BOOST_CHECK_THROW(data.at({0, 3, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 4, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 3, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 4, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 0, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 1, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 2, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 3, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 4, 0}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 3, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 4, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 3, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 4, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 0, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 1, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 2, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 3, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 4, 1}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 0, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 1, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({0, 3, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 0, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 1, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({1, 3, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 0, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 1, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(data.at({2, 3, 2}), std::out_of_range);


   BOOST_TEST(data.first() == 5);

   data.first() = -5;

   BOOST_TEST((data[{0, 0, 0}]) == -5);

   BOOST_TEST(data.first() == -5);

   data.first() =  5;


   BOOST_TEST(data.last() == 126);

   data.last() = -126;

   BOOST_TEST((data[{1U, 2U, 1U}]) == -126);

   BOOST_TEST(data.last() == -126);

   data.last() =  126;


   auto const& constData = data;


   BOOST_TEST

     (std::addressof(constData.first()) == std::addressof(data.first()));

   BOOST_TEST

     (std::addressof(constData.last()) == std::addressof(data.last()));


   BOOST_TEST((constData[{0, 0, 0}]) == (data[{0, 0, 0}]));

   BOOST_TEST((constData[{0, 0, 1}]) == (data[{0, 0, 1}]));

   BOOST_TEST((constData[{0, 1, 0}]) == (data[{0, 1, 0}]));

   BOOST_TEST((constData[{0, 1, 1}]) == (data[{0, 1, 1}]));

   BOOST_TEST((constData[{0, 2, 0}]) == (data[{0, 2, 0}]));

   BOOST_TEST((constData[{0, 2, 1}]) == (data[{0, 2, 1}]));

   BOOST_TEST((constData[{1, 0, 0}]) == (data[{1, 0, 0}]));

   BOOST_TEST((constData[{1, 0, 1}]) == (data[{1, 0, 1}]));

   BOOST_TEST((constData[{1, 1, 0}]) == (data[{1, 1, 0}]));

   BOOST_TEST((constData[{1, 1, 1}]) == (data[{1, 1, 1}]));

   BOOST_TEST((constData[{1, 2, 0}]) == (data[{1, 2, 0}]));

   BOOST_TEST((constData[{1, 2, 1}]) == (data[{1, 2, 1}]));

   BOOST_TEST(constData.at({0, 0, 0}) == data.at({0, 0, 0}));

   BOOST_TEST(constData.at({0, 0, 1}) == data.at({0, 0, 1}));

   BOOST_TEST(constData.at({0, 1, 0}) == data.at({0, 1, 0}));

   BOOST_TEST(constData.at({0, 1, 1}) == data.at({0, 1, 1}));

   BOOST_TEST(constData.at({0, 2, 0}) == data.at({0, 2, 0}));

   BOOST_TEST(constData.at({0, 2, 1}) == data.at({0, 2, 1}));

   BOOST_TEST(constData.at({1, 0, 0}) == data.at({1, 0, 0}));

   BOOST_TEST(constData.at({1, 0, 1}) == data.at({1, 0, 1}));

   BOOST_TEST(constData.at({1, 1, 0}) == data.at({1, 1, 0}));

   BOOST_TEST(constData.at({1, 1, 1}) == data.at({1, 1, 1}));

   BOOST_TEST(constData.at({1, 2, 0}) == data.at({1, 2, 0}));

   BOOST_TEST(constData.at({1, 2, 1}) == data.at({1, 2, 1}));


   BOOST_CHECK_THROW(constData.at({0, 3, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 4, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 3, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 4, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 0, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 1, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 2, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 3, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 4, 0}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 3, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 4, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 3, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 4, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 0, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 1, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 2, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 3, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 4, 1}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 0, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 1, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({0, 3, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 0, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 1, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({1, 3, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 0, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 1, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 2, 2}), std::out_of_range);

   BOOST_CHECK_THROW(constData.at({2, 3, 2}), std::out_of_range);


   auto const cb = constData.begin();

   auto const ce = constData.end();

   BOOST_TEST(static_cast<size_t>(ce - cb) == N);


   // simple read-only iteration test

   expected_index = 0U;

   for (auto& value: constData) {

     static_assert(std::is_same_v

       <decltype(value), std::decay_t<decltype(constData)>::const_reference>

       );


     readout::ROPID const expected_ID = constData.mapper().ID(expected_index);

     BOOST_TEST(value == constData[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(constData.size() == expected_index);


   // ID/data pair read-only iteration test

   expected_index = 0U;

   for (auto&& [ ID, value ]: constData.items()) {

     static_assert(std::is_same_v<decltype(ID), readout::ROPID>);

     static_assert(std::is_same_v

       <decltype(value), std::decay_t<decltype(constData)>::const_reference>

       );


     readout::ROPID const expected_ID = constData.mapper().ID(expected_index);

     BOOST_TEST(ID == expected_ID);

     BOOST_TEST(value == constData[expected_ID]);


     ++expected_index;

   } // for

   BOOST_TEST(constData.size() == expected_index);


   data.fill(14);

   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       for (auto r: util::counter<unsigned int>(NROPs))

         BOOST_TEST((data[{ c, s, r }]) == 14);


   data.apply([](int& v){ v *= 2; });

   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       for (auto r: util::counter<unsigned int>(NROPs))

         BOOST_TEST((data[{ c, s, r }]) == 28);


   Summer<int> summer;

   static_assert(std::is_same_v<decltype(data.apply(summer)), Summer<int>&>);

   data.apply(summer);

   BOOST_TEST(summer.get() == N * 28);


   summer.reset();

   static_assert

     (std::is_same_v<decltype(constData.apply(summer)), Summer<int>&>);

   constData.apply(summer);

   BOOST_TEST(summer.get() == N * 28);


   auto summer1 = data.apply(Summer<int>{});

   BOOST_TEST(summer1.get() == N * 28);


   auto summer2 = constData.apply(Summer<int>{});

   BOOST_TEST(summer2.get() == N * 28);


   data.reset();

   for (auto c: util::counter<unsigned int>(NCryostats))

     for (auto s: util::counter<unsigned short int>(NTPCsets))

       for (auto r: util::counter<unsigned int>(NROPs))

         BOOST_TEST((data[{ c, s, r }]) == 0);


   data.clear();

   BOOST_TEST(data.empty());


 } // ROPDataContainerTest()


 BOOST_AUTO_TEST_SUITE(readoutdatacontainers_test)


 //------------------------------------------------------------------------------

 BOOST_AUTO_TEST_CASE(TPCsetDataContainerTestCase) {


   constexpr std::size_t NCryostats = 2U;

   constexpr std::size_t NTPCsets   = 3U;


   //

   // size constructor

   //

   readout::TPCsetDataContainer<int> data1(NCryostats, NTPCsets);

   TPCsetDataContainerTest(data1, NCryostats, NTPCsets);


   //

   // default constructor + resize

   //

   readout::TPCsetDataContainer<int> data2;

   BOOST_TEST(data2.empty());


   data2.resizeAs(data1);

   TPCsetDataContainerTest(data2, NCryostats, NTPCsets);


 } // TPCsetDataContainerTestCase


 //------------------------------------------------------------------------------

 BOOST_AUTO_TEST_CASE(ROPDataContainerTestCase) {


   constexpr std::size_t NCryostats = 2U;

   constexpr std::size_t NTPCsets   = 3U;

   constexpr std::size_t NROPs      = 2U;


   //

   // size constructor

   //

   readout::ROPDataContainer<int> data1(NCryostats, NTPCsets, NROPs);

   ROPDataContainerTest(data1, NCryostats, NTPCsets, NROPs);


   //

   // default constructor + resize

   //

   readout::ROPDataContainer<int> data2;

   BOOST_TEST(data2.empty());


   data2.resizeAs(data1);

   ROPDataContainerTest(data2, NCryostats, NTPCsets, NROPs);


 } // ROPDataContainerTestCase


 //------------------------------------------------------------------------------


 BOOST_AUTO_TEST_SUITE_END()

BOOST_AUTO_TEST_CASE
BOOST_AUTO_TEST_CASE(AllTests)
Definition: WaveformOperations_test.cc:128

readout::TPCsetDataContainer
Container with one element per readout TPC set.
Definition: ReadoutDataContainers.h:23

geo::GeoIDdataContainer< T, readout::TPCsetIDmapper<> >::firstID
GeoID firstID() const
Returns the ID of the first element with GeoID type.

geo::GeoIDdataContainer< T, readout::TPCsetIDmapper<> >::lastID
GeoID lastID() const
Returns the ID of the last covered element with GeoID type.

readout_types.h
Classes identifying readout-related concepts.

readout::fhicl::ROPID
IDparameter< readout::ROPID > ROPID
Member type of validated readout::ROPID parameter.
Definition: readout_types_fhicl.h:156

readout::ROPDataContainer
Container with one element per readout plane.
Definition: ReadoutDataContainers.h:26

geo::GeoIDdataContainer< T, readout::TPCsetIDmapper<> >::capacity
size_type capacity() const
Returns the number of elements the container has memory for.

readout::TPCsetID
Class identifying a set of TPC sharing readout channels.
Definition: readout_types.h:70

TPCsetDataContainerTest
void TPCsetDataContainerTest(readout::TPCsetDataContainer< int > data, std::size_t const NCryostats, std::size_t const NTPCsets)
Definition: readoutdatacontainers_test.cxx:32

Summer::get
T get() const
Definition: geometrydatacontainers_test.cxx:27

readout::fhicl::TPCsetID
IDparameter< readout::TPCsetID > TPCsetID
Member type of validated readout::TPCsetID parameter.
Definition: readout_types_fhicl.h:139

counter.h
Test of util::counter and support utilities.

readout::ROPID
Class identifying a set of planes sharing readout channels.
Definition: readout_types.h:168

Summer
Definition: geometrydatacontainers_test.cxx:21

Summer::sum
T sum
Definition: geometrydatacontainers_test.cxx:23

s
then echo File list $list not found else cat $list while read file do echo $file sed s
Definition: file_to_url.sh:60

N
process_name largeant stream1 can override from command line with o or output physics producers generator N
Definition: prova_source.fcl:33

value
temporary value
Definition: pmtsimulation_icarus.fcl:216

geo::GeoIDdataContainer< T, readout::TPCsetIDmapper<> >::size
size_type size() const
Returns the number of elements in the container.

ROPDataContainerTest
void ROPDataContainerTest(readout::ROPDataContainer< int > data, std::size_t const NCryostats, std::size_t const NTPCsets, std::size_t const NROPs)
Definition: readoutdatacontainers_test.cxx:285

Summer::operator()
void operator()(T v)
Definition: geometrydatacontainers_test.cxx:25

geo::GeoIDdataContainer< T, readout::TPCsetIDmapper<> >::empty
bool empty() const
Returns whether the container has no elements (false by assumptions).

geo::GeoIDdataContainer< T, readout::TPCsetIDmapper<> >::resizeAs
void resizeAs(geo::GeoIDdataContainer< OT, Mapper_t > const &other)
Prepares the container with default-constructed data.

ReadoutDataContainers.h
Containers to hold one datum per TPC set or readout plane.

r
esac echo uname r
Definition: condor_lar_pubs.sh:698

Summer::reset
void reset()
Definition: readoutdatacontainers_test.cxx:27