doc/master/RField_8cxx_source.html

 /// \file RField.cxx
 /// \ingroup NTuple ROOT7
 /// \author Jakob Blomer <jblomer@cern.ch>
 /// \date 2018-10-15
 /// \warning This is part of the ROOT 7 prototype! It will change without notice. It might trigger earthquakes. Feedback
 /// is welcome!

 /*************************************************************************
  * Copyright (C) 1995-2019, Rene Brun and Fons Rademakers.               *
  * All rights reserved.                                                  *
  *                                                                       *
  * For the licensing terms see $ROOTSYS/LICENSE.                         *
  * For the list of contributors see $ROOTSYS/README/CREDITS.             *
  *************************************************************************/

 #include <ROOT/RColumn.hxx>
 #include <ROOT/RColumnModel.hxx>
 #include <ROOT/REntry.hxx>
 #include <ROOT/RField.hxx>
 #include <ROOT/RFieldValue.hxx>
 #include <ROOT/RFieldVisitor.hxx>
 #include <ROOT/RLogger.hxx>
 #include <ROOT/RNTuple.hxx>
 #include <ROOT/RNTupleModel.hxx>

 #include <TClass.h>
 #include <TCollection.h>
 #include <TDataMember.h>
 #include <TError.h>
 #include <TList.h>

 #include <algorithm>
 #include <cctype> // for isspace
 #include <cstdlib> // for malloc, free
 #include <cstring> // for memset
 #include <exception>
 #include <iostream>
 #include <type_traits>

 namespace {

 /// Used in CreateField() in order to get the comma-separated list of template types
 /// E.g., gets {"int", "std::variant<double,int>"} from "int,std::variant<double,int>"
 std::vector<std::string> TokenizeTypeList(std::string templateType) {
    std::vector<std::string> result;
    if (templateType.empty())
       return result;

    const char *eol = templateType.data() + templateType.length();
    const char *typeBegin = templateType.data();
    const char *typeCursor = templateType.data();
    unsigned int nestingLevel = 0;
    while (typeCursor != eol) {
       switch (*typeCursor) {
       case '<':
          ++nestingLevel;
          break;
       case '>':
          --nestingLevel;
          break;
       case ',':
          if (nestingLevel == 0) {
             result.push_back(std::string(typeBegin, typeCursor - typeBegin));
             typeBegin = typeCursor + 1;
          }
          break;
       }
       typeCursor++;
    }
    result.push_back(std::string(typeBegin, typeCursor - typeBegin));
    return result;
 }

 } // anonymous namespace

 void ROOT::Experimental::Detail::RFieldFuse::Connect(DescriptorId_t fieldId, RPageStorage &pageStorage, RFieldBase &field)
 {
    if (field.fColumns.empty())
       field.GenerateColumnsImpl();
    for (auto& column : field.fColumns)
       column->Connect(fieldId, &pageStorage);
 }


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


 ROOT::Experimental::Detail::RFieldBase::RFieldBase(
    std::string_view name, std::string_view type, ENTupleStructure structure, bool isSimple, std::size_t nRepetitions)
    : fName(name), fType(type), fStructure(structure), fNRepetitions(nRepetitions), fIsSimple(isSimple),
      fParent(nullptr), fPrincipalColumn(nullptr)
 {
 }

 ROOT::Experimental::Detail::RFieldBase::~RFieldBase()
 {
 }

 ROOT::Experimental::Detail::RFieldBase*
 ROOT::Experimental::Detail::RFieldBase::Create(const std::string &fieldName, const std::string &typeName)
 {
    std::string normalizedType(typeName);
    normalizedType.erase(remove_if(normalizedType.begin(), normalizedType.end(), isspace), normalizedType.end());
    // TODO(jblomer): use a type translation map
    if (normalizedType == "Bool_t") normalizedType = "bool";
    if (normalizedType == "Float_t") normalizedType = "float";
    if (normalizedType == "Double_t") normalizedType = "double";
    if (normalizedType == "UChar_t") normalizedType = "std::uint8_t";
    if (normalizedType == "unsigned char") normalizedType = "std::uint8_t";
    if (normalizedType == "uint8_t") normalizedType = "std::uint8_t";
    if (normalizedType == "Int_t") normalizedType = "std::int32_t";
    if (normalizedType == "int") normalizedType = "std::int32_t";
    if (normalizedType == "int32_t") normalizedType = "std::int32_t";
    if (normalizedType == "unsigned") normalizedType = "std::uint32_t";
    if (normalizedType == "unsigned int") normalizedType = "std::uint32_t";
    if (normalizedType == "UInt_t") normalizedType = "std::uint32_t";
    if (normalizedType == "uint32_t") normalizedType = "std::uint32_t";
    if (normalizedType == "ULong64_t") normalizedType = "std::uint64_t";
    if (normalizedType == "uint64_t") normalizedType = "std::uint64_t";
    if (normalizedType == "string") normalizedType = "std::string";
    if (normalizedType.substr(0, 7) == "vector<") normalizedType = "std::" + normalizedType;
    if (normalizedType.substr(0, 6) == "array<") normalizedType = "std::" + normalizedType;
    if (normalizedType.substr(0, 8) == "variant<") normalizedType = "std::" + normalizedType;

    if (normalizedType == "ROOT::Experimental::ClusterSize_t") return new RField<ClusterSize_t>(fieldName);
    if (normalizedType == "bool") return new RField<bool>(fieldName);
    if (normalizedType == "std::uint8_t") return new RField<std::uint8_t>(fieldName);
    if (normalizedType == "std::int32_t") return new RField<std::int32_t>(fieldName);
    if (normalizedType == "std::uint32_t") return new RField<std::uint32_t>(fieldName);
    if (normalizedType == "std::uint64_t") return new RField<std::uint64_t>(fieldName);
    if (normalizedType == "float") return new RField<float>(fieldName);
    if (normalizedType == "double") return new RField<double>(fieldName);
    if (normalizedType == "std::string") return new RField<std::string>(fieldName);
    if (normalizedType == "std::vector<bool>") return new RField<std::vector<bool>>(fieldName);
    if (normalizedType.substr(0, 12) == "std::vector<") {
       std::string itemTypeName = normalizedType.substr(12, normalizedType.length() - 13);
       auto itemField = Create(itemTypeName, itemTypeName);
       return new RFieldVector(fieldName, std::unique_ptr<Detail::RFieldBase>(itemField));
    }
    // For the time being, we silently read RVec fields as std::vector
    if (normalizedType == "ROOT::VecOps::RVec<bool>") return new RField<ROOT::VecOps::RVec<bool>>(fieldName);
    if (normalizedType.substr(0, 19) == "ROOT::VecOps::RVec<") {
       std::string itemTypeName = normalizedType.substr(19, normalizedType.length() - 20);
       auto itemField = Create(itemTypeName, itemTypeName);
       return new RFieldVector(fieldName, std::unique_ptr<Detail::RFieldBase>(itemField));
    }
    if (normalizedType.substr(0, 11) == "std::array<") {
       auto arrayDef = TokenizeTypeList(normalizedType.substr(11, normalizedType.length() - 12));
       R__ASSERT(arrayDef.size() == 2);
       auto arrayLength = std::stoi(arrayDef[1]);
       auto itemField = Create(arrayDef[0], arrayDef[0]);
       return new RFieldArray(fieldName, std::unique_ptr<Detail::RFieldBase>(itemField), arrayLength);
    }
 #if __cplusplus >= 201703L
    if (normalizedType.substr(0, 13) == "std::variant<") {
       auto innerTypes = TokenizeTypeList(normalizedType.substr(13, normalizedType.length() - 14));
       std::vector<RFieldBase *> items;
       for (unsigned int i = 0; i < innerTypes.size(); ++i) {
          items.emplace_back(Create("variant" + std::to_string(i), innerTypes[i]));
       }
       return new RFieldVariant(fieldName, items);
    }
 #endif
    // TODO: create an RFieldCollection?
    if (normalizedType == ":Collection:") return new RField<ClusterSize_t>(fieldName);
    auto cl = TClass::GetClass(normalizedType.c_str());
    if (cl != nullptr) {
       return new RFieldClass(fieldName, normalizedType);
    }
    R__ERROR_HERE("NTuple") << "Field " << fieldName << " has unknown type " << normalizedType;
    R__ASSERT(false);
    return nullptr;
 }

 void ROOT::Experimental::Detail::RFieldBase::AppendImpl(const ROOT::Experimental::Detail::RFieldValue& /*value*/) {
    R__ASSERT(false);
 }

 void ROOT::Experimental::Detail::RFieldBase::ReadGlobalImpl(
    ROOT::Experimental::NTupleSize_t /*index*/,
    RFieldValue* /*value*/)
 {
    R__ASSERT(false);
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::Detail::RFieldBase::GenerateValue()
 {
    void *where = malloc(GetValueSize());
    R__ASSERT(where != nullptr);
    return GenerateValue(where);
 }

 void ROOT::Experimental::Detail::RFieldBase::DestroyValue(const RFieldValue &value, bool dtorOnly)
 {
    if (!dtorOnly)
       free(value.GetRawPtr());
 }

 std::vector<ROOT::Experimental::Detail::RFieldValue>
 ROOT::Experimental::Detail::RFieldBase::SplitValue(const RFieldValue & /*value*/) const
 {
    return std::vector<RFieldValue>();
 }

 void ROOT::Experimental::Detail::RFieldBase::Attach(
    std::unique_ptr<ROOT::Experimental::Detail::RFieldBase> child)
 {
    child->fParent = this;
    fSubFields.emplace_back(std::move(child));
 }


 std::vector<const ROOT::Experimental::Detail::RFieldBase *>
 ROOT::Experimental::Detail::RFieldBase::GetSubFields() const
 {
    std::vector<const RFieldBase *> result;
    for (const auto &f : fSubFields) {
       result.emplace_back(f.get());
    }
    return result;
 }


 void ROOT::Experimental::Detail::RFieldBase::Flush() const
 {
    for (auto& column : fColumns) {
       column->Flush();
    }
 }


 void ROOT::Experimental::Detail::RFieldBase::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitField(*this);
 }


 ROOT::Experimental::Detail::RFieldBase::RSchemaIterator ROOT::Experimental::Detail::RFieldBase::begin()
 {
    if (fSubFields.empty()) return RSchemaIterator(this, -1);
    return RSchemaIterator(this->fSubFields[0].get(), 0);
 }


 ROOT::Experimental::Detail::RFieldBase::RSchemaIterator ROOT::Experimental::Detail::RFieldBase::end()
 {
    return RSchemaIterator(this, -1);
 }


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


 void ROOT::Experimental::Detail::RFieldBase::RSchemaIterator::Advance()
 {
    auto itr = fStack.rbegin();
    if (!itr->fFieldPtr->fSubFields.empty()) {
       fStack.emplace_back(Position(itr->fFieldPtr->fSubFields[0].get(), 0));
       return;
    }

    unsigned int nextIdxInParent = ++(itr->fIdxInParent);
    while (nextIdxInParent >= itr->fFieldPtr->fParent->fSubFields.size()) {
       if (fStack.size() == 1) {
          itr->fFieldPtr = itr->fFieldPtr->fParent;
          itr->fIdxInParent = -1;
          return;
       }
       fStack.pop_back();
       itr = fStack.rbegin();
       nextIdxInParent = ++(itr->fIdxInParent);
    }
    itr->fFieldPtr = itr->fFieldPtr->fParent->fSubFields[nextIdxInParent].get();
 }


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


 ROOT::Experimental::Detail::RFieldBase *ROOT::Experimental::RFieldRoot::Clone(std::string_view /*newName*/)
 {
    Detail::RFieldBase* result = new RFieldRoot();
    for (auto &f : fSubFields) {
       auto clone = f->Clone(f->GetName());
       result->Attach(std::unique_ptr<RFieldBase>(clone));
    }
    return result;
 }


 ROOT::Experimental::REntry* ROOT::Experimental::RFieldRoot::GenerateEntry()
 {
    auto entry = new REntry();
    for (auto& f : fSubFields) {
       entry->AddValue(f->GenerateValue());
    }
    return entry;
 }

 void ROOT::Experimental::RFieldRoot::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitRootField(*this);
 }


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


 void ROOT::Experimental::RField<ROOT::Experimental::ClusterSize_t>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kIndex, true /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<ClusterSize_t, EColumnType::kIndex>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<ROOT::Experimental::ClusterSize_t>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitClusterSizeField(*this);
 }

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

 void ROOT::Experimental::RField<std::uint8_t>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kByte, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(Detail::RColumn::Create<
       std::uint8_t, EColumnType::kByte>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<std::uint8_t>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitUInt8Field(*this);
 }

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


 void ROOT::Experimental::RField<bool>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kBit, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<bool, EColumnType::kBit>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<bool>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitBoolField(*this);
 }

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


 void ROOT::Experimental::RField<float>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kReal32, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<float, EColumnType::kReal32>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<float>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitFloatField(*this);
 }


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

 void ROOT::Experimental::RField<double>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kReal64, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<double, EColumnType::kReal64>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<double>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitDoubleField(*this);
 }

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

 void ROOT::Experimental::RField<std::int32_t>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kInt32, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(Detail::RColumn::Create<
       std::int32_t, EColumnType::kInt32>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<std::int32_t>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitIntField(*this);
 }

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

 void ROOT::Experimental::RField<std::uint32_t>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kInt32, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<std::uint32_t, EColumnType::kInt32>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<std::uint32_t>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitUInt32Field(*this);
 }

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

 void ROOT::Experimental::RField<std::uint64_t>::GenerateColumnsImpl()
 {
    RColumnModel model(EColumnType::kInt64, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<std::uint64_t, EColumnType::kInt64>(model, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<std::uint64_t>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitUInt64Field(*this);
 }

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


 void ROOT::Experimental::RField<std::string>::GenerateColumnsImpl()
 {
    RColumnModel modelIndex(EColumnType::kIndex, true /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<ClusterSize_t, EColumnType::kIndex>(modelIndex, 0)));

    RColumnModel modelChars(EColumnType::kByte, false /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<char, EColumnType::kByte>(modelChars, 1)));
    fPrincipalColumn = fColumns[0].get();
 }

 void ROOT::Experimental::RField<std::string>::AppendImpl(const ROOT::Experimental::Detail::RFieldValue& value)
 {
    auto typedValue = value.Get<std::string>();
    auto length = typedValue->length();
    Detail::RColumnElement<char, EColumnType::kByte> elemChars(const_cast<char*>(typedValue->data()));
    fColumns[1]->AppendV(elemChars, length);
    fIndex += length;
    fColumns[0]->Append(fElemIndex);
 }

 void ROOT::Experimental::RField<std::string>::ReadGlobalImpl(
    ROOT::Experimental::NTupleSize_t globalIndex, ROOT::Experimental::Detail::RFieldValue *value)
 {
    auto typedValue = value->Get<std::string>();
    RClusterIndex collectionStart;
    ClusterSize_t nChars;
    fPrincipalColumn->GetCollectionInfo(globalIndex, &collectionStart, &nChars);
    if (nChars == 0) {
       typedValue->clear();
    } else {
       typedValue->resize(nChars);
       Detail::RColumnElement<char, EColumnType::kByte> elemChars(const_cast<char*>(typedValue->data()));
       fColumns[1]->ReadV(collectionStart, nChars, &elemChars);
    }
 }

 void ROOT::Experimental::RField<std::string>::CommitCluster()
 {
    fIndex = 0;
 }

 void ROOT::Experimental::RField<std::string>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitStringField(*this);
 }

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


 ROOT::Experimental::RFieldClass::RFieldClass(std::string_view fieldName, std::string_view className)
    : ROOT::Experimental::Detail::RFieldBase(fieldName, className, ENTupleStructure::kRecord, false /* isSimple */)
    , fClass(TClass::GetClass(std::string(className).c_str()))
 {
    if (fClass == nullptr) {
       throw std::runtime_error("RField: no I/O support for type " + std::string(className));
    }
    TIter next(fClass->GetListOfDataMembers());
    while (auto dataMember = static_cast<TDataMember *>(next())) {
       //printf("Now looking at %s %s\n", dataMember->GetName(), dataMember->GetFullTypeName());
       auto subField = Detail::RFieldBase::Create(dataMember->GetName(), dataMember->GetFullTypeName());
       fMaxAlignment = std::max(fMaxAlignment, subField->GetAlignment());
       Attach(std::unique_ptr<Detail::RFieldBase>(subField));
    }
 }

 ROOT::Experimental::Detail::RFieldBase* ROOT::Experimental::RFieldClass::Clone(std::string_view newName)
 {
    return new RFieldClass(newName, GetType());
 }

 void ROOT::Experimental::RFieldClass::AppendImpl(const Detail::RFieldValue& value) {
    TIter next(fClass->GetListOfDataMembers());
    unsigned i = 0;
    while (auto dataMember = static_cast<TDataMember *>(next())) {
       auto memberValue = fSubFields[i]->CaptureValue(value.Get<unsigned char>() + dataMember->GetOffset());
       fSubFields[i]->Append(memberValue);
       i++;
    }
 }

 void ROOT::Experimental::RFieldClass::ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue *value)
 {
    TIter next(fClass->GetListOfDataMembers());
    unsigned i = 0;
    while (auto dataMember = static_cast<TDataMember *>(next())) {
       auto memberValue = fSubFields[i]->GenerateValue(value->Get<unsigned char>() + dataMember->GetOffset());
       fSubFields[i]->Read(globalIndex, &memberValue);
       i++;
    }
 }

 void ROOT::Experimental::RFieldClass::ReadInClusterImpl(const RClusterIndex &clusterIndex, Detail::RFieldValue *value)
 {
    TIter next(fClass->GetListOfDataMembers());
    unsigned i = 0;
    while (auto dataMember = static_cast<TDataMember *>(next())) {
       auto memberValue = fSubFields[i]->GenerateValue(value->Get<unsigned char>() + dataMember->GetOffset());
       fSubFields[i]->Read(clusterIndex, &memberValue);
       i++;
    }
 }

 void ROOT::Experimental::RFieldClass::GenerateColumnsImpl()
 {
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldClass::GenerateValue(void* where)
 {
    return Detail::RFieldValue(true /* captureFlag */, this, fClass->New(where));
 }

 void ROOT::Experimental::RFieldClass::DestroyValue(const Detail::RFieldValue& value, bool dtorOnly)
 {
    fClass->Destructor(value.GetRawPtr(), true /* dtorOnly */);
    if (!dtorOnly)
       free(value.GetRawPtr());
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldClass::CaptureValue(void* where)
 {
    return Detail::RFieldValue(true /* captureFlat */, this, where);
 }


 std::vector<ROOT::Experimental::Detail::RFieldValue>
 ROOT::Experimental::RFieldClass::SplitValue(const Detail::RFieldValue &value) const
 {
    TIter next(fClass->GetListOfDataMembers());
    unsigned i = 0;
    std::vector<Detail::RFieldValue> result;
    while (auto dataMember = static_cast<TDataMember *>(next())) {
       auto memberValue = fSubFields[i]->CaptureValue(value.Get<unsigned char>() + dataMember->GetOffset());
       result.emplace_back(memberValue);
       i++;
    }
    return result;
 }


 size_t ROOT::Experimental::RFieldClass::GetValueSize() const
 {
    return fClass->GetClassSize();
 }

 void ROOT::Experimental::RFieldClass::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitClassField(*this);
 }

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


 ROOT::Experimental::RFieldVector::RFieldVector(
    std::string_view fieldName, std::unique_ptr<Detail::RFieldBase> itemField)
    : ROOT::Experimental::Detail::RFieldBase(
       fieldName, "std::vector<" + itemField->GetType() + ">", ENTupleStructure::kCollection, false /* isSimple */)
    , fItemSize(itemField->GetValueSize()), fNWritten(0)
 {
    Attach(std::move(itemField));
 }

 ROOT::Experimental::Detail::RFieldBase* ROOT::Experimental::RFieldVector::Clone(std::string_view newName)
 {
    auto newItemField = fSubFields[0]->Clone(fSubFields[0]->GetName());
    return new RFieldVector(newName, std::unique_ptr<Detail::RFieldBase>(newItemField));
 }

 void ROOT::Experimental::RFieldVector::AppendImpl(const Detail::RFieldValue& value) {
    auto typedValue = value.Get<std::vector<char>>();
    R__ASSERT((typedValue->size() % fItemSize) == 0);
    auto count = typedValue->size() / fItemSize;
    for (unsigned i = 0; i < count; ++i) {
       auto itemValue = fSubFields[0]->CaptureValue(typedValue->data() + (i * fItemSize));
       fSubFields[0]->Append(itemValue);
    }
    Detail::RColumnElement<ClusterSize_t, EColumnType::kIndex> elemIndex(&fNWritten);
    fNWritten += count;
    fColumns[0]->Append(elemIndex);
 }

 void ROOT::Experimental::RFieldVector::ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue *value)
 {
    auto typedValue = value->Get<std::vector<char>>();

    ClusterSize_t nItems;
    RClusterIndex collectionStart;
    fPrincipalColumn->GetCollectionInfo(globalIndex, &collectionStart, &nItems);

    typedValue->resize(nItems * fItemSize);
    for (unsigned i = 0; i < nItems; ++i) {
       auto itemValue = fSubFields[0]->GenerateValue(typedValue->data() + (i * fItemSize));
       fSubFields[0]->Read(collectionStart + i, &itemValue);
    }
 }

 void ROOT::Experimental::RFieldVector::GenerateColumnsImpl()
 {
    RColumnModel modelIndex(EColumnType::kIndex, true /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<ClusterSize_t, EColumnType::kIndex>(modelIndex, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldVector::GenerateValue(void* where)
 {
    return Detail::RFieldValue(this, reinterpret_cast<std::vector<char>*>(where));
 }

 void ROOT::Experimental::RFieldVector::DestroyValue(const Detail::RFieldValue& value, bool dtorOnly)
 {
    auto vec = static_cast<std::vector<char>*>(value.GetRawPtr());
    R__ASSERT((vec->size() % fItemSize) == 0);
    auto nItems = vec->size() / fItemSize;
    for (unsigned i = 0; i < nItems; ++i) {
       auto itemValue = fSubFields[0]->CaptureValue(vec->data() + (i * fItemSize));
       fSubFields[0]->DestroyValue(itemValue, true /* dtorOnly */);
    }
    vec->~vector();
    if (!dtorOnly)
       free(vec);
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldVector::CaptureValue(void* where)
 {
    return Detail::RFieldValue(true /* captureFlag */, this, where);
 }

 std::vector<ROOT::Experimental::Detail::RFieldValue>
 ROOT::Experimental::RFieldVector::SplitValue(const Detail::RFieldValue &value) const
 {
    auto vec = static_cast<std::vector<char>*>(value.GetRawPtr());
    R__ASSERT((vec->size() % fItemSize) == 0);
    auto nItems = vec->size() / fItemSize;
    std::vector<Detail::RFieldValue> result;
    for (unsigned i = 0; i < nItems; ++i) {
       result.emplace_back(fSubFields[0]->CaptureValue(vec->data() + (i * fItemSize)));
    }
    return result;
 }

 void ROOT::Experimental::RFieldVector::CommitCluster()
 {
    fNWritten = 0;
 }

 void ROOT::Experimental::RFieldVector::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitVectorField(*this);
 }


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


 ROOT::Experimental::RField<std::vector<bool>>::RField(std::string_view name)
    : ROOT::Experimental::Detail::RFieldBase(name, "std::vector<bool>", ENTupleStructure::kCollection,
                                             false /* isSimple */)
 {
    Attach(std::make_unique<RField<bool>>("bool"));
 }

 void ROOT::Experimental::RField<std::vector<bool>>::AppendImpl(const Detail::RFieldValue& value) {
    auto typedValue = value.Get<std::vector<bool>>();
    auto count = typedValue->size();
    for (unsigned i = 0; i < count; ++i) {
       bool bval = (*typedValue)[i];
       auto itemValue = fSubFields[0]->CaptureValue(&bval);
       fSubFields[0]->Append(itemValue);
    }
    Detail::RColumnElement<ClusterSize_t, EColumnType::kIndex> elemIndex(&fNWritten);
    fNWritten += count;
    fColumns[0]->Append(elemIndex);
 }

 void ROOT::Experimental::RField<std::vector<bool>>::ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue* value)
 {
    auto typedValue = value->Get<std::vector<bool>>();

    ClusterSize_t nItems;
    RClusterIndex collectionStart;
    fPrincipalColumn->GetCollectionInfo(globalIndex, &collectionStart, &nItems);

    typedValue->resize(nItems);
    for (unsigned i = 0; i < nItems; ++i) {
       bool bval;
       auto itemValue = fSubFields[0]->GenerateValue(&bval);
       fSubFields[0]->Read(collectionStart + i, &itemValue);
       (*typedValue)[i] = bval;
    }
 }

 void ROOT::Experimental::RField<std::vector<bool>>::GenerateColumnsImpl()
 {
    RColumnModel modelIndex(EColumnType::kIndex, true /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<ClusterSize_t, EColumnType::kIndex>(modelIndex, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 std::vector<ROOT::Experimental::Detail::RFieldValue>
 ROOT::Experimental::RField<std::vector<bool>>::SplitValue(const Detail::RFieldValue& value) const
 {
    const static bool trueValue = true;
    const static bool falseValue = false;

    auto typedValue = value.Get<std::vector<bool>>();
    auto count = typedValue->size();
    std::vector<Detail::RFieldValue> result;
    for (unsigned i = 0; i < count; ++i) {
       if ((*typedValue)[i])
          result.emplace_back(fSubFields[0]->CaptureValue(const_cast<bool *>(&trueValue)));
       else
          result.emplace_back(fSubFields[0]->CaptureValue(const_cast<bool *>(&falseValue)));
    }
    return result;
 }


 void ROOT::Experimental::RField<std::vector<bool>>::DestroyValue(const Detail::RFieldValue& value, bool dtorOnly)
 {
    auto vec = static_cast<std::vector<bool>*>(value.GetRawPtr());
    vec->~vector();
    if (!dtorOnly)
       free(vec);
 }

 void ROOT::Experimental::RField<std::vector<bool>>::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitVectorBoolField(*this);
 }


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


 ROOT::Experimental::RFieldArray::RFieldArray(
    std::string_view fieldName, std::unique_ptr<Detail::RFieldBase> itemField, std::size_t arrayLength)
    : ROOT::Experimental::Detail::RFieldBase(
       fieldName, "std::array<" + itemField->GetType() + "," + std::to_string(arrayLength) + ">",
       ENTupleStructure::kLeaf, false /* isSimple */, arrayLength)
    , fItemSize(itemField->GetValueSize()), fArrayLength(arrayLength)
 {
    Attach(std::move(itemField));
 }

 ROOT::Experimental::Detail::RFieldBase *ROOT::Experimental::RFieldArray::Clone(std::string_view newName)
 {
    auto newItemField = fSubFields[0]->Clone(fSubFields[0]->GetName());
    return new RFieldArray(newName, std::unique_ptr<Detail::RFieldBase>(newItemField), fArrayLength);
 }

 void ROOT::Experimental::RFieldArray::AppendImpl(const Detail::RFieldValue& value) {
    auto arrayPtr = value.Get<unsigned char>();
    for (unsigned i = 0; i < fArrayLength; ++i) {
       auto itemValue = fSubFields[0]->CaptureValue(arrayPtr + (i * fItemSize));
       fSubFields[0]->Append(itemValue);
    }
 }

 void ROOT::Experimental::RFieldArray::ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue *value)
 {
    auto arrayPtr = value->Get<unsigned char>();
    for (unsigned i = 0; i < fArrayLength; ++i) {
       auto itemValue = fSubFields[0]->GenerateValue(arrayPtr + (i * fItemSize));
       fSubFields[0]->Read(globalIndex * fArrayLength + i, &itemValue);
    }
 }

 void ROOT::Experimental::RFieldArray::ReadInClusterImpl(const RClusterIndex &clusterIndex, Detail::RFieldValue *value)
 {
    auto arrayPtr = value->Get<unsigned char>();
    for (unsigned i = 0; i < fArrayLength; ++i) {
       auto itemValue = fSubFields[0]->GenerateValue(arrayPtr + (i * fItemSize));
       fSubFields[0]->Read(RClusterIndex(clusterIndex.GetClusterId(), clusterIndex.GetIndex() * fArrayLength + i),
                           &itemValue);
    }
 }

 void ROOT::Experimental::RFieldArray::GenerateColumnsImpl()
 {
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldArray::GenerateValue(void *where)
 {
    auto arrayPtr = reinterpret_cast<unsigned char *>(where);
    for (unsigned i = 0; i < fArrayLength; ++i) {
       fSubFields[0]->GenerateValue(arrayPtr + (i * fItemSize));
    }
    return Detail::RFieldValue(true /* captureFlag */, this, where);
 }

 void ROOT::Experimental::RFieldArray::DestroyValue(const Detail::RFieldValue& value, bool dtorOnly)
 {
    auto arrayPtr = value.Get<unsigned char>();
    for (unsigned i = 0; i < fArrayLength; ++i) {
       auto itemValue = fSubFields[0]->CaptureValue(arrayPtr + (i * fItemSize));
       fSubFields[0]->DestroyValue(itemValue, true /* dtorOnly */);
    }
    if (!dtorOnly)
       free(arrayPtr);
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldArray::CaptureValue(void *where)
 {
    return Detail::RFieldValue(true /* captureFlag */, this, where);
 }

 std::vector<ROOT::Experimental::Detail::RFieldValue>
 ROOT::Experimental::RFieldArray::SplitValue(const Detail::RFieldValue &value) const
 {
    auto arrayPtr = value.Get<unsigned char>();
    std::vector<Detail::RFieldValue> result;
    for (unsigned i = 0; i < fArrayLength; ++i) {
       auto itemValue = fSubFields[0]->CaptureValue(arrayPtr + (i * fItemSize));
       result.emplace_back(itemValue);
    }
    return result;
 }

 void ROOT::Experimental::RFieldArray::AcceptVisitor(Detail::RFieldVisitor &visitor) const
 {
    visitor.VisitArrayField(*this);
 }

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

 #if __cplusplus >= 201703L
 std::string ROOT::Experimental::RFieldVariant::GetTypeList(const std::vector<Detail::RFieldBase *> &itemFields)
 {
    std::string result;
    for (size_t i = 0; i < itemFields.size(); ++i) {
       result += itemFields[i]->GetType() + ",";
    }
    R__ASSERT(!result.empty()); // there is always at least one variant
    result.pop_back(); // remove trailing comma
    return result;
 }

 ROOT::Experimental::RFieldVariant::RFieldVariant(
    std::string_view fieldName, const std::vector<Detail::RFieldBase *> &itemFields)
    : ROOT::Experimental::Detail::RFieldBase(fieldName,
       "std::variant<" + GetTypeList(itemFields) + ">", ENTupleStructure::kVariant, false /* isSimple */)
 {
    auto nFields = itemFields.size();
    R__ASSERT(nFields > 0);
    fNWritten.resize(nFields, 0);
    for (unsigned int i = 0; i < nFields; ++i) {
       fMaxItemSize = std::max(fMaxItemSize, itemFields[i]->GetValueSize());
       fMaxAlignment = std::max(fMaxAlignment, itemFields[i]->GetAlignment());
       Attach(std::unique_ptr<Detail::RFieldBase>(itemFields[i]));
    }
    fTagOffset = (fMaxItemSize < fMaxAlignment) ? fMaxAlignment : fMaxItemSize;
 }

 ROOT::Experimental::Detail::RFieldBase *ROOT::Experimental::RFieldVariant::Clone(std::string_view newName)
 {
    auto nFields = fSubFields.size();
    std::vector<Detail::RFieldBase *> itemFields;
    for (unsigned i = 0; i < nFields; ++i) {
       itemFields.emplace_back(fSubFields[i]->Clone(fSubFields[i]->GetName()));
    }
    return new RFieldVariant(newName, itemFields);
 }

 std::uint32_t ROOT::Experimental::RFieldVariant::GetTag(void *variantPtr) const
 {
    auto index = *(reinterpret_cast<char *>(variantPtr) + fTagOffset);
    return (index < 0) ? 0 : index + 1;
 }

 void ROOT::Experimental::RFieldVariant::SetTag(void *variantPtr, std::uint32_t tag) const
 {
    auto index = reinterpret_cast<char *>(variantPtr) + fTagOffset;
    *index = static_cast<char>(tag - 1);
 }

 void ROOT::Experimental::RFieldVariant::AppendImpl(const Detail::RFieldValue& value)
 {
    auto tag = GetTag(value.GetRawPtr());
    auto index = 0;
    if (tag > 0) {
       auto itemValue = fSubFields[tag - 1]->CaptureValue(value.GetRawPtr());
       fSubFields[tag - 1]->Append(itemValue);
       index = fNWritten[tag - 1]++;
    }
    RColumnSwitch varSwitch(ClusterSize_t(index), tag);
    Detail::RColumnElement<RColumnSwitch, EColumnType::kSwitch> elemSwitch(&varSwitch);
    fColumns[0]->Append(elemSwitch);
 }

 void ROOT::Experimental::RFieldVariant::ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue *value)
 {
    RClusterIndex variantIndex;
    std::uint32_t tag;
    fPrincipalColumn->GetSwitchInfo(globalIndex, &variantIndex, &tag);
    R__ASSERT(tag > 0); // TODO(jblomer): deal with invalid variants

    auto itemValue = fSubFields[tag - 1]->GenerateValue(value->GetRawPtr());
    fSubFields[tag - 1]->Read(variantIndex, &itemValue);
    SetTag(value->GetRawPtr(), tag);
 }

 void ROOT::Experimental::RFieldVariant::GenerateColumnsImpl()
 {
    RColumnModel modelSwitch(EColumnType::kSwitch, false);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<RColumnSwitch, EColumnType::kSwitch>(modelSwitch, 0)));
    fPrincipalColumn = fColumns[0].get();
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldVariant::GenerateValue(void *where)
 {
    memset(where, 0, GetValueSize());
    fSubFields[0]->GenerateValue(where);
    SetTag(where, 1);
    return Detail::RFieldValue(this, reinterpret_cast<unsigned char *>(where));
 }

 void ROOT::Experimental::RFieldVariant::DestroyValue(const Detail::RFieldValue& value, bool dtorOnly)
 {
    auto variantPtr = value.GetRawPtr();
    auto tag = GetTag(variantPtr);
    if (tag > 0) {
       auto itemValue = fSubFields[tag - 1]->CaptureValue(variantPtr);
       fSubFields[tag - 1]->DestroyValue(itemValue, true /* dtorOnly */);
    }
    if (!dtorOnly)
       free(variantPtr);
 }

 ROOT::Experimental::Detail::RFieldValue ROOT::Experimental::RFieldVariant::CaptureValue(void *where)
 {
    return Detail::RFieldValue(true /* captureFlag */, this, where);
 }

 size_t ROOT::Experimental::RFieldVariant::GetValueSize() const
 {
    return fMaxItemSize + fMaxAlignment;  // TODO: fix for more than 255 items
 }

 void ROOT::Experimental::RFieldVariant::CommitCluster()
 {
    std::fill(fNWritten.begin(), fNWritten.end(), 0);
 }
 #endif


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


 ROOT::Experimental::RFieldCollection::RFieldCollection(
    std::string_view name,
    std::shared_ptr<RCollectionNTuple> collectionNTuple,
    std::unique_ptr<RNTupleModel> collectionModel)
    : RFieldBase(name, ":Collection:", ENTupleStructure::kCollection, true /* isSimple */)
    , fCollectionNTuple(collectionNTuple)
 {
    for (unsigned i = 0; i < collectionModel->GetRootField()->fSubFields.size(); ++i) {
       auto& subField = collectionModel->GetRootField()->fSubFields[i];
       Attach(std::move(subField));
    }
 }


 void ROOT::Experimental::RFieldCollection::GenerateColumnsImpl()
 {
    RColumnModel modelIndex(EColumnType::kIndex, true /* isSorted*/);
    fColumns.emplace_back(std::unique_ptr<Detail::RColumn>(
       Detail::RColumn::Create<ClusterSize_t, EColumnType::kIndex>(modelIndex, 0)));
    fPrincipalColumn = fColumns[0].get();
 }


 ROOT::Experimental::Detail::RFieldBase* ROOT::Experimental::RFieldCollection::Clone(std::string_view /*newName*/)
 {
    // TODO(jblomer)
    return nullptr;
    //auto result = new RFieldCollection(newName, fCollectionNTuple, RNTupleModel::Create());
    //for (auto& f : fSubFields) {
    //   // switch the name prefix for the new parent name
    //   std::string cloneName = std::string(newName) + f->GetName().substr(GetName().length());
    //   auto clone = f->Clone(cloneName);
    //   result->Attach(std::unique_ptr<RFieldBase>(clone));
    //}
    //return result;
 }

 void ROOT::Experimental::RFieldCollection::CommitCluster() {
    *fCollectionNTuple->GetOffsetPtr() = 0;
 }

ROOT::Experimental::RFieldRoot
The container field for an ntuple model, which itself has no physical representation.
Definition: RField.hxx:251

ROOT::Experimental::RField< double >
Definition: RField.hxx:579

ROOT::Experimental::Detail::RFieldVisitor::VisitClassField
virtual void VisitClassField(const RFieldClass &field)
Definition: RFieldVisitor.hxx:50

Cppyy::GetName
std::string GetName(const std::string &scope_name)
Definition: Cppyy.cxx:150

ROOT::Experimental::REntry
 The REntry is a collection of values in an ntuple corresponding to a complete row in the data set ...
Definition: REntry.hxx:42

ROOT::Experimental::RColumnModel
 Holds the static meta-data of a column in a tree
Definition: RColumnModel.hxx:60

ROOT::Experimental::Detail::RFieldBase::RSchemaIterator::Position
Definition: RField.hxx:118

ROOT::Experimental::RFieldCollection::Clone
RFieldBase * Clone(std::string_view newName) final
Definition: RField.cxx:1008

ROOT::Experimental::Detail::RFieldVisitor::VisitVectorField
virtual void VisitVectorField(const RFieldVector &field)
Definition: RFieldVisitor.hxx:59

ROOT::Experimental::Detail::RFieldBase::RFieldBase
RFieldBase(std::string_view name, std::string_view type, ENTupleStructure structure, bool isSimple, std::size_t nRepetitions=0)
The constructor creates the underlying column objects and connects them to either a sink or a source...
Definition: RField.cxx:88

TClass.h

TDataMember.h

ROOT::Experimental::Detail::RFieldBase::CommitCluster
virtual void CommitCluster()
Perform housekeeping tasks for global to cluster-local index translation.
Definition: RField.hxx:206

ROOT
Returns the available number of logical cores.
Definition: StringConv.hxx:21

ROOT::Experimental::RFieldArray::AcceptVisitor
void AcceptVisitor(Detail::RFieldVisitor &visitor) const final
Definition: RField.cxx:854

ROOT::Experimental::kCollection
Definition: RNTupleUtil.hxx:34

ROOT::Experimental::RFieldArray::Clone
RFieldBase * Clone(std::string_view newName) final
Definition: RField.cxx:780

ROOT::Experimental::RField< bool >
Definition: RField.hxx:504

ROOT::Experimental::Detail::RFieldVisitor::VisitArrayField
virtual void VisitArrayField(const RFieldArray &field)
Definition: RFieldVisitor.hxx:48

ROOT::Experimental::Detail::RFieldVisitor::VisitFloatField
virtual void VisitFloatField(const RField< float > &field)
Definition: RFieldVisitor.hxx:53

ROOT::Experimental::RFieldClass::fClass
TClass * fClass
Definition: RField.hxx:270

ROOT::Experimental::RFieldCollection::GenerateColumnsImpl
void GenerateColumnsImpl() final
Creates the backing columns corresponsing to the field type and name.
Definition: RField.cxx:999

ROOT::Experimental::RFieldBase
 A field translates read and write calls from/to underlying columns to/from tree values ...
Definition: RField.hxx:60

fit1_py.fill
fill
Definition: fit1_py.py:6

ROOT::Experimental::ENTupleStructure
ENTupleStructure
The fields in the ntuple model tree can carry different structural information about the type system...
Definition: RNTupleUtil.hxx:32

ROOT::Experimental::RFieldArray::SplitValue
std::vector< Detail::RFieldValue > SplitValue(const Detail::RFieldValue &value) const final
Creates the list of direct child values given a value for this field.
Definition: RField.cxx:843

R__ASSERT
#define R__ASSERT(e)
Definition: TError.h:96

RNTuple.hxx

ROOT::Experimental::DescriptorId_t
std::uint64_t DescriptorId_t
Distriniguishes elements of the same type within a descriptor, e.g. different fields.
Definition: RNTupleUtil.hxx:78

TClass::GetListOfDataMembers
TList * GetListOfDataMembers(Bool_t load=kTRUE)
Return list containing the TDataMembers of a class.
Definition: TClass.cxx:3646

ROOT::Experimental::NTupleSize_t
std::uint64_t NTupleSize_t
Integer type long enough to hold the maximum number of entries in a column.
Definition: RNTupleUtil.hxx:42

ROOT::Experimental::EColumnType::kInt32

f
#define f(i)
Definition: RSha256.hxx:104

ROOT::Experimental::Detail::RFieldBase::end
RSchemaIterator end()
Definition: RField.cxx:245

ROOT::Experimental::EColumnType::kSwitch

ROOT::Experimental::RFieldArray
The generic field for fixed size arrays, which do not need an offset column.
Definition: RField.hxx:333

RooStats::HistFactory::Constraint::GetType
Type GetType(const std::string &Name)
Definition: Systematics.cxx:34

std
STL namespace.

ROOT::Experimental::RFieldCollection::CommitCluster
void CommitCluster() final
Perform housekeeping tasks for global to cluster-local index translation.
Definition: RField.cxx:1022

malloc
#define malloc
Definition: civetweb.c:1536

ROOT::Experimental::RFieldClass::Clone
RFieldBase * Clone(std::string_view newName) final
Definition: RField.cxx:500

ROOT::Experimental::RFieldClass::ReadGlobalImpl
void ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue *value) final
Definition: RField.cxx:515

ROOT::Experimental::RFieldVector::ReadGlobalImpl
void ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue *value) final
Definition: RField.cxx:615

ROOT::Experimental::RFieldClass::SplitValue
std::vector< Detail::RFieldValue > SplitValue(const Detail::RFieldValue &value) const final
Creates the list of direct child values given a value for this field.
Definition: RField.cxx:560

ROOT::Experimental::RFieldArray::ReadInClusterImpl
void ReadInClusterImpl(const RClusterIndex &clusterIndex, Detail::RFieldValue *value) final
Definition: RField.cxx:803

TCollection.h

RField.hxx

ROOT::Experimental::RFieldClass
The field for a class with dictionary.
Definition: RField.hxx:268

ROOT::GetClass
TClass * GetClass(T *)
Definition: TClass.h:603

ROOT::Experimental::EColumnType::kReal64

TIter
Definition: TCollection.h:233

ROOT::Experimental::RClusterSize
Wrap the 32bit integer in a struct in order to avoid template specialization clash with std::uint32_t...
Definition: RNTupleUtil.hxx:45

ROOT::Experimental::Detail::RFieldVisitor::VisitField
virtual void VisitField(const Detail::RFieldBase &field)=0

ROOT::Experimental::Detail::RFieldVisitor::VisitDoubleField
virtual void VisitDoubleField(const RField< double > &field)
Definition: RFieldVisitor.hxx:52

ROOT::Experimental::RFieldClass::ReadInClusterImpl
void ReadInClusterImpl(const RClusterIndex &clusterIndex, Detail::RFieldValue *value) final
Definition: RField.cxx:526

ROOT::Experimental::RFieldArray::RFieldArray
RFieldArray(std::string_view fieldName, std::unique_ptr< Detail::RFieldBase > itemField, std::size_t arrayLength)
Definition: RField.cxx:770

ROOT::Experimental::RFieldRoot::GenerateEntry
REntry * GenerateEntry()
Generates managed values for the top-level sub fields.
Definition: RField.cxx:291

ROOT::Experimental::RFieldArray::ReadGlobalImpl
void ReadGlobalImpl(NTupleSize_t globalIndex, Detail::RFieldValue *value) final
Definition: RField.cxx:794

ROOT::Experimental::Detail::RFieldBase::RSchemaIterator::Advance
void Advance()
Given that the iterator points to a valid field which is not the end iterator, go to the next field i...
Definition: RField.cxx:254

ROOT::Experimental::RFieldClass::fMaxAlignment
std::size_t fMaxAlignment
Definition: RField.hxx:271

ROOT::Experimental::Detail::RColumn::Create
static RColumn * Create(const RColumnModel &model, std::uint32_t index)
Definition: RColumn.hxx:70

ROOT::Experimental::RFieldArray::GenerateColumnsImpl
void GenerateColumnsImpl() final
Creates the backing columns corresponsing to the field type and name.
Definition: RField.cxx:813

ROOT::Experimental::RField
Classes with dictionaries that can be inspected by TClass.
Definition: RField.hxx:403

ROOT::Experimental::RFieldVector::DestroyValue
void DestroyValue(const Detail::RFieldValue &value, bool dtorOnly=false) final
Releases the resources acquired during GenerateValue (memory and constructor) This implementation wor...
Definition: RField.cxx:643

TList.h

ROOT::Experimental::Detail::RFieldBase::Create
static RFieldBase * Create(const std::string &fieldName, const std::string &typeName)
Factory method to resurrect a field from the stored on-disk type information.
Definition: RField.cxx:100

ROOT::Experimental::Detail::RFieldBase::SplitValue
virtual std::vector< RFieldValue > SplitValue(const RFieldValue &value) const
Creates the list of direct child values given a value for this field.
Definition: RField.cxx:200

ROOT::Experimental::Detail::RFieldValue
Definition: RFieldValue.hxx:41

ROOT::Experimental::Detail::RPageStorage
 Common functionality of an ntuple storage for both reading and writing
Definition: RPageStorage.hxx:58

RFieldVisitor.hxx

ROOT::Experimental::RFieldVector::GenerateColumnsImpl
void GenerateColumnsImpl() final
Creates the backing columns corresponsing to the field type and name.
Definition: RField.cxx:630

ROOT::Experimental::Detail::RFieldBase::fColumns
std::vector< std::unique_ptr< RColumn > > fColumns
The columns are connected either to a sink or to a source (not to both); they are owned by the field...
Definition: RField.hxx:100

ROOT::Experimental::RFieldArray::GetValueSize
size_t GetValueSize() const final
The number of bytes taken by a value of the appropriate type.
Definition: RField.hxx:357

ROOT::Experimental::RFieldVector::SplitValue
std::vector< Detail::RFieldValue > SplitValue(const Detail::RFieldValue &value) const final
Creates the list of direct child values given a value for this field.
Definition: RField.cxx:663

ROOT::Experimental::Detail::RFieldBase::~RFieldBase
virtual ~RFieldBase()
Definition: RField.cxx:95

ROOT::Experimental::EColumnType::kReal32

ROOT::Experimental::Detail::RFieldBase::AcceptVisitor
virtual void AcceptVisitor(RFieldVisitor &visitor) const
Definition: RField.cxx:232

ROOT::Experimental::Detail::RFieldBase::Flush
void Flush() const
Ensure that all received items are written from page buffers to the storage.
Definition: RField.cxx:224

ROOT::Experimental::Detail::RFieldBase::DestroyValue
virtual void DestroyValue(const RFieldValue &value, bool dtorOnly=false)
Releases the resources acquired during GenerateValue (memory and constructor) This implementation wor...
Definition: RField.cxx:193

ROOT::Experimental::RFieldClass::RFieldClass
RFieldClass(std::string_view fieldName, std::string_view className)
Definition: RField.cxx:484

ROOT::Experimental::RFieldClass::GetValueSize
size_t GetValueSize() const override
The number of bytes taken by a value of the appropriate type.
Definition: RField.cxx:574

TError.h

ROOT::Experimental::RFieldClass::CaptureValue
Detail::RFieldValue CaptureValue(void *where) final
Creates a value from a memory location with an already constructed object.
Definition: RField.cxx:553

ROOT::Experimental::Detail::RFieldBase::GenerateValue
RFieldValue GenerateValue()
Generates a tree value of the field type and allocates new initialized memory according to the type...
Definition: RField.cxx:186

ROOT::Experimental::RField< float >
Definition: RField.hxx:541

ROOT::Experimental::RFieldRoot::AcceptVisitor
void AcceptVisitor(Detail::RFieldVisitor &visitor) const final
Definition: RField.cxx:300

ROOT::Experimental::RFieldVector
The generic field for a (nested) std::vector<Type> except for std::vector<bool>
Definition: RField.hxx:297

TClass
TClass instances represent classes, structs and namespaces in the ROOT type system.
Definition: TClass.h:75

ROOT::Experimental::Detail::RFieldBase::ReadGlobalImpl
virtual void ReadGlobalImpl(NTupleSize_t globalIndex, RFieldValue *value)
Definition: RField.cxx:179

ROOT::Experimental::Detail::RFieldBase::RSchemaIterator
Iterates over the sub tree of fields in depth-first search order.
Definition: RField.hxx:115

ROOT::Experimental::RFieldClass::GenerateColumnsImpl
void GenerateColumnsImpl() final
Creates the backing columns corresponsing to the field type and name.
Definition: RField.cxx:537

RFieldValue.hxx

fType
PyObject * fType
Definition: MethodProxy.cxx:120

ROOT::Experimental::RFieldArray::GetAlignment
size_t GetAlignment() const final
For many types, the alignment requirement is equal to the size; otherwise override.
Definition: RField.hxx:358

ROOT::Experimental::EColumnType::kBit

ROOT::Experimental::kRecord
Definition: RNTupleUtil.hxx:35

ROOT::Experimental::EColumnType::kInt64

ROOT::Experimental::RField< ClusterSize_t >
Template specializations for concrete C++ types.
Definition: RField.hxx:458

ROOT::Experimental::Detail::RFieldBase::begin
RSchemaIterator begin()
Definition: RField.cxx:238

ROOT::Experimental::RFieldArray::AppendImpl
void AppendImpl(const Detail::RFieldValue &value) final
Operations on values of complex types, e.g.
Definition: RField.cxx:786

ROOT::Experimental::RFieldVector::CommitCluster
void CommitCluster() final
Perform housekeeping tasks for global to cluster-local index translation.
Definition: RField.cxx:675

ROOT::Experimental::RFieldClass::AcceptVisitor
void AcceptVisitor(Detail::RFieldVisitor &visitor) const override
Definition: RField.cxx:579

type
int type
Definition: TGX11.cxx:120

ROOT::Experimental::Detail::RFieldValue::GetRawPtr
void * GetRawPtr() const
Definition: RFieldValue.hxx:81

free
#define free
Definition: civetweb.c:1539

ROOT::Experimental::Detail::RFieldBase::AppendImpl
virtual void AppendImpl(const RFieldValue &value)
Operations on values of complex types, e.g.
Definition: RField.cxx:175

ROOT::Experimental::Detail::RFieldVisitor::VisitRootField
virtual void VisitRootField(const RFieldRoot &field)
Definition: RFieldVisitor.hxx:47

ROOT::Experimental::Detail::RFieldValue::Get
T * Get() const
Definition: RFieldValue.hxx:79

ROOT::Experimental::Detail::RFieldBase::GetSubFields
std::vector< const RFieldBase * > GetSubFields() const
Definition: RField.cxx:214

ROOT::Experimental::Detail::RFieldVisitor::VisitBoolField
virtual void VisitBoolField(const RField< bool > &field)
Definition: RFieldVisitor.hxx:49

ROOT::Experimental::ClusterSize_t
RClusterSize ClusterSize_t
Definition: RNTupleUtil.hxx:57

TClass::GetClass
static TClass * GetClass(const char *name, Bool_t load=kTRUE, Bool_t silent=kFALSE)
Static method returning pointer to TClass of the specified class name.
Definition: TClass.cxx:2906

ROOT::Experimental::RFieldVector::CaptureValue
Detail::RFieldValue CaptureValue(void *where) override
Creates a value from a memory location with an already constructed object.
Definition: RField.cxx:657

RColumnModel.hxx

ROOT::Experimental::RFieldVector::AppendImpl
void AppendImpl(const Detail::RFieldValue &value) final
Operations on values of complex types, e.g.
Definition: RField.cxx:602

ROOT::Experimental::Detail::RFieldBase::Attach
void Attach(std::unique_ptr< Detail::RFieldBase > child)
Add a new subfield to the list of nested fields.
Definition: RField.cxx:205

ROOT::Experimental::RFieldRoot::Clone
RFieldBase * Clone(std::string_view newName)
Definition: RField.cxx:280

RNTupleModel.hxx

ROOT::Experimental::kVariant
Definition: RNTupleUtil.hxx:36

REntry.hxx

ROOT::Experimental::RClusterIndex::GetClusterId
DescriptorId_t GetClusterId() const
Definition: RNTupleUtil.hxx:102

ROOT::Experimental::RFieldVector::AcceptVisitor
void AcceptVisitor(Detail::RFieldVisitor &visitor) const final
Definition: RField.cxx:680

ROOT::Experimental::RFieldVector::RFieldVector
RFieldVector(std::string_view fieldName, std::unique_ptr< Detail::RFieldBase > itemField)
Definition: RField.cxx:587

ROOT::Experimental::Detail::RColumnElement< ClusterSize_t, EColumnType::kIndex >
Definition: RColumnElement.hxx:196

ROOT::Experimental::RFieldClass::AppendImpl
void AppendImpl(const Detail::RFieldValue &value) final
Operations on values of complex types, e.g.
Definition: RField.cxx:505

ROOT::Experimental::Detail::RFieldVisitor
 Abstract base class for classes implementing the visitor design pattern.
Definition: RFieldVisitor.hxx:44

RColumn.hxx

ROOT::Experimental::RClusterIndex::GetIndex
ClusterSize_t::ValueType GetIndex() const
Definition: RNTupleUtil.hxx:103

ROOT::Experimental::RFieldArray::CaptureValue
Detail::RFieldValue CaptureValue(void *where) final
Creates a value from a memory location with an already constructed object.
Definition: RField.cxx:837

R__ERROR_HERE
#define R__ERROR_HERE(GROUP)
Definition: RLogger.hxx:183

ROOT::Experimental::EColumnType::kByte

ROOT::Experimental::Detail::RFieldBase
Definition: RField.hxx:74

ROOT::Experimental::RClusterIndex
Addresses a column element or field item relative to a particular cluster, instead of a global NTuple...
Definition: RNTupleUtil.hxx:82

ROOT::Experimental::RFieldVector::Clone
RFieldBase * Clone(std::string_view newName) final
Definition: RField.cxx:596

name
char name[80]
Definition: TGX11.cxx:109

ROOT::Experimental::RFieldClass::DestroyValue
void DestroyValue(const Detail::RFieldValue &value, bool dtorOnly=false) final
Releases the resources acquired during GenerateValue (memory and constructor) This implementation wor...
Definition: RField.cxx:546

ROOT::Experimental::RFieldCollection::RFieldCollection
RFieldCollection(std::string_view name, std::shared_ptr< RCollectionNTuple > collectionNTuple, std::unique_ptr< RNTupleModel > collectionModel)
Definition: RField.cxx:985

ROOT::Experimental::Detail::RFieldBase::GenerateColumnsImpl
virtual void GenerateColumnsImpl()=0
Creates the backing columns corresponsing to the field type and name.

ROOT::Experimental::RFieldArray::DestroyValue
void DestroyValue(const Detail::RFieldValue &value, bool dtorOnly=false) final
Releases the resources acquired during GenerateValue (memory and constructor) This implementation wor...
Definition: RField.cxx:826

ROOT::Experimental::kLeaf
Definition: RNTupleUtil.hxx:33

ROOT::Experimental::Detail::RFieldFuse::Connect
static void Connect(DescriptorId_t fieldId, RPageStorage &pageStorage, RFieldBase &field)
Definition: RField.cxx:76

RLogger.hxx

ROOT::Experimental::EColumnType::kIndex