// @(#)root/cont:$Id: TRefArray.cxx 34226 2010-06-30 12:03:31Z brun $ // Author: Rene Brun 02/10/2001 /************************************************************************* * Copyright (C) 1995-2001, Rene Brun and Fons Rademakers. * * All rights reserved. * * * * For the licensing terms see $ROOTSYS/LICENSE. * * For the list of contributors see $ROOTSYS/README/CREDITS. * *************************************************************************/ //////////////////////////////////////////////////////////////////////////// // // // TRefArray // // // // An array of references to TObjects. The array expands automatically // // when objects are added (shrinking can be done by hand using Expand() )// // // // The TRefArray can be filled with: // // array.Add(obj) // // array.AddAt(obj,i) // // but not array[i] = obj !!! // // // // The array elements can be retrieved with: // // TObject *obj = array.At(i); // // // // By default the TRefArray 'points' to the current process and can only // // receive object that have been created in this process. // // To point the TRefArray to a different process do: // // TRefArray array( processId ); // // // // For example, if 'obj' is an instance that was created in the different // // process and you do: // // TRefArray array( TProcessID::GetProcessWithUID( obj ) ); // // Then // // array.Add(obj); // // is correct (obj comes from the process the array is pointed to // // while // // TObject *nobj = new TObject; // // array.Add(nobj); // // is incorrect since 'nobj' was created in a different process than the // // one the array is pointed to. In this case you will see error message: // // Error in <TRefArray::AddAtAndExpand>: The object at 0x... is not // // registered in the process the TRefArray point to // // (pid = ProcessID../....) // // // // When a TRefArray is Streamed, only the pointer unique id is written, // // not the referenced object. TRefArray may be assigned to different // // branches of one Tree or several Trees. // // The branch containing the TRefArray can be read before or after the // // array (eg TClonesArray, STL vector,..) of the referenced objects. // // // // See an example in $ROOTSYS/test/Event.h // // // // RESTRICTIONS when using TRefArray // // --------------------------------- // // - Elements in a TRefArray cannot point to a TFile or TDirectory. // // - All elements of a TRefArray must be set in the same process, // // In particular, one cannot modify some elements of the array in // // a different process. // // Use an array of TRef when one of the above restrictions is met. // // // //////////////////////////////////////////////////////////////////////////// #include "TRefArray.h" #include "TRefTable.h" #include "TError.h" #include "TBits.h" #include "TSystem.h" #include "TROOT.h" ClassImp(TRefArray) //______________________________________________________________________________ TRefArray::TRefArray(TProcessID *pid) { // default constructor fPID = pid ? pid : TProcessID::GetSessionProcessID(); fUIDs = 0; fSize = 0; fLast = -1; fLowerBound = 0; Changed(); } //______________________________________________________________________________ TRefArray::TRefArray(Int_t s, TProcessID *pid) { // Create an object array. Using s one can set the array size // and lowerBound can be used to set the array lowerbound // index (default is 0). if (s < 0) { Warning("TRefArray", "size (%d) < 0", s); s = TCollection::kInitCapacity; } fPID = pid ? pid : TProcessID::GetSessionProcessID(); fUIDs = 0; Init(s, 0); } //______________________________________________________________________________ TRefArray::TRefArray(Int_t s, Int_t lowerBound, TProcessID *pid) { // Create an object array. Using s one can set the array size // and lowerBound can be used to set the array lowerbound // index (default is 0). if (s < 0) { Warning("TRefArray", "size (%d) < 0", s); s = TCollection::kInitCapacity; } fPID = pid ? pid : TProcessID::GetSessionProcessID(); fUIDs = 0; Init(s, lowerBound); } //______________________________________________________________________________ TRefArray::TRefArray(const TRefArray &a) : TSeqCollection() { // Create a copy of TRefArray a. fPID = a.fPID; fUIDs = 0; Init(a.fSize, a.fLowerBound); for (Int_t i = 0; i < fSize; i++) fUIDs[i] = a.fUIDs[i]; fLast = a.fLast; fName = a.fName; } //______________________________________________________________________________ TRefArray& TRefArray::operator=(const TRefArray &a) { // Assignment operator. if (this != &a) { // Copy this by hand because the assigment operator // of TCollection is private fName = a.fName; fSize = a.fSize; fSorted = a.fSorted; fPID = a.fPID; Init(a.fSize, a.fLowerBound); for (Int_t i = 0; i < fSize; i++) fUIDs[i] = a.fUIDs[i]; fLast = a.fLast; fName = a.fName; } return *this; } //______________________________________________________________________________ TRefArray::~TRefArray() { // Usual destructor (The object pointed to by the array are never deleted). if (fUIDs) delete [] fUIDs; fPID = 0; fUIDs = 0; fSize = 0; } //______________________________________________________________________________ static Bool_t R__GetUID(Int_t &uid, TObject *obj, TProcessID *pid, const char *methodname) { // Private/static function, check for validity of pid. // Check if the object can belong here. Bool_t valid = kTRUE; if (obj->TestBit(kHasUUID)) { valid = kFALSE; } else if (obj->TestBit(kIsReferenced)) { valid = (pid == TProcessID::GetProcessWithUID(obj)); if (valid) { uid = obj->GetUniqueID(); } } else { valid = (pid == TProcessID::GetSessionProcessID()); if (valid) { uid = TProcessID::AssignID(obj); } } if (!valid) { TString name; name.Form("TRefArray::%s",methodname); ::Error(name, "The object at %p is not registered in the process the TRefArray point to (pid = %s/%s)",obj,pid->GetName(),pid->GetTitle()); } return valid; } //______________________________________________________________________________ void TRefArray::AddFirst(TObject *obj) { // Add object in the first slot of the array. This will overwrite the // first element that might have been there. To have insertion semantics // use either a TList or a TOrdCollection. if (!obj) return; // Check if the object can belong here Int_t uid; if (R__GetUID(uid, obj, fPID, "AddFirst")) { fUIDs[0] = uid; Changed(); } } //______________________________________________________________________________ void TRefArray::AddLast(TObject *obj) { // Add object in the next empty slot in the array. Expand the array // if necessary. AddAtAndExpand(obj, GetAbsLast()+1+fLowerBound); } //______________________________________________________________________________ void TRefArray::AddBefore(const TObject *before, TObject *obj) { // Add object in the slot before object before. If before=0 add object // in the first slot. Note that this will overwrite any object that // might have already been in this slot. For insertion semantics use // either a TList or a TOrdCollection. if (!before) AddFirst(obj); else { Int_t idx = IndexOf(before) - fLowerBound; if (idx == -1) { Error("AddBefore", "before not found, object not added"); return; } if (idx == 0) { Error("AddBefore", "cannot add before lowerbound (%d)", fLowerBound); return; } AddAt(obj, idx+fLowerBound-1); } } //______________________________________________________________________________ void TRefArray::AddAfter(const TObject *after, TObject *obj) { // Add object in the slot after object after. If after=0 add object in // the last empty slot. Note that this will overwrite any object that // might have already been in this slot. For insertion semantics use // either a TList or a TOrdCollection. if (!after) AddLast(obj); else { Int_t idx = IndexOf(after) - fLowerBound; if (idx == -1) { Error("AddAfter", "after not found, object not added"); return; } AddAtAndExpand(obj, idx+fLowerBound+1); } } //______________________________________________________________________________ void TRefArray::AddAtAndExpand(TObject *obj, Int_t idx) { // Add object at position idx. If idx is larger than the current size // of the array, expand the array (double its size). if (!obj) return; if (idx < fLowerBound) { Error("AddAt", "out of bounds at %d in %lx", idx, (Long_t)this); return; } if (idx-fLowerBound >= fSize) Expand(TMath::Max(idx-fLowerBound+1, GrowBy(fSize))); // Check if the object can belong here Int_t uid; if (R__GetUID(uid, obj, fPID, "AddAtAndExpand")) { fUIDs[idx-fLowerBound] = uid; fLast = TMath::Max(idx-fLowerBound, GetAbsLast()); Changed(); } } //______________________________________________________________________________ void TRefArray::AddAt(TObject *obj, Int_t idx) { // Add object at position ids. Give an error when idx is out of bounds // (i.e. the array is not expanded). if (!obj) return; if (!BoundsOk("AddAt", idx)) return; // Check if the object can belong here Int_t uid; if (R__GetUID(uid, obj, fPID, "AddAt")) { fUIDs[idx-fLowerBound] = uid;; fLast = TMath::Max(idx-fLowerBound, GetAbsLast()); Changed(); } } //______________________________________________________________________________ Int_t TRefArray::AddAtFree(TObject *obj) { // Return the position of the new object. // Find the first empty cell or AddLast if there is no empty cell if (!obj) return 0; if (Last()) { // <---------- This is to take in account "empty" TRefArray's Int_t i; for (i = 0; i < fSize; i++) if (!fUIDs[i]) { // Add object at position i // Check if the object can belong here Int_t uid; if (R__GetUID(uid, obj, fPID, "AddAtFree")) { fUIDs[i] = uid; fLast = TMath::Max(i, GetAbsLast()); Changed(); return i+fLowerBound; } } } AddLast(obj); return GetLast(); } //______________________________________________________________________________ TObject *TRefArray::After(const TObject *obj) const { // Return the object after obj. Returns 0 if obj is last object. if (!obj || !fPID) return 0; Int_t idx = IndexOf(obj) - fLowerBound; if (idx == -1 || idx == fSize-1) return 0; return fPID->GetObjectWithID(fUIDs[idx+1]); } //______________________________________________________________________________ TObject *TRefArray::Before(const TObject *obj) const { // Return the object before obj. Returns 0 if obj is first object. if (!obj || !fPID) return 0; Int_t idx = IndexOf(obj) - fLowerBound; if (idx == -1 || idx == 0) return 0; return fPID->GetObjectWithID(fUIDs[idx-1]); } //______________________________________________________________________________ void TRefArray::Clear(Option_t *) { // Remove all objects from the array. fLast = - 1; for (Int_t j=0 ; j < fSize; j++) fUIDs[j] = 0; Changed(); } //______________________________________________________________________________ void TRefArray::Compress() { // Remove empty slots from array. Int_t j = 0; for (Int_t i = 0; i < fSize; i++) { if (fUIDs[i]) { fUIDs[j] = fUIDs[i]; j++; } } fLast = j - 1; for ( ; j < fSize; j++) fUIDs[j] = 0; } //______________________________________________________________________________ void TRefArray::Delete(Option_t *) { // Remove all objects from the array and free the internal memory. fLast = -1; fSize = 0; if (fUIDs) { delete [] fUIDs; fUIDs = 0; } Changed(); } //______________________________________________________________________________ void TRefArray::Expand(Int_t newSize) { // Expand or shrink the array to newSize elements. if (newSize < 0) { Error ("Expand", "newSize must be positive (%d)", newSize); return; } if (newSize == fSize) return; UInt_t *temp = fUIDs; if (newSize != 0) { fUIDs = new UInt_t[newSize]; if (newSize < fSize) memcpy(fUIDs,temp, newSize*sizeof(UInt_t)); else { memcpy(fUIDs,temp,fSize*sizeof(UInt_t)); memset(&fUIDs[fSize],0,(newSize-fSize)*sizeof(UInt_t)); } } else { fUIDs = 0; } if (temp) delete [] temp; fSize = newSize; } //______________________________________________________________________________ TObject *TRefArray::GetFromTable(Int_t idx) const { //the reference may be in the TRefTable TRefTable *table = TRefTable::GetRefTable(); if (table) { table->SetUID(fUIDs[idx], fPID); table->Notify(); return fPID->GetObjectWithID(fUIDs[idx]); } return 0; } //_______________________________________________________________________ void TRefArray::Streamer(TBuffer &R__b) { // Stream all objects in the array to or from the I/O buffer. UInt_t R__s, R__c; Int_t nobjects; UShort_t pidf; if (R__b.IsReading()) { R__b.ReadVersion(&R__s, &R__c); TObject::Streamer(R__b); fName.Streamer(R__b); R__b >> nobjects; R__b >> fLowerBound; if (nobjects >= fSize) Expand(nobjects); fLast = -1; R__b >> pidf; pidf += R__b.GetPidOffset(); fPID = R__b.ReadProcessID(pidf); if (gDebug > 1) printf("Reading TRefArray, pidf=%d, fPID=%lx, nobjects=%d\n",pidf,(Long_t)fPID,nobjects); for (Int_t i = 0; i < nobjects; i++) { R__b >> fUIDs[i]; if (fUIDs[i] != 0) fLast = i; if (gDebug > 1) { printf(" %d",fUIDs[i]); if ((i > 0 && i%10 == 0) || (i == nobjects-1)) printf("\n"); } } Changed(); R__b.CheckByteCount(R__s, R__c,TRefArray::IsA()); } else { R__c = R__b.WriteVersion(TRefArray::IsA(), kTRUE); TObject::Streamer(R__b); fName.Streamer(R__b); nobjects = GetAbsLast()+1; R__b << nobjects; R__b << fLowerBound; pidf = R__b.WriteProcessID(fPID); R__b << pidf; if (gDebug > 1) printf("Writing TRefArray, pidf=%d, fPID=%lx, nobjects=%d\n",pidf,(Long_t)fPID,nobjects); for (Int_t i = 0; i < nobjects; i++) { R__b << fUIDs[i]; if (gDebug > 1) { printf(" %d",fUIDs[i]); if ((i > 0 && i%10 == 0) || (i == nobjects-1)) printf("\n"); } } R__b.SetByteCount(R__c, kTRUE); } } //______________________________________________________________________________ TObject *TRefArray::First() const { // Return the object in the first slot. return fPID->GetObjectWithID(fUIDs[0]); } //______________________________________________________________________________ TObject *TRefArray::Last() const { // Return the object in the last filled slot. Returns 0 if no entries. if (fLast == -1) return 0; else return fPID->GetObjectWithID(fUIDs[GetAbsLast()]); } //______________________________________________________________________________ Int_t TRefArray::GetEntries() const { // Return the number of objects in array (i.e. number of non-empty slots). // Attention: use this method ONLY if you want to know the number of // non-empty slots. This function loops over the complete array and // is therefore very slow when applied in a loop. Most of the time you // better use GetLast()+1. Int_t cnt = 0; for (Int_t i = 0; i < fSize; i++) if (fUIDs[i]) cnt++; return cnt; } //______________________________________________________________________________ Int_t TRefArray::GetAbsLast() const { // Return absolute index to last object in array. Returns -1 in case // array is empty. // For efficiency we need sometimes to update fLast so we have // to cast const away. Ugly, but making GetAbsLast() not const breaks // many other const functions. if (fLast == -2) { for (Int_t i = fSize-1; i >= 0; i--) if (fUIDs[i]) { ((TRefArray*)this)->fLast = i; return fLast; } ((TRefArray*)this)->fLast = -1; } return fLast; } //______________________________________________________________________________ Int_t TRefArray::GetLast() const { // Return index of last object in array. Returns lowerBound-1 in case // array is empty. return fLowerBound+GetAbsLast(); } //______________________________________________________________________________ TObject **TRefArray::GetObjectRef(const TObject *) const { // Return address of pointer obj. //Int_t index = IndexOf(obj); //return &fCont[index]; return 0; } //______________________________________________________________________________ UInt_t TRefArray::GetUID(Int_t at) const { // Return UID of element at. int j = at-fLowerBound; if (j >= 0 && j < fSize) { if (!fPID) return 0; return fUIDs[j]; } BoundsOk("At", at); return 0; } //______________________________________________________________________________ Int_t TRefArray::IndexOf(const TObject *obj) const { // obj != 0 Return index of object in array. // Returns lowerBound-1 in case array doesn't contain the obj. // // obj == 0 Return the index of the first empty slot. // Returns lowerBound-1 in case array doesn't contain any empty slot. Int_t i; if (obj) { for (i = 0; i < fSize; i++) if (fUIDs[i] && fPID->GetObjectWithID(fUIDs[i]) == obj) return i+fLowerBound; } else { // Look for the first empty slot for (i = 0; i < fSize; i++) if (!fUIDs[i]) return i+fLowerBound; } return fLowerBound-1; } //______________________________________________________________________________ void TRefArray::Init(Int_t s, Int_t lowerBound) { // Initialize a TRefArray. if (fUIDs && fSize != s) { delete [] fUIDs; fUIDs = 0; } fSize = s; if (fSize) { fUIDs = new UInt_t[fSize]; for (Int_t i=0;i<s;i++) fUIDs[i] = 0; } else { fUIDs = 0; } fLowerBound = lowerBound; fLast = -1; Changed(); } //______________________________________________________________________________ TIterator *TRefArray::MakeIterator(Bool_t dir) const { // Returns an array iterator. return new TRefArrayIter(this, dir); } //______________________________________________________________________________ Bool_t TRefArray::OutOfBoundsError(const char *where, Int_t i) const { // Generate an out-of-bounds error. Always returns false. Error(where, "index %d out of bounds (size: %d, this: 0x%lx)", i, fSize, (Long_t)this); return kFALSE; } //______________________________________________________________________________ TObject *TRefArray::RemoveAt(Int_t idx) { // Remove object at index idx. if (!BoundsOk("RemoveAt", idx)) return 0; int i = idx-fLowerBound; TObject *obj = 0; if (fUIDs[i]) { obj = fPID->GetObjectWithID(fUIDs[i]); fUIDs[i] = 0; // recalculate array size if (i == fLast) do { fLast--; } while (fLast >= 0 && fUIDs[fLast] == 0); Changed(); } return obj; } //______________________________________________________________________________ TObject *TRefArray::Remove(TObject *obj) { // Remove object from array. if (!obj) return 0; Int_t idx = IndexOf(obj) - fLowerBound; if (idx == -1) return 0; TObject *ob = fPID->GetObjectWithID(fUIDs[idx]); fUIDs[idx] = 0; // recalculate array size if (idx == fLast) do { fLast--; } while (fLast >= 0 && fUIDs[fLast] == 0); Changed(); return ob; } //______________________________________________________________________________ void TRefArray::SetLast(Int_t last) { // Set index of last object in array, effectively truncating the // array. Use carefully since whenever last position has to be // recalculated, e.g. after a Remove() or Sort() it will be reset // to the last non-empty slot. If last is -2 this will force the // recalculation of the last used slot. if (last == -2) fLast = -2; else if (BoundsOk("SetLast", last)) fLast = last - fLowerBound; } //______________________________________________________________________________ void TRefArray::Sort(Int_t) { // If objects in array are sortable (i.e. IsSortable() returns true // for all objects) then sort array. Error("Sort","Function not yet implemented"); /* if (GetAbsLast() == -1 || fSorted) return; for (Int_t i = 0; i < fSize; i++) if (fUIDs[i]) { if (!fUIDs[i]->IsSortable()) { Error("Sort", "objects in array are not sortable"); return; } } QSort(fUIDs, 0, TMath::Min(fSize, upto-fLowerBound)); fLast = -2; fSorted = kTRUE; */ } //______________________________________________________________________________ Int_t TRefArray::BinarySearch(TObject *, Int_t) { // Find object using a binary search. Array must first have been sorted. // Search can be limited by setting upto to desired index. Error("BinarySearch","Function not yet implemented"); /* Int_t base, position, last, result = 0; TObject *op2; if (!op) return -1; if (!fSorted) { Error("BinarySearch", "array must first be sorted"); return -1; } base = 0; last = TMath::Min(fSize, upto-fLowerBound) - 1; while (last >= base) { //position = (base+last) / 2; //op2 = fCont[position]; //if (op2 && (result = op->Compare(op2)) == 0) // return position + fLowerBound; //if (!op2 || result < 0) // last = position-1; //else // base = position+1; } */ return -1; } ////////////////////////////////////////////////////////////////////////// // // // TRefArrayIter // // // // Iterator of object array. // // // ////////////////////////////////////////////////////////////////////////// ClassImp(TRefArrayIter) //______________________________________________________________________________ TRefArrayIter::TRefArrayIter(const TRefArray *arr, Bool_t dir) { // Create array iterator. By default the iteration direction // is kIterForward. To go backward use kIterBackward. fArray = arr; fDirection = dir; Reset(); } //______________________________________________________________________________ TRefArrayIter::TRefArrayIter(const TRefArrayIter &iter) : TIterator(iter) { // Copy ctor. fArray = iter.fArray; fDirection = iter.fDirection; fCursor = iter.fCursor; fCurCursor = iter.fCurCursor; } //______________________________________________________________________________ TIterator &TRefArrayIter::operator=(const TIterator &rhs) { // Overridden assignment operator. if (this != &rhs && rhs.IsA() == TRefArrayIter::Class()) { const TRefArrayIter &rhs1 = (const TRefArrayIter &)rhs; fArray = rhs1.fArray; fDirection = rhs1.fDirection; fCursor = rhs1.fCursor; fCurCursor = rhs1.fCurCursor; } return *this; } //______________________________________________________________________________ TRefArrayIter &TRefArrayIter::operator=(const TRefArrayIter &rhs) { // Overloaded assignment operator. if (this != &rhs) { fArray = rhs.fArray; fDirection = rhs.fDirection; fCursor = rhs.fCursor; fCurCursor = rhs.fCurCursor; } return *this; } //______________________________________________________________________________ TObject *TRefArrayIter::Next() { // Return next object in array. Returns 0 when no more objects in array. if (fDirection == kIterForward) { for ( ; fCursor < fArray->Capacity() && fArray->At(fCursor+fArray->LowerBound()) == 0; fCursor++) { } fCurCursor = fCursor; if (fCursor < fArray->Capacity()) { fCursor++; return fArray->At(fCurCursor+fArray->LowerBound()); } } else { for ( ; fCursor >= 0 && fArray->At(fCursor) == 0; fCursor--) { } fCurCursor = fCursor; if (fCursor >= 0) { fCursor--; return fArray->At(fCurCursor+fArray->LowerBound()); } } return 0; } //______________________________________________________________________________ void TRefArrayIter::Reset() { // Reset array iterator. if (fDirection == kIterForward) fCursor = 0; else fCursor = fArray->Capacity() - 1; fCurCursor = fCursor; } //______________________________________________________________________________ bool TRefArrayIter::operator!=(const TIterator &aIter) const { // This operator compares two TIterator objects. if (nullptr == (&aIter)) return (fCurCursor < fArray->Capacity()); if (aIter.IsA() == TRefArrayIter::Class()) { const TRefArrayIter &iter(dynamic_cast<const TRefArrayIter &>(aIter)); return (fCurCursor != iter.fCurCursor); } return false; // for base class we don't implement a comparison } //______________________________________________________________________________ bool TRefArrayIter::operator!=(const TRefArrayIter &aIter) const { // This operator compares two TRefArrayIter objects. if (nullptr == (&aIter)) return (fCurCursor < fArray->Capacity()); return (fCurCursor != aIter.fCurCursor); } //______________________________________________________________________________ TObject *TRefArrayIter::operator*() const { // Return current object or nullptr. return (((fCurCursor >= 0) && (fCurCursor < fArray->Capacity())) ? fArray->At(fCurCursor) : nullptr); }