netgen/libsrc/core/table.hpp

636 lines
15 KiB
C++
Raw Normal View History

2019-08-29 17:21:18 +05:00
#ifndef NETGEN_CORE_TABLE_HPP
#define NETGEN_CORE_TABLE_HPP
/**************************************************************************/
/* File: table.hpp */
/* Author: Joachim Schoeberl */
/* Date: 25. Mar. 2000 */
/**************************************************************************/
#include <atomic>
#include <iostream>
#include "array.hpp"
#include "bitarray.hpp"
#include "taskmanager.hpp"
#include "ngcore_api.hpp"
namespace ngcore
{
2019-09-29 20:43:45 +05:00
template <class T, class IndexType = size_t>
class FlatTable
2019-08-29 17:21:18 +05:00
{
protected:
static constexpr IndexType BASE = IndexBASE<IndexType>();
/// number of rows
size_t size;
/// pointer to first in row
size_t * index;
/// array of data
T * data;
2019-08-29 17:21:18 +05:00
public:
FlatTable() = delete;
2019-08-29 17:21:18 +05:00
NETGEN_INLINE FlatTable(size_t as, size_t * aindex, T * adata)
: size(as), index(aindex), data(adata) { ; }
2019-08-29 17:21:18 +05:00
/// Size of table
NETGEN_INLINE size_t Size() const { return size; }
2019-08-29 17:21:18 +05:00
/// Access entry
NETGEN_INLINE const FlatArray<T> operator[] (IndexType i) const
{
i = i-BASE;
return FlatArray<T> (index[i+1]-index[i], data+index[i]);
}
2019-08-29 17:21:18 +05:00
NETGEN_INLINE T * Data() const { return data; }
2019-08-29 17:21:18 +05:00
NETGEN_INLINE FlatArray<T> AsArray() const
{
return FlatArray<T> (index[size]-index[0], data+index[0]);
}
NETGEN_INLINE FlatArray<size_t> IndexArray() const
{
return FlatArray<size_t, IndexType> (size+1, index);
}
/// takes range starting from position start of end-start elements
NETGEN_INLINE FlatTable<T> Range (size_t start, size_t end) const
{
return FlatTable<T> (end-start, index+start-BASE, data);
}
/// takes range starting from position start of end-start elements
NETGEN_INLINE FlatTable<T> Range (T_Range<size_t> range) const
{
return FlatTable<T> (range.Size(), index+range.First()-BASE, data);
}
NETGEN_INLINE T_Range<IndexType> Range () const
{
return T_Range<IndexType> (BASE, size+BASE);
}
2019-09-29 20:43:45 +05:00
class Iterator
{
const FlatTable & tab;
size_t row;
public:
Iterator (const FlatTable & _tab, size_t _row) : tab(_tab), row(_row) { ; }
Iterator & operator++ () { ++row; return *this; }
FlatArray<T> operator* () const { return tab[row]; }
bool operator!= (const Iterator & it2) { return row != it2.row; }
};
2019-08-29 17:21:18 +05:00
Iterator begin() const { return Iterator(*this, BASE); }
Iterator end() const { return Iterator(*this, BASE+size); }
};
2019-08-29 17:21:18 +05:00
NGCORE_API extern size_t * TablePrefixSum32 (FlatArray<unsigned int> entrysize);
NGCORE_API extern size_t * TablePrefixSum64 (FlatArray<size_t> entrysize);
NETGEN_INLINE size_t * TablePrefixSum (FlatArray<unsigned int> entrysize)
{ return TablePrefixSum32 (entrysize); }
NETGEN_INLINE size_t * TablePrefixSum (FlatArray<int> entrysize)
{ return TablePrefixSum32 (FlatArray<unsigned> (entrysize.Size(), (unsigned int*)(int*)(entrysize.Addr(0)))); }
NETGEN_INLINE size_t * TablePrefixSum (FlatArray<std::atomic<int>> entrysize)
{ return TablePrefixSum32 (FlatArray<unsigned> (entrysize.Size(), (unsigned int*)(std::atomic<int>*)entrysize.Addr(0))); }
NETGEN_INLINE size_t * TablePrefixSum (FlatArray<size_t> entrysize)
{ return TablePrefixSum64 (entrysize); }
/**
A compact Table container.
A table contains size entries of variable size.
The entry sizes must be known at construction.
*/
2019-09-29 20:43:45 +05:00
template <class T, class IndexType = size_t>
class Table : public FlatTable<T, IndexType>
2019-08-29 17:21:18 +05:00
{
protected:
2019-08-29 17:21:18 +05:00
using FlatTable<T,IndexType>::size;
using FlatTable<T,IndexType>::index;
using FlatTable<T,IndexType>::data;
2019-08-29 17:21:18 +05:00
public:
///
NETGEN_INLINE Table () : FlatTable<T,IndexType> (0,nullptr,nullptr) { ; }
/// Construct table of uniform entrysize
NETGEN_INLINE Table (size_t asize, size_t entrysize)
: FlatTable<T,IndexType>( asize, new size_t[asize+1], new T[asize*entrysize] )
{
for (size_t i : IntRange(size+1))
index[i] = i*entrysize;
}
2019-08-29 17:21:18 +05:00
/// Construct table of variable entrysize
template <typename TI>
NETGEN_INLINE Table (FlatArray<TI,IndexType> entrysize)
: FlatTable<T,IndexType> (0, nullptr, nullptr)
{
size = entrysize.Size();
index = TablePrefixSum (FlatArray<TI> (entrysize.Size(), entrysize.Data()));
size_t cnt = index[size];
data = new T[cnt];
}
2019-08-29 17:21:18 +05:00
explicit NETGEN_INLINE Table (const Table & tab2)
: FlatTable<T,IndexType>(0, nullptr, nullptr)
{
size = tab2.Size();
2019-08-29 17:21:18 +05:00
index = new size_t[size+1];
for (size_t i = 0; i <= size; i++)
index[i] = tab2.index[i];
2019-08-29 17:21:18 +05:00
size_t cnt = index[size];
data = new T[cnt];
for (size_t i = 0; i < cnt; i++)
data[i] = tab2.data[i];
}
2019-08-29 17:21:18 +05:00
NETGEN_INLINE Table (Table && tab2)
: FlatTable<T,IndexType>(0, nullptr, nullptr)
{
tab2.mt.Free(tab2.GetMemUsage());
Swap (size, tab2.size);
Swap (index, tab2.index);
Swap (data, tab2.data);
}
2019-08-29 17:21:18 +05:00
NETGEN_INLINE Table & operator= (Table && tab2)
{
mt.Swap(GetMemUsage(), tab2.mt, tab2.GetMemUsage());
Swap (size, tab2.size);
Swap (index, tab2.index);
Swap (data, tab2.data);
return *this;
}
2019-08-29 17:21:18 +05:00
/// Delete data
NETGEN_INLINE ~Table ()
{
mt.Free(GetMemUsage());
delete [] data;
delete [] index;
}
/// Size of table
using FlatTable<T,IndexType>::Size;
/// number of elements in all rows
NETGEN_INLINE size_t NElements() const { return index[size]; }
2019-08-29 17:21:18 +05:00
using FlatTable<T,IndexType>::operator[];
2021-02-18 14:30:01 +05:00
NETGEN_INLINE void StartMemoryTracing (int /* mem_id */)
{
mt.Alloc(GetMemUsage());
}
const MemoryTracer& GetMemoryTracer() const { return mt; }
private:
size_t GetMemUsage() const { return size == 0 ? 0 : sizeof(T)*index[size] + sizeof(IndexType) * size+1; }
MemoryTracer mt;
};
2019-08-29 17:21:18 +05:00
/// Print table
2019-09-29 20:43:45 +05:00
template <class T, typename IndexType>
inline ostream & operator<< (ostream & s, const Table<T,IndexType> & table)
{
for (auto i : table.Range())
{
s << i << ":";
for (auto el : table[i])
s << " " << el;
s << "\n";
}
s << std::flush;
return s;
}
2019-08-29 17:21:18 +05:00
2019-09-29 20:43:45 +05:00
template <class T, typename IndexType=size_t>
2019-08-29 17:21:18 +05:00
class TableCreator
{
protected:
int mode; // 1 .. cnt, 2 .. cnt entries, 3 .. fill table
std::atomic<size_t> nd;
2019-09-29 20:43:45 +05:00
Array<std::atomic<int>,IndexType> cnt;
Table<T,IndexType> table;
2019-08-29 17:21:18 +05:00
public:
TableCreator()
{ nd = 0; mode = 1; }
TableCreator (size_t acnt)
{ nd = acnt; SetMode(2); }
2019-09-29 20:43:45 +05:00
Table<T,IndexType> MoveTable()
2019-08-29 17:21:18 +05:00
{
return std::move(table);
}
bool Done () { return mode > 3; }
void operator++(int) { SetMode (mode+1); }
int GetMode () const { return mode; }
void SetMode (int amode)
{
mode = amode;
if (mode == 2)
{
// cnt.SetSize(nd); // atomic has no copy
2019-09-29 20:43:45 +05:00
cnt = Array<std::atomic<int>,IndexType> (nd);
2019-08-29 17:21:18 +05:00
for (auto & ci : cnt) ci.store (0, std::memory_order_relaxed);
}
if (mode == 3)
{
2019-09-29 20:43:45 +05:00
table = Table<T,IndexType> (cnt);
2019-08-29 17:21:18 +05:00
// for (auto & ci : cnt) ci = 0;
for (auto & ci : cnt) ci.store (0, std::memory_order_relaxed);
// cnt = 0;
}
}
void SetSize (size_t _nd)
{
if (mode == 1)
nd = _nd;
else
{
if (nd != _nd)
throw Exception ("cannot change size of table-creator");
}
}
2019-09-29 20:43:45 +05:00
void Add (IndexType blocknr, const T & data)
2019-08-29 17:21:18 +05:00
{
switch (mode)
{
case 1:
{
size_t oldval = nd;
while (blocknr+1>nd) {
nd.compare_exchange_weak (oldval, blocknr+1);
oldval = nd;
}
break;
}
case 2:
cnt[blocknr]++;
break;
case 3:
int ci = cnt[blocknr]++;
table[blocknr][ci] = data;
break;
}
}
2019-09-29 20:43:45 +05:00
void Add (IndexType blocknr, IntRange range)
2019-08-29 17:21:18 +05:00
{
switch (mode)
{
case 1:
{
size_t oldval = nd;
while (blocknr+1>nd) {
nd.compare_exchange_weak (oldval, blocknr+1);
oldval = nd;
}
break;
}
case 2:
cnt[blocknr] += range.Size();
break;
case 3:
size_t ci = ( cnt[blocknr] += range.Size() ) - range.Size();
for (size_t j = 0; j < range.Size(); j++)
table[blocknr][ci+j] = range.First()+j;
break;
}
}
2019-09-29 20:43:45 +05:00
void Add (IndexType blocknr, const FlatArray<int> & dofs)
2019-08-29 17:21:18 +05:00
{
switch (mode)
{
case 1:
{
size_t oldval = nd;
while (blocknr+1>nd) {
nd.compare_exchange_weak (oldval, blocknr+1);
oldval = nd;
}
break;
}
case 2:
cnt[blocknr] += dofs.Size();
break;
case 3:
size_t ci = ( cnt[blocknr] += dofs.Size() ) - dofs.Size();
for (size_t j = 0; j < dofs.Size(); j++)
table[blocknr][ci+j] = dofs[j];
break;
}
}
};
class NGCORE_API FilteredTableCreator : public TableCreator<int>
{
protected:
const BitArray* takedofs;
public:
FilteredTableCreator(const BitArray* atakedofs)
: TableCreator<int>(), takedofs(atakedofs) { };
FilteredTableCreator(int acnt, const BitArray* atakedofs)
: TableCreator<int>(acnt),takedofs(atakedofs) { };
void Add (size_t blocknr, int data);
void Add (size_t blocknr, IntRange range);
void Add (size_t blocknr, FlatArray<int> dofs);
};
/**
A dynamic table class.
A DynamicTable contains entries of variable size. Entry sizes can
be increased dynamically.
*/
template <class T, class IndexType = size_t>
class DynamicTable
2019-08-29 17:21:18 +05:00
{
protected:
static constexpr IndexType BASE = IndexBASE<IndexType>();
2019-08-29 17:21:18 +05:00
struct linestruct
{
int size;
int maxsize;
T * col;
2019-08-29 17:21:18 +05:00
};
2020-08-29 12:36:46 +05:00
Array<linestruct, IndexType> data;
T * oneblock = nullptr;
2019-08-29 17:21:18 +05:00
public:
/// Creates table of size size
DynamicTable (int size = 0)
2020-08-29 12:36:46 +05:00
: data(size)
{
for (auto & d : data)
{
d.maxsize = 0;
d.size = 0;
d.col = nullptr;
}
oneblock = nullptr;
}
/// Creates table with a priori fixed entry sizes.
DynamicTable (const Array<int, IndexType> & entrysizes)
2020-08-29 12:36:46 +05:00
: data(entrysizes.Size())
{
size_t cnt = 0;
// size_t n = entrysizes.Size();
2020-08-29 12:36:46 +05:00
for (auto es : entrysizes)
cnt += es;
oneblock = new T[cnt];
2020-08-29 12:36:46 +05:00
cnt = 0;
for (auto i : data.Range())
2020-08-29 12:36:46 +05:00
{
data[i].maxsize = entrysizes[i];
data[i].size = 0;
data[i].col = &oneblock[cnt];
2020-08-29 12:36:46 +05:00
cnt += entrysizes[i];
}
}
DynamicTable (DynamicTable && tab2)
{
Swap (data, tab2.data);
Swap (oneblock, tab2.oneblock);
}
~DynamicTable ()
2020-08-29 12:36:46 +05:00
{
if (oneblock)
delete [] oneblock;
else
for (auto & d : data)
delete [] d.col;
}
DynamicTable & operator= (DynamicTable && tab2)
{
Swap (data, tab2.data);
Swap (oneblock, tab2.oneblock);
return *this;
2020-08-29 12:36:46 +05:00
}
2019-08-29 17:21:18 +05:00
/// Changes Size of table to size, deletes data
2020-08-29 12:36:46 +05:00
void SetSize (int size)
{
for (auto & d : data)
delete [] d.col;
2020-08-29 12:36:46 +05:00
data.SetSize(size);
for (auto & d : data)
{
d.maxsize = 0;
d.size = 0;
d.col = nullptr;
2020-08-29 12:36:46 +05:00
}
}
void ChangeSize (size_t size)
{
if (oneblock)
throw Exception ("cannot change size of oneblock dynamic table");
size_t oldsize = data.Size();
if (size == oldsize)
return;
if (size < oldsize)
for (int i = size; i < oldsize; i++)
delete [] data[i+BASE].col;
data.SetSize(size);
for (int i = oldsize; i < size; i++)
{
data[i+BASE].maxsize = 0;
data[i+BASE].size = 0;
data[i+BASE].col = nullptr;
}
}
2019-08-29 17:21:18 +05:00
///
void IncSize (IndexType i)
2020-08-29 12:36:46 +05:00
{
NETGEN_CHECK_RANGE(i,BASE,data.Size()+BASE);
2020-08-29 12:36:46 +05:00
linestruct & line = data[i];
2020-08-29 12:36:46 +05:00
if (line.size == line.maxsize)
{
T * p;
if constexpr (std::is_default_constructible<T>::value)
p = new T[(2*line.maxsize+5)];
else
p = reinterpret_cast<T*>(new char[(2*line.maxsize+5)*sizeof(T)]);
for (size_t i = 0; i < line.maxsize; i++)
p[i] = std::move(line.col[i]);
// memcpy (p, line.col, line.maxsize * sizeof(T));
delete [] line.col;
2020-08-29 12:36:46 +05:00
line.col = p;
line.maxsize = 2*line.maxsize+5;
}
2020-08-29 12:36:46 +05:00
line.size++;
}
2020-08-29 12:36:46 +05:00
void DecSize (IndexType i)
{
NETGEN_CHECK_RANGE(i,BASE,data.Size()+BASE);
linestruct & line = data[i];
#ifdef NETGEN_ENABLE_CHECK_RANGE
2020-08-29 12:36:46 +05:00
if (line.size == 0)
throw Exception ("BaseDynamicTable::Dec: EntrySize < 0");
#endif
line.size--;
}
2019-08-29 17:21:18 +05:00
/// Inserts element acont into row i. Does not test if already used.
2020-08-29 12:36:46 +05:00
void Add (IndexType i, const T & acont)
2019-08-29 17:21:18 +05:00
{
if (data[i].size == data[i].maxsize)
this->IncSize (i);
2019-08-29 17:21:18 +05:00
else
data[i].size++;
data[i].col[data[i].size-1] = acont;
2019-08-29 17:21:18 +05:00
}
2019-08-29 17:21:18 +05:00
/// Inserts element acont into row i, iff not yet exists.
2020-08-29 12:36:46 +05:00
void AddUnique (IndexType i, const T & cont)
2019-08-29 17:21:18 +05:00
{
int es = EntrySize (i);
T * line = data[i].col;
2019-08-29 17:21:18 +05:00
for (int j = 0; j < es; j++)
if (line[j] == cont)
return;
Add (i, cont);
}
2019-08-29 17:21:18 +05:00
/// Inserts element acont into row i. Does not test if already used.
2020-08-29 12:36:46 +05:00
void AddEmpty (IndexType i)
2019-08-29 17:21:18 +05:00
{
IncSize (i);
2019-08-29 17:21:18 +05:00
}
2019-08-29 17:21:18 +05:00
/** Set the nr-th element in the i-th row to acont.
Does not check for overflow. */
2020-08-29 12:36:46 +05:00
void Set (IndexType i, int nr, const T & acont)
{
data[i].col[nr] = acont;
}
2019-08-29 17:21:18 +05:00
/** Returns the nr-th element in the i-th row.
Does not check for overflow. */
2020-08-29 12:36:46 +05:00
const T & Get (IndexType i, int nr) const
{
return data[i].col[nr];
}
2019-08-29 17:21:18 +05:00
/** Returns pointer to the first element in row i. */
2020-08-29 12:36:46 +05:00
const T * GetLine (IndexType i) const
{
return data[i].col;
}
2019-08-29 17:21:18 +05:00
/// Returns size of the table.
size_t Size () const
{
return data.Size();
}
auto Range () const
{
return data.Range();
}
2019-08-29 17:21:18 +05:00
/// Returns size of the i-th row.
2020-08-29 12:36:46 +05:00
int EntrySize (IndexType i) const
{
return data[i].size;
}
2019-08-29 17:21:18 +05:00
///
2020-08-29 12:36:46 +05:00
void DecEntrySize (IndexType i)
{
DecSize(i);
}
2019-08-29 17:21:18 +05:00
/// Access entry i
2020-08-29 12:36:46 +05:00
FlatArray<T> operator[] (IndexType i)
{
return FlatArray<T> (data[i].size, data[i].col);
}
2019-08-29 17:21:18 +05:00
/*
typedef const FlatArray<T> ConstFlatArray;
/// Access entry i
ConstFlatArray operator[] (int i) const
{ return FlatArray<T> (data[i].size, static_cast<T*> (data[i].col)); }
2019-08-29 17:21:18 +05:00
*/
2020-08-29 12:36:46 +05:00
FlatArray<T> operator[] (IndexType i) const
{
return FlatArray<T> (data[i].size, data[i].col);
}
2019-08-29 17:21:18 +05:00
};
/// Print table
template <class T>
inline ostream & operator<< (ostream & s, const DynamicTable<T> & table)
{
for (auto i : Range(table))
2019-08-29 17:21:18 +05:00
{
s << i << ":";
for (int j = 0; j < table[i].Size(); j++)
s << " " << table[i][j];
s << "\n";
}
s << std::flush;
return s;
}
typedef DynamicTable<int> IntTable;
} // namespace ngcore
#endif // NETGEN_CORE_TABLE_HPP