haiku/headers/libs/agg/agg_array.h

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//----------------------------------------------------------------------------
// Anti-Grain Geometry - Version 2.2
// Copyright (C) 2002-2004 Maxim Shemanarev (http://www.antigrain.com)
//
// Permission to copy, use, modify, sell and distribute this software
// is granted provided this copyright notice appears in all copies.
// This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
//
//----------------------------------------------------------------------------
// Contact: mcseem@antigrain.com
// mcseemagg@yahoo.com
// http://www.antigrain.com
//----------------------------------------------------------------------------
#ifndef AGG_ARRAY_INCLUDED
#define AGG_ARRAY_INCLUDED
#include <stddef.h>
#include <string.h>
#include "agg_basics.h"
namespace agg
{
//---------------------------------------------------------------pod_array
// A simple class template to store Plain Old Data, a vector
// of a fixed size. The data is continous in memory
//------------------------------------------------------------------------
template<class T> class pod_array
{
public:
typedef T value_type;
~pod_array() { delete [] m_array; }
pod_array() : m_size(0), m_capacity(0), m_array(0) {}
pod_array(unsigned cap, unsigned extra_tail=0);
// Copying
pod_array(const pod_array<T>&);
const pod_array<T>& operator = (const pod_array<T>&);
unsigned capacity() const { return m_capacity; }
void capacity(unsigned cap, unsigned extra_tail=0);
void resize(unsigned new_size);
void add(const T& v) { m_array[m_size++] = v; }
void inc_size(unsigned size) { m_size += size; }
unsigned size() const { return m_size; }
unsigned byte_size() const { return m_size * sizeof(T); }
void serialize(int8u* ptr) const;
void deserialize(const int8u* data, unsigned byte_size);
const T& operator [] (unsigned idx) const { return m_array[idx]; }
T& operator [] (unsigned idx) { return m_array[idx]; }
void remove_all() { m_size = 0; }
void cut_at(unsigned num) { if(num < m_size) m_size = num; }
private:
unsigned m_size;
unsigned m_capacity;
T* m_array;
};
//------------------------------------------------------------------------
template<class T>
void pod_array<T>::capacity(unsigned cap, unsigned extra_tail)
{
m_size = 0;
if(cap > m_capacity)
{
delete [] m_array;
m_capacity = cap + extra_tail;
m_array = m_capacity ? new T [m_capacity] : 0;
}
}
//------------------------------------------------------------------------
template<class T>
void pod_array<T>::resize(unsigned new_size)
{
if(new_size > m_size)
{
if(new_size > m_capacity)
{
T* data = new T[new_size];
memcpy(data, m_array, m_size * sizeof(T));
delete [] m_array;
m_array = data;
}
}
else
{
m_size = new_size;
}
}
//------------------------------------------------------------------------
template<class T> pod_array<T>::pod_array(unsigned cap, unsigned extra_tail) :
m_size(0), m_capacity(0), m_array(0)
{
capacity(cap, extra_tail);
}
//------------------------------------------------------------------------
template<class T> pod_array<T>::pod_array(const pod_array<T>& v) :
m_size(v.m_size),
m_capacity(v.m_capacity),
m_array(v.m_capacity ? new T [v.m_capacity] : 0)
{
memcpy(m_array, v.m_array, sizeof(T) * v.m_size);
}
//------------------------------------------------------------------------
template<class T> const pod_array<T>&
pod_array<T>::operator = (const pod_array<T>&v)
{
capacity(v.m_capacity);
if(v.m_size) memcpy(m_array, v.m_array, sizeof(T) * v.m_size);
return *this;
}
//------------------------------------------------------------------------
template<class T> void pod_array<T>::serialize(int8u* ptr) const
{
if(m_size) memcpy(ptr, m_array, m_size * sizeof(T));
}
//------------------------------------------------------------------------
template<class T>
void pod_array<T>::deserialize(const int8u* data, unsigned byte_size)
{
byte_size /= sizeof(T);
capacity(byte_size);
if(byte_size) memcpy(m_array, data, byte_size * sizeof(T));
}
//------------------------------------------------------------------------
template<class T> class pod_array_adaptor
{
public:
typedef T value_type;
pod_array_adaptor(T* array, unsigned size) :
m_array(array), m_size(size) {}
unsigned size() const { return m_size; }
const T& operator [] (unsigned idx) const { return m_array[idx]; }
T& operator [] (unsigned idx) { return m_array[idx]; }
private:
T* m_array;
unsigned m_size;
};
//---------------------------------------------------------------pod_deque
// A simple class template to store Plain Old Data, similar to std::deque
// It doesn't reallocate memory but instead, uses blocks of data of size
// of (1 << S), that is, power of two. The data is NOT continuous in memory,
// so the only valid access method is operator [] or curr(), prev(), next()
//
// There reallocs occure only when the pool of pointers to blocks needs
// to be extended (it happens very rear). You can control the value
// of increment to reallocate the pointer buffer. See the second constructor.
// By default, the incremeent value equals (1 << S), i.e., the block size.
//------------------------------------------------------------------------
template<class T, unsigned S=6> class pod_deque
{
public:
enum
{
block_shift = S,
block_size = 1 << block_shift,
block_mask = block_size - 1
};
typedef T value_type;
~pod_deque();
pod_deque();
pod_deque(unsigned block_ptr_inc);
// Copying
pod_deque(const pod_deque<T, S>& v);
const pod_deque<T, S>& operator = (const pod_deque<T, S>& v);
void remove_all() { m_size = 0; }
void free_all() { free_tail(0); }
void free_tail(unsigned size);
void add(const T& val);
void modify_last(const T& val);
void remove_last();
int allocate_continuous_block(unsigned num_elements);
void add_array(const T* ptr, unsigned num_elem)
{
while(num_elem--)
{
add(*ptr++);
}
}
template<class DataAccessor> void add_data(DataAccessor& data)
{
while(data.size())
{
add(*data);
++data;
}
}
void cut_at(unsigned size)
{
if(size < m_size) m_size = size;
}
unsigned size() const { return m_size; }
const T& operator [] (unsigned idx) const
{
return m_blocks[idx >> block_shift][idx & block_mask];
}
T& operator [] (unsigned idx)
{
return m_blocks[idx >> block_shift][idx & block_mask];
}
const T& curr(unsigned idx) const
{
return (*this)[idx];
}
T& curr(unsigned idx)
{
return (*this)[idx];
}
const T& prev(unsigned idx) const
{
return (*this)[(idx + m_size - 1) % m_size];
}
T& prev(unsigned idx)
{
return (*this)[(idx + m_size - 1) % m_size];
}
const T& next(unsigned idx) const
{
return (*this)[(idx + 1) % m_size];
}
T& next(unsigned idx)
{
return (*this)[(idx + 1) % m_size];
}
const T& last() const
{
return (*this)[m_size - 1];
}
T& last()
{
return (*this)[m_size - 1];
}
unsigned byte_size() const;
void serialize(int8u* ptr) const;
void deserialize(const int8u* data, unsigned byte_size);
void deserialize(unsigned start, const T& empty_val,
const int8u* data, unsigned byte_size);
template<class ByteAccessor>
void deserialize(ByteAccessor data)
{
remove_all();
unsigned elem_size = data.size() / sizeof(T);
for(unsigned i = 0; i < elem_size; ++i)
{
int8u* ptr = (int8u*)data_ptr();
for(unsigned j = 0; j < sizeof(T); ++j)
{
*ptr++ = *data;
++data;
}
++m_size;
}
}
template<class ByteAccessor>
void deserialize(unsigned start, const T& empty_val, ByteAccessor data)
{
while(m_size < start)
{
add(empty_val);
}
unsigned elem_size = data.size() / sizeof(T);
for(unsigned i = 0; i < elem_size; ++i)
{
int8u* ptr;
if(start + i < m_size)
{
ptr = (int8u*)(&((*this)[start + i]));
}
else
{
ptr = (int8u*)data_ptr();
++m_size;
}
for(unsigned j = 0; j < sizeof(T); ++j)
{
*ptr++ = *data;
++data;
}
}
}
const T* block(unsigned nb) const { return m_blocks[nb]; }
private:
void allocate_block(unsigned nb);
T* data_ptr();
unsigned m_size;
unsigned m_num_blocks;
unsigned m_max_blocks;
T** m_blocks;
unsigned m_block_ptr_inc;
};
//------------------------------------------------------------------------
template<class T, unsigned S> pod_deque<T, S>::~pod_deque()
{
if(m_num_blocks)
{
T** blk = m_blocks + m_num_blocks - 1;
while(m_num_blocks--)
{
delete [] *blk;
--blk;
}
delete [] m_blocks;
}
}
//------------------------------------------------------------------------
template<class T, unsigned S>
void pod_deque<T, S>::free_tail(unsigned size)
{
if(size < m_size)
{
unsigned nb = (size + block_mask) >> block_shift;
while(m_num_blocks > nb)
{
delete [] m_blocks[--m_num_blocks];
}
m_size = size;
}
}
//------------------------------------------------------------------------
template<class T, unsigned S> pod_deque<T, S>::pod_deque() :
m_size(0),
m_num_blocks(0),
m_max_blocks(0),
m_blocks(0),
m_block_ptr_inc(block_size)
{
}
//------------------------------------------------------------------------
template<class T, unsigned S>
pod_deque<T, S>::pod_deque(unsigned block_ptr_inc) :
m_size(0),
m_num_blocks(0),
m_max_blocks(0),
m_blocks(0),
m_block_ptr_inc(block_ptr_inc)
{
}
//------------------------------------------------------------------------
template<class T, unsigned S>
pod_deque<T, S>::pod_deque(const pod_deque<T, S>& v) :
m_size(v.m_size),
m_num_blocks(v.m_num_blocks),
m_max_blocks(v.m_max_blocks),
m_blocks(v.m_max_blocks ? new T* [v.m_max_blocks] : 0),
m_block_ptr_inc(v.m_block_ptr_inc)
{
unsigned i;
for(i = 0; i < v.m_num_blocks; ++i)
{
m_blocks[i] = new T [block_size];
memcpy(m_blocks[i], v.m_blocks[i], block_size * sizeof(T));
}
}
//------------------------------------------------------------------------
template<class T, unsigned S>
const pod_deque<T, S>& pod_deque<T, S>::operator = (const pod_deque<T, S>& v)
{
unsigned i;
for(i = m_num_blocks; i < v.m_num_blocks; ++i)
{
allocate_block(i);
}
for(i = 0; i < v.m_num_blocks; ++i)
{
memcpy(m_blocks[i], v.m_blocks[i], block_size * sizeof(T));
}
m_size = v.m_size;
return *this;
}
//------------------------------------------------------------------------
template<class T, unsigned S>
void pod_deque<T, S>::allocate_block(unsigned nb)
{
if(nb >= m_max_blocks)
{
T** new_blocks = new T* [m_max_blocks + m_block_ptr_inc];
if(m_blocks)
{
memcpy(new_blocks,
m_blocks,
m_num_blocks * sizeof(T*));
delete [] m_blocks;
}
m_blocks = new_blocks;
m_max_blocks += m_block_ptr_inc;
}
m_blocks[nb] = new T [block_size];
m_num_blocks++;
}
//------------------------------------------------------------------------
template<class T, unsigned S>
inline T* pod_deque<T, S>::data_ptr()
{
unsigned nb = m_size >> block_shift;
if(nb >= m_num_blocks)
{
allocate_block(nb);
}
return m_blocks[nb] + (m_size & block_mask);
}
//------------------------------------------------------------------------
template<class T, unsigned S>
inline void pod_deque<T, S>::add(const T& val)
{
*data_ptr() = val;
++m_size;
}
//------------------------------------------------------------------------
template<class T, unsigned S>
inline void pod_deque<T, S>::remove_last()
{
if(m_size) --m_size;
}
//------------------------------------------------------------------------
template<class T, unsigned S>
void pod_deque<T, S>::modify_last(const T& val)
{
remove_last();
add(val);
}
//------------------------------------------------------------------------
template<class T, unsigned S>
int pod_deque<T, S>::allocate_continuous_block(unsigned num_elements)
{
if(num_elements < block_size)
{
data_ptr(); // Allocate initial block if necessary
unsigned rest = block_size - (m_size & block_mask);
unsigned index;
if(num_elements <= rest)
{
// The rest of the block is good, we can use it
//-----------------
index = m_size;
m_size += num_elements;
return index;
}
// New block
//---------------
m_size += rest;
data_ptr();
index = m_size;
m_size += num_elements;
return index;
}
return -1; // Impossible to allocate
}
//------------------------------------------------------------------------
template<class T, unsigned S>
unsigned pod_deque<T, S>::byte_size() const
{
return m_size * sizeof(T);
}
//------------------------------------------------------------------------
template<class T, unsigned S>
void pod_deque<T, S>::serialize(int8u* ptr) const
{
unsigned i;
for(i = 0; i < m_size; i++)
{
memcpy(ptr, &(*this)[i], sizeof(T));
ptr += sizeof(T);
}
}
//------------------------------------------------------------------------
template<class T, unsigned S>
void pod_deque<T, S>::deserialize(const int8u* data, unsigned byte_size)
{
remove_all();
byte_size /= sizeof(T);
for(unsigned i = 0; i < byte_size; ++i)
{
T* ptr = data_ptr();
memcpy(ptr, data, sizeof(T));
++m_size;
data += sizeof(T);
}
}
// Replace or add a number of elements starting from "start" position
//------------------------------------------------------------------------
template<class T, unsigned S>
void pod_deque<T, S>::deserialize(unsigned start, const T& empty_val,
const int8u* data, unsigned byte_size)
{
while(m_size < start)
{
add(empty_val);
}
byte_size /= sizeof(T);
for(unsigned i = 0; i < byte_size; ++i)
{
if(start + i < m_size)
{
memcpy(&((*this)[start + i]), data, sizeof(T));
}
else
{
T* ptr = data_ptr();
memcpy(ptr, data, sizeof(T));
++m_size;
}
data += sizeof(T);
}
}
//-----------------------------------------------------------pod_allocator
// Allocator for arbitrary POD data. Most usable in different cache
// systems for efficient memory allocations.
// Memory is allocated with blocks of fixed size ("block_size" in
// the constructor). If required size exceeds the block size the allocator
// creates a new block of the required size. However, the most efficient
// use is when the average reqired size is much less than the block size.
//------------------------------------------------------------------------
class pod_allocator
{
public:
void remove_all()
{
if(m_num_blocks)
{
int8u** blk = m_blocks + m_num_blocks - 1;
while(m_num_blocks--)
{
delete [] *blk;
--blk;
}
delete [] m_blocks;
}
m_num_blocks = 0;
m_max_blocks = 0;
m_blocks = 0;
m_buf_ptr = 0;
m_rest = 0;
}
~pod_allocator()
{
remove_all();
}
pod_allocator(unsigned block_size, unsigned block_ptr_inc=256-8) :
m_block_size(block_size),
m_block_ptr_inc(block_ptr_inc),
m_num_blocks(0),
m_max_blocks(0),
m_blocks(0),
m_buf_ptr(0),
m_rest(0)
{
}
int8u* allocate(unsigned size, unsigned alignment=1)
{
if(size == 0) return 0;
if(size <= m_rest)
{
int8u* ptr = m_buf_ptr;
if(alignment > 1)
{
unsigned align = (alignment - unsigned((size_t)ptr) % alignment) % alignment;
size += align;
ptr += align;
if(size <= m_rest)
{
m_rest -= size;
m_buf_ptr += size;
return ptr;
}
allocate_block(size);
return allocate(size - align, alignment);
}
m_rest -= size;
m_buf_ptr += size;
return ptr;
}
allocate_block(size + alignment - 1);
return allocate(size, alignment);
}
private:
void allocate_block(unsigned size)
{
if(size < m_block_size) size = m_block_size;
if(m_num_blocks >= m_max_blocks)
{
int8u** new_blocks = new int8u* [m_max_blocks + m_block_ptr_inc];
if(m_blocks)
{
memcpy(new_blocks,
m_blocks,
m_num_blocks * sizeof(int8u*));
delete [] m_blocks;
}
m_blocks = new_blocks;
m_max_blocks += m_block_ptr_inc;
}
m_blocks[m_num_blocks] = m_buf_ptr = new int8u [size];
m_num_blocks++;
m_rest = size;
}
unsigned m_block_size;
unsigned m_block_ptr_inc;
unsigned m_num_blocks;
unsigned m_max_blocks;
int8u** m_blocks;
int8u* m_buf_ptr;
unsigned m_rest;
};
//------------------------------------------------------------------------
enum
{
quick_sort_threshold = 9
};
//-----------------------------------------------------------swap_elements
template<class T> inline void swap_elements(T& a, T& b)
{
T temp = a;
a = b;
b = temp;
}
//--------------------------------------------------------------quick_sort
template<class Array, class Less>
void quick_sort(Array& arr, Less less)
{
if(arr.size() < 2) return;
typename Array::value_type* e1;
typename Array::value_type* e2;
int stack[80];
int* top = stack;
int limit = arr.size();
int base = 0;
for(;;)
{
int len = limit - base;
int i;
int j;
int pivot;
if(len > quick_sort_threshold)
{
// we use base + len/2 as the pivot
pivot = base + len / 2;
swap_elements(arr[base], arr[pivot]);
i = base + 1;
j = limit - 1;
// now ensure that *i <= *base <= *j
e1 = &(arr[j]);
e2 = &(arr[i]);
if(less(*e1, *e2)) swap_elements(*e1, *e2);
e1 = &(arr[base]);
e2 = &(arr[i]);
if(less(*e1, *e2)) swap_elements(*e1, *e2);
e1 = &(arr[j]);
e2 = &(arr[base]);
if(less(*e1, *e2)) swap_elements(*e1, *e2);
for(;;)
{
do i++; while( less(arr[i], arr[base]) );
do j--; while( less(arr[base], arr[j]) );
if( i > j )
{
break;
}
swap_elements(arr[i], arr[j]);
}
swap_elements(arr[base], arr[j]);
// now, push the largest sub-array
if(j - base > limit - i)
{
top[0] = base;
top[1] = j;
base = i;
}
else
{
top[0] = i;
top[1] = limit;
limit = j;
}
top += 2;
}
else
{
// the sub-array is small, perform insertion sort
j = base;
i = j + 1;
for(; i < limit; j = i, i++)
{
for(; less(*(e1 = &(arr[j + 1])), *(e2 = &(arr[j]))); j--)
{
swap_elements(*e1, *e2);
if(j == base)
{
break;
}
}
}
if(top > stack)
{
top -= 2;
base = top[0];
limit = top[1];
}
else
{
break;
}
}
}
}
//------------------------------------------------------remove_duplicates
// Remove duplicates from a sorted array. It doesn't cut the the
// tail of the array, it just returns the number of remaining elements.
//-----------------------------------------------------------------------
template<class Array, class Equal>
unsigned remove_duplicates(Array& arr, Equal equal)
{
if(arr.size() < 2) return arr.size();
unsigned i, j;
for(i = 1, j = 1; i < arr.size(); i++)
{
typename Array::value_type& e = arr[i];
if(!equal(e, arr[i - 1]))
{
arr[j++] = e;
}
}
return j;
}
}
#endif