/usr/include/gecode/kernel/region.hpp is in libgecode-dev 4.4.0-3.
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/*
* Main authors:
* Christian Schulte <schulte@gecode.org>
*
* Contributing authors:
* Filip Konvicka <filip.konvicka@logis.cz>
*
* Copyright:
* Christian Schulte, 2008
* LOGIS, s.r.o., 2009
*
* Last modified:
* $Date: 2013-02-20 18:27:38 +0100 (Wed, 20 Feb 2013) $ by $Author: schulte $
* $Revision: 13347 $
*
* This file is part of Gecode, the generic constraint
* development environment:
* http://www.gecode.org
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
* LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
* OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
*/
namespace Gecode {
/**
* \defgroup FuncMemRegion Region memory management
*
* A region provides a handle to temporary memory owned by
* a space. The memory will be managed in a stack fashion, that is,
* the memory allocated through a region will be released
* only after the region is deleted and all other regions
* created later also have been deleted.
*
* In case a memory request cannot be fulfilled from a space's region,
* heap memory is allocated and returned to the operating system
* as soon as the region is deleted.
*
* \ingroup FuncMem
*/
//@{
/// Handle to region
class Region {
private:
/// Location to space
Space& home;
/// Free memory to reset
size_t free_reset;
/// Heap information data structure
class HeapInfo {
public:
/// Number of allocated heap blocks
unsigned int n;
/// Limit of allocated heap blocks
unsigned int size;
/// Pointers to allocated heap blocks (more entries)
void* blocks[1];
};
/**
* \brief Heap allocation information
*
* If NULL, no heap memory has been allocated. If the pointer
* is marked, it points to a single heap allocated block. Otherwise,
* it points to a HeapInfo data structure.
*/
void* hi;
/// Allocate memory from heap
GECODE_KERNEL_EXPORT void* heap_alloc(size_t s);
/// Free memory previously allocated from heap
GECODE_KERNEL_EXPORT void heap_free(void);
public:
/// Initialize region from space
Region(const Space& home);
/// \name Typed allocation routines
//@{
/**
* \brief Allocate block of \a n objects of type \a T from region
*
* Note that this function implements C++ semantics: the default
* constructor of \a T is run for all \a n objects.
*/
template<class T>
T* alloc(long unsigned int n);
/**
* \brief Allocate block of \a n objects of type \a T from region
*
* Note that this function implements C++ semantics: the default
* constructor of \a T is run for all \a n objects.
*/
template<class T>
T* alloc(long int n);
/**
* \brief Allocate block of \a n objects of type \a T from region
*
* Note that this function implements C++ semantics: the default
* constructor of \a T is run for all \a n objects.
*/
template<class T>
T* alloc(unsigned int n);
/**
* \brief Allocate block of \a n objects of type \a T from region
*
* Note that this function implements C++ semantics: the default
* constructor of \a T is run for all \a n objects.
*/
template<class T>
T* alloc(int n);
/**
* \brief Delete \a n objects allocated from the region starting at \a b
*
* Note that this function implements C++ semantics: the destructor
* of \a T is run for all \a n objects.
*
* Note that the memory is not freed, the only effect is running the
* destructors.
*/
template<class T>
void free(T* b, long unsigned int n);
/**
* \brief Delete \a n objects allocated from the region starting at \a b
*
* Note that this function implements C++ semantics: the destructor
* of \a T is run for all \a n objects.
*
* Note that the memory is not freed, the only effect is running the
* destructors.
*/
template<class T>
void free(T* b, long int n);
/**
* \brief Delete \a n objects allocated from the region starting at \a b
*
* Note that this function implements C++ semantics: the destructor
* of \a T is run for all \a n objects.
*
* Note that the memory is not freed, the only effect is running the
* destructors.
*/
template<class T>
void free(T* b, unsigned int n);
/**
* \brief Delete \a n objects allocated from the region starting at \a b
*
* Note that this function implements C++ semantics: the destructor
* of \a T is run for all \a n objects.
*
* Note that the memory is not freed, the only effect is running the
* destructors.
*/
template<class T>
void free(T* b, int n);
/**
* \brief Reallocate block of \a n objects starting at \a b to \a m objects of type \a T from the region
*
* Note that this function implements C++ semantics: the copy constructor
* of \a T is run for all \f$\min(n,m)\f$ objects, the default
* constructor of \a T is run for all remaining
* \f$\max(n,m)-\min(n,m)\f$ objects, and the destrucor of \a T is
* run for all \a n objects in \a b.
*
* Returns the address of the new block.
*/
template<class T>
T* realloc(T* b, long unsigned int n, long unsigned int m);
/**
* \brief Reallocate block of \a n objects starting at \a b to \a m objects of type \a T from the region
*
* Note that this function implements C++ semantics: the copy constructor
* of \a T is run for all \f$\min(n,m)\f$ objects, the default
* constructor of \a T is run for all remaining
* \f$\max(n,m)-\min(n,m)\f$ objects, and the destrucor of \a T is
* run for all \a n objects in \a b.
*
* Returns the address of the new block.
*/
template<class T>
T* realloc(T* b, long int n, long int m);
/**
* \brief Reallocate block of \a n objects starting at \a b to \a m objects of type \a T from the region
*
* Note that this function implements C++ semantics: the copy constructor
* of \a T is run for all \f$\min(n,m)\f$ objects, the default
* constructor of \a T is run for all remaining
* \f$\max(n,m)-\min(n,m)\f$ objects, and the destrucor of \a T is
* run for all \a n objects in \a b.
*
* Returns the address of the new block.
*/
template<class T>
T* realloc(T* b, unsigned int n, unsigned int m);
/**
* \brief Reallocate block of \a n objects starting at \a b to \a m objects of type \a T from the region
*
* Note that this function implements C++ semantics: the copy constructor
* of \a T is run for all \f$\min(n,m)\f$ objects, the default
* constructor of \a T is run for all remaining
* \f$\max(n,m)-\min(n,m)\f$ objects, and the destrucor of \a T is
* run for all \a n objects in \a b.
*
* Returns the address of the new block.
*/
template<class T>
T* realloc(T* b, int n, int m);
//@}
/// \name Raw allocation routines
//@{
/// Allocate memory from region
void* ralloc(size_t s);
/**
* \brief Free memory previously allocated
*
* Note that the memory is only guaranteed to be freed after the
* region object itself gets deleted.
*/
void rfree(void* p, size_t s);
//@}
/// \name Construction routines
//@{
/**
* \brief Constructs a single object of type \a T from region using the default constructor.
*/
template<class T>
T& construct(void);
/**
* \brief Constructs a single object of type \a T from region using a unary constructor.
*
* The parameter is passed as a const reference.
*/
template<class T, typename A1>
T& construct(A1 const& a1);
/**
* \brief Constructs a single object of type \a T from region using a binary constructor.
*
* The parameters are passed as const references.
*/
template<class T, typename A1, typename A2>
T& construct(A1 const& a1, A2 const& a2);
/**
* \brief Constructs a single object of type \a T from region using a ternary constructor.
*
* The parameters are passed as const references.
*/
template<class T, typename A1, typename A2, typename A3>
T& construct(A1 const& a1, A2 const& a2, A3 const& a3);
/**
* \brief Constructs a single object of type \a T from region using a quaternary constructor.
*
* The parameters are passed as const references.
*/
template<class T, typename A1, typename A2, typename A3, typename A4>
T& construct(A1 const& a1, A2 const& a2, A3 const& a3, A4 const& a4);
/**
* \brief Constructs a single object of type \a T from region using a quinary constructor.
*
* The parameters are passed as const references.
*/
template<class T, typename A1, typename A2, typename A3, typename A4, typename A5>
T& construct(A1 const& a1, A2 const& a2, A3 const& a3, A4 const& a4, A5 const& a5);
//@}
/// Return memory
~Region(void);
private:
/// Allocate memory from heap (disabled)
static void* operator new(size_t s) throw() { (void) s; return NULL; }
/// Free memory allocated from heap (disabled)
static void operator delete(void* p) { (void) p; };
/// Copy constructor (disabled)
Region(const Region& r) : home(r.home) {}
/// Assignment operator (disabled)
const Region& operator =(const Region&) { return *this; }
};
//@}
/*
* Implementation
*
*/
forceinline
Region::Region(const Space& h)
: home(const_cast<Space&>(h)), free_reset(home.sm->region.free), hi(0) {}
forceinline void*
Region::ralloc(size_t s) {
void* p;
if (home.sm->region_alloc(s,p))
return p;
return heap_alloc(s);
}
forceinline void
Region::rfree(void*, size_t) {}
forceinline
Region::~Region(void) {
home.sm->region.free = free_reset;
if (hi != NULL)
heap_free();
}
/*
* Typed allocation routines
*
*/
template<class T>
forceinline T*
Region::alloc(long unsigned int n) {
T* p = static_cast<T*>(ralloc(sizeof(T)*n));
for (long unsigned int i=n; i--; )
(void) new (p+i) T();
return p;
}
template<class T>
forceinline T*
Region::alloc(long int n) {
assert(n >= 0);
return alloc<T>(static_cast<long unsigned int>(n));
}
template<class T>
forceinline T*
Region::alloc(unsigned int n) {
return alloc<T>(static_cast<long unsigned int>(n));
}
template<class T>
forceinline T*
Region::alloc(int n) {
assert(n >= 0);
return alloc<T>(static_cast<long unsigned int>(n));
}
template<class T>
forceinline void
Region::free(T* b, long unsigned int n) {
for (long unsigned int i=n; i--; )
b[i].~T();
rfree(b,n*sizeof(T));
}
template<class T>
forceinline void
Region::free(T* b, long int n) {
assert(n >= 0);
free<T>(b,static_cast<long unsigned int>(n));
}
template<class T>
forceinline void
Region::free(T* b, unsigned int n) {
free<T>(b,static_cast<long unsigned int>(n));
}
template<class T>
forceinline void
Region::free(T* b, int n) {
assert(n >= 0);
free<T>(b,static_cast<long unsigned int>(n));
}
template<class T>
forceinline T*
Region::realloc(T* b, long unsigned int n, long unsigned int m) {
if (n < m) {
T* p = static_cast<T*>(ralloc(sizeof(T)*m));
for (long unsigned int i=n; i--; )
(void) new (p+i) T(b[i]);
for (long unsigned int i=n; i<m; i++)
(void) new (p+i) T();
free<T>(b,n);
return p;
} else {
free<T>(b+m,m-n);
return b;
}
}
template<class T>
forceinline T*
Region::realloc(T* b, long int n, long int m) {
assert((n >= 0) && (m >= 0));
return realloc<T>(b,static_cast<long unsigned int>(n),
static_cast<long unsigned int>(m));
}
template<class T>
forceinline T*
Region::realloc(T* b, unsigned int n, unsigned int m) {
return realloc<T>(b,static_cast<long unsigned int>(n),
static_cast<long unsigned int>(m));
}
template<class T>
forceinline T*
Region::realloc(T* b, int n, int m) {
assert((n >= 0) && (m >= 0));
return realloc<T>(b,static_cast<long unsigned int>(n),
static_cast<long unsigned int>(m));
}
/*
* Region construction support
*
*/
template<class T>
forceinline T&
Region::construct(void) {
return alloc<T>(1);
}
template<class T, typename A1>
forceinline T&
Region::construct(A1 const& a1) {
T& t = *static_cast<T*>(ralloc(sizeof(T)));
new (&t) T(a1);
return t;
}
template<class T, typename A1, typename A2>
forceinline T&
Region::construct(A1 const& a1, A2 const& a2) {
T& t = *static_cast<T*>(ralloc(sizeof(T)));
new (&t) T(a1,a2);
return t;
}
template<class T, typename A1, typename A2, typename A3>
forceinline T&
Region::construct(A1 const& a1, A2 const& a2, A3 const& a3) {
T& t = *static_cast<T*>(ralloc(sizeof(T)));
new (&t) T(a1,a2,a3);
return t;
}
template<class T, typename A1, typename A2, typename A3, typename A4>
forceinline T&
Region::construct(A1 const& a1, A2 const& a2, A3 const& a3, A4 const& a4) {
T& t = *static_cast<T*>(ralloc(sizeof(T)));
new (&t) T(a1,a2,a3,a4);
return t;
}
template<class T, typename A1, typename A2, typename A3, typename A4, typename A5>
forceinline T&
Region::construct(A1 const& a1, A2 const& a2, A3 const& a3, A4 const& a4, A5 const& a5) {
T& t = *static_cast<T*>(ralloc(sizeof(T)));
new (&t) T(a1,a2,a3,a4,a5);
return t;
}
}
// STATISTICS: kernel-memory
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