// PR optimization/12340
// Origin: Richard Guenther <richard.guenther@uni-tuebingen.de>
// Testcase by Eric Botcazou <ebotcazou@libertysurf.fr>
// This used to segfault on x86 because the loop optimizer wrongly
// interpreted a double assignment to a biv as a double increment,
// which subsequently fooled the unroller.
// { dg-do run }
// { dg-options "-O2 -fno-exceptions -funroll-loops" }
typedef __SIZE_TYPE__ size_t;
inline void* operator new(size_t, void* __p) throw() { return __p; }
inline void operator delete (void*, void*) throw() { };
class Loc;
class Interval;
template<class DT>
class DomainBase
{
public:
typedef typename DT::Domain_t Domain_t;
typedef typename DT::Storage_t Storage_t;
Domain_t &unwrap() { return *static_cast<Domain_t *>(this); }
const Domain_t &unwrap() const {
return *static_cast<Domain_t *>(const_cast<DomainBase<DT> *>(this));
}
protected:
Storage_t domain_m;
};
template<class DT>
class Domain : public DomainBase<DT>
{
typedef DomainBase<DT> Base_t;
public:
typedef typename DT::Size_t Size_t;
typedef typename DT::Element_t Element_t;
typedef typename Base_t::Domain_t Domain_t;
typedef typename Base_t::Storage_t Storage_t;
Domain_t &operator[](int) { return this->unwrap(); }
const Domain_t &operator[](int) const { return this->unwrap(); }
template<class T>
void setDomain(const T &newdom) {
DT::setDomain(this->domain_m, newdom);
}
Element_t first() const { return DT::first(this->domain_m); }
Size_t length() const { return DT::length(this->domain_m); }
Size_t size() const { return length(); }
};
template<class T>
struct DomainTraits;
template<>
struct DomainTraits<Interval>
{
typedef int Size_t;
typedef int Element_t;
typedef Interval Domain_t;
typedef Interval OneDomain_t;
typedef Loc AskDomain_t;
typedef int Storage_t[2];
enum { dimensions = 1 };
enum { wildcard = false };
static int first(const Storage_t &d) { return d[0]; }
static int length(const Storage_t &d) { return d[1]; }
static OneDomain_t &getDomain(Domain_t &d, int) { return d; }
static const OneDomain_t &getDomain(const Domain_t &d, int) { return d; }
template<class T>
static void setDomain(Storage_t &dom, const T &newdom) {
dom[0] = newdom.first();
dom[1] = newdom.length();
}
template<class T1, class T2>
static void setDomain(Storage_t &dom, const T1 &begval, const T2 &endval) {
dom[0] = begval;
dom[1] = (endval - begval + 1);
}
};
class Interval : public Domain<DomainTraits<Interval> >
{
public:
Interval(const Interval &a) : Domain<DomainTraits<Interval> >() {
for (int i=0; i < DomainTraits<Interval>::dimensions; ++i)
DomainTraits<Interval>::getDomain(*this, i).setDomain(
DomainTraits<Interval>::getDomain(a, i));
}
Interval(int a) : Domain<DomainTraits<Interval> >()
{
DomainTraits<Interval>::setDomain(domain_m, 0, a - 1);
}
};
template<>
struct DomainTraits<Loc>
{
typedef int Size_t;
typedef int Element_t;
typedef Loc Domain_t;
typedef Loc AskDomain_t;
typedef Loc MultResult_t;
typedef int Storage_t;
static int first(int d) { return d; }
template<class T>
static void setDomain(int &dom, const T &newdom) {
dom = DomainTraits<T>::getFirst(newdom);
}
};
template<>
struct DomainTraits<int>
{
enum { dimensions = 1 };
enum { wildcard = false };
static int getPointDomain(int d, int) { return d; }
static int getFirst(const int &d) { return d; }
};
class Loc : public Domain<DomainTraits<Loc> >
{
public:
explicit Loc(const int &a) : Domain<DomainTraits<Loc> >() {
for (int i=0; i < 1; ++i)
(*this)[i].setDomain(DomainTraits<int>::getPointDomain(a, 0));
}
};
struct ElementProperties
{
enum { hasTrivialDefaultConstructor = false };
enum { hasTrivialDestructor = false };
static void construct(double* addr)
{
new (addr) double();
}
static void construct(double* addr, const double& model)
{
new (addr) double(model);
}
static void destruct(double *addr) {}
};
class RefCounted
{
public:
RefCounted() : count_m(0) {}
void addReference() { ++count_m; }
bool removeRefAndCheckGarbage()
{
return (--count_m == 0);
}
private:
int count_m;
};
class RefBlockController : public RefCounted
{
public:
explicit RefBlockController(unsigned int size)
: pBegin_m(0), pEnd_m(0), pEndOfStorage_m(0), dealloc_m(false)
{
reallocateStorage(size, false);
if (!ElementProperties::hasTrivialDefaultConstructor)
{
for (double * pt = begin(); pt != end(); ++pt)
ElementProperties::construct(pt);
}
}
~RefBlockController()
{
deleteStorage();
}
double *begin() const
{
return pBegin_m;
}
double *end() const
{
return pEnd_m;
}
bool isMine() const
{
return dealloc_m;
}
private:
void deleteStorage()
{
if (isMine() && pBegin_m != 0)
{
if (!ElementProperties::hasTrivialDestructor)
for (double *pt = begin(); pt != end(); ++pt)
ElementProperties::destruct(pt);
char *tmp = reinterpret_cast<char *>(pBegin_m);
delete [] tmp;
}
}
void reallocateStorage(unsigned int newsize, bool copyold = false)
{
double *pBeginNew = 0;
double *pEndNew = 0;
double *pEndOfStorageNew = 0;
if (newsize > 0)
{
int nsize = newsize * sizeof(double);
char *tmp = new char[nsize];
pBeginNew = reinterpret_cast<double *>(tmp);
pEndNew = pBeginNew + newsize;
pEndOfStorageNew = pBeginNew + (nsize / sizeof(double));
if (copyold)
{
double * pOld = begin();
double * pNew = pBeginNew;
while (pOld != end() && pNew != pEndNew)
ElementProperties::construct(pNew++,*pOld++);
}
}
deleteStorage();
pBegin_m = pBeginNew;
pEnd_m = pEndNew;
pEndOfStorage_m = pEndOfStorageNew;
dealloc_m = true;
}
double *pBegin_m;
double *pEnd_m;
double *pEndOfStorage_m;
bool dealloc_m;
};
class DataBlockController : public RefBlockController
{
public:
explicit
DataBlockController(unsigned int size)
: RefBlockController(size), dataObjectPtr_m(new char), owned_m(true) {}
~DataBlockController()
{
if (owned_m) delete dataObjectPtr_m;
}
private:
mutable char *dataObjectPtr_m;
bool owned_m;
};
class RefCountedPtr
{
public:
RefCountedPtr(DataBlockController * const pT) : ptr_m(pT)
{ if (isValid()) ptr_m->addReference(); }
~RefCountedPtr() { invalidate(); }
DataBlockController* operator->() const { return ptr_m; }
void invalidate();
bool isValid() const { return ptr_m != 0; }
private:
friend class RefCountedBlockPtr;
DataBlockController * ptr_m;
};
inline void RefCountedPtr::invalidate()
{
if ( isValid() && ptr_m->removeRefAndCheckGarbage() )
delete ptr_m;
ptr_m = 0;
}
class RefCountedBlockPtr
{
public:
explicit RefCountedBlockPtr(unsigned int size)
: offset_m(0),
blockControllerPtr_m(new DataBlockController(size)) {}
int offset() const
{
return offset_m;
}
double *beginPointer() const
{
return blockControllerPtr_m->begin();
}
double *currentPointer() const
{
return beginPointer() + offset();
}
protected:
int offset_m;
RefCountedPtr blockControllerPtr_m;
};
class DataBlockPtr : public RefCountedBlockPtr
{
public:
explicit DataBlockPtr(unsigned int size) : RefCountedBlockPtr(size) {}
};
class Node
{
public:
Node(const Interval &owned, const Interval &allocated)
: domain_m(owned), allocated_m(allocated) {}
const Interval &allocated() const { return allocated_m; }
private:
Interval domain_m;
Interval allocated_m;
};
class DomainLayout
{
public:
explicit DomainLayout(const Interval &dom) : node_m(0, dom) {}
const Interval &domain() const
{
return node_m.allocated();
}
private:
Node node_m;
};
class BrickBase
{
public:
explicit BrickBase(const Interval &domain);
int offset(const Loc &dom) const { return off_m + dom[0].first(); }
protected:
DomainLayout layout_m;
int firsts_m;
int off_m;
};
BrickBase::BrickBase(const Interval &dom)
: layout_m(dom)
{
firsts_m = layout_m.domain()[0].first();
off_m = -firsts_m;
}
class Engine : public BrickBase
{
public:
explicit Engine(const Interval &dom)
: BrickBase(dom), dataBlock_m(dom.size()), data_m(dataBlock_m.currentPointer()) {}
double& operator()(const Loc &loc) const
{
return data_m[this->offset(loc)];
}
private:
DataBlockPtr dataBlock_m;
double *data_m;
};
int
main()
{
Interval I(10);
Engine A(I);
for (int i = 0; i < 10; i++)
A(Loc(i)) = 2.0 + i - i*i;
return 0;
}