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// Simple vectors.
#ifndef _CL_SV_H
#define _CL_SV_H
#include "cl_object.h"
#include "cl_V.h"
#include "cl_abort.h"
#include <stdlib.h>
// A simple vector has the same operations as a vector, but it can store
// _only_ cl_gcobject's.
// This class is here because the general vectors always need a function
// call for getting/setting the element of a vector. Our main application
// of the general vectors are the bit vectors, needed for implementing
// polynomials over modular integer rings. I don't want that polynomials
// over other rings (in particular cl_I) be penalized by the mere existence
// of polynomials over modular integer rings.
// When the vectors were implemented like this:
//
// cl_GV<cl_I> --> cl_GV<cl_RA> --> cl_GV<cl_R> --> cl_GV<cl_N>
//
// a bit/byte-vector (of integers with limited range) could actually be
// treated correctly by all the functions which manipulate vectors of cl_N.
// This is not crucial, however. Here, we'll have disjoint sets
//
// cl_SV<cl_I> --> cl_SV<cl_RA> --> cl_SV<cl_R> --> cl_SV<cl_N>
//
// cl_GV<cl_I>
//
// i.e. the functions which manipulate a (simple!) vector of cl_N cannot
// deal with a bit/byte-vector.
// (This is the same issue as UPGRADED-ARRAY-ELEMENT-TYPE in Common Lisp.)
template <class T> class cl_SV_inner;
template <class T>
class cl_SV_inner {
protected:
uintL len; // number of elements
private:
// T data[]; // the elements
T * data() { return (T *) (this+1); }
const T * data() const { return (const T *) (this+1); }
public:
uintL length () const { return len; } // number of elements
const T & operator[] (unsigned long index) const
{
#ifndef CL_SV_NO_RANGECHECKS
if (!(index < length())) cl_abort();
#endif
return data()[index];
}
T & operator[] (unsigned long index)
{
#ifndef CL_SV_NO_RANGECHECKS
if (!(index < length())) cl_abort();
#endif
return data()[index];
}
// New ANSI C++ compilers also want the following.
const T & operator[] (unsigned int index) const
{ return operator[]((unsigned long)index); }
T & operator[] (unsigned int index)
{ return operator[]((unsigned long)index); }
const T & operator[] (long index) const
{ return operator[]((unsigned long)index); }
T & operator[] (long index)
{ return operator[]((unsigned long)index); }
const T & operator[] (int index) const
{ return operator[]((unsigned long)index); }
T & operator[] (int index)
{ return operator[]((unsigned long)index); }
public: /* ugh */
// Constructor.
cl_SV_inner (uintL l) : len (l) {}
public:
// Destructor.
~cl_SV_inner ();
// Ability to place an object at a given address.
void* operator new (size_t size, cl_SV_inner* ptr) { (void)size; return ptr; }
private:
// No default constructor, copy constructor, assignment operator, new.
cl_SV_inner ();
cl_SV_inner (const cl_SV_inner&);
cl_SV_inner& operator= (const cl_SV_inner&);
void* operator new (size_t size);
};
// All member functions are inline.
template <class T>
inline cl_SV_inner<T>::~cl_SV_inner ()
{
uintL i = len;
while (i > 0) {
i--;
data()[i].~T();
}
}
// In memory, a simple vector looks like this:
template <class T>
struct cl_heap_SV : cl_heap {
cl_SV_inner<T> v;
// here room for the elements
};
template <class T, class BASE>
struct cl_SV : public BASE {
public:
// Length.
uintL length () const
{
return ((const cl_heap_SV<T> *) pointer)->v.length();
}
// Reference. Forbid modification of `const cl_SV&' arguments.
const T & operator[] (unsigned long index) const
{
return ((const cl_heap_SV<T> *) pointer)->v[index];
}
T & operator[] (unsigned long index)
{
return ((cl_heap_SV<T> *) pointer)->v[index];
}
// New ANSI C++ compilers also want the following.
const T & operator[] (unsigned int index) const
{ return operator[]((unsigned long)index); }
T & operator[] (unsigned int index)
{ return operator[]((unsigned long)index); }
const T & operator[] (long index) const
{ return operator[]((unsigned long)index); }
T & operator[] (long index)
{ return operator[]((unsigned long)index); }
const T & operator[] (int index) const
{ return operator[]((unsigned long)index); }
T & operator[] (int index)
{ return operator[]((unsigned long)index); }
// Constructors.
cl_SV (const cl_SV&);
// Assignment operators.
cl_SV& operator= (const cl_SV&);
// Private pointer manipulations.
cl_SV (cl_heap_SV<T>* p) : BASE ((cl_private_thing)p) {}
cl_SV (cl_private_thing p) : BASE (p) {}
protected:
// Forbid use of default constructor.
cl_SV ();
};
#define CL_SV(T,BASE) cl_SV<T,BASE>
// Define copy constructor.
template <class T, class BASE>
_CL_DEFINE_COPY_CONSTRUCTOR2(CL_SV(T,BASE),cl_SV,BASE)
// Define assignment operator.
template <class T, class BASE>
CL_DEFINE_ASSIGNMENT_OPERATOR(CL_SV(T,BASE),CL_SV(T,BASE))
#undef CL_SV
// The "generic" simple vector type.
typedef cl_heap_SV<cl_gcobject> cl_heap_SV_any;
typedef cl_SV<cl_gcobject,cl_V_any> cl_SV_any;
// Copy a simple vector.
extern const cl_SV_any copy (const cl_SV_any&);
// Hack section.
// Conversions to subtypes without checking:
#define The(type) *(const type *) & cl_identity
// This inline function is for type checking purposes only.
inline const cl_SV_any& cl_identity (const cl_SV_any& x) { return x; }
#endif /* _CL_SV_H */